860 Citations
UreE is a nickel chaperone required for the safe and efficient delivery of nickel to the active site of the metalloenzyme urease a key virulence factor of the urinary tract pathogen Proteus mirabilis We investigated the structural features of P mirabilis UreE using protein X-ray crystallography and its nickel-binding capacity by inductively coupled plasma-mass spectrometry Here we report a crystal structure of homodimeric PmUreE and show it has capacity to bind five nickel ions per dimer Truncation of the histidine-rich C-terminus reduced nickel binding capacity by two nickel ions per dimer and comparison with homologous UreE structures allowed the assignment ... More
UreE is a nickel chaperone required for the safe and efficient delivery of nickel to the active site of the metalloenzyme, urease; a key virulence factor of the urinary tract pathogen, Proteus mirabilis. We investigated the structural features of P. mirabilis UreE using protein X-ray crystallography and its nickel-binding capacity by inductively coupled plasma-mass spectrometry. Here, we report a 2.0 Å crystal structure of homodimeric PmUreE and show it has capacity to bind five nickel ions per dimer. Truncation of the histidine-rich C-terminus reduced nickel binding capacity by two nickel ions per dimer and comparison with homologous UreE structures allowed the assignment of putative nickel binding sites within the PmUreE structure. These findings increase our understanding of how PmUreE binds nickel and ultimately prevents this toxic metal from causing significant cellular damage in P. mirabilis. Less
Human T-cell Leukemia Virus type HTLV- is an untreatable retrovirus that causes lethal malignancies and degenerative inflammatory conditions Effective treatments have been delayed by substantial gaps in our knowledge of the fundamental virology especially when compared to the closely related virus HIV A recently developed and highly effective anti-HIV strategy is to target the virus with drugs that interfere with capsid integrity and interactions with the host Importantly the first in class anti-capsid drug approved lenacapavir can provide long-acting pre-exposure prophylaxis Such a property would provide a means to prevent the transmission of HTLV- but its capsid has not previously ... More
Human T-cell Leukemia Virus type 1 (HTLV-1) is an untreatable retrovirus that causes lethal malignancies and degenerative inflammatory conditions. Effective treatments have been delayed by substantial gaps in our knowledge of the fundamental virology, especially when compared to the closely related virus, HIV. A recently developed and highly effective anti-HIV strategy is to target the virus with drugs that interfere with capsid integrity and interactions with the host. Importantly, the first in class anti-capsid drug approved, lenacapavir, can provide long-acting pre-exposure prophylaxis. Such a property would provide a means to prevent the transmission of HTLV-1, but its capsid has not previously been considered as a drug target. Here we describe the first high-resolution crystal structures of the HTLV-1 capsid protein, define essential lattice interfaces, and identify a previously unknown ligand-binding pocket. We show that this pocket is essential for virus infectivity, providing a potential target for future anti-capsid drug development. Less
Photobleaching of fluorescent proteins often limits the acquisition of high-quality images in microscopy StayGold a novel dimeric GFP recently monomerized through sequence engineering addresses this challenge with its high photostability There is now a focus on producing different colored StayGold derivatives to facilitate concurrent tagging of multiple targets The unnatural amino acid -aminotyrosine has previously been shown to redshift superfolder GFP upon incorporation into its chromophore via genetic code expansion Here we apply the same strategy to redshift StayGold through substitution of tyrosine- with -aminotyrosine The resultant red fluorescent protein StayRose shows an excitation wavelength maximum of nm and an ... More
Photobleaching of fluorescent proteins often limits the acquisition of high-quality images in microscopy. StayGold, a novel dimeric GFP recently monomerized through sequence engineering, addresses this challenge with its high photostability. There is now a focus on producing different colored StayGold derivatives to facilitate concurrent tagging of multiple targets. The unnatural amino acid 3-aminotyrosine has previously been shown to redshift superfolder GFP upon incorporation into its chromophore via genetic code expansion. Here, we apply the same strategy to redshift StayGold through substitution of tyrosine-58 with 3-aminotyrosine. The resultant red fluorescent protein, StayRose, shows an excitation wavelength maximum of 530 nm and an emission wavelength maximum of 588 nm. Importantly, the monomeric mStayRose retains the favorable photostability in vivo in Escherichia coli and zebrafish embryos. A high-resolution crystal structure of StayRose confirms the modified structure of the amino chromophore within an unperturbed 3D fold. Although reliant on genetic code expansion, StayRose provides an important step toward developing redshifted StayGold derivatives. Less
Heliorhodopsins HeRs the third rhodopsin family are characterized by inverted membrane topology and confinement to monoderm organisms yet their biological meaning has so far remained a mystery We report the first crystal structure of a eukaryotic HeR supported by structural modeling and comparative analyses across all domains of life A conserved carotenoid-binding site reminiscent of secondary antennae in some microbial rhodopsins is identified and found to be common among HeRs We show that inverted topology allows recruitment of exogenous xanthophylls inaccessible in diderm cells explaining HeRs distinctive orientation and distribution These findings reveal a previously unrecognized light-harvesting mechanism of HeRs ... More
Heliorhodopsins (HeRs), the third rhodopsin family, are characterized by inverted membrane topology and confinement to monoderm organisms, yet their biological meaning has so far remained a mystery. We report the first crystal structure of a eukaryotic HeR, supported by structural modeling and comparative analyses across all domains of life. A conserved carotenoid-binding site, reminiscent of secondary antennae in some microbial rhodopsins, is identified and found to be common among HeRs. We show that inverted topology allows recruitment of exogenous xanthophylls, inaccessible in diderm cells, explaining HeRs’ distinctive orientation and distribution. These findings reveal a previously unrecognized light-harvesting mechanism of HeRs, expand the known repertoire of microbial phototrophy, and suggest evolutionary constraints linking membrane topology to environmental metabolite accessibility. Less
The composition of the primordial genetic material remains uncertain Studies of duplex structure and stability and of nonenzymatic template copying chemistry provide insight into the viability of potentially primordial genetic polymers Recent work suggests that - deoxyribo-purine nucleotides may have been generated together with ribonucleotides on the early Earth Since DNA RNA duplexes are known to be less stable than RNA RNA duplexes we have examined the impact of dA dI and dG substitutions on RNA structure and nonenzymatic template copying We find that single -deoxyribo-purine substitutions reduce RNA duplex stability as expected Crystallographic studies show that such substitutions lead ... More
The composition of the primordial genetic material remains uncertain. Studies of duplex structure and stability, and of nonenzymatic template copying chemistry, provide insight into the viability of potentially primordial genetic polymers. Recent work suggests that 2′- deoxyribo-purine nucleotides may have been generated together with ribonucleotides on the early Earth. Since DNA/RNA duplexes are known to be less stable than RNA/RNA duplexes, we have examined the impact of dA, dI, and dG substitutions on RNA structure and nonenzymatic template copying. We find that single 2′-deoxyribo-purine substitutions reduce RNA duplex stability, as expected. Crystallographic studies show that such substitutions lead to minimal structural changes but point to diminished solvation as a likely reason for duplex destabilization. Kinetic studies show that dI and dG substrates exhibit slightly weaker template binding and slower rates of template-directed primer extension than the corresponding ribo-purine substrates. In contrast, dA substrates exhibit much slower reaction kinetics but higher template affinity than rA substrates. Our results suggest that a mixed RNA/DNA primordial genetic polymer would have suffered from moderately slower rates of template copying, but that this could have been offset by an advantage due to more facile strand separation or exchange. Less
C domains are ubiquitous membrane-binding modules of residues in eukaryotes that are often associated with proteins involved in membrane trafficking and lipid modification The genome of Trichomonas vaginalis the most common non-viral sexually transmitted human pathogen encodes eight genes that contain a N-terminal C module linked to a XYPPX-repeat domain of more than four XYPPX repeats C -XYPPX While the function of the XYPPX-repeat domain remains unknown its multiple association with C domains in T vaginalis suggests it is important The C domain from one of these C -XYPPX-repeat proteins Tv-C - was structurally and physically characterized using X-ray crystallography ... More
C2 domains are ubiquitous membrane-binding modules of ∼130 residues in eukaryotes that are often associated with proteins involved in membrane trafficking and lipid modification. The genome of Trichomonas vaginalis, the most common, non-viral, sexually transmitted human pathogen, encodes eight genes that contain a N-terminal C2 module linked to a XYPPX-repeat domain of more than four XYPPX repeats (C2-XYPPX). While the function of the XYPPX-repeat domain remains unknown, its multiple association with C2 domains in T. vaginalis suggests it is important. The C2 domain from one of these C2-XYPPX-repeat proteins, Tv-C2-1, was structurally and physically characterized using X-ray crystallography and NMR spectroscopy. The crystal structure for Tv-C2-1 shows that this domain shares a fold common to all C2 domains, a compact Greek-key motif composed of eight anti-parallel β-strands in the type-2 topology. An NMR chemical shift perturbation study with Ca2+ showed that Tv-C2-1 bound two Ca2+ atoms primarily via two loops (loop-1 and loop-3) on the predicted calcium binding face of the protein with Kds of 58.0 ± 0.1 μM and 232 ± 6 μM. Estimations of the overall rotational correlation time, τc, in the apo (11.1 ns) and Ca2+-bound (9.2 ns) state suggests the protein becomes more compact upon Ca2+ binding, consistent with a decrease in dynamics in loop-3 and marginally in loop-1 suggested by amide 15N heteronuclear steady-state {1H}-15N NOEs. Showing Tv-C2-1 binds calcium and adopts a compact Greek-key motif structure, two primary features of C2 domains, suggests understanding the function of the XYPPX-repeat domain may be warranted. Less
Spermine a pivotal player in biomolecular condensation and diverse cellular processes has emerged as a focus of investigation in aging neurodegeneration and other diseases Despite its significance the mechanistic details of spermine remain incompletely understood Here we describe the distinct modulation by spermine on Alzheimer s Tau and Parkinson s -synuclein elucidating their condensation behaviors in vitro and in vivo Using biophysical techniques including time-resolved SAXS and NMR we trace electrostatically driven transitions from atomic-scale conformational changes to mesoscopic structures Notably spermine extends lifespan ameliorates movement deficits and restores mitochondrial function in C elegans models expressing Tau and -synuclein Acting ... More
Spermine, a pivotal player in biomolecular condensation and diverse cellular processes, has emerged as a focus of investigation in aging, neurodegeneration, and other diseases. Despite its significance, the mechanistic details of spermine remain incompletely understood. Here, we describe the distinct modulation by spermine on Alzheimer’s Tau and Parkinson’s α-synuclein, elucidating their condensation behaviors in vitro and in vivo. Using biophysical techniques including time-resolved SAXS and NMR, we trace electrostatically driven transitions from atomic-scale conformational changes to mesoscopic structures. Notably, spermine extends lifespan, ameliorates movement deficits, and restores mitochondrial function in C. elegans models expressing Tau and α-synuclein. Acting as a molecular glue, spermine orchestrates in vivo condensation of α-synuclein, influences condensate mobility, and promotes degradation via autophagy, specifically through autophagosome expansion. This study unveils the interplay between spermine, protein condensation, and functional outcomes, advancing our understanding of neurodegenerative diseases and paving the way for therapeutic development. Less
The ribosome is a universally conserved and essential protein complex but its biogenesis in mammals is more complex than in single-celled eukaryotes To explore this added complexity we conducted a protein protein interaction screen in human cells This led to the identification of the eumetazoan-specific SPATA SPATA L CINP C ORF LCC complex as a key regulator of ribosome biogenesis Structural analyses using cryo-EM and X-ray crystallography defined the architecture of LCC Functional studies following acute depletion revealed that each component is essential for pre- S maturation Swapping endogenous LCC components with mutant versions pinpointed critical functional interactions and showed ... More
The ribosome is a universally conserved and essential protein complex, but its biogenesis in mammals is more complex than in single-celled eukaryotes. To explore this added complexity, we conducted a protein–protein interaction screen in human cells. This led to the identification of the eumetazoan-specific SPATA5–SPATA5L1–CINP–C1ORF109 (55LCC) complex as a key regulator of ribosome biogenesis. Structural analyses using cryo-EM and X-ray crystallography defined the architecture of 55LCC. Functional studies following acute depletion revealed that each component is essential for pre-60S maturation. Swapping endogenous 55LCC components with mutant versions pinpointed critical functional interactions and showed that SPATA5’s ATPase activity is more important than SPATA5L1’s. Our findings support that SPATA5 evolved from the solitary yeast ATPase Drg1 into the multiprotein 55LCC complex in metazoans. This work provides insights into the complexity of ribosome biogenesis and lays the foundation for deeper exploration of 55LCC’s role in pre-60S maturation. Less
Macromolecular crystallography provides mechanistic understanding of biological processes and can be applied in drug design Nowadays the use of robotic systems for crystal growth and diffraction analysis is widespread and high throughput protein-to-structure pipelines for ligand and fragment screening are revolutionizing the field However the identification of crystals is still largely carried out through manual inspection sometimes involving tens of thousands of images which represents a bottleneck in an otherwise highly automated process Here we describe AXIS an AI-based Crystal Identification System combining the DINOv computer vision model state-of-the-art transfer learning and MARCO the largest crystallization dataset available to date ... More
Macromolecular crystallography provides mechanistic understanding of biological processes and can be applied in drug design. Nowadays, the use of robotic systems for crystal growth and diffraction analysis is widespread and high throughput protein-to-structure pipelines for ligand and fragment screening are revolutionizing the field. However, the identification of crystals is still largely carried out through manual inspection, sometimes involving tens of thousands of images, which represents a bottleneck in an otherwise highly automated process. Here we describe AXIS, an AI-based Crystal Identification System combining the DINOv2 computer vision model, state-of-the-art transfer learning and MARCO, the largest crystallization dataset available to date, for automated crystal detection. AXIS can operate both with visible and UV light images and integrates a Lab-In-The-Loop approach combining ML and expert inputs for continuous learning and specialization. AXIS enables automated annotation of large crystallization image datasets with performance and accuracy comparable to that of human experts and the Lab-In-The-Loop approach introduced here enables efficient adaptation to local conditions facilitating widespread application, which has been a major limitation to date. AXIS can help correct human errors in image annotation and removes critical bottlenecks, particularly in the context of extensive crystallization screens or high throughput applications like fragment and ligand screening unlocking the potential for higher levels of automation that are key both in fundamental and translational research. Less
Thrombin is generated from prothrombin through cleavage at two sites by the enzyme prothrombinase composed of factor Xa fXa and fVa The affinity of fXa for fVa is low with assembly and function dependent on phospholipid PL membranes Some snakes have evolved venom versions of fXa that bind to fVa with high affinity and efficiently activate prothrombin in the absence of PL We created a similar high-affinity PL-independent human prothrombinase with mutations to human fXa M The increase in affinity enabled cryogenic electron microscopy cryo-EM structure determination of M -prothrombinase to a resolution of All protein domains were well resolved ... More
Thrombin is generated from prothrombin through cleavage at two sites by the enzyme prothrombinase, composed of factor Xa (fXa) and fVa. The affinity of fXa for fVa is low, with assembly and function dependent on phospholipid (PL) membranes. Some snakes have evolved venom versions of fXa that bind to fVa with high affinity and efficiently activate prothrombin in the absence of PL. We created a similar high-affinity, PL-independent human prothrombinase with 17 mutations to human fXa (M17). The increase in affinity enabled cryogenic electron microscopy (cryo-EM) structure determination of M17-prothrombinase to a resolution of 3.3 Å. All protein domains were well resolved in the map, except for the Gla domain of fXa. The main contacts involve the serine protease and EGF2 domains of fXa and the A2 and A3 domains of fVa, resulting in the burying of a total surface area of 4,900 Å2. The map is of sufficient quality to resolve side chain interactions, including several key M17 mutations. To aid in the placement of the loop Cterminal to the A2 domain (a2-loop), we solved a high-resolution crystal structure of fXa in complex with a synthetic a2 peptide. The acidic a2-loop interacts with the basic heparin binding site of fXa, involving a conserved antiparallel -strand interaction. The M17-prothrombinase structure is compatible with data from biochemical and mutagenesis research and provides important new insights into the assembly and function of the prothrombinase complex. Less
Severe acute respiratory syndrome coronavirus SARS-CoV- continues to threaten global health This underpins the need for novel therapeutics against this virus Nonstructural protein Nsp of SARS-CoV- is a multifunctional protein with an essential role in viral replication As such it presents itself as an attractive target for drug discovery Here we describe two crystallographic fragment-screening campaigns against Nsp one using the established F X-Entry Screen and one using a new chemically and structurally diverse fragment library which we call the KIT library Together hits could be identified from screened fragments which constitutes the highest hit rate reported for Nsp to ... More
Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) continues to threaten global health. This underpins the need for novel therapeutics against this virus. Nonstructural protein 1 (Nsp1) of SARS-CoV-2 is a multifunctional protein with an essential role in viral replication. As such, it presents itself as an attractive target for drug discovery. Here, we describe two crystallographic fragment-screening campaigns against Nsp1, one using the established F2X-Entry Screen and one using a new, chemically and structurally diverse fragment library, which we call the KIT library. Together, 21 hits could be identified from 192 screened fragments, which constitutes the highest hit rate reported for Nsp1 to date. Many hits bind to a key functional region and interact with residues involved in cellular mRNA cleavage, ribosome binding and viral RNA recognition. Furthermore, most of the identified fragments share a common binding mode, providing promising starting points for further optimization into drug-like compounds that can disrupt the role of Nsp1 in viral replication. Less
Ferritins are a widespread family of proteins involved in iron homeostasis While classic ferritins consist of four -helices and form -meric nanocages related ferritin-like proteins display other types of assemblies and sometimes lack any iron storage capacity Here by analyzing the available genomic data we identify a family of double ferritin-like proteins DFLPs composed of two four-helical domains which arose by duplication of a ferritin fold protein We characterize representative DFLPs from Thermocrinis minervae and Caldanaerovirga acetigignens TmDFLP and CaDFLP and show that they form homodimers and bind heme We determine the X-ray structure of TmDFLP and demonstrate its ferroxidase ... More
Ferritins are a widespread family of proteins involved in iron homeostasis. While classic ferritins consist of four α-helices and form 24-meric nanocages, related ferritin-like proteins display other types of assemblies and sometimes lack any iron storage capacity. Here, by analyzing the available genomic data, we identify a family of double ferritin-like proteins (DFLPs) composed of two four-helical domains, which arose by duplication of a ferritin fold protein. We characterize representative DFLPs from Thermocrinis minervae and Caldanaerovirga acetigignens, TmDFLP and CaDFLP, and show that they form homodimers and bind heme. We determine the X-ray structure of TmDFLP and demonstrate its ferroxidase activity. Furthermore, we show that some DFLPs, including TmDFLP and CaDFLP, are highly likely to be targeted into encapsulin shells. Our work expands the range of known iron metabolism systems and highlights the power of genome mining for discovery of new proteins. Less
Efficient drug discovery relies on workflows that integrate structural insights with rapid and cost-effective exploration of chemical space Here we present a data-driven fragment-based lead discovery approach to target Neuronal Calcium Sensor NCS- protein-protein interactions PPIs This study represents a complete implementation of a single high-value design-make-test-analyze cycle that directly yields compounds with micromolar affinity with the potential to modulate NCS- interactions with key targets including the G-protein chaperone Ric- A and the dopamine D and cannabinoid CB receptors X-ray crystallographic fragment screening CFS revealed diverse interaction patterns within the NCS- hydrophobic crevice Algorithmically guided fragment evolution and automated synthesis ... More
Efficient drug discovery relies on workflows that integrate structural insights with rapid and cost-effective exploration of chemical space. Here, we present a data-driven fragment-based lead discovery approach to target Neuronal Calcium Sensor 1 (NCS-1) protein-protein interactions (PPIs). This study represents a complete implementation of a single high-value design-make-test-analyze cycle that directly yields compounds with micromolar affinity with the potential to modulate NCS-1 interactions with key targets, including the G-protein chaperone Ric-8A and the dopamine D2 and cannabinoid CB1 receptors. X-ray crystallographic fragment screening (CFS) revealed diverse interaction patterns within the NCS-1 hydrophobic crevice. Algorithmically guided fragment evolution and automated synthesis enabled the rapid generation of over 250 derivatives, with biophysical validation using LC-MS and Grating-coupled interferometry. Structural analyses highlighted key pharmacophores, with selected compounds exhibiting favorable drug-like properties and potential blood-brain barrier penetration, making them promising candidates for neurodegenerative and neurodevelopmental disorders. Our results demonstrate the feasibility of accelerated hit-to-lead development at synchrotrons, demonstrating a robust, scalable platform for PPI-targeting drug discovery. The generated chemically diverse scaffolds provide a strong foundation for future therapeutic optimization. Less
The enzymatic degradation of polyethylene terephthalate PET offers a sustainable solution for PET recycling Over the past two decades more than PETases have been characterized primarily exhibiting similar sequences and structures Here we report new PET-degrading hydrolases including HaloPETase from the marine Halopseudomonas lineage thereby extending the narrow sequence space by novel features at the active site The crystal structure of HaloPETase was determined to a resolution of revealing a unique active site architecture and a lack of the canonical -stacking clamp found in PETases so far Further variations in active site composition and loop structures were observed Additionally we ... More
The enzymatic degradation of polyethylene terephthalate (PET) offers a sustainable solution for PET recycling. Over the past two decades, more than 100 PETases have been characterized, primarily exhibiting similar sequences and structures. Here, we report new PET-degrading α/β hydrolases, including HaloPETase1 from the marine Halopseudomonas lineage, thereby extending the narrow sequence space by novel features at the active site. The crystal structure of HaloPETase1 was determined to a resolution of 1.16 Å, revealing a unique active site architecture and a lack of the canonical π-stacking clamp found in PETases so far. Further, variations in active site composition and loop structures were observed. Additionally, we found five more enzymes from the same lineage, two of which have a high similarity to type IIa bacterial PETases, while the other three resemble HaloPETase1. All these enzymes exhibited high salt tolerance ranging from 2.5 to 5 M NaCl leading to higher total product releases upon PET degradation at 40 or 50 °C. Based on these findings, we propose an extension of the existing PETase classification system to include type III PETases. Less
In more and more drug discovery projects crystallographic fragment screening CFS is employed as an early screening method Here we demonstrate that choosing the right crystal form has a profound influence on the hit rates and hence success and speed of downstream lead generation Two CFS campaigns with the same fragment library and an almost identical experimental setup were carried out against the two crystal forms of the SARS-CoV- main protease While both crystal forms exhibit similar diffraction properties the observed hit rates in the two campaigns were vastly different For the monoclinic crystals a hit rate of was determined ... More
In more and more drug discovery projects, crystallographic fragment screening (CFS) is employed as an early screening method. Here, we demonstrate that choosing the right crystal form has a profound influence on the hit rates and hence success and speed of downstream lead generation. Two CFS campaigns with the same fragment library and an almost identical experimental setup were carried out against the two crystal forms of the SARS-CoV-2 main protease.While both crystal forms exhibit similar diffraction properties, the observed hit rates in the two campaigns were vastly different. For the monoclinic crystals a hit rate of 3% was determined, while a hit rate of 16% was observed for the orthorhombic crystals. These findings align with the more open molecular packing in the orthorhombic crystals where the solvent channels leading to the active sites are about twice larger than in the monoclinic crystal form. Our results highlight the critical importance of the crystal system in a crystallographic fragment-screening campaign and identify this parameter as one of the most important ones to be optimized during preparation of a campaign. Less
Glutarimide analogs such as thalidomide redirect the E ubiquitin ligase CRL CRBN to induce degradation of certain zinc finger ZF proteins Although the core structural motif recognized by CRBN has been characterized it does not fully explain substrate specificity To explore the role of residues adjacent to this core motif we constructed a comprehensive ZF reporter library of reporters derived from human ZF proteins and conducted a library-on-library screen with glutarimide analogs to identify compounds that collectively degrade ZF reporters Cryo-electron microscopy and crystal structures of ZFs in complex with CRBN revealed the importance of interactions beyond the core ZF ... More
Glutarimide analogs, such as thalidomide, redirect the E3 ubiquitin ligase CRL4CRBN to induce degradation of certain zinc finger (ZF) proteins. Although the core structural motif recognized by CRBN has been characterized, it does not fully explain substrate specificity. To explore the role of residues adjacent to this core motif, we constructed a comprehensive ZF reporter library of 9,097 reporters derived from 1,655 human ZF proteins and conducted a library-on-library screen with 29 glutarimide analogs to identify compounds that collectively degrade 38 ZF reporters. Cryo-electron microscopy and crystal structures of ZFs in complex with CRBN revealed the importance of interactions beyond the core ZF degron. We used systematic mutagenesis of ZFs and CRBN to identify modes of neosubstrate recruitment requiring distinct amino acids. Finally, we found subtle chemical variations in glutarimide analogs that alter target scope and selectivity, thus providing a roadmap for their rational design. Less
Deep learning has revolutionized soluble protein design yet de novo transmembrane TM protein engineering remains hindered by scarce structural data complex membrane-specific interactions and conformational dynamics We developed TMDiffusion TMDF a joint all-heavy-atom sequence structure diffusion model trained to capture the full interaction diversity of natural TM proteins including weak and polar contact networks TMDF designs diverse TM architectures associating domains inhibitors and conformational switches in a single step achieving experimental success A crystal structure of designed proteins matches predictions with atomic accuracy Leveraging TMDF we built synthetic single-pass receptors whose de novo TM domains toggle between conformations enabling precise ... More
Deep learning has revolutionized soluble protein design, yet de novo transmembrane (TM) protein engineering remains hindered by scarce structural data, complex membrane-specific interactions and conformational dynamics. We developed TMDiffusion (TMDF), a joint all-heavy-atom sequence–structure diffusion model trained to capture the full interaction diversity of natural TM proteins, including weak and polar contact networks. TMDF designs diverse TM architectures—associating domains, inhibitors, and conformational switches—in a single step, achieving >70% experimental success. A crystal structure of designed proteins matches predictions with atomic accuracy. Leveraging TMDF, we built synthetic single-pass receptors whose de novo TM domains toggle between conformations, enabling precise control of signalling outputs consistent with predicted equilibria. These results show that membrane-adapted DL models can accurately encode and program TM association energetics and conformations. TMDF establishes a general framework for bottom-up design of TM proteins with programmable functions, advancing both mechanistic studies of membrane proteins and development of next-generation therapeutics. Less
Transcription factors TFs regulate gene expression by engaging chromatin remodeling complexes yet the structural principles governing these critical interactions remain poorly defined Here we uncover the molecular mechanism by which lineage-specific pioneer transcription factor PU encoded by SPI directly engages the BAF mSWI SNF chromatin remodeling complex First using a variety of genomic approaches we establish that BAF collaborates with PU to regulate transcription in AML cells Then using a combination of biochemistry and biophysics mass spectrometry-based protein footprinting and crystallography we map the PU -BAF A interface to a disordered region of PU that adopts a helical conformation upon ... More
Transcription factors (TFs) regulate gene expression by engaging chromatin remodeling complexes, yet the structural principles governing these critical interactions remain poorly defined. Here, we uncover the molecular mechanism by which lineage-specific pioneer transcription factor PU.1 (encoded by SPI1) directly engages the BAF (mSWI/SNF) chromatin remodeling complex. First, using a variety of genomic approaches, we establish that BAF collaborates with PU.1 to regulate transcription in AML cells. Then, using a combination of biochemistry and biophysics, mass spectrometry-based protein footprinting, and crystallography, we map the PU.1-BAF60A interface to a disordered region of PU.1 that adopts a helical conformation upon binding to the YEATS-like domain of BAF60A. Disruption of this functionally critical interface via knockdown abrogates the ability of PU.1 to rescue cell viability. Finally, we conducted a high-throughput screen that yielded small molecules which selectively bind BAF60A and disrupt PU.1 binding. Co-crystal structures reveal distinct compound binding modes that converge on a critical PU.1-BAF60A interaction hotspot. These findings define, for the first time, the structural interface between a pioneer transcription factor and the BAF complex and establish a platform that enables targeting transcription factor-chromatin remodeling complex interactions in cancer. Less
Dual-specificity mitogen-activated protein kinase MAPK phosphatases MKPs directly dephosphorylate and inactivate the MAPKs Although the catalytic mechanism of dephosphorylation of the MAPKs by the MKPs is established a complete molecular picture of the regulatory interplay between the MAPKs and MKPs still remains to be fully explored Here we sought to define the molecular mechanism of MKP regulation through an allosteric site within its catalytic domain We demonstrate using crystallographic and NMR spectroscopy approaches that residue Y is required to maintain the structural integrity of the allosteric pocket Along with molecular dynamics simulations these data provide insight into how changes in ... More
Dual-specificity mitogen-activated protein kinase (MAPK) phosphatases (MKPs) directly dephosphorylate and inactivate the MAPKs. Although the catalytic mechanism of dephosphorylation of the MAPKs by the MKPs is established, a complete molecular picture of the regulatory interplay between the MAPKs and MKPs still remains to be fully explored. Here, we sought to define the molecular mechanism of MKP5 regulation through an allosteric site within its catalytic domain. We demonstrate using crystallographic and NMR spectroscopy approaches that residue Y435 is required to maintain the structural integrity of the allosteric pocket. Along with molecular dynamics simulations, these data provide insight into how changes in the allosteric pocket propagate conformational flexibility in the surrounding loops to reorganize catalytically crucial residues in the active site. Furthermore, Y435 contributes to the interaction with p38 MAPK and JNK, thereby promoting dephosphorylation. Collectively, these results highlight the role of Y435 in the allosteric site as a novel mode of MKP5 regulation by p38 MAPK and JNK Less
Transport and Golgi Organization Homolog TANGO protein deficiency disorder TDD is a rare autosomal recessive disorder characterized by multi-systemic abnormalities and significant phenotypic variability including neurodevelopmental delay seizures intermittent ataxia hypothyroidism rhabdomyolysis life-threatening metabolic derangements and cardiac arrhythmias Mutations in TANGO result in mitochondrial dysfunction abnormal lipid homeostasis with cardiolipin deficiency and impaired Golgi-ER trafficking in TANGO patient-derived cells Despite the wide recognition of the clinical manifestations of TDD and numerous molecular studies the precise function of TANGO and the pathophysiology of TDD remain poorly understood A computationally derived three-dimensional structure model suggested that TANGO adopts an -fold similar to ... More
Transport and Golgi Organization 2 Homolog (TANGO2) protein deficiency disorder (TDD) is a rare autosomal recessive disorder characterized by multi-systemic abnormalities and significant phenotypic variability including neurodevelopmental delay, seizures, intermittent ataxia, hypothyroidism, rhabdomyolysis, life-threatening metabolic derangements, and cardiac arrhythmias. Mutations in TANGO2 result in mitochondrial dysfunction, abnormal lipid homeostasis with cardiolipin deficiency, and impaired Golgi-ER trafficking in TANGO2 patient-derived cells. Despite the wide recognition of the clinical manifestations of TDD and numerous molecular studies, the precise function of TANGO2 and the pathophysiology of TDD remain poorly understood. A computationally derived three-dimensional structure model suggested that TANGO2 adopts an αββα-fold, similar to the N-terminal nucleophile aminohydrolase (Ntn) superfamily of proteins, but the experimentally verified structure has not been available thus far. Here, we present the first crystal structure of the recombinant human TANGO2, determined at 1.70 Å resolution. The X-ray structure data confirmed its predicted tertiary fold with similarity to the Ntn-hydrolase family of proteins, and the comparative analysis of the active site architecture, including residues involved in catalysis and putative ligand binding site, suggests a potential hydrolase function. Additional examination of the common mutation sites found in TDD patients provides insight regarding their potential effect on protein structure integrity. Less
This protocol describes the crystallization of Enterovirus EV- A protease mutant C A containing the VP - A junction in the active site The crystals form within - hours using a crystallization screen composed of M NaCl and ethanol The crystal structure was determined using X-ray diffraction resulting in hexagonal prism crystals in space group P with unit cell dimensions of and an average resolution of The protein was expressed using the plasmid Enterovirus Coxsackievirus A A protease
This protocol describes the crystallization of Enterovirus EV- A protease mutant C A containing the VP - A junction in the active site The crystals form within - hours using a crystallization screen composed of M NaCl and ethanol The crystal structure was determined using X-ray diffraction resulting in hexagonal prism crystals in space group P with unit cell dimensions of and an average resolution of The protein was expressed using the plasmid Enterovirus Coxsackievirus A A protease
This review highlights the development and evolution of three macromolecular crystallography MX beamlines at the Swiss Light Source SLS over the past two decades We discuss key advancements in X-ray optics detectors goniometers sample changers and MX methodology emphasizing their impact on high-throughput and high-resolution structural biology Our contributions are presented within the broader context of global efforts in synchrotron-based MX Looking ahead we explore the future experiments enabled by SLS and new opportunities at SwissFEL to enhance experimental capabilities and drive scientific discoveries
Fungal cell walls composed of polysaccharides and proteins play critical roles in adaptation cell division and protection against environmental stress Their polyglucan components are continuously remodeled by various types of glycosyl hydrolases GHs and transferases GTs In Saccharomyces cerevisiae and other ascomycetes enzymes of the Dfg subfamily which belong as GTs to the GH family cleave an linkage between glucosamine and mannose to facilitate covalent linkage of GPI-anchored proteins to the cell wall s polyglucans In contrast the functions of other fungal GH subfamilies are not understood We characterized CtGH from the sordariomycete Chaetomium thermophilum a member of the Fungi ... More
Fungal cell walls, composed of polysaccharides and proteins, play critical roles in adaptation, cell division, and protection against environmental stress. Their polyglucan components are continuously remodeled by various types of glycosyl hydrolases (GHs) and transferases (GTs). In Saccharomyces cerevisiae and other ascomycetes, enzymes of the Dfg5 subfamily, which belong as GTs to the GH76 family, cleave an α1,4 linkage between glucosamine and mannose to facilitate covalent linkage of GPI-anchored proteins to the cell wall’s polyglucans. In contrast, the functions of other fungal GH76 subfamilies are not understood. We characterized CtGH76 from the sordariomycete Chaetomium thermophilum, a member of the Fungi/Bacteria-mixed GH76 subfamily, revealing conserved structural features and functional divergence within the GH76 family. Notably, our structural characterization by X-ray crystallography combined with glycan fragment screening indicated that CtGH76 can recognize GPI-anchors like members of the Dfg5 subfamily but shows a broader promiscuity toward other glycans with central α1,6-mannobiose motifs due to the presence of an elongated glycan binding canyon. These findings provide new insights into GH76 enzyme diversity and fungal cell wall maturation. Less
Malaria remains a global health threat exacerbated by emerging resistance to antimalarial therapies and insecticides climate-driven outbreaks and limited chemoprotective options Here we report the characterization of RUPB- the first orally bioavailable inhibitor of Plasmodium falciparum cGMP-dependent protein kinase PfPKG RUPB- prevents infection by P falciparum and P cynomolgi sporozoites including the formation of hypnozoites by the latter A single oral dose blocks liver infection by P berghei sporozoites in vivo demonstrating efficacy consistent with further development as a once-weekly prophylaxis based on pharmacokinetic modeling The compound retains activity against field isolates resistant to chloroquine mefloquine cycloguanil sulfadoxine and pyrimethamine ... More
Malaria remains a global health threat exacerbated by emerging resistance to antimalarial therapies and insecticides, climate-driven outbreaks, and limited chemoprotective options. Here, we report the characterization of RUPB-61, the first orally bioavailable inhibitor of Plasmodium falciparum cGMP-dependent protein kinase (PfPKG). RUPB-61 prevents infection by P. falciparum and P. cynomolgi sporozoites, including the formation of hypnozoites by the latter. A single oral dose blocks liver infection by P. berghei sporozoites in vivo, demonstrating efficacy consistent with further development as a once-weekly prophylaxis based on pharmacokinetic modeling. The compound retains activity against field isolates resistant to chloroquine, mefloquine, cycloguanil, sulfadoxine and pyrimethamine, suggesting low likelihood of cross-resistance to existing antimalarials. Structural studies and free energy-based modeling guided compound design and prospectively validated the predictive accuracy of an in silico model of PfPKG interactions with this chemotype. While selectivity profiling identified off-target activity against human kinases, structural modeling provides a clear path for optimization. These results establish PfPKG inhibitors as promising candidates for chemoprotection and support further preclinical development of the RUPB-61 chemotype. Less
Malaria poses an enormous threat to human health With ever-increasing resistance to currently deployed antimalarials new targets and starting point compounds with novel mechanisms of action need to be identified Here we explore the antimalarial activity of the Streptomyces sp natural product -O-sulfamoyl- -chloroadenosine dealanylascamycin DACM and compare it with the synthetic adenosine monophosphate AMP mimic -O-sulfamoyladenosine AMS These nucleoside sulfamates exhibit potent inhibition of P falciparum growth with an efficacy comparable to that of the current front-line antimalarial dihydroartemisinin Exposure of P falciparum to DACM leads to inhibition of protein translation driven by eIF phosphorylation We show that DACM ... More
Malaria poses an enormous threat to human health. With ever-increasing resistance to currently deployed antimalarials, new targets and starting point compounds with novel mechanisms of action need to be identified. Here, we explore the antimalarial activity of the Streptomyces sp natural product, 5ʹ-O-sulfamoyl-2-chloroadenosine (dealanylascamycin, DACM) and compare it with the synthetic adenosine monophosphate (AMP) mimic, 5-O-sulfamoyladenosine (AMS). These nucleoside sulfamates exhibit potent inhibition of P. falciparum growth with an efficacy comparable to that of the current front-line antimalarial dihydroartemisinin. Exposure of P. falciparum to DACM leads to inhibition of protein translation, driven by eIF2α phosphorylation. We show that DACM targets multiple amino acyl tRNA synthetase (aaRS) targets, including the cytoplasmic aspartyl tRNA synthetase (AspRS). The mechanism involves hijacking of the reaction product, leading to the formation of a tightly bound inhibitory amino acid-sulfamate conjugate. We show that recombinant P. falciparum and P. vivax AspRS are susceptible to hijacking by DACM and AMS, generating Asp-DACM and Asp-AMS adducts that stabilize these proteins. By contrast, human AspRS appears less susceptible to hijacking. X-ray crystallography reveals that apo P. vivax AspRS exhibits a stabilized flipping loop over the active site that is poised to bind substrates. By contrast, human AspRS exhibits disorder in an extended region around the flexible flipping loop as well as in a loop in motif II. These structural differences may underpin the decreased susceptibility of human AspRS to reaction-hijacking by DACM and AMS. Our work reveals Plasmodium AspRS as a promising antimalarial target and highlights structural features that underpin differences in the susceptibility of aaRSs to reaction hijacking inhibition. Less
Glaucoma is a neurodegenerative condition involving optic nerve damage and retinal ganglion cells death Animal studies suggested that the pathway linking these events can be mediated by mobile zinc secreted into the intraretinal space and exerting cytotoxic effects Whether this mechanism is relevant for human glaucoma and what are the targets of extracellular zinc is unknown We report that increased zinc content in the aqueous humor and retina is indeed a characteristic of glaucomatous neuropathy and excess extracellular zinc may be recognized by the key retinal neurotrophic factor PEDF Biophysical and X-ray crystallographic studies show that PEDF coordinates zinc ions ... More
Glaucoma is a neurodegenerative condition involving optic nerve damage and retinal ganglion cells death. Animal studies suggested that the pathway linking these events can be mediated by mobile zinc secreted into the intraretinal space and exerting cytotoxic effects. Whether this mechanism is relevant for human glaucoma and what are the targets of extracellular zinc is unknown. We report that increased zinc content in the aqueous humor and retina is indeed a characteristic of glaucomatous neuropathy, and excess extracellular zinc may be recognized by the key retinal neurotrophic factor PEDF. Biophysical and X-ray crystallographic studies show that PEDF coordinates zinc ions in five types of intermolecular high-affinity sites, leading to a decrease in negative surface charge and reversible oligomerization of the protein, thereby masking the target recognition sites responsible for its neurotrophic and antiangiogenic activities and collagen binding. Notably, PEDF secretion is enhanced in both glaucoma and retinal cell models in response to zinc stress; however, zinc binding negatively affects axogenic, differentiative and prosurvival functions of PEDF by suppressing its ability to activate receptor PEDF-R/PNPLA2. We suggest that glaucomatous neurodegeneration is associated with direct inhibition of PEDF signaling by extracellular zinc, making their complex a promising target for neuroprotective therapy. Less
Glycyl tRNA synthetases GlyRSs are prospective drug targets for combating Mycobacterium tuberculosis Mtb and cancer in humans These synthetases are of the -subtype with the ortholog in humans being dual targeted to the cytosol and mitochondria Whereas the human enzyme has been structurally characterized previously in several liganded states no structures of MtbGlyRS have thus far been reported Here we describe our recent work with MtbGlyRS and the closely-related Mycobacterium thermoresitibile GlyRS MtrGlyRS which progressed through all phases of the structural genomics pipeline for the purpose of facilitating structure-based drug discovery MtbGlyRS was expressed in Mycobacterium smegmatis and MtrGlyRS in ... More
Glycyl tRNA synthetases (GlyRSs) are prospective drug targets for combating Mycobacterium tuberculosis (Mtb) and cancer in humans. These synthetases are of the α2-subtype, with the ortholog in humans being dual targeted to the cytosol and mitochondria. Whereas the human enzyme has been structurally characterized previously in several liganded states, no structures of MtbGlyRS have thus far been reported. Here, we describe our recent work with MtbGlyRS and the closely-related Mycobacterium thermoresitibile GlyRS (MtrGlyRS), which progressed through all phases of the structural genomics pipeline, for the purpose of facilitating structure-based drug discovery. MtbGlyRS was expressed in Mycobacterium smegmatis and MtrGlyRS in Escherichia coli. Crystal structures are described for complexes of the two enzymes with adenosine monophosphate (AMP) and glycyl-sulfamoyl-adenylate (glycyl-AMS) at resolutions of 1.65/2.90 and 2.25/1.95 Å, respectively, and for MtrGlyRS in its apo state at 2.85 Å. Despite crystallizing in the dimeric state characteristic of many class II synthetases, the two enzymes elute predominantly as monomers during size exclusion chromatography. Strikingly, significant portions of the dimer interface and active site are unstructured in the MtrGlyRS apoenzyme crystal. AMP orders two tRNA recognition loops and a section of the insertion domain, and glycyl-AMS further stabilizes the structure, including the closure of a lid motif. Both the active and anticodon binding sites display structural differences with the human GlyRS and thus the collection of crystal structures should be useful for guiding drug development efforts targeting the various characterized structural states. Less
Efficient drug discovery relies on workflows that integrate structural insights with rapid and cost-effective exploration of chemical space Here we present a data-driven fragment-based lead discovery approach to target Neuronal Calcium Sensor NCS- protein-protein interactions PPIs This study represents the first implementation of a complete design-make-test-analyze cycle leading to the identification of micromolar affinity compounds with the potential to modulate NCS- interactions with key targets including the G-protein chaperone Ric- A and the dopamine D and cannabinoid CB receptors Through X-ray crystallographic fragment screening CFS diverse interaction patterns within the NCS- hydrophobic crevice were revealed Algorithmically guided fragment evolution and ... More
Efficient drug discovery relies on workflows that integrate structural insights with rapid and cost-effective exploration of chemical space. Here, we present a data-driven fragment-based lead discovery approach to target Neuronal Calcium Sensor 1 (NCS-1) protein-protein interactions (PPIs). This study represents the first implementation of a complete design-make-test-analyze cycle leading to the identification of micromolar affinity compounds with the potential to modulate NCS-1 interactions with key targets, including the G-protein chaperone Ric-8A and the dopamine D2 and cannabinoid CB1 receptors. Through X-ray crystallographic fragment screening (CFS), diverse interaction patterns within the NCS-1 hydrophobic crevice were revealed. Algorithmically guided fragment evolution and automated synthesis enabled the rapid generation of over 400 derivatives, with biophysical validation using LC-MS and waveRAPID technology. Structural analyses highlighted key pharmacophores, with selected compounds exhibiting favorable drug-like properties and potential blood-brain barrier penetration, making them promising candidates for neurodegenerative and neurodevelopmental disorders. Our results demonstrate the feasibility of accelerated hit-to-lead development at synchrotrons, demonstrating a robust, scalable platform for PPI-targeting drug discovery. The generated chemically diverse scaffolds provide a strong foundation for future therapeutic optimization. Less
Room-temperature RT X-ray diffraction experiments enable us to investigate protein dynamics efficiently probe fragment binding and perform time-resolved crystallography experiments The Versatile Macromolecular Crystallography in-situ VMXi beamline at Diamond Light Source DLS in the United Kingdom specializes in the collection of RT X-ray diffraction data in situ directly from crystallization trays without any manipulation of protein crystals improving crystal integrity for fragile crystals While many X-ray sources are now equipped to grow crystals on site for in-situ experiments to date there has been no comprehensive analysis that we are aware of on the effect of shipping crystals on plates at ... More
Room-temperature (RT) X-ray diffraction experiments enable us to investigate protein dynamics, efficiently probe fragment binding, and perform time-resolved crystallography experiments. The Versatile Macromolecular Crystallography in-situ (VMXi) beamline at Diamond Light Source (DLS) in the United Kingdom specializes in the collection of RT X-ray diffraction data in situ directly from crystallization trays without any manipulation of protein crystals, improving crystal integrity for fragile crystals. While many X-ray sources are now equipped to grow crystals on site for in-situ experiments, to date there has been no comprehensive analysis that we are aware of on the effect of shipping crystals on plates at ambient temperature for RT data collection, while the equivalent methodology for cryo-cooled crystals is well established. Here we examine the impact of shipping on crystals grown on MiTeGen In Situ-1 plates at the University of Buffalo Hauptman Woodward Research Institute (UB-HWI) in Buffalo, NY, United States transatlantic to DLS in Didcot, United Kingdom. We utilized the Stanford Synchrotron Radiation Lightsource (SSRL) Blue Box Thermal Shipper (Blue Box), which can maintain temperature for up to 168 hours, to ship crystallization plates at room temperature from UB-HWI to DLS. We hypothesized that long-distance shipping might compromise data quality through mechanical stress or temperature fluctuations. Instead, we found that room-temperature data collected at VMXi showed no significant differences for crystals set up at UB-HWI and shipped relative to crystals set up on site in the UK. High-resolution structures were successfully determined for all proteins in the study, demonstrating that long-distance shipment of crystals at non-cryogenic temperatures is feasible without compromising diffraction quality. This study provides a proof-of-concept workflow for expanding access to room-temperature crystallography worldwide, enabling more researchers to leverage cutting-edge techniques without needing to grow crystals on site. Less
ADP-ribosylation is an enzymatic process where an ADP-ribose moiety is transferred from NAD to an acceptor molecule While ADP-ribosylation is well-established as a post-translational modification of proteins rifamycin antibiotics are its only known small-molecule targets ADP-ribosylation of rifampicin was first identified in Mycolicibacterium smegmatis whose Arr enzyme transfers the ADP-ribose moiety to the -hydroxy group of rifampicin preventing its interaction with the bacterial RNA polymerase thereby inactivating the antibiotic Arr homologues are widely spread among bacterial species and present in several pathogenic species often associated with mobile genetic elements Inhibition of Arr enzymes offers a promising strategy to overcome ADP-ribosylation ... More
ADP-ribosylation is an enzymatic process where an ADP-ribose moiety is transferred from NAD+ to an acceptor molecule. While ADP-ribosylation is well-established as a post-translational modification of proteins, rifamycin antibiotics are its only known small-molecule targets. ADP-ribosylation of rifampicin was first identified in Mycolicibacterium smegmatis, whose Arr enzyme transfers the ADP-ribose moiety to the 23-hydroxy group of rifampicin preventing its interaction with the bacterial RNA polymerase thereby inactivating the antibiotic. Arr homologues are widely spread among bacterial species and present in several pathogenic species often associated with mobile genetic elements. Inhibition of Arr enzymes offers a promising strategy to overcome ADP-ribosylation mediated rifamycin resistance. We developed a high-throughput activity assay, which was applied to screen an in-house library of human ADP-ribosyltransferase-targeted compounds. We identified 15 inhibitors with IC50 values below 5 µM against four Arr enzymes from M. smegmatis, Pseudomonas aeruginosa, Stenotrophomonas maltophilia and Mycobacteroides abscessus. The observed overall selectivity of the hit compounds over the other homologues indicated structural differences between the proteins. We crystallized M. smegmatis and P. aeruginosa Arr enzymes, the former in complex with its most potent hit compound with an IC50 value of 1.3 µM. We observed structural differences in the NAD+ binding pockets of the two Arr homologues explaining the selectivity. Although the Arr inhibitors did not sensitize M. smegmatis to rifampicin in a growth inhibition assay, the structural information and the collection of inhibitors provide a foundation for rational modifications and further development of the compounds. Less
In this work we present the high-resolution structure of human aconitate decarboxylase hACOD in its true apo form active site empty as well in complex with the inhibitor citraconate These two new structures show the architecture of the active site and the structure-activity relationships of citraconate inhibition Careful analysis of the structures indicates probable dynamics required for substrate inhibitor binding and catalysis These observations were further explored using molecular dynamic simulations which show a clear open-close mechanism of hACOD between the A and A loops the lid- and helical-domain respectively As part of the biochemical characterization of the protein we ... More
In this work, we present the high-resolution structure of human aconitate decarboxylase 1 (hACOD1) in its true apo form (active site empty) as well in complex with the inhibitor citraconate. These two new structures show the architecture of the active site and the structure-activity relationships of citraconate inhibition. Careful analysis of the structures indicates probable dynamics required for substrate/inhibitor binding and catalysis. These observations were further explored using molecular dynamic simulations, which show a clear open-close mechanism of hACOD1 between the A1 and A2 loops, the lid- and helical-domain respectively. As part of the biochemical characterization of the protein, we also developed an alternative kinetic assay which measures the rate of catalysis of hACOD1 by direct observation of the conversion of cis-aconitate to itaconate by NMR spectroscopy. The work herein offers a foundation for structure- and dynamic-driven design of novel hACOD1 inhibitors as novel chemotherapeutics. Less
Flavin-binding proteins flavoproteins are widespread in nature revealing versatile oxidation-reduction reactions and photochemistry Flavoproteins derived from LOV domains are used for engineering of ligh-tresponsive tools in optogenetics as well as fluorescent markers and photogenerators of reactive oxygen species Despite extensiev efforts all currently used LOV-derived proteins have similar absorption spectra with maxima around - and - nm Here we describe the discovery of a large Stokes shift flavi-nbased fluorescent protein LSSFbFP which can be obtainedin vivo and in vitro with absorption maxima at - and - nm Fluorescence emission of LSSFbFP mirrors that of classical FbFPs with the maximum at ... More
Flavin-binding proteins (flavoproteins) are widespread in nature, revealing versatile oxidation-reduction reactions and photochemistry. Flavoproteins derived from LOV domains are used for engineering of ligh-tresponsive tools in optogenetics, as well as fluorescent markers and photogenerators of reactive oxygen species. Despite extensiev efforts, all currently used LOV-derived proteins have similar absorption spectra with maxima around 275, 35-0375, and 450-485 nm. Here, we describe the discovery of a large Stokes shift flavi-nbased fluorescent protein, LSSFbFP, which can be obtainedin vivo and in vitro, with absorption maxima at 340-350 and 395-405 nm. Fluorescence emission of LSSFbFP mirrors that of classical FbFPs with the maximum at ~500 nm. We sho that the protein binds lumichrome as the chromophore and use low temperature and time-resolved spectroscopy, X-ray crystallography and modeling to prove that the apparent Stokes shift of LSSFbFP occurs due to excited state proton phenomena observed in flavoproteni s and pave the way for engineering of new flavin-based molecular instruments. Less
West Nile virus NS B-NS innactive fusion protease was crystallized using vapor diffusion in Morpheus screen conditions at pH Hexagonal rod-shaped crystals grew to m in length after days at C The crystals belonged to space group P and diffracted to resolution at Diamond Light Source beamline I The structure has been deposited as PDB ID CO In this version we added the Addgene id of the plasmid used for the protein expresssion and purification
Crystal-based structural methods including X-ray crystallography are frequently utilized for the determination of high-resolution structures of biomolecules All crystal-based diffraction methods first require the preparation of biomolecular crystals and careful sample preparation for crystallization experiments can increase the frequency of success In this article strategies to optimize factors that can impact crystallization are presented from which buffers and reducing agents are most favorable to which crystallization techniques could be used
In the human commensal Gram-positive bacterial pathogen Streptococcus pneumoniae the essential extracellular cell-division-associated peptidoglycan PG hydrolase PcsB interacts directly with the cytoplasmic-membrane-bound complex between FtsE and FtsX PcsB contains a cysteine hishdine-dependent amidohydrolase pephdase CHAP domain responsible for PG hydrolysis as well as a coiled-coil domain required for interaction with FtsEX ATP hydrolysis of FtsE in the cytoplasm drives conformational changes in FtsX in the cytoplasmic membrane which ultimately regulates the PG hydrolase on the outside of the cell In this work we show using in vitro and in vivo approaches that the CHAP domain of PcsB predominately functions as ... More
In the human commensal Gram-positive bacterial pathogen Streptococcus pneumoniae, the essential extracellular cell-division-associated peptidoglycan (PG) hydrolase PcsB interacts directly with the cytoplasmic-membrane-bound complex between FtsE and FtsX (1–3). PcsB contains a cysteine, hishdine-dependent amidohydrolase/pephdase (CHAP) domain responsible for PG hydrolysis, as well as a coiled-coil domain required for interaction with FtsEX (1,4). ATP hydrolysis of FtsE in the cytoplasm drives conformational changes in FtsX in the cytoplasmic membrane, which ultimately regulates the PG hydrolase on the outside of the cell (5). In this work we show using in vitro and in vivo approaches, that the CHAP domain of PcsB predominately functions as an iso-D-Glutaminyl-Lysyl D,L-endopeptidase, with particular substrate specificity for Lys-containing, amidated PG, cleaving between the second and third amino acids of the peptidoglycan stem peptide. The catalytic activity of PcsB is regulated and activated by conformation changes of the coiled-coil region of PcsB and in part by a short helical region immediately adjacent to the CHAP domain to guard against PcsB hydrolytic activation outside of its cell division specific functional requirement. This work supports a model for the overall biological activity of the FtsEX-PcsB complex, in which ATP hydrolysis by FtsE in the cytoplasm, drives conformational changes in FtsX and PcsB resulting in the liberation of the hydrolytic CHAP domain of PcsB from its regulatory helix to allow PG stem peptide cleavage that splits the septal disk and marks a region of the peptidoglycan sacculus for subsequent cell division remodelling. Less
Nonenzymatic RNA copying is thought to have been responsible for the replication of genetic information during the origin of life However chemical copying with the canonical nucleotides A U G and C strongly favors the incorporation of G and C and disfavors the incorporation of A and especially U because of the stronger G C vs A U base pair and the weaker stacking interactions of U Recent advances in prebiotic chemistry suggest that the -thiopyrimidines were precursors to the canonical pyrimidines raising the possibility that they may have played an important early role in RNA copying chemistry Furthermore -thiouridine ... More
Nonenzymatic RNA copying is thought to have been responsible for the replication of genetic information during the origin of life. However, chemical copying with the canonical nucleotides (A, U, G, and C) strongly favors the incorporation of G and C and disfavors the incorporation of A and especially U, because of the stronger G:C vs. A:U base pair, and the weaker stacking interactions of U. Recent advances in prebiotic chemistry suggest that the 2-thiopyrimidines were precursors to the canonical pyrimidines, raising the possibility that they may have played an important early role in RNA copying chemistry. Furthermore, 2-thiouridine (s2U) and inosine (I) form by deamination of 2-thiocytidine (s2C) and A respectively. We used thermodynamic and crystallographic analyses to compare the I:s2C and A:s2U base pairs. We find that the I:s2C base pair is isomorphic and isoenergetic with the A:s2U base pair. The I:s2C base pair is weaker than a canonical G:C base pair, while the A:s2U base pair is stronger than the canonical A:U base pair, so that a genetic alphabet consisting of s2U, s2C, I and A generates RNA duplexes with uniform base pairing energies. Consistent with these results, kinetic analysis of nonenzymatic template-directed primer extension reactions reveals that s2C and s2U substrates bind similarly to I and A in the template, and vice versa. Our work supports the plausibility of a potentially primordial genetic alphabet consisting of s2U, s2C, I and A, and offers a potential solution to the long-standing problem of biased nucleotide incorporation during nonenzymatic template copying. Less
Collagen prolyl -hydroxylase C-P H catalyzes the -hydroxylation of Y-prolines of the XYG-repeat of procollagen C-P Hs are tetrameric enzymes The -subunit provides the N-terminal dimerization domain the middle peptide-substrate binding PSB domain and the C-terminal catalytic CAT domain There are three isoforms of the -subunit complexed with a -subunit that is protein disulfide isomerase forming C-P H I-III The PSB domain of the -subunit binds proline-rich peptides but its function with respect to the prolyl hydroxylation mechanism is unknown An extended mode of binding of proline-rich peptides PPII polyproline type-II conformation to the PSB-I domain has previously been reported ... More
Collagen prolyl 4-hydroxylase (C-P4H) catalyzes the 4-hydroxylation of Y-prolines of the XYG-repeat of procollagen. C-P4Hs are tetrameric α2β2 enzymes. The α-subunit provides the N-terminal dimerization domain, the middle peptide-substrate–binding (PSB) domain, and the C-terminal catalytic (CAT) domain. There are three isoforms of the α-subunit, complexed with a β-subunit that is protein disulfide isomerase, forming C-P4H I-III. The PSB domain of the α-subunit binds proline-rich peptides, but its function with respect to the prolyl hydroxylation mechanism is unknown. An extended mode of binding of proline-rich peptides (PPII, polyproline type-II, conformation) to the PSB-I domain has previously been reported for the PPG-PPG-PPG and P9 peptides. Crystal structures now show that peptides with the motif PxGP (PPG-PRG-PPG, PPG-PAG-PPG) (where x, at Y-position 5, is not a proline) bind to the PSB-I domain differently, more deeply, in the peptide-binding groove. The latter mode of binding has previously been reported for structures of the PSB-II domain complexed with these PxGP-peptides. In addition, it is shown here by crystallographic binding studies that the POG-PAG-POG peptide (with 4-hydroxyprolines at Y-positions 2 and 8) also adopts the PxGP mode of binding to PSB-I as well as to PSB-II. Calorimetric binding studies show that the affinities of these peptides are lower for PSB-I than for PSB-II, with, respectively, KD values of about 70 μM for PSB-I and 20 μM for PSB-II. The importance of these results for understanding the reaction mechanism of C-P4H, in particular concerning the function of the PSB domain, is discussed. Less
Immunomodulatory imide drugs IMiDs degrade specific C H zinc finger degrons in transcription factors making them effective against certain cancers SALL a cancer driver contains seven C H zinc fingers in four clusters including an IMiD degron in zinc finger cluster two ZFC Surprisingly IMiDs do not inhibit growth of SALL expressing cancer cells To overcome this limit we focused on a non-IMiD degron SALL zinc finger cluster four ZFC By combining AlphaFold and the ZFC -DNA crystal structure we identified a potential ZFC drug pocket Utilizing an in silico docking algorithm and cell viability assays we screened chemical libraries ... More
Immunomodulatory imide drugs (IMiDs) degrade specific C2H2 zinc finger degrons in transcription factors, making them effective against certain cancers. SALL4, a cancer driver, contains seven C2H2 zinc fingers in four clusters, including an IMiD degron in zinc finger cluster two (ZFC2). Surprisingly, IMiDs do not inhibit growth of SALL4 expressing cancer cells. To overcome this limit, we focused on a non-IMiD degron, SALL4 zinc finger cluster four (ZFC4). By combining AlphaFold and the ZFC4-DNA crystal structure, we identified a potential ZFC4 drug pocket. Utilizing an in silico docking algorithm and cell viability assays, we screened chemical libraries and discovered SH6, which selectively targets SALL4-expressing cancer cells. Mechanistic studies revealed that SH6 degrades SALL4 protein through the CUL4A/CRBN pathway, while deletion of ZFC4 abolished this activity. Moreover, SH6 led to significant 62% tumor growth inhibition of SALL4+ xenografts in vivo and demonstrated good bioavailability in pharmacokinetic studies. In summary, these studies represent a new approach for IMiD independent drug discovery targeting C2H2 transcription factors in cancer. Less
The COVID- pandemic has highlighted the need to identify novel therapeutic interventions and strategies for pandemic preparedness Other than Severe Acute Respiratory Syndrome Coronavirus SARS-CoV- there are several human coronaviruses that are of pandemic concern these include SARS-CoV and Middle Eastern Respiratory Syndrome MERS-CoV MERS-CoV is a zoonotic virus that was first discovered in The disease has spread rapidly with large outbreaks as recent as and Currently there is no therapeutic intervention for MERS-CoV with of reported cases resulting in human death Like-wise to SARS-CoV- MERS-CoV produces a main protease Mpro which is essential for viral replication and therefore an ... More
The COVID-19 pandemic has highlighted the need to identify novel therapeutic interventions and strategies for pandemic preparedness. Other than Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), there are several human coronaviruses that are of pandemic concern, these include SARS-CoV and Middle Eastern Respiratory Syndrome (MERS-CoV). MERS-CoV is a zoonotic virus that was first discovered in 2012. The disease has spread rapidly with large outbreaks as recent as 2015 and 2018. Currently there is no therapeutic intervention for MERS-CoV with 35% of reported cases resulting in human death. Like-wise to SARS-CoV-2, MERS-CoV produces a main protease (Mpro) which is essential for viral replication and therefore an attractive target to inhibit the virus. In this new version we added the protein purification protocol and Addgene id, together with the solvent test and compound soaking conditions. Less
Bacteriorhodopsin is a seven-helical light-driven proton pump and a model membrane protein Here we report engineering of soluble analogues of bacteriorhodopsin NeuroBRs which bind retinal and photocycle under illumination We also report the crystallographic structure of NeuroBR A determined at anisotropic resolution reaching that reveals a conserved chromophore binding pocket and tertiary structure Our results highlight the power of modern protein engineering approaches and pave the way towards wider development of molecular tools derived from membrane proteins
The Fe II - and -oxoglutarate -OG -dependent dioxygenase FOGDD enzyme superfamily catalyzes the oxidation of RNA DNA and peptide substrates to install chemical modifications that regulate the diverse functions of these biomolecules For decades it has been appreciated that many FOGDDs require ascorbate Vitamin C as a cofactor for efficient catalysis but ascorbate requirements across different FOGDD enzymes its effects on the catalysis of different substrates and how it engages the FOGDD active site remain poorly understood Here we use RNA demethylases FTO and AlkBH as model FOGDD enzymes and show that their ascorbate requirements for efficient demethylation reactions ... More
The Fe(II)- and 2-oxoglutarate(2-OG)-dependent dioxygenase (FOGDD) enzyme superfamily catalyzes the oxidation of RNA, DNA, and peptide substrates to install chemical modifications that regulate the diverse functions of these biomolecules. For decades, it has been appreciated that many FOGDDs require ascorbate (Vitamin C) as a cofactor for efficient catalysis, but ascorbate requirements across different FOGDD enzymes, its effects on the catalysis of different substrates, and how it engages the FOGDD active site, remain poorly understood. Here, we use RNA demethylases FTO and AlkBH5 as model FOGDD enzymes and show that their ascorbate requirements for efficient demethylation reactions are dramatically different. Furthermore, FTO was found to have strikingly different ascorbate requirements for its own demethylation reactions with different methylated RNA substrates. Our enzymology experiments suggest FTO and AlkBH5, and likely FOGDDs generally, can have widely different ascorbate dependencies based on the balance between an enzyme’s intrinsic ability to decarboxylate co-substrate 2-oxoglutarate and the kinetics of its substrate oxidation reaction. Finally, we determined a crystal structure of FTO in complex with ascorbate, which for the first time shows how ascorbate selectively engages the FOGDD active site. Together, our biochemical and structural data show that ascorbate can selectively tune the RNA demethylation reactions of FTO and AlkBH5, and that more globally, differences in ascorbate concentrations in different environments or diseases may regulate the activity and specificity of diverse FOGDD-catalyzed oxidation reactions in the cell. Less
Solid-state nuclear magnetic resonance ssNMR is a powerful technique for studying membrane protein structure and dynamics Ideally measurements are performed with the protein in a lipid bilayer However homogenous reconstitution of functional protein into intact bilayers at sufficiently high concentrations is often difficult to achieve In this work we investigate the suitability of the lipid cubic phase LCP which incorporates a lipid bilayer as an alternative medium for ssNMR of integral membrane peptides and proteins The cubic mesophase has long been used to generate membrane protein crystals for use in X-ray crystallographic structure determination by the so-called in meso method ... More
Solid-state nuclear magnetic resonance (ssNMR) is a powerful technique for studying membrane protein structure and dynamics. Ideally, measurements are performed with the protein in a lipid bilayer. However, homogenous reconstitution of functional protein into intact bilayers at sufficiently high concentrations is often difficult to achieve. In this work, we investigate the suitability of the lipid cubic phase (LCP), which incorporates a lipid bilayer, as an alternative medium for ssNMR of integral membrane peptides and proteins. The cubic mesophase has long been used to generate membrane protein crystals for use in X-ray crystallographic structure determination by the so-called in meso method and for protein functional and biophysical characterization. Preparing and handling protein-laden LCP is straightforward. LCP may therefore provide a valuable alternative to native membranes and other membrane mimetics for ssNMR. We tested this idea by conducting standard magic-angle spinning ssNMR experiments on LCP into which gramicidin, a ∼4-kDa transmembrane peptide, or bacterial lipoprotein signal peptidase II (LspA), a ∼20-kDa integral membrane enzyme, had been reconstituted. We report one- and two-dimensional ssNMR spectra for both gramicidin and LspA and the parameters for optimizing spectral quality. The high protein-carrying capacity of the cubic phase facilitated 13C ssNMR at natural abundance. Lowering temperature and raising magic-angle spinning frequency enabled significant improvements in spectral quality. One-dimensional 13C and 15N spectra were collected for LspA. Two-dimensional ssNMR experiments provided information on LspA dynamics and its interaction with the water and lipid components of the cubic phase. Solution NMR measurements carried out in parallel yielded information on the effect of the antibiotic, globomycin, on LspA structure and dynamics. Less
The Elettra synchrotron radiation facility located in Trieste Italy is a third-generation storage ring operating in top-up mode at both and GeV The facility currently hosts one beamline fully dedicated to macromolecular crystallography XRD XRD is based on a superconducting wiggler and it has been open to users since On-site and remote access for data collection as well as monitoring tools and automatic data analysis pipelines are available to its users In addition since Elettra has operated a general-purpose diffraction beamline XRD offering the macromolecular community a wide spectrum extending to long wavelengths for phasing and ion identification Ancillary facilities ... More
The Elettra synchrotron radiation facility, located in Trieste, Italy, is a third-generation storage ring, operating in top-up mode at both 2.0 and 2.4 GeV. The facility currently hosts one beamline fully dedicated to macromolecular crystallography, XRD2. XRD2 is based on a superconducting wiggler, and it has been open to users since 2018. On-site and remote access for data collection, as well as monitoring tools and automatic data analysis pipelines are available to its users. In addition, since 1994 Elettra has operated a general-purpose diffraction beamline, XRD1, offering the macromolecular community a wide spectrum extending to long wavelengths for phasing and ion identification. Ancillary facilities support the beamlines, providing sample preparation and a high-throughput crystallization platform for the user community. A new CryoEM facility is being established on campus and jointly operated by the Consiglio Nazionale della Ricerche – Istituto Officina dei Materiali (CNR–IOM) and Elettra, providing further opportunities to the Elettra user community. This review outlines the current capabilities and anticipated developments for macromolecular crystallography at Elettra to accompany the upcoming upgrade to Elettra 2.0, featuring a six-bend enhanced achromat lattice. The new source is expected to deliver a high-brilliance beam, enabling the macromolecular crystallography community to better address the emerging and future scientific challenges. Less
Bacteria face a constant existential threat in the form of infection by viruses along with other forms of mobile genetic elements such as bacteriophage and transposable elements To survive bacteria and other prokaryotes have evolved various immune systems to evade these would-be invaders One such immune system is the CRISPR-Cas system an adaptive immune system able to record the genetic signature of invading viruses in order to recognize and destroy them should they be encountered again in the future In this thesis I present data that sheds light on the mechanism of one particular subtype of CRISPR-Cas systems the type ... More
Bacteria face a constant existential threat in the form of infection by viruses along with other forms of mobile genetic elements, such as bacteriophage and transposable elements. To survive, bacteria and other prokaryotes have evolved various immune systems to evade these would-be invaders. One such immune system is the CRISPR-Cas system, an adaptive immune system able to record the genetic signature of invading viruses in order to recognize and destroy them should they be encountered again in the future. In this thesis I present data that sheds light on the mechanism of one particular subtype of CRISPR-Cas systems: the type IV-A1 system from Pseudomonas aeruginosa. I also report on some of the newly identified tools used by viruses and plasmids to evade this system, called anti-CRISPRs.
The type IV-A1 system is unique in that unlike most CRISPR-Cas systems, it doesn’t appear to destroy or degrade the genome of invading viruses. Instead, it relies on an additional helicase protein called CasDinG to repress the expression of any genes near its target. I report data which explains the genetic signatures necessary to activate type IV-A CRISPR system, and I also explore the significance of a particular domain of the CasDinG helicase.
This thesis also identifies the first-ever reported anti-CRISPRs against the type IV-A system, along with hypothesized mechanisms by which they repress immunity. Less
The type IV-A1 system is unique in that unlike most CRISPR-Cas systems, it doesn’t appear to destroy or degrade the genome of invading viruses. Instead, it relies on an additional helicase protein called CasDinG to repress the expression of any genes near its target. I report data which explains the genetic signatures necessary to activate type IV-A CRISPR system, and I also explore the significance of a particular domain of the CasDinG helicase.
This thesis also identifies the first-ever reported anti-CRISPRs against the type IV-A system, along with hypothesized mechanisms by which they repress immunity. Less
DNA replication is tightly regulated to ensure genomic stability and prevent several diseases including cancers Eukaryotes and archaea partly achieve this regulation by strictly controlling the activation of hexameric minichromosome maintenance MCM helicase rings that unwind DNA during its replication In eukaryotes MCM activation critically relies on the sequential recruitment of the essential factors Cdc and a tetrameric GINS complex at the onset of the S-phase to generate a larger CMG complex We present the crystal structure of the tetrameric GINS complex from the archaeal organism Saccharolobus solfataricus Sso to reveal a core structure that is highly similar to the ... More
DNA replication is tightly regulated to ensure genomic stability and prevent several diseases, including cancers. Eukaryotes and archaea partly achieve this regulation by strictly controlling the activation of hexameric minichromosome maintenance (MCM) helicase rings that unwind DNA during its replication. In eukaryotes, MCM activation critically relies on the sequential recruitment of the essential factors Cdc45 and a tetrameric GINS complex at the onset of the S-phase to generate a larger CMG complex. We present the crystal structure of the tetrameric GINS complex from the archaeal organism Saccharolobus solfataricus (Sso) to reveal a core structure that is highly similar to the previously determined GINS core structures of other eukaryotes and archaea. Using molecular modeling, we illustrate that a subdomain of SsoGINS would need to move to accommodate known interactions of the archaeal GINS complex and to generate a SsoCMG complex analogous to that of eukaryotes. Less
T cell receptors TCRs recognize specific peptides presented by human leukocyte antigens HLAs on the surface of antigen-presenting cells and are involved in fighting pathogens and cancer surveillance Canonical docking orientation of TCRs to their target peptide-HLAs pHLAs is essential for T cell activation with reverse binding TCRs lacking functionality TCR binding geometry and molecular interaction footprint with pHLAs are typically obtained by determining the crystal structure Here we describe the use of a cross-linking tandem mass spectrometry XL-MS MS method to decipher the binding orientation of several TCRs to their target pHLAs Cross-linking sites were localized to specific residues ... More
T cell receptors (TCRs) recognize specific peptides presented by human leukocyte antigens (HLAs) on the surface of antigen-presenting cells and are involved in fighting pathogens and cancer surveillance. Canonical docking orientation of TCRs to their target peptide-HLAs (pHLAs) is essential for T cell activation, with reverse binding TCRs lacking functionality. TCR binding geometry and molecular interaction footprint with pHLAs are typically obtained by determining the crystal structure. Here, we describe the use of a cross-linking tandem mass spectrometry (XL-MS/MS) method to decipher the binding orientation of several TCRs to their target pHLAs. Cross-linking sites were localized to specific residues and their molecular interactions showed differentiation between TCRs binding in canonical or reverse orientations. Structural prediction and crystal structure determination of two TCR-pHLA complexes validated these findings. The XL-MS/MS method described herein offers a faster and simpler approach for elucidating TCR-pHLA binding orientation and interactions. Less
Since the Macromolecular Crystallography MX group at Helmholtz-Zentrum Berlin HZB has been operating three MX beamlines at the BESSY II storage ring in Berlin These beamlines were established to support the emerging structural genomics initiatives founded in Germany Europe and overseas around the turn of the century Over the past two decades these beamlines have been continuously developed to enable state-of-the-art diffraction experiments and to provide supporting facilities such as a sample preparation laboratory a spectroscopy laboratory a Biosafety Level laboratory and all necessary computing resources for the MX and chemical crystallography user community Currently more than independent research groups ... More
Since 2003, the Macromolecular Crystallography (MX) group at Helmholtz-Zentrum Berlin (HZB) has been operating three MX beamlines at the BESSY II storage ring in Berlin. These beamlines were established to support the emerging structural genomics initiatives founded in Germany, Europe, and overseas around the turn of the century. Over the past two decades, these beamlines have been continuously developed to enable state-of-the-art diffraction experiments and to provide supporting facilities such as a sample preparation laboratory, a spectroscopy laboratory, a Biosafety Level 1 laboratory and all necessary computing resources for the MX and chemical crystallography user community. Currently, more than 100 independent research groups from the greater Berlin area, Germany, and Europe utilize these beamlines. Over time, more than 4500 Protein Data Bank depositions have been accrued based on data collected at the beamlines. This paper presents historical aspects of the beamlines, their current status including their research output, and future directions. Less
Picornaviridae coxsackievirus A is the causative agent of paediatric hand-foot-and-mouth disease and a target for pandemic preparedness due to the risk of higher order complications in a large-scale outbreak The A protease of the virus is responsible for self-cleavage from the poly protein allowing for correct folding and assembly of capsid proteins in the final stages of viral replication Inhibition deranges capsid folding and assembly preventing formation of mature virions in host cells and making the protease a valuable target for antiviral activity This protocol was used to grow coxsackievirus A crystals PDB POA that were used in high-throughput crystallographic ... More
Picornaviridae coxsackievirus A16 is the causative agent of paediatric hand-foot-and-mouth disease, and a target for pandemic preparedness due to the risk of higher order complications in a large-scale outbreak. The 2A protease of the virus is responsible for self-cleavage from the poly protein, allowing for correct folding and assembly of capsid proteins in the final stages of viral replication. Inhibition deranges capsid folding and assembly, preventing formation of mature virions in host cells and making the protease a valuable target for antiviral activity. This protocol was used to grow coxsackievirus A16 crystals (PDB 8POA) that were used in high-throughput crystallographic fragment screening, and follow up compounds on the target. In this new version we added: the group deposition code; details about the fragment screen and solvent tolerance; also the protein production protocol. Less
The development of effective broad-spectrum antivirals forms an important part of preparing for future pandemics A current cause for concern is the emerging pathogen Enterovirus D EV-D which primarily spreads through respiratory routes While it mostly causes mild to severe respiratory illness in severe cases it can lead to acute flaccid myelitis The C protease of EV-D is a potential target for antiviral drug development due to its essential role in the viral life cycle and high sequence conservation This protocol was used to grow EV-D C crystals that were subjected to high-throughput fragment screening crystallography PDB group deposition G ... More
The development of effective broad-spectrum antivirals forms an important part of preparing for future pandemics. A current cause for concern is the emerging pathogen Enterovirus D68 (EV-D68), which primarily spreads through respiratory routes. While it mostly causes mild to severe respiratory illness, in severe cases it can lead to acute flaccid myelitis. The 3C protease of EV-D68 is a potential target for antiviral drug development due to its essential role in the viral life cycle and high sequence conservation. This protocol was used to grow EV-D68 3C crystals that were subjected to high-throughput fragment screening crystallography (PDB group deposition G_10002271). In this new version, we have added the protocols for protein expression and purification, soaking conditions, and fragment screening information, as well as the affiliation with the ASAP Discovery Consortium. Less