Your search keyword '"Bacterial Proteins ultrastructure"' showing total 64 results

1. Plasmid targeting and destruction by the DdmDE bacterial defence system.

Author

Bravo JPK, Ramos DA, Fregoso Ocampo R, Ingram C, and Taylor DW

Subjects

Cryoelectron Microscopy, Deoxyribonucleases chemistry, Deoxyribonucleases metabolism, Deoxyribonucleases ultrastructure, DNA Helicases chemistry, DNA Helicases metabolism, DNA Helicases ultrastructure, DNA, Single-Stranded genetics, DNA, Single-Stranded metabolism, Models, Molecular, Protein Domains, Protein Multimerization, Argonaute Proteins chemistry, Argonaute Proteins metabolism, Argonaute Proteins ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Plasmids genetics, Plasmids immunology, Plasmids metabolism, Vibrio cholerae genetics, Vibrio cholerae immunology, Vibrio cholerae pathogenicity

Abstract

Although eukaryotic Argonautes have a pivotal role in post-transcriptional gene regulation through nucleic acid cleavage, some short prokaryotic Argonaute variants (pAgos) rely on auxiliary nuclease factors for efficient foreign DNA degradation 1 . Here we reveal the activation pathway of the DNA defence module DdmDE system, which rapidly eliminates small, multicopy plasmids from the Vibrio cholerae seventh pandemic strain (7PET) 2 . Through a combination of cryo-electron microscopy, biochemistry and in vivo plasmid clearance assays, we demonstrate that DdmE is a catalytically inactive, DNA-guided, DNA-targeting pAgo with a distinctive insertion domain. We observe that the helicase-nuclease DdmD transitions from an autoinhibited, dimeric complex to a monomeric state upon loading of single-stranded DNA targets. Furthermore, the complete structure of the DdmDE-guide-target handover complex provides a comprehensive view into how DNA recognition triggers processive plasmid destruction. Our work establishes a mechanistic foundation for how pAgos utilize ancillary factors to achieve plasmid clearance, and provides insights into anti-plasmid immunity in bacteria., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

2. Streptomyces umbrella toxin particles block hyphal growth of competing species.

Author

Zhao Q, Bertolli S, Park YJ, Tan Y, Cutler KJ, Srinivas P, Asfahl KL, Fonesca-García C, Gallagher LA, Li Y, Wang Y, Coleman-Derr D, DiMaio F, Zhang D, Peterson SB, Veesler D, and Mougous JD

Subjects

Anti-Bacterial Agents biosynthesis, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents metabolism, Anti-Bacterial Agents pharmacology, Cryoelectron Microscopy, Lectins chemistry, Lectins genetics, Lectins metabolism, Lectins ultrastructure, Microbial Sensitivity Tests, Models, Molecular, Streptomyces coelicolor chemistry, Streptomyces coelicolor genetics, Streptomyces coelicolor metabolism, Streptomyces griseus drug effects, Streptomyces griseus genetics, Streptomyces griseus growth & development, Streptomyces griseus metabolism, Antibiosis drug effects, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bacterial Proteins pharmacology, Bacterial Proteins ultrastructure, Bacterial Toxins chemistry, Bacterial Toxins genetics, Bacterial Toxins metabolism, Bacterial Toxins pharmacology, Streptomyces chemistry, Streptomyces drug effects, Streptomyces genetics, Streptomyces growth & development

Abstract

Streptomyces are a genus of ubiquitous soil bacteria from which the majority of clinically utilized antibiotics derive 1 . The production of these antibacterial molecules reflects the relentless competition Streptomyces engage in with other bacteria, including other Streptomyces species 1,2 . Here we show that in addition to small-molecule antibiotics, Streptomyces produce and secrete antibacterial protein complexes that feature a large, degenerate repeat-containing polymorphic toxin protein. A cryo-electron microscopy structure of these particles reveals an extended stalk topped by a ringed crown comprising the toxin repeats scaffolding five lectin-tipped spokes, which led us to name them umbrella particles. Streptomyces coelicolor encodes three umbrella particles with distinct toxin and lectin composition. Notably, supernatant containing these toxins specifically and potently inhibits the growth of select Streptomyces species from among a diverse collection of bacteria screened. For one target, Streptomyces griseus, inhibition relies on a single toxin and that intoxication manifests as rapid cessation of vegetative hyphal growth. Our data show that Streptomyces umbrella particles mediate competition among vegetative mycelia of related species, a function distinct from small-molecule antibiotics, which are produced at the onset of reproductive growth and act broadly 3,4 . Sequence analyses suggest that this role of umbrella particles extends beyond Streptomyces, as we identified umbrella loci in nearly 1,000 species across Actinobacteria., (© 2024. The Author(s).)

Published

2024

3. Structures and activation mechanism of the Gabija anti-phage system.

Author

Li J, Cheng R, Wang Z, Yuan W, Xiao J, Zhao X, Du X, Xia S, Wang L, Zhu B, and Wang L

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphatases chemistry, Adenosine Triphosphatases ultrastructure, Adenosine Triphosphate chemistry, Adenosine Triphosphate metabolism, Apoproteins chemistry, Apoproteins immunology, Apoproteins metabolism, Apoproteins ultrastructure, DNA metabolism, DNA chemistry, DNA Cleavage, Magnesium chemistry, Magnesium metabolism, Models, Molecular, Protein Binding, Protein Domains, Microbial Viability, Protein Structure, Quaternary, DNA Primase chemistry, DNA Primase metabolism, DNA Primase ultrastructure, DNA Topoisomerases chemistry, DNA Topoisomerases metabolism, DNA Topoisomerases ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins immunology, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Bacteriophages immunology, Cryoelectron Microscopy, Immunity, Innate, Bacillus cereus chemistry, Bacillus cereus immunology, Bacillus cereus metabolism, Bacillus cereus ultrastructure

Abstract

Prokaryotes have evolved intricate innate immune systems against phage infection 1-7 . Gabija is a highly widespread prokaryotic defence system that consists of two components, GajA and GajB 8 . GajA functions as a DNA endonuclease that is inactive in the presence of ATP 9 . Here, to explore how the Gabija system is activated for anti-phage defence, we report its cryo-electron microscopy structures in five states, including apo GajA, GajA in complex with DNA, GajA bound by ATP, apo GajA-GajB, and GajA-GajB in complex with ATP and Mg 2+ . GajA is a rhombus-shaped tetramer with its ATPase domain clustered at the centre and the topoisomerase-primase (Toprim) domain located peripherally. ATP binding at the ATPase domain stabilizes the insertion region within the ATPase domain, keeping the Toprim domain in a closed state. Upon ATP depletion by phages, the Toprim domain opens to bind and cleave the DNA substrate. GajB, which docks on GajA, is activated by the cleaved DNA, ultimately leading to prokaryotic cell death. Our study presents a mechanistic landscape of Gabija activation., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

4. Activation of Thoeris antiviral system via SIR2 effector filament assembly.

Author

Tamulaitiene G, Sabonis D, Sasnauskas G, Ruksenaite A, Silanskas A, Avraham C, Ofir G, Sorek R, Zaremba M, and Siksnys V

Subjects

Adenosine Diphosphate Ribose analogs & derivatives, Adenosine Diphosphate Ribose biosynthesis, Adenosine Diphosphate Ribose chemistry, Adenosine Diphosphate Ribose metabolism, Cryoelectron Microscopy, Hydrolysis, NAD metabolism, Protein Domains, Protein Multimerization, Protein Stability, Bacteria metabolism, Bacteria virology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Bacteriophages chemistry, Bacteriophages metabolism, Bacteriophages ultrastructure

Abstract

To survive bacteriophage (phage) infections, bacteria developed numerous anti-phage defence systems 1-7 . Some of them (for example, type III CRISPR-Cas, CBASS, Pycsar and Thoeris) consist of two modules: a sensor responsible for infection recognition and an effector that stops viral replication by destroying key cellular components 8-12 . In the Thoeris system, a Toll/interleukin-1 receptor (TIR)-domain protein, ThsB, acts as a sensor that synthesizes an isomer of cyclic ADP ribose, 1''-3' glycocyclic ADP ribose (gcADPR), which is bound in the Smf/DprA-LOG (SLOG) domain of the ThsA effector and activates the silent information regulator 2 (SIR2)-domain-mediated hydrolysis of a key cell metabolite, NAD + (refs.  12-14 ). Although the structure of ThsA has been solved 15 , the ThsA activation mechanism remained incompletely understood. Here we show that 1''-3' gcADPR, synthesized in vitro by the dimeric ThsB' protein, binds to the ThsA SLOG domain, thereby activating ThsA by triggering helical filament assembly of ThsA tetramers. The cryogenic electron microscopy (cryo-EM) structure of activated ThsA revealed that filament assembly stabilizes the active conformation of the ThsA SIR2 domain, enabling rapid NAD + depletion. Furthermore, we demonstrate that filament formation enables a switch-like response of ThsA to the 1''-3' gcADPR signal., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

5. A new family of bacterial ribosome hibernation factors.

Author

Helena-Bueno K, Rybak MY, Ekemezie CL, Sullivan R, Brown CR, Dingwall C, Baslé A, Schneider C, Connolly JPR, Blaza JN, Csörgő B, Moynihan PJ, Gagnon MG, Hill CH, and Melnikov SV

Subjects

Peptide Elongation Factor Tu chemistry, Peptide Elongation Factor Tu metabolism, Peptide Elongation Factor Tu ultrastructure, Cryoelectron Microscopy, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Protein Biosynthesis, Ribosomal Proteins chemistry, Ribosomal Proteins genetics, Ribosomal Proteins metabolism, Ribosomal Proteins ultrastructure, Ribosomes chemistry, Ribosomes metabolism, Ribosomes ultrastructure, Psychrobacter chemistry, Psychrobacter genetics, Psychrobacter metabolism, Psychrobacter ultrastructure, Cold-Shock Response, Peptide Termination Factors chemistry, Peptide Termination Factors genetics, Peptide Termination Factors metabolism, Peptide Termination Factors ultrastructure

Abstract

To conserve energy during starvation and stress, many organisms use hibernation factor proteins to inhibit protein synthesis and protect their ribosomes from damage 1,2 . In bacteria, two families of hibernation factors have been described, but the low conservation of these proteins and the huge diversity of species, habitats and environmental stressors have confounded their discovery 3-6 . Here, by combining cryogenic electron microscopy, genetics and biochemistry, we identify Balon, a new hibernation factor in the cold-adapted bacterium Psychrobacter urativorans. We show that Balon is a distant homologue of the archaeo-eukaryotic translation factor aeRF1 and is found in 20% of representative bacteria. During cold shock or stationary phase, Balon occupies the ribosomal A site in both vacant and actively translating ribosomes in complex with EF-Tu, highlighting an unexpected role for EF-Tu in the cellular stress response. Unlike typical A-site substrates, Balon binds to ribosomes in an mRNA-independent manner, initiating a new mode of ribosome hibernation that can commence while ribosomes are still engaged in protein synthesis. Our work suggests that Balon-EF-Tu-regulated ribosome hibernation is a ubiquitous bacterial stress-response mechanism, and we demonstrate that putative Balon homologues in Mycobacteria bind to ribosomes in a similar fashion. This finding calls for a revision of the current model of ribosome hibernation inferred from common model organisms and holds numerous implications for how we understand and study ribosome hibernation., (© 2024. The Author(s).)

Published

2024

6. Structural basis of Gabija anti-phage defence and viral immune evasion.

Author

Antine SP, Johnson AG, Mooney SE, Leavitt A, Mayer ML, Yirmiya E, Amitai G, Sorek R, and Kranzusch PJ

Subjects

Cryoelectron Microscopy, Crystallography, X-Ray, Deoxyribonucleases chemistry, Deoxyribonucleases metabolism, Deoxyribonucleases ultrastructure, DNA, Viral chemistry, DNA, Viral metabolism, DNA, Viral ultrastructure, Bacteria genetics, Bacteria immunology, Bacteria metabolism, Bacteria virology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Bacteriophages genetics, Bacteriophages immunology, Bacteriophages metabolism, Immune Evasion, Protein Multimerization

Abstract

Bacteria encode hundreds of diverse defence systems that protect them from viral infection and inhibit phage propagation 1-5 . Gabija is one of the most prevalent anti-phage defence systems, occurring in more than 15% of all sequenced bacterial and archaeal genomes 1,6,7 , but the molecular basis of how Gabija defends cells from viral infection remains poorly understood. Here we use X-ray crystallography and cryo-electron microscopy (cryo-EM) to define how Gabija proteins assemble into a supramolecular complex of around 500 kDa that degrades phage DNA. Gabija protein A (GajA) is a DNA endonuclease that tetramerizes to form the core of the anti-phage defence complex. Two sets of Gabija protein B (GajB) dimers dock at opposite sides of the complex and create a 4:4 GajA-GajB assembly (hereafter, GajAB) that is essential for phage resistance in vivo. We show that a phage-encoded protein, Gabija anti-defence 1 (Gad1), directly binds to the Gabija GajAB complex and inactivates defence. A cryo-EM structure of the virally inhibited state shows that Gad1 forms an octameric web that encases the GajAB complex and inhibits DNA recognition and cleavage. Our results reveal the structural basis of assembly of the Gabija anti-phage defence complex and define a unique mechanism of viral immune evasion., (© 2023. The Author(s).)

Published

2024

7. Structure of an endogenous mycobacterial MCE lipid transporter.

Author

Chen J, Fruhauf A, Fan C, Ponce J, Ueberheide B, Bhabha G, and Ekiert DC

Subjects

Animals, Tuberculosis microbiology, Virulence Factors chemistry, Virulence Factors metabolism, ATP-Binding Cassette Transporters chemistry, ATP-Binding Cassette Transporters metabolism, ATP-Binding Cassette Transporters ultrastructure, Periplasm metabolism, Protein Domains, Hydrophobic and Hydrophilic Interactions, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Multiprotein Complexes ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, Lipids, Membrane Transport Proteins chemistry, Membrane Transport Proteins metabolism, Membrane Transport Proteins ultrastructure, Mycobacterium tuberculosis chemistry, Mycobacterium tuberculosis metabolism, Mycobacterium tuberculosis ultrastructure, Virus Internalization

Abstract

To replicate inside macrophages and cause tuberculosis, Mycobacterium tuberculosis must scavenge a variety of nutrients from the host 1,2 . The mammalian cell entry (MCE) proteins are important virulence factors in M. tuberculosis 1,3 , where they are encoded by large gene clusters and have been implicated in the transport of fatty acids 4-7 and cholesterol 1,4,8 across the impermeable mycobacterial cell envelope. Very little is known about how cargos are transported across this barrier, and it remains unclear how the approximately ten proteins encoded by a mycobacterial mce gene cluster assemble to transport cargo across the cell envelope. Here we report the cryo-electron microscopy (cryo-EM) structure of the endogenous Mce1 lipid-import machine of Mycobacterium smegmatis-a non-pathogenic relative of M. tuberculosis. The structure reveals how the proteins of the Mce1 system assemble to form an elongated ABC transporter complex that is long enough to span the cell envelope. The Mce1 complex is dominated by a curved, needle-like domain that appears to be unrelated to previously described protein structures, and creates a protected hydrophobic pathway for lipid transport across the periplasm. Our structural data revealed the presence of a subunit of the Mce1 complex, which we identified using a combination of cryo-EM and AlphaFold2, and name LucB. Our data lead to a structural model for Mce1-mediated lipid import across the mycobacterial cell envelope., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

8. Cryo-EM structure of the transposon-associated TnpB enzyme.

Author

Nakagawa R, Hirano H, Omura SN, Nety S, Kannan S, Altae-Tran H, Yao X, Sakaguchi Y, Ohira T, Wu WY, Nakayama H, Shuto Y, Tanaka T, Sano FK, Kusakizako T, Kise Y, Itoh Y, Dohmae N, van der Oost J, Suzuki T, Zhang F, and Nureki O

Subjects

CRISPR-Associated Proteins chemistry, CRISPR-Associated Proteins metabolism, CRISPR-Cas Systems, DNA chemistry, DNA genetics, DNA metabolism, DNA ultrastructure, RNA, Guide, CRISPR-Cas Systems chemistry, RNA, Guide, CRISPR-Cas Systems genetics, RNA, Guide, CRISPR-Cas Systems metabolism, RNA, Guide, CRISPR-Cas Systems ultrastructure, Substrate Specificity, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, DNA Transposable Elements genetics, Endodeoxyribonucleases chemistry, Endodeoxyribonucleases metabolism, Endodeoxyribonucleases ultrastructure, Deinococcus enzymology, Deinococcus genetics

Abstract

The class 2 type V CRISPR effector Cas12 is thought to have evolved from the IS200/IS605 superfamily of transposon-associated TnpB proteins 1 . Recent studies have identified TnpB proteins as miniature RNA-guided DNA endonucleases 2,3 . TnpB associates with a single, long RNA (ωRNA) and cleaves double-stranded DNA targets complementary to the ωRNA guide. However, the RNA-guided DNA cleavage mechanism of TnpB and its evolutionary relationship with Cas12 enzymes remain unknown. Here we report the cryo-electron microscopy (cryo-EM) structure of Deinococcus radiodurans ISDra2 TnpB in complex with its cognate ωRNA and target DNA. In the structure, the ωRNA adopts an unexpected architecture and forms a pseudoknot, which is conserved among all guide RNAs of Cas12 enzymes. Furthermore, the structure, along with our functional analysis, reveals how the compact TnpB recognizes the ωRNA and cleaves target DNA complementary to the guide. A structural comparison of TnpB with Cas12 enzymes suggests that CRISPR-Cas12 effectors acquired an ability to recognize the protospacer-adjacent motif-distal end of the guide RNA-target DNA heteroduplex, by either asymmetric dimer formation or diverse REC2 insertions, enabling engagement in CRISPR-Cas adaptive immunity. Collectively, our findings provide mechanistic insights into TnpB function and advance our understanding of the evolution from transposon-encoded TnpB proteins to CRISPR-Cas12 effectors., (© 2023. The Author(s).)

Published

2023

9. Structural basis for GSDMB pore formation and its targeting by IpaH7.8.

Author

Wang C, Shivcharan S, Tian T, Wright S, Ma D, Chang J, Li K, Song K, Xu C, Rathinam VA, and Ruan J

Subjects

Animals, Humans, Mice, Binding Sites, Conserved Sequence, Cryoelectron Microscopy, Protein Domains, Protein Isoforms chemistry, Protein Isoforms metabolism, Protein Isoforms ultrastructure, Pyroptosis, Shigella, Species Specificity, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Pore Forming Cytotoxic Proteins chemistry, Pore Forming Cytotoxic Proteins metabolism, Pore Forming Cytotoxic Proteins ultrastructure, Gasdermins chemistry, Gasdermins metabolism, Gasdermins ultrastructure

Abstract

Gasdermins (GSDMs) are pore-forming proteins that play critical roles in host defence through pyroptosis 1,2 . Among GSDMs, GSDMB is unique owing to its distinct lipid-binding profile and a lack of consensus on its pyroptotic potential 3-7 . Recently, GSDMB was shown to exhibit direct bactericidal activity through its pore-forming activity 4 . Shigella, an intracellular, human-adapted enteropathogen, evades this GSDMB-mediated host defence by secreting IpaH7.8, a virulence effector that triggers ubiquitination-dependent proteasomal degradation of GSDMB 4 . Here, we report the cryogenic electron microscopy structures of human GSDMB in complex with Shigella IpaH7.8 and the GSDMB pore. The structure of the GSDMB-IpaH7.8 complex identifies a motif of three negatively charged residues in GSDMB as the structural determinant recognized by IpaH7.8. Human, but not mouse, GSDMD contains this conserved motif, explaining the species specificity of IpaH7.8. The GSDMB pore structure shows the alternative splicing-regulated interdomain linker in GSDMB as a regulator of GSDMB pore formation. GSDMB isoforms with a canonical interdomain linker exhibit normal pyroptotic activity whereas other isoforms exhibit attenuated or no pyroptotic activity. Overall, this work sheds light on the molecular mechanisms of Shigella IpaH7.8 recognition and targeting of GSDMs and shows a structural determinant in GSDMB critical for its pyroptotic activity., (© 2023. The Author(s).)

Published

2023

10. From primordial clocks to circadian oscillators.

Author

Pitsawong W, Pádua RAP, Grant T, Hoemberger M, Otten R, Bradshaw N, Grigorieff N, and Kern D

Subjects

Phosphorylation, Crystallography, X-Ray, Cryoelectron Microscopy, Adenosine Triphosphate metabolism, Adenosine Diphosphate metabolism, Kinetics, Protein Folding, Protein Conformation, Allosteric Regulation, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Circadian Clocks, Circadian Rhythm, Rhodobacter sphaeroides chemistry, Rhodobacter sphaeroides metabolism

Abstract

Circadian rhythms play an essential part in many biological processes, and only three prokaryotic proteins are required to constitute a true post-translational circadian oscillator 1 . The evolutionary history of the three Kai proteins indicates that KaiC is the oldest member and a central component of the clock 2 . Subsequent additions of KaiB and KaiA regulate the phosphorylation state of KaiC for time synchronization. The canonical KaiABC system in cyanobacteria is well understood 3-6 , but little is known about more ancient systems that only possess KaiBC. However, there are reports that they might exhibit a basic, hourglass-like timekeeping mechanism 7-9 . Here we investigate the primordial circadian clock in Rhodobacter sphaeroides, which contains only KaiBC, to elucidate its inner workings despite missing KaiA. Using a combination of X-ray crystallography and cryogenic electron microscopy, we find a new dodecameric fold for KaiC, in which two hexamers are held together by a coiled-coil bundle of 12 helices. This interaction is formed by the carboxy-terminal extension of KaiC and serves as an ancient regulatory moiety that is later superseded by KaiA. A coiled-coil register shift between daytime and night-time conformations is connected to phosphorylation sites through a long-range allosteric network that spans over 140 Å. Our kinetic data identify the difference in the ATP-to-ADP ratio between day and night as the environmental cue that drives the clock. They also unravel mechanistic details that shed light on the evolution of self-sustained oscillators., (© 2023. The Author(s).)

Published

2023

11. Structures of the holo CRISPR RNA-guided transposon integration complex.

Author

Park JU, Tsai AW, Rizo AN, Truong VH, Wellner TX, Schargel RD, and Kellogg EH

Subjects

Clustered Regularly Interspaced Short Palindromic Repeats genetics, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, DNA-Binding Proteins ultrastructure, Cryoelectron Microscopy, Ribosome Subunits chemistry, Ribosome Subunits metabolism, Ribosome Subunits ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, DNA Transposable Elements genetics, Gene Editing methods, Transposases chemistry, Transposases metabolism, Transposases ultrastructure, RNA, Guide, CRISPR-Cas Systems genetics, CRISPR-Cas Systems, Holoenzymes chemistry, Holoenzymes metabolism, Holoenzymes ultrastructure, Multiprotein Complexes chemistry, Multiprotein Complexes metabolism, Multiprotein Complexes ultrastructure

Abstract

CRISPR-associated transposons (CAST) are programmable mobile genetic elements that insert large DNA cargos using an RNA-guided mechanism 1-3 . CAST elements contain multiple conserved proteins: a CRISPR effector (Cas12k or Cascade), a AAA+ regulator (TnsC), a transposase (TnsA-TnsB) and a target-site-associated factor (TniQ). These components are thought to cooperatively integrate DNA via formation of a multisubunit transposition integration complex (transpososome). Here we reconstituted the approximately 1 MDa type V-K CAST transpososome from Scytonema hofmannii (ShCAST) and determined its structure using single-particle cryo-electon microscopy. The architecture of this transpososome reveals modular association between the components. Cas12k forms a complex with ribosomal subunit S15 and TniQ, stabilizing formation of a full R-loop. TnsC has dedicated interaction interfaces with TniQ and TnsB. Of note, we observe TnsC-TnsB interactions at the C-terminal face of TnsC, which contribute to the stimulation of ATPase activity. Although the TnsC oligomeric assembly deviates slightly from the helical configuration found in isolation, the TnsC-bound target DNA conformation differs markedly in the transpososome. As a consequence, TnsC makes new protein-DNA interactions throughout the transpososome that are important for transposition activity. Finally, we identify two distinct transpososome populations that differ in their DNA contacts near TniQ. This suggests that associations with the CRISPR effector can be flexible. This ShCAST transpososome structure enhances our understanding of CAST transposition systems and suggests ways to improve CAST transposition for precision genome-editing applications., (© 2022. The Author(s).)

Published

2023

12. Mechanism of AAA+ ATPase-mediated RuvAB-Holliday junction branch migration.

Author

Wald J, Fahrenkamp D, Goessweiner-Mohr N, Lugmayr W, Ciccarelli L, Vesper O, and Marlovits TC

Subjects

Adenosine Triphosphate metabolism, Cryoelectron Microscopy, DNA, Single-Stranded chemistry, DNA, Single-Stranded metabolism, DNA, Single-Stranded ultrastructure, Homologous Recombination, Hydrolysis, Multienzyme Complexes chemistry, Multienzyme Complexes metabolism, Multienzyme Complexes ultrastructure, Nucleotides, Protein Conformation, Rotation, ATPases Associated with Diverse Cellular Activities chemistry, ATPases Associated with Diverse Cellular Activities metabolism, ATPases Associated with Diverse Cellular Activities ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, DNA Helicases chemistry, DNA Helicases metabolism, DNA Helicases ultrastructure, DNA, Cruciform chemistry, DNA, Cruciform metabolism, DNA, Cruciform ultrastructure

Abstract

The Holliday junction is a key intermediate formed during DNA recombination across all kingdoms of life 1 . In bacteria, the Holliday junction is processed by two homo-hexameric AAA+ ATPase RuvB motors, which assemble together with the RuvA-Holliday junction complex to energize the strand-exchange reaction 2 . Despite its importance for chromosome maintenance, the structure and mechanism by which this complex facilitates branch migration are unknown. Here, using time-resolved cryo-electron microscopy, we obtained structures of the ATP-hydrolysing RuvAB complex in seven distinct conformational states, captured during assembly and processing of a Holliday junction. Five structures together resolve the complete nucleotide cycle and reveal the spatiotemporal relationship between ATP hydrolysis, nucleotide exchange and context-specific conformational changes in RuvB. Coordinated motions in a converter formed by DNA-disengaged RuvB subunits stimulate hydrolysis and nucleotide exchange. Immobilization of the converter enables RuvB to convert the ATP-contained energy into a lever motion, which generates the pulling force driving the branch migration. We show that RuvB motors rotate together with the DNA substrate, which, together with a progressing nucleotide cycle, forms the mechanistic basis for DNA recombination by continuous branch migration. Together, our data decipher the molecular principles of homologous recombination by the RuvAB complex, elucidate discrete and sequential transition-state intermediates for chemo-mechanical coupling of hexameric AAA+ motors and provide a blueprint for the design of state-specific compounds targeting AAA+ motors., (© 2022. The Author(s).)

Published

2022

13. Molecular interplay of an assembly machinery for nitrous oxide reductase.

Author

Müller C, Zhang L, Zipfel S, Topitsch A, Lutz M, Eckert J, Prasser B, Chami M, Lü W, Du J, and Einsle O

Subjects

Adenosine Triphosphate metabolism, Binding Sites, Copper chemistry, Copper metabolism, Cytoplasm enzymology, Molecular Chaperones metabolism, Periplasm enzymology, Protein Binding, Protein Conformation, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, Nitrous Oxide metabolism, Oxidoreductases chemistry, Oxidoreductases metabolism, Oxidoreductases ultrastructure, Pseudomonas stutzeri cytology, Pseudomonas stutzeri enzymology

Abstract

Emissions of the critical ozone-depleting and greenhouse gas nitrous oxide (N 2 O) from soils and industrial processes have increased considerably over the last decades 1-3 . As the final step of bacterial denitrification, N 2 O is reduced to chemically inert N 2 (refs. 1,4 ) in a reaction that is catalysed by the copper-dependent nitrous oxide reductase (N 2 OR) (ref. 5 ). The assembly of its unique [4Cu:2S] active site cluster Cu Z requires both the ATP-binding-cassette (ABC) complex NosDFY and the membrane-anchored copper chaperone NosL (refs. 4,6 ). Here we report cryo-electron microscopy structures of Pseudomonas stutzeri NosDFY and its complexes with NosL and N 2 OR, respectively. We find that the periplasmic NosD protein contains a binding site for a Cu + ion and interacts specifically with NosL in its nucleotide-free state, whereas its binding to N 2 OR requires a conformational change that is triggered by ATP binding. Mutually exclusive structures of NosDFY in complex with NosL and with N 2 OR reveal a sequential metal-trafficking and assembly pathway for a highly complex copper site. Within this pathway, NosDFY acts as a mechanical energy transducer rather than as a transporter. It links ATP hydrolysis in the cytoplasm to a conformational transition of the NosD subunit in the periplasm, which is required for NosDFY to switch its interaction partner so that copper ions are handed over from the chaperone NosL to the enzyme N 2 OR., (© 2022. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2022

14. Cryo-EM structure of an active bacterial TIR-STING filament complex.

Author

Morehouse BR, Yip MCJ, Keszei AFA, McNamara-Bordewick NK, Shao S, and Kranzusch PJ

Subjects

Animals, Antiviral Agents metabolism, Bacteriophages immunology, Dinucleoside Phosphates metabolism, Humans, Immunity, Innate, Operon genetics, Bacterial Proteins chemistry, Bacterial Proteins immunology, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, Membrane Proteins chemistry, Membrane Proteins immunology, Membrane Proteins metabolism, Membrane Proteins ultrastructure, Receptors, Interleukin-1 chemistry, Receptors, Interleukin-1 immunology, Receptors, Interleukin-1 metabolism, Receptors, Interleukin-1 ultrastructure, Sphingobacterium chemistry, Sphingobacterium genetics, Sphingobacterium ultrastructure, Sphingobacterium virology, Toll-Like Receptors chemistry, Toll-Like Receptors immunology, Toll-Like Receptors metabolism, Toll-Like Receptors ultrastructure

Abstract

Stimulator of interferon genes (STING) is an antiviral signalling protein that is broadly conserved in both innate immunity in animals and phage defence in prokaryotes 1-4 . Activation of STING requires its assembly into an oligomeric filament structure through binding of a cyclic dinucleotide 4-13 , but the molecular basis of STING filament assembly and extension remains unknown. Here we use cryogenic electron microscopy to determine the structure of the active Toll/interleukin-1 receptor (TIR)-STING filament complex from a Sphingobacterium faecium cyclic-oligonucleotide-based antiphage signalling system (CBASS) defence operon. Bacterial TIR-STING filament formation is driven by STING interfaces that become exposed on high-affinity recognition of the cognate cyclic dinucleotide signal c-di-GMP. Repeating dimeric STING units stack laterally head-to-head through surface interfaces, which are also essential for human STING tetramer formation and downstream immune signalling in mammals 5 . The active bacterial TIR-STING structure reveals further cross-filament contacts that brace the assembly and coordinate packing of the associated TIR NADase effector domains at the base of the filament to drive NAD + hydrolysis. STING interface and cross-filament contacts are essential for cell growth arrest in vivo and reveal a stepwise mechanism of activation whereby STING filament assembly is required for subsequent effector activation. Our results define the structural basis of STING filament formation in prokaryotic antiviral signalling., (© 2022. The Author(s).)

Published

2022

15. Cryo-EM structure of a type IV secretion system.

Author

Macé K, Vadakkepat AK, Redzej A, Lukoyanova N, Oomen C, Braun N, Ukleja M, Lu F, Costa TRD, Orlova EV, Baker D, Cong Q, and Waksman G

Subjects

Conjugation, Genetic, DNA genetics, Evolution, Molecular, Fimbriae, Bacterial metabolism, Plasmids genetics, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, Type IV Secretion Systems chemistry, Type IV Secretion Systems metabolism, Type IV Secretion Systems ultrastructure

Abstract

Bacterial conjugation is the fundamental process of unidirectional transfer of DNAs, often plasmid DNAs, from a donor cell to a recipient cell 1 . It is the primary means by which antibiotic resistance genes spread among bacterial populations 2,3 . In Gram-negative bacteria, conjugation is mediated by a large transport apparatus-the conjugative type IV secretion system (T4SS)-produced by the donor cell and embedded in both its outer and inner membranes. The T4SS also elaborates a long extracellular filament-the conjugative pilus-that is essential for DNA transfer 4,5 . Here we present a high-resolution cryo-electron microscopy (cryo-EM) structure of a 2.8 megadalton T4SS complex composed of 92 polypeptides representing 8 of the 10 essential T4SS components involved in pilus biogenesis. We added the two remaining components to the structural model using co-evolution analysis of protein interfaces, to enable the reconstitution of the entire system including the pilus. This structure describes the exceptionally large protein-protein interaction network required to assemble the many components that constitute a T4SS and provides insights on the unique mechanism by which they elaborate pili., (© 2022. The Author(s).)

Published

2022

16. Target site selection and remodelling by type V CRISPR-transposon systems.

Author

Querques I, Schmitz M, Oberli S, Chanez C, and Jinek M

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphatases ultrastructure, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Biopolymers, CRISPR-Associated Proteins metabolism, Cryoelectron Microscopy, DNA, Bacterial genetics, DNA, Bacterial metabolism, DNA, Bacterial ultrastructure, Models, Molecular, Mutagenesis, Insertional, Polymerization, RNA genetics, RNA metabolism, Substrate Specificity, Transposases metabolism, Transposases ultrastructure, Zinc Fingers, CRISPR-Cas Systems genetics, Cyanobacteria enzymology, Cyanobacteria genetics, DNA Transposable Elements genetics, Gene Editing methods

Abstract

Canonical CRISPR-Cas systems provide adaptive immunity against mobile genetic elements 1 . However, type I-F, I-B and V-K systems have been adopted by Tn7-like transposons to direct RNA-guided transposon insertion 2-7 . Type V-K CRISPR-associated transposons rely on the pseudonuclease Cas12k, the transposase TnsB, the AAA+ ATPase TnsC and the zinc-finger protein TniQ 7 , but the molecular mechanism of RNA-directed DNA transposition has remained elusive. Here we report cryo-electron microscopic structures of a Cas12k-guide RNA-target DNA complex and a DNA-bound, polymeric TnsC filament from the CRISPR-associated transposon system of the photosynthetic cyanobacterium Scytonema hofmanni. The Cas12k complex structure reveals an intricate guide RNA architecture and critical interactions mediating RNA-guided target DNA recognition. TnsC helical filament assembly is ATP-dependent and accompanied by structural remodelling of the bound DNA duplex. In vivo transposition assays corroborate key features of the structures, and biochemical experiments show that TniQ restricts TnsC polymerization, while TnsB interacts directly with TnsC filaments to trigger their disassembly upon ATP hydrolysis. Together, these results suggest that RNA-directed target selection by Cas12k primes TnsC polymerization and DNA remodelling, generating a recruitment platform for TnsB to catalyse site-specific transposon insertion. Insights from this work will inform the development of CRISPR-associated transposons as programmable site-specific gene insertion tools., (© 2021. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2021

17. Molecular basis for control of antibiotic production by a bacterial hormone.

Author

Zhou S, Bhukya H, Malet N, Harrison PJ, Rea D, Belousoff MJ, Venugopal H, Sydor PK, Styles KM, Song L, Cryle MJ, Alkhalaf LM, Fülöp V, Challis GL, and Corre C

Subjects

Apoproteins chemistry, Apoproteins metabolism, Apoproteins ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins classification, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, Crystallography, X-Ray, DNA chemistry, DNA genetics, DNA metabolism, DNA ultrastructure, Furans chemistry, Hormones chemistry, Hormones classification, Hormones metabolism, Ligands, Models, Molecular, Peptides metabolism, Repressor Proteins chemistry, Repressor Proteins classification, Repressor Proteins metabolism, Repressor Proteins ultrastructure, Signal Transduction, Streptomyces coelicolor chemistry, Streptomyces coelicolor genetics, Structure-Activity Relationship, Anti-Bacterial Agents biosynthesis, Furans metabolism, Streptomyces coelicolor metabolism

Abstract

Actinobacteria produce numerous antibiotics and other specialized metabolites that have important applications in medicine and agriculture 1 . Diffusible hormones frequently control the production of such metabolites by binding TetR family transcriptional repressors (TFTRs), but the molecular basis for this remains unclear 2 . The production of methylenomycin antibiotics in Streptomyces coelicolor A3(2) is initiated by the binding of 2-alkyl-4-hydroxymethylfuran-3-carboxylic acid (AHFCA) hormones to the TFTR MmfR 3 . Here we report the X-ray crystal structure of an MmfR-AHFCA complex, establishing the structural basis for hormone recognition. We also elucidate the mechanism for DNA release upon hormone binding through the single-particle cryo-electron microscopy structure of an MmfR-operator complex. DNA binding and release assays with MmfR mutants and synthetic AHFCA analogues define the role of individual amino acid residues and hormone functional groups in ligand recognition and DNA release. These findings will facilitate the exploitation of actinobacterial hormones and their associated TFTRs in synthetic biology and in the discovery of new antibiotics.

Published

2021

18. Assembly properties of bacterial tubulin homolog FtsZ regulated by the positive regulator protein ZipA and ZapA from Pseudomonas aeruginosa.

Author

Rahman MU, Li Z, Zhang T, Du S, Ma X, Wang P, and Chen Y

Subjects

Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Cell Cycle Proteins chemistry, Cell Cycle Proteins ultrastructure, Cytoskeletal Proteins chemistry, Cytoskeletal Proteins ultrastructure, Fluorescence Resonance Energy Transfer, GTP Phosphohydrolases chemistry, GTP Phosphohydrolases metabolism, Kinetics, Microscopy, Electron, Protein Conformation, Pseudomonas aeruginosa ultrastructure, Tubulin chemistry, Tubulin ultrastructure, Bacterial Proteins metabolism, Cell Cycle Proteins metabolism, Cytoskeletal Proteins metabolism, Pseudomonas aeruginosa metabolism, Tubulin metabolism

Abstract

Bacterial tubulin homolog FtsZ self-assembles into dynamic protofilaments, which forms the scaffold for the contractile ring (Z-ring) to achieve bacterial cell division. Here, we study the biochemical properties of FtsZ from Pseudomonas aeruginosa (PaFtsZ) and the effects of its two positive regulator proteins, ZipA and ZapA. Similar to Escherichia coli FtsZ, PaFtsZ had a strong GTPase activity, ~ 7.8 GTP min -1 FtsZ -1 at pH 7.5, and assembled into mainly short single filaments in vitro. However, PaFtsZ protofilaments were mixtures of straight and "intermediate-curved" (100-300 nm diameter) in pH 7.5 solution and formed some bundles in pH 6.5 solution. The effects of ZipA on PaFtsZ assembly varied with pH. In pH 6.5 buffer ZipA induced PaFtsZ to form large bundles. In pH 7.5 buffer PaFtsZ-ZipA protofilaments were not bundled, but ZipA enhanced PaFtsZ assembly and promoted more curved filaments. Comparable to ZapA from other bacterial species, ZapA from P. aeruginosa induced PaFtsZ protofilaments to associate into long straight loose bundles and/or sheets at both pH 6.5 and pH 7.5, which had little effect on the GTPase activity of PaFtsZ. These results provide us further information that ZipA functions as an enhancer of FtsZ curved filaments, while ZapA works as a stabilizer of FtsZ straight filaments.

Published

2020

19. Structural analysis of a new carotenoid-binding protein: the C-terminal domain homolog of the OCP.

Author

Dominguez-Martin MA, Hammel M, Gupta S, Lechno-Yossef S, Sutter M, Rosenberg DJ, Chen Y, Petzold CJ, Ralston CY, Polívka T, and Kerfeld CA

Subjects

Bacterial Proteins chemistry, Crystallography, X-Ray, Cyanobacteria chemistry, Nucleocytoplasmic Transport Proteins chemistry, Nucleocytoplasmic Transport Proteins genetics, Protein Binding drug effects, Protein Domains genetics, Scattering, Small Angle, Bacterial Proteins ultrastructure, Canthaxanthin chemistry, Cyanobacteria ultrastructure, Nucleocytoplasmic Transport Proteins ultrastructure

Abstract

The Orange Carotenoid Protein (OCP) is a water-soluble protein that governs photoprotection in many cyanobacteria. The 35 kDa OCP is structurally and functionally modular, consisting of an N-terminal effector domain (NTD) and a C-terminal regulatory domain (CTD); a carotenoid spans the two domains. The CTD is a member of the ubiquitous Nuclear Transport Factor-2 (NTF2) superfamily (pfam02136). With the increasing availability of cyanobacterial genomes, bioinformatic analysis has revealed the existence of a new family of proteins, homologs to the CTD, the C-terminal domain-like carotenoid proteins (CCPs). Here we purify holo-CCP2 directly from cyanobacteria and establish that it natively binds canthaxanthin (CAN). We use small-angle X-ray scattering (SAXS) to characterize the structure of this carotenoprotein in two distinct oligomeric states. A single carotenoid molecule spans the two CCPs in the dimer. Our analysis with X-ray footprinting-mass spectrometry (XFMS) identifies critical residues for carotenoid binding that likely contribute to the extreme red shift (ca. 80 nm) of the absorption maximum of the carotenoid bound by the CCP2 dimer and a further 10 nm shift in the tetramer form. These data provide the first structural description of carotenoid binding by a protein consisting of only an NTF2 domain.

Published

2020

20. Studies of structural determinants of substrate binding in the Creatine Transporter (CreaT, SLC6A8) using molecular models.

Author

Colas C, Banci G, Martini R, and Ecker GF

Subjects

Aquifex, Bacterial Proteins ultrastructure, Binding Sites, Creatine chemistry, Ligands, Nerve Tissue Proteins chemistry, Nerve Tissue Proteins ultrastructure, Plasma Membrane Neurotransmitter Transport Proteins chemistry, Plasma Membrane Neurotransmitter Transport Proteins ultrastructure, Protein Conformation, alpha-Helical, Sequence Alignment, Sequence Homology, Amino Acid, Serotonin Plasma Membrane Transport Proteins ultrastructure, Substrate Specificity, Creatine metabolism, Molecular Docking Simulation, Nerve Tissue Proteins metabolism, Plasma Membrane Neurotransmitter Transport Proteins metabolism

Abstract

Creatine is a crucial metabolite that plays a fundamental role in ATP homeostasis in tissues with high-energy demands. The creatine transporter (CreaT, SLC6A8) belongs to the solute carrier 6 (SLC6) transporters family, and more particularly to the GABA transporters (GATs) subfamily. Understanding the molecular determinants of specificity within the SLC6 transporters in general, and the GATs in particular is very challenging due to the high similarity of these proteins. In the study presented here, our efforts focused on finding key structural features involved in binding selectivity for CreaT using structure-based computational methods. Due to the lack of three-dimensional structures of SLC6A8, our approach was based on the realization of two reliable homology models of CreaT using the structures of two templates, i.e. the human serotonin transporter (hSERT) and the prokaryotic leucine transporter (LeuT). Our models reveal that an optimal complementarity between the shape of the binding site and the size of the ligands is necessary for transport. These findings provide a framework for a deeper understanding of substrate selectivity of the SLC6 family and other LeuT fold transporters.

Published

2020

21. Cryo-EM structure of a type I-F CRISPR RNA guided surveillance complex bound to transposition protein TniQ.

Author

Li Z, Zhang H, Xiao R, and Chang L

Subjects

DNA Transposable Elements genetics, Models, Molecular, Vibrio cholerae genetics, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Clustered Regularly Interspaced Short Palindromic Repeats genetics, Cryoelectron Microscopy, RNA, Guide, CRISPR-Cas Systems metabolism

Published

2020

22. Molecular and structural insights into an asymmetric proteolytic complex (ClpP1P2) from Mycobacterium smegmatis.

Author

Nagpal J, Paxman JJ, Zammit JE, Thomas AA, Truscott KN, Heras B, and Dougan DA

Subjects

Adenosine Triphosphatases metabolism, Adenosine Triphosphatases ultrastructure, Bacterial Proteins metabolism, Crystallography, X-Ray, Endopeptidase Clp metabolism, Molecular Docking Simulation, Protein Structure, Quaternary, Proteolysis, Bacterial Proteins ultrastructure, Endopeptidase Clp ultrastructure, Mycobacterium smegmatis metabolism, Protein Multimerization, Protein Subunits metabolism

Abstract

The ClpP protease is found in all kingdoms of life, from bacteria to humans. In general, this protease forms a homo-oligomeric complex composed of 14 identical subunits, which associates with its cognate ATPase in a symmetrical manner. Here we show that, in contrast to this general architecture, the Clp protease from Mycobacterium smegmatis (Msm) forms an asymmetric hetero-oligomeric complex ClpP1P2, which only associates with its cognate ATPase through the ClpP2 ring. Our structural and functional characterisation of this complex demonstrates that asymmetric docking of the ATPase component is controlled by both the composition of the ClpP1 hydrophobic pocket (Hp) and the presence of a unique C-terminal extension in ClpP1 that guards this Hp. Our structural analysis of Msm ClpP1 also revealed openings in the side-walls of the inactive tetradecamer, which may represent sites for product egress.

Published

2019

23. Exit tunnel modulation as resistance mechanism of S. aureus erythromycin resistant mutant.

Author

Halfon Y, Matzov D, Eyal Z, Bashan A, Zimmerman E, Kjeldgaard J, Ingmer H, and Yonath A

Subjects

Anti-Bacterial Agents therapeutic use, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Cryoelectron Microscopy, Erythromycin therapeutic use, Humans, Mutation, Protein Binding genetics, RNA, Ribosomal, 23S metabolism, RNA, Ribosomal, 23S ultrastructure, Ribosomal Proteins genetics, Ribosomal Proteins metabolism, Ribosome Subunits, Large, Bacterial drug effects, Ribosome Subunits, Large, Bacterial metabolism, Ribosome Subunits, Large, Bacterial ultrastructure, Ribosomes drug effects, Ribosomes metabolism, Ribosomes ultrastructure, Single Molecule Imaging, Staphylococcal Infections drug therapy, Staphylococcal Infections microbiology, Staphylococcus aureus genetics, Staphylococcus aureus ultrastructure, Anti-Bacterial Agents pharmacology, Bacterial Proteins ultrastructure, Drug Resistance, Bacterial genetics, Erythromycin pharmacology, Ribosomal Proteins ultrastructure, Staphylococcus aureus drug effects

Abstract

The clinical use of the antibiotic erythromycin (ery) is hampered owing to the spread of resistance genes that are mostly mutating rRNA around the ery binding site at the entrance to the protein exit tunnel. Additional effective resistance mechanisms include deletion or insertion mutations in ribosomal protein uL22, which lead to alterations of the exit tunnel shape, located 16 Å away from the drug's binding site. We determined the cryo-EM structures of the Staphylococcus aureus 70S ribosome, and its ery bound complex with a two amino acid deletion mutation in its ß hairpin loop, which grants the bacteria resistance to ery. The structures reveal that, although the binding of ery is stable, the movement of the flexible shorter uL22 loop towards the tunnel wall creates a wider path for nascent proteins, thus enabling bypass of the barrier formed by the drug. Moreover, upon drug binding, the tunnel widens further.

Published

2019

24. X-ray Crystallographic Structure and Oligomerization of Gloeobacter Rhodopsin.

Author

Morizumi T, Ou WL, Van Eps N, Inoue K, Kandori H, Brown LS, and Ernst OP

Subjects

Amino Acid Sequence genetics, Bacterial Proteins ultrastructure, Bacteroidetes chemistry, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Hydrogen Bonding, Protein Multimerization genetics, Proton Pumps chemical synthesis, Proton Pumps chemistry, Rhodopsin chemistry, Rhodopsin genetics, Rhodopsins, Microbial ultrastructure, Spectrum Analysis, Raman, Bacteroidetes ultrastructure, Protein Conformation, Proton Pumps ultrastructure, Rhodopsin ultrastructure

Abstract

Gloeobacter rhodopsin (GR) is a cyanobacterial proton pump which can be potentially applied to optogenetics. We solved the crystal structure of GR and found that it has overall similarity to the homologous proton pump from Salinibacter ruber, xanthorhodopsin (XR). We identified distinct structural characteristics of GR's hydrogen bonding network in the transmembrane domain as well as the displacement of extracellular sides of the transmembrane helices relative to those of XR. Employing Raman spectroscopy and flash-photolysis, we found that GR in the crystals exists in a state which displays retinal conformation and photochemical cycle similar to the functional form observed in lipids. Based on the crystal structure of GR, we selected a site for spin labeling to determine GR's oligomerization state using double electron-electron resonance (DEER) spectroscopy and demonstrated the pH-dependent pentamer formation of GR. Determination of the structure of GR as well as its pentamerizing propensity enabled us to reveal the role of structural motifs (extended helices, 3-omega motif and flipped B-C loop) commonly found among light-driven bacterial pumps in oligomer formation. Here we propose a new concept to classify these pumps based on the relationship between their oligomerization propensities and these structural determinants.

Published

2019

25. Structural and biochemical characterization of Rv0187, an O-methyltransferase from Mycobacterium tuberculosis.

Author

Lee S, Kang J, and Kim J

Subjects

Bacterial Proteins genetics, Bacterial Proteins isolation & purification, Bacterial Proteins ultrastructure, Catalytic Domain genetics, Catechol O-Methyltransferase genetics, Catechol O-Methyltransferase isolation & purification, Catechol O-Methyltransferase ultrastructure, Coenzymes metabolism, Crystallography, X-Ray, Enzyme Assays, Lysine genetics, Lysine metabolism, Methylation, Models, Molecular, Mutation, Mycobacterium tuberculosis genetics, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Recombinant Proteins ultrastructure, S-Adenosylhomocysteine metabolism, Strontium metabolism, Substrate Specificity genetics, Bacterial Proteins metabolism, Catechol O-Methyltransferase metabolism, Mycobacterium tuberculosis enzymology

Abstract

Catechol O-methyltransferase (COMT) is widely distributed in nature and installs a methyl group onto one of the vicinal hydroxyl groups of a catechol derivative. Enzymes belonging to this family require two cofactors for methyl transfer: S-adenosyl-l-methionine as a methyl donor and a divalent metal cation for regiospecific binding and activation of a substrate. We have determined two high-resolution crystal structures of Rv0187, one of three COMT paralogs from Mycobacterium tuberculosis, in the presence and absence of cofactors. The cofactor-bound structure clearly locates strontium ions and S-adenosyl-l-homocysteine in the active site, and together with the complementary structure of the ligand-free form, it suggests conformational dynamics induced by the binding of cofactors. Examination of in vitro activities revealed promiscuous substrate specificity and relaxed regioselectivity against various catechol-like compounds. Unexpectedly, mutation of the proposed catalytic lysine residue did not abolish activity but altered the overall landscape of regiospecific methylation.

Published

2019

26. Rubisco condensate formation by CcmM in β-carboxysome biogenesis.

Author

Wang H, Yan X, Aigner H, Bracher A, Nguyen ND, Hee WY, Long BM, Price GD, Hartl FU, and Hayer-Hartl M

Subjects

Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Carbon Cycle, Carbon Dioxide metabolism, Carbonic Anhydrases chemistry, Carbonic Anhydrases metabolism, Carbonic Anhydrases ultrastructure, Cryoelectron Microscopy, Disulfides metabolism, Models, Molecular, Oxidation-Reduction, Protein Subunits chemistry, Protein Subunits metabolism, Ribulose-Bisphosphate Carboxylase ultrastructure, Bacterial Proteins metabolism, Organelles metabolism, Protein Multimerization, Ribulose-Bisphosphate Carboxylase chemistry, Ribulose-Bisphosphate Carboxylase metabolism, Synechococcus enzymology

Abstract

Cells use compartmentalization of enzymes as a strategy to regulate metabolic pathways and increase their efficiency 1 . The α- and β-carboxysomes of cyanobacteria contain ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco)-a complex of eight large (RbcL) and eight small (RbcS) subunits-and carbonic anhydrase 2-4 . As HCO 3 - can diffuse through the proteinaceous carboxysome shell but CO 2 cannot 5 , carbonic anhydrase generates high concentrations of CO 2 for carbon fixation by Rubisco 6 . The shell also prevents access to reducing agents, generating an oxidizing environment 7-9 . The formation of β-carboxysomes involves the aggregation of Rubisco by the protein CcmM 10 , which exists in two forms: full-length CcmM (M58 in Synechococcus elongatus PCC7942), which contains a carbonic anhydrase-like domain 8 followed by three Rubisco small subunit-like (SSUL) modules connected by flexible linkers; and M35, which lacks the carbonic anhydrase-like domain 11 . It has long been speculated that the SSUL modules interact with Rubisco by replacing RbcS 2-4 . Here we have reconstituted the Rubisco-CcmM complex and solved its structure. Contrary to expectation, the SSUL modules do not replace RbcS, but bind close to the equatorial region of Rubisco between RbcL dimers, linking Rubisco molecules and inducing phase separation into a liquid-like matrix. Disulfide bond formation in SSUL increases the network flexibility and is required for carboxysome function in vivo. Notably, the formation of the liquid-like condensate of Rubisco is mediated by dynamic interactions with the SSUL domains, rather than by low-complexity sequences, which typically mediate liquid-liquid phase separation in eukaryotes 12,13 . Indeed, within the pyrenoids of eukaryotic algae, the functional homologues of carboxysomes, Rubisco adopts a liquid-like state by interacting with the intrinsically disordered protein EPYC1 14 . Understanding carboxysome biogenesis will be important for efforts to engineer CO 2 -concentrating mechanisms in plants 15-19 .

Published

2019

27. Collapse of genetic division of labour and evolution of autonomy in pellicle biofilms.

Author

Dragoš A, Martin M, Falcón García C, Kricks L, Pausch P, Heimerl T, Bálint B, Maróti G, Bange G, López D, Lieleg O, and Kovács ÁT

Subjects

Adaptation, Physiological, Amyloid chemistry, Amyloid ultrastructure, Bacillus subtilis ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Coculture Techniques, Gene Expression Regulation, Bacterial, Genes, Bacterial genetics, Mutation, Phenotype, Polysaccharides, Bacterial genetics, Polysaccharides, Bacterial metabolism, Protein Multimerization, Bacillus subtilis genetics, Bacillus subtilis metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biofilms, Cell Division physiology

Abstract

Closely related microorganisms often cooperate, but the prevalence and stability of cooperation between different genotypes remain debatable. Here, we track the evolution of pellicle biofilms formed through genetic division of labour and ask whether partially deficient partners can evolve autonomy. Pellicles of Bacillus subtilis rely on an extracellular matrix composed of exopolysaccharide (EPS) and the fibre protein TasA. In monocultures, ∆eps and ∆tasA mutants fail to form pellicles, but, facilitated by cooperation, they succeed in co-culture. Interestingly, cooperation collapses on an evolutionary timescale and ∆tasA gradually outcompetes its partner ∆eps. Pellicle formation can evolve independently from division of labour in ∆eps and ∆tasA monocultures, by selection acting on the residual matrix component, TasA or EPS, respectively. Using a set of interdisciplinary tools, we unravel that the TasA producer (∆eps) evolves via an unconventional but reproducible substitution in TasA that modulates the biochemical properties of the protein. Conversely, the EPS producer (ΔtasA) undergoes genetically variable adaptations, all leading to enhanced EPS secretion and biofilms with different biomechanical properties. Finally, we revisit the collapse of division of labour between Δeps and ΔtasA in light of a strong frequency versus exploitability trade-off that manifested in the solitarily evolving partners. We propose that such trade-off differences may represent an additional barrier to evolution of division of labour between genetically distinct microorganisms.

Published

2018

28. Structure of bacterial oligosaccharyltransferase PglB bound to a reactive LLO and an inhibitory peptide.

Author

Napiórkowska M, Boilevin J, Darbre T, Reymond JL, and Locher KP

Subjects

Bacterial Proteins antagonists & inhibitors, Bacterial Proteins metabolism, Crystallography, X-Ray, Hexosyltransferases antagonists & inhibitors, Hexosyltransferases metabolism, Membrane Proteins antagonists & inhibitors, Membrane Proteins metabolism, Models, Molecular, Peptides pharmacology, Protein Binding, Recombinant Proteins metabolism, Recombinant Proteins ultrastructure, Bacterial Proteins ultrastructure, Campylobacter lari enzymology, Hexosyltransferases ultrastructure, Lipopolysaccharides metabolism, Membrane Proteins ultrastructure

Abstract

Oligosaccharyltransferase (OST) is a key enzyme of the N-glycosylation pathway, where it catalyzes the transfer of a glycan from a lipid-linked oligosaccharide (LLO) to an acceptor asparagine within the conserved sequon N-X-T/S. A previous structure of a ternary complex of bacterial single subunit OST, PglB, bound to a non-hydrolyzable LLO analog and a wild type acceptor peptide showed how both substrates bind and how an external loop (EL5) of the enzyme provided specific substrate-binding contacts. However, there was a relatively large separation of the substrates at the active site. Here we present the X-ray structure of PglB bound to a reactive LLO analog and an inhibitory peptide, revealing previously unobserved interactions in the active site. We found that the atoms forming the N-glycosidic bond (C-1 of the GlcNAc moiety of LLO and the -NH 2 group of the peptide) are closer than in the previous structure, suggesting that we have captured a conformation closer to the transition state of the reaction. We find that the distance between the divalent metal ion and the glycosidic oxygen of LLO is now 4 Å, suggesting that the metal stabilizes the leaving group of the nucleophilic substitution reaction. Further, the carboxylate group of a conserved aspartate of PglB mediates an interaction network between the reducing-end sugar of the LLO, the asparagine side chain of the acceptor peptide, and a bound divalent metal ion. The interactions identified in this novel state are likely to be relevant in the catalytic mechanisms of all OSTs.

Published

2018

29. Off-axis rotor in Enterococcus hirae V-ATPase visualized by Zernike phase plate single-particle cryo-electron microscopy.

Author

Tsunoda J, Song C, Imai FL, Takagi J, Ueno H, Murata T, Iino R, and Murata K

Subjects

Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Enterococcus hirae metabolism, Enterococcus hirae ultrastructure, Gram-Positive Bacterial Infections microbiology, Humans, Models, Molecular, Protein Subunits metabolism, Recombinant Proteins metabolism, Recombinant Proteins ultrastructure, Vacuolar Proton-Translocating ATPases metabolism, Cryoelectron Microscopy methods, Enterococcus hirae enzymology, Vacuolar Proton-Translocating ATPases ultrastructure

Abstract

EhV-ATPase is an ATP-driven Na + pump in the eubacteria Enterococcus hirae (Eh). Here, we present the first entire structure of detergent-solubilized EhV-ATPase by single-particle cryo-electron microscopy (cryo-EM) using Zernike phase plate. The cryo-EM map dominantly showed one of three catalytic conformations in this rotary enzyme. To further stabilize the originally heterogeneous structure caused by the ATP hydrolysis states of the V 1 -ATPases, a peptide epitope tag system was adopted, in which the inserted peptide epitope sequence interfered with rotation of the central rotor by binding the Fab. As a result, the map unexpectedly showed another catalytic conformation of EhV-ATPase. Interestingly, these two conformations identified with and without Fab conversely coincided with those of the minor state 2 and the major state 1 of Thermus thermophilus V/A-ATPase, respectively. The most prominent feature in EhV-ATPase was the off-axis rotor, where the cytoplasmic V 1 domain was connected to the transmembrane V o domain through the off-axis central rotor. Furthermore, compared to the structure of ATP synthases, the larger size of the interface between the transmembrane a-subunit and c-ring of EhV-ATPase would be more advantageous for active ion pumping.

Published

2018

30. Mechanism of loading and translocation of type VI secretion system effector Tse6.

Author

Quentin D, Ahmad S, Shanthamoorthy P, Mougous JD, Whitney JC, and Raunser S

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins ultrastructure, Bacterial Toxins chemistry, Bacterial Toxins genetics, Cell Membrane chemistry, Cell Membrane metabolism, Cryoelectron Microscopy, Lipid Bilayers chemistry, Models, Molecular, Molecular Chaperones metabolism, Mutation, Protein Domains, Protein Stability, Type VI Secretion Systems metabolism, Bacterial Proteins metabolism, Bacterial Toxins metabolism, Pseudomonas aeruginosa metabolism, Type VI Secretion Systems chemistry

Abstract

The type VI secretion system (T6SS) primarily functions to mediate antagonistic interactions between contacting bacterial cells, but also mediates interactions with eukaryotic hosts. This molecular machine secretes antibacterial effector proteins by undergoing cycles of extension and contraction; however, how effectors are loaded into the T6SS and subsequently delivered to target bacteria remains poorly understood. Here, using electron cryomicroscopy, we analysed the structures of the Pseudomonas aeruginosa effector Tse6 loaded onto the T6SS spike protein VgrG1 in solution and embedded in lipid nanodiscs. In the absence of membranes, Tse6 stability requires the chaperone EagT6, two dimers of which interact with the hydrophobic transmembrane domains of Tse6. EagT6 is not directly involved in Tse6 delivery but is crucial for its loading onto VgrG1. VgrG1-loaded Tse6 spontaneously enters membranes and its toxin domain translocates across a lipid bilayer, indicating that effector delivery by the T6SS does not require puncturing of the target cell inner membrane by VgrG1. Eag chaperone family members from diverse Proteobacteria are often encoded adjacent to putative toxins with predicted transmembrane domains and we therefore anticipate that our findings will be generalizable to numerous T6SS-exported membrane-associated effectors.

Published

2018

31. Direct production of a genetically-encoded immobilized biodiesel catalyst.

Author

Heater BS, Lee MM, and Chan MK

Subjects

Bacillus thuringiensis ultrastructure, Bacillus thuringiensis Toxins, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Catalysis, Crystallization, Endotoxins metabolism, Escherichia coli metabolism, Escherichia coli ultrastructure, Hemolysin Proteins metabolism, Hemolysin Proteins ultrastructure, Kinetics, Lipase metabolism, Recombinant Fusion Proteins metabolism, Biofuels, Biotechnology methods, Enzymes, Immobilized metabolism, Lipase genetics

Abstract

The use of immobilized enzymes as biocatalysts has great potential to improve the efficiency and environmental sustainability of many industrial processes. Here, we report a novel approach that allows for the direct production of a highly active immobilized lipase within the bacterium Bacillus thuringiensis. Cry3Aa-lipA crystals were generated by genetically fusing Bacillus subtilis lipase A to Cry3Aa, a protein that naturally forms crystals in the bacteria. The crystal framework significantly stabilized the lipase against denaturation in organic solvents and high temperatures, resulting in a highly efficient fusion crystal that could catalyze the conversion of triacylglycerols to fatty acid methyl ester biodiesel to near-completion over 10 cycles. The simplicity and robustness of the Cry-fusion crystal (CFC) immobilization system could make it an appealing platform for generating industrial biocatalysts for multiple bioprocesses.

Published

2018

32. Cryo-EM structure of the Blastochloris viridis LH1-RC complex at 2.9 Å.

Author

Qian P, Siebert CA, Wang P, Canniffe DP, and Hunter CN

Subjects

Apoproteins chemistry, Apoproteins metabolism, Apoproteins ultrastructure, Bacterial Proteins metabolism, Bacteriochlorophylls chemistry, Bacteriochlorophylls metabolism, Benzoquinones metabolism, Binding Sites, Light-Harvesting Protein Complexes metabolism, Magnesium chemistry, Magnesium metabolism, Models, Molecular, Photosynthesis, Protein Conformation, Protein Stability, Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, Hyphomicrobiaceae chemistry, Light-Harvesting Protein Complexes chemistry, Light-Harvesting Protein Complexes ultrastructure

Abstract

The light-harvesting 1-reaction centre (LH1-RC) complex is a key functional component of bacterial photosynthesis. Here we present a 2.9 Å resolution cryo-electron microscopy structure of the bacteriochlorophyll b-based LH1-RC complex from Blastochloris viridis that reveals the structural basis for absorption of infrared light and the molecular mechanism of quinone migration across the LH1 complex. The triple-ring LH1 complex comprises a circular array of 17 β-polypeptides sandwiched between 17 α- and 16 γ-polypeptides. Tight packing of the γ-apoproteins between β-polypeptides collectively interlocks and stabilizes the LH1 structure; this, together with the short Mg-Mg distances of bacteriochlorophyll b pairs, contributes to the large redshift of bacteriochlorophyll b absorption. The 'missing' 17th γ-polypeptide creates a pore in the LH1 ring, and an adjacent binding pocket provides a folding template for a quinone, Q P , which adopts a compact, export-ready conformation before passage through the pore and eventual diffusion to the cytochrome bc 1 complex.

Published

2018

33. Structural basis of MsbA-mediated lipopolysaccharide transport.

Author

Mi W, Li Y, Yoon SH, Ernst RK, Walz T, and Liao M

Subjects

ATP-Binding Cassette Transporters chemistry, Adenosine Diphosphate chemistry, Adenosine Diphosphate metabolism, Bacterial Proteins chemistry, Biological Transport, Cell Membrane chemistry, Cell Membrane metabolism, Cell Membrane ultrastructure, Hydrophobic and Hydrophilic Interactions, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Models, Molecular, Nanostructures chemistry, Nanostructures ultrastructure, Periplasm chemistry, Periplasm metabolism, Periplasm ultrastructure, Protein Binding, Protein Domains, ATP-Binding Cassette Transporters metabolism, ATP-Binding Cassette Transporters ultrastructure, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Cryoelectron Microscopy, Escherichia coli cytology, Escherichia coli enzymology, Escherichia coli ultrastructure, Lipopolysaccharides metabolism

Abstract

Lipopolysaccharide (LPS) in the outer membrane of Gram-negative bacteria is critical for the assembly of their cell envelopes. LPS synthesized in the cytoplasmic leaflet of the inner membrane is flipped to the periplasmic leaflet by MsbA, an ATP-binding cassette transporter. Despite substantial efforts, the structural mechanisms underlying MsbA-driven LPS flipping remain elusive. Here we use single-particle cryo-electron microscopy to elucidate the structures of lipid-nanodisc-embedded MsbA in three functional states. The 4.2 Å-resolution structure of the transmembrane domains of nucleotide-free MsbA reveals that LPS binds deep inside MsbA at the height of the periplasmic leaflet, establishing extensive hydrophilic and hydrophobic interactions with MsbA. Two sub-nanometre-resolution structures of MsbA with ADP-vanadate and ADP reveal an unprecedented closed and an inward-facing conformation, respectively. Our study uncovers the structural basis for LPS recognition, delineates the conformational transitions of MsbA to flip LPS, and paves the way for structural characterization of other lipid flippases.

Published

2017

34. Alternate binding modes of anti-CRISPR viral suppressors AcrF1/2 to Csy surveillance complex revealed by cryo-EM structures.

Author

Peng R, Xu Y, Zhu T, Li N, Qi J, Chai Y, Wu M, Zhang X, Shi Y, Wang P, Wang J, Gao N, and Gao GF

Subjects

Bacterial Proteins genetics, Bacterial Proteins ultrastructure, Binding Sites, CRISPR-Associated Proteins genetics, CRISPR-Associated Proteins ultrastructure, Cryoelectron Microscopy, DNA, Bacterial metabolism, Endopeptidases metabolism, Membrane Proteins genetics, Membrane Proteins ultrastructure, Models, Molecular, Potyvirus, Pseudomonas Phages, RNA, Bacterial metabolism, Viral Proteins metabolism, Bacterial Proteins chemistry, CRISPR-Associated Proteins chemistry, CRISPR-Cas Systems, Membrane Proteins chemistry, Pseudomonas aeruginosa virology

Abstract

Bacteriophages encode anti-CRISPR suppressors to counteract the CRISPR/Cas immunity of their bacterial hosts, thus facilitating their survival and replication. Previous studies have shown that two phage-encoded anti-CRISPR proteins, AcrF1 and AcrF2, suppress the type I-F CRISPR/Cas system of Pseudomonas aeruginosa by preventing target DNA recognition by the Csy surveillance complex, but the precise underlying mechanism was unknown. Here we present the structure of AcrF1/2 bound to the Csy complex determined by cryo-EM single-particle reconstruction. By structural analysis, we found that AcrF1 inhibits target DNA recognition of the Csy complex by interfering with base pairing between the DNA target strand and crRNA spacer. In addition, multiple copies of AcrF1 bind to the Csy complex with different modes when working individually or cooperating with AcrF2, which might exclude target DNA binding through different mechanisms. Together with previous reports, we provide a comprehensive working scenario for the two anti-CRISPR suppressors, AcrF1 and AcrF2, which silence CRISPR/Cas immunity by targeting the Csy surveillance complex.

Published

2017

35. Crystal Structure of StnA for the Biosynthesis of Antitumor Drug Streptonigrin Reveals a Unique Substrate Binding Mode.

Author

Qian T, Wo J, Zhang Y, Song Q, Feng G, Luo R, Lin S, Wu G, and Chen HF

Subjects

Antibiotics, Antineoplastic pharmacokinetics, Bacterial Proteins ultrastructure, Carboxylic Ester Hydrolases ultrastructure, Catalytic Domain, Escherichia coli, Molecular Conformation, Molecular Dynamics Simulation, Sequence Analysis, Protein, Streptonigrin chemistry, Substrate Specificity, Antibiotics, Antineoplastic chemistry, Bacterial Proteins chemistry, Carboxylic Ester Hydrolases chemistry, Streptonigrin biosynthesis

Abstract

Streptonigrin methylesterase A (StnA) is one of the tailoring enzymes that modify the aminoquinone skeleton in the biosynthesis pathway of Streptomyces species. Although StnA has no significant sequence homology with the reported α/β-fold hydrolases, it shows typical hydrolytic activity in vivo and in vitro. In order to reveal its functional characteristics, the crystal structures of the selenomethionine substituted StnA (SeMet-StnA) and the complex (S185A mutant) with its substrate were resolved to the resolution of 2.71 Å and 2.90 Å, respectively. The overall structure of StnA can be described as an α-helix cap domain on top of a common α/β hydrolase domain. The substrate methyl ester of 10'-demethoxystreptonigrin binds in a hydrophobic pocket that mainly consists of cap domain residues and is close to the catalytic triad Ser185-His349-Asp308. The transition state is stabilized by an oxyanion hole formed by the backbone amides of Ala102 and Leu186. The substrate binding appears to be dominated by interactions with several specific hydrophobic contacts and hydrogen bonds in the cap domain. The molecular dynamics simulation and site-directed mutagenesis confirmed the important roles of the key interacting residues in the cap domain. Structural alignment and phylogenetic tree analysis indicate that StnA represents a new subfamily of lipolytic enzymes with the specific binding pocket located at the cap domain instead of the interface between the two domains.

Published

2017

36. The pathway to GTPase activation of elongation factor SelB on the ribosome.

Author

Fischer N, Neumann P, Bock LV, Maracci C, Wang Z, Paleskava A, Konevega AL, Schröder GF, Grubmüller H, Ficner R, Rodnina MV, and Stark H

Subjects

Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Binding Sites, Codon, Terminator chemistry, Codon, Terminator genetics, Codon, Terminator metabolism, Cryoelectron Microscopy, Endoribonucleases metabolism, Enzyme Activation, Escherichia coli chemistry, Escherichia coli genetics, Escherichia coli ultrastructure, Fungal Proteins metabolism, GTP Phosphohydrolases ultrastructure, Models, Molecular, Nucleic Acid Conformation, Protein Binding, Protein Biosynthesis, Protein Domains, RNA, Transfer, Amino Acid-Specific chemistry, RNA, Transfer, Amino Acid-Specific genetics, RNA, Transfer, Amino Acid-Specific metabolism, RNA, Transfer, Amino Acid-Specific ultrastructure, Ribosome Subunits, Large, Bacterial chemistry, Ribosome Subunits, Large, Bacterial metabolism, Ribosome Subunits, Large, Bacterial ultrastructure, Ribosome Subunits, Small, Bacterial chemistry, Ribosome Subunits, Small, Bacterial metabolism, Ribosome Subunits, Small, Bacterial ultrastructure, Ribosomes chemistry, Ribosomes enzymology, Ribosomes ultrastructure, Ricin metabolism, Selenocysteine metabolism, Bacterial Proteins metabolism, Escherichia coli metabolism, GTP Phosphohydrolases metabolism, Ribosomes metabolism

Abstract

In all domains of life, selenocysteine (Sec) is delivered to the ribosome by selenocysteine-specific tRNA (tRNA Sec ) with the help of a specialized translation factor, SelB in bacteria. Sec-tRNA Sec recodes a UGA stop codon next to a downstream mRNA stem-loop. Here we present the structures of six intermediates on the pathway of UGA recoding in Escherichia coli by single-particle cryo-electron microscopy. The structures explain the specificity of Sec-tRNA Sec binding by SelB and show large-scale rearrangements of Sec-tRNA Sec . Upon initial binding of SelB-Sec-tRNA Sec to the ribosome and codon reading, the 30S subunit adopts an open conformation with Sec-tRNA Sec covering the sarcin-ricin loop (SRL) on the 50S subunit. Subsequent codon recognition results in a local closure of the decoding site, which moves Sec-tRNA Sec away from the SRL and triggers a global closure of the 30S subunit shoulder domain. As a consequence, SelB docks on the SRL, activating the GTPase of SelB. These results reveal how codon recognition triggers GTPase activation in translational GTPases.

Published

2016

37. An Atomic Force Microscope with Dual Actuation Capability for Biomolecular Experiments.

Author

Sevim S, Shamsudhin N, Ozer S, Feng L, Fakhraee A, Ergeneman O, Pané S, Nelson BJ, and Torun H

Subjects

Electromagnetic Fields, Magnets, Microscopy, Atomic Force methods, Bacterial Proteins ultrastructure, Biotin analogs & derivatives, Equipment Design, Microscopy, Atomic Force instrumentation

Abstract

We report a modular atomic force microscope (AFM) design for biomolecular experiments. The AFM head uses readily available components and incorporates deflection-based optics and a piezotube-based cantilever actuator. Jetted-polymers have been used in the mechanical assembly, which allows rapid manufacturing. In addition, a FeCo-tipped electromagnet provides high-force cantilever actuation with vertical magnetic fields up to 0.55 T. Magnetic field calibration has been performed with a micro-hall sensor, which corresponds well with results from finite element magnetostatics simulations. An integrated force resolution of 1.82 and 2.98 pN, in air and in DI water, respectively was achieved in 1 kHz bandwidth with commercially available cantilevers made of Silicon Nitride. The controller and user interface are implemented on modular hardware to ensure scalability. The AFM can be operated in different modes, such as molecular pulling or force-clamp, by actuating the cantilever with the available actuators. The electromagnetic and piezoelectric actuation capabilities have been demonstrated in unbinding experiments of the biotin-streptavidin complex.

Published

2016

38. Binding interface between the Salmonella σ(S)/RpoS subunit of RNA polymerase and Crl: hints from bacterial species lacking crl.

Author

Cavaliere P, Sizun C, Levi-Acobas F, Nowakowski M, Monteil V, Bontems F, Bellalou J, Mayer C, and Norel F

Subjects

Amino Acid Sequence, Amino Acid Substitution, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Binding Sites, DNA-Directed RNA Polymerases metabolism, DNA-Directed RNA Polymerases ultrastructure, Models, Chemical, Molecular Docking Simulation, Molecular Sequence Data, Protein Binding, Protein Conformation, Protein Subunits, Sigma Factor metabolism, Sigma Factor ultrastructure, Species Specificity, Structure-Activity Relationship, Bacterial Proteins chemistry, DNA-Directed RNA Polymerases chemistry, Pseudomonas aeruginosa metabolism, Salmonella metabolism, Sigma Factor chemistry

Abstract

In many Gram-negative bacteria, including Salmonella enterica serovar Typhimurium (S. Typhimurium), the sigma factor RpoS/σ(S) accumulates during stationary phase of growth, and associates with the core RNA polymerase enzyme (E) to promote transcription initiation of genes involved in general stress resistance and starvation survival. Whereas σ factors are usually inactivated upon interaction with anti-σ proteins, σ(S) binding to the Crl protein increases σ(S) activity by favouring its association to E. Taking advantage of evolution of the σ(S) sequence in bacterial species that do not contain a crl gene, like Pseudomonas aeruginosa, we identified and assigned a critical arginine residue in σ(S) to the S. Typhimurium σ(S)-Crl binding interface. We solved the solution structure of S. Typhimurium Crl by NMR and used it for NMR binding assays with σ(S) and to generate in silico models of the σ(S)-Crl complex constrained by mutational analysis. The σ(S)-Crl models suggest that the identified arginine in σ(S) interacts with an aspartate of Crl that is required for σ(S) binding and is located inside a cavity enclosed by flexible loops, which also contribute to the interface. This study provides the basis for further structural investigation of the σ(S)-Crl complex.

Published

2015

39. The Crystal Structure of Pneumolysin at 2.0 Å Resolution Reveals the Molecular Packing of the Pre-pore Complex.

Author

Marshall JE, Faraj BH, Gingras AR, Lonnen R, Sheikh MA, El-Mezgueldi M, Moody PC, Andrew PW, and Wallis R

Subjects

Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Computer Simulation, Models, Chemical, Models, Molecular, Protein Conformation, Protein Structure, Tertiary, Lipid Bilayers chemistry, Porins chemistry, Porins ultrastructure, Streptolysins chemistry

Abstract

Pneumolysin is a cholesterol-dependent cytolysin (CDC) and virulence factor of Streptococcus pneumoniae. It kills cells by forming pores assembled from oligomeric rings in cholesterol-containing membranes. Cryo-EM has revealed the structures of the membrane-surface bound pre-pore and inserted-pore oligomers, however the molecular contacts that mediate these oligomers are unknown because high-resolution information is not available. Here we have determined the crystal structure of full-length pneumolysin at 1.98 Å resolution. In the structure, crystal contacts demonstrate the likely interactions that enable polymerisation on the cell membrane and the molecular packing of the pre-pore complex. The hemolytic activity is abrogated in mutants that disrupt these intermolecular contacts, highlighting their importance during pore formation. An additional crystal structure of the membrane-binding domain alone suggests that changes in the conformation of a tryptophan rich-loop at the base of the toxin promote monomer-monomer interactions upon membrane binding by creating new contacts. Notably, residues at the interface are conserved in other members of the CDC family, suggesting a common mechanism for pore and pre-pore assembly.

Published

2015

40. Structural rearrangements of a polyketide synthase module during its catalytic cycle.

Author

Whicher JR, Dutta S, Hansen DA, Hale WA, Chemler JA, Dosey AM, Narayan AR, Håkansson K, Sherman DH, Smith JL, and Skiniotis G

Subjects

Acyl Carrier Protein chemistry, Acyl Carrier Protein metabolism, Acyl Carrier Protein ultrastructure, Acyltransferases chemistry, Acyltransferases metabolism, Acyltransferases ultrastructure, Alcohol Oxidoreductases chemistry, Alcohol Oxidoreductases metabolism, Alcohol Oxidoreductases ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Catalytic Domain, Cryoelectron Microscopy, Macrolides metabolism, Models, Molecular, Polyketide Synthases ultrastructure, Protein Structure, Tertiary, Biocatalysis, Polyketide Synthases chemistry, Polyketide Synthases metabolism, Streptomyces enzymology

Abstract

The polyketide synthase (PKS) mega-enzyme assembly line uses a modular architecture to synthesize diverse and bioactive natural products that often constitute the core structures or complete chemical entities for many clinically approved therapeutic agents. The architecture of a full-length PKS module from the pikromycin pathway of Streptomyces venezuelae creates a reaction chamber for the intramodule acyl carrier protein (ACP) domain that carries building blocks and intermediates between acyltransferase, ketosynthase and ketoreductase active sites (see accompanying paper). Here we determine electron cryo-microscopy structures of a full-length pikromycin PKS module in three key biochemical states of its catalytic cycle. Each biochemical state was confirmed by bottom-up liquid chromatography/Fourier transform ion cyclotron resonance mass spectrometry. The ACP domain is differentially and precisely positioned after polyketide chain substrate loading on the active site of the ketosynthase, after extension to the β-keto intermediate, and after β-hydroxy product generation. The structures reveal the ACP dynamics for sequential interactions with catalytic domains within the reaction chamber, and for transferring the elongated and processed polyketide substrate to the next module in the PKS pathway. During the enzymatic cycle the ketoreductase domain undergoes dramatic conformational rearrangements that enable optimal positioning for reductive processing of the ACP-bound polyketide chain elongation intermediate. These findings have crucial implications for the design of functional PKS modules, and for the engineering of pathways to generate pharmacologically relevant molecules.

Published

2014

41. Structural analyses of Legionella LepB reveal a new GAP fold that catalytically mimics eukaryotic RasGAP.

Author

Yu Q, Hu L, Yao Q, Zhu Y, Dong N, Wang DC, and Shao F

Subjects

Bacterial Proteins genetics, Catalytic Domain, Crystallography, X-Ray, Escherichia coli Proteins metabolism, Legionella pneumophila metabolism, Protein Folding, Protein Structure, Tertiary, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, GTPase-Activating Proteins metabolism, rab1 GTP-Binding Proteins metabolism

Abstract

Rab GTPases are emerging targets of diverse bacterial pathogens. Here, we perform biochemical and structural analyses of LepB, a Rab GTPase-activating protein (GAP) effector from Legionella pneumophila. We map LepB GAP domain to residues 313-618 and show that the GAP domain is Rab1 specific with a catalytic activity higher than the canonical eukaryotic TBC GAP and the newly identified VirA/EspG family of bacterial RabGAP effectors. Exhaustive mutation analyses identify Arg444 as the arginine finger, but no catalytically essential glutamine residues. Crystal structures of LepB313-618 alone and the GAP domain of Legionella drancourtii LepB in complex with Rab1-GDP-AlF3 support the catalytic role of Arg444, and also further reveal a 3D architecture and a GTPase-binding mode distinct from all known GAPs. Glu449, structurally equivalent to TBC RabGAP glutamine finger in apo-LepB, undergoes a drastic movement upon Rab1 binding, which induces Rab1 Gln70 side-chain flipping towards GDP-AlF3 through a strong ionic interaction. This conformationally rearranged Gln70 acts as the catalytic cis-glutamine, therefore uncovering an unexpected RasGAP-like catalytic mechanism for LepB. Our studies highlight an extraordinary structural and catalytic diversity of RabGAPs, particularly those from bacterial pathogens.

Published

2013

42. A syringe-like injection mechanism in Photorhabdus luminescens toxins.

Author

Gatsogiannis C, Lang AE, Meusch D, Pfaumann V, Hofnagel O, Benz R, Aktories K, and Raunser S

Subjects

ADP Ribose Transferases chemistry, ADP Ribose Transferases metabolism, ADP Ribose Transferases ultrastructure, Animals, Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Bacterial Toxins chemistry, Cell Membrane metabolism, Cryoelectron Microscopy, Cytoplasm metabolism, Host-Pathogen Interactions, Insecta cytology, Insecta metabolism, Insecta microbiology, Models, Biological, Models, Molecular, Photorhabdus pathogenicity, Photorhabdus ultrastructure, Pore Forming Cytotoxic Proteins chemistry, Pore Forming Cytotoxic Proteins ultrastructure, Protein Conformation, Protein Transport, Bacterial Proteins metabolism, Bacterial Toxins metabolism, Photorhabdus metabolism, Pore Forming Cytotoxic Proteins metabolism

Abstract

Photorhabdus luminescens is an insect pathogenic bacterium that is symbiotic with entomopathogenic nematodes. On invasion of insect larvae, P. luminescens is released from the nematodes and kills the insect through the action of a variety of virulence factors including large tripartite ABC-type toxin complexes (Tcs). Tcs are typically composed of TcA, TcB and TcC proteins and are biologically active only when complete. Functioning as ADP-ribosyltransferases, TcC proteins were identified as the actual functional components that induce actin-clustering, defects in phagocytosis and cell death. However, little is known about the translocation of TcC into the cell by the TcA and TcB components. Here we show that TcA in P. luminescens (TcdA1) forms a transmembrane pore and report its structure in the prepore and pore state determined by cryoelectron microscopy. We find that the TcdA1 prepore assembles as a pentamer forming an α-helical, vuvuzela-shaped channel less than 1.5 nanometres in diameter surrounded by a large outer shell. Membrane insertion is triggered not only at low pH as expected, but also at high pH, explaining Tc action directly through the midgut of insects. Comparisons with structures of the TcdA1 pore inserted into a membrane and in complex with TcdB2 and TccC3 reveal large conformational changes during membrane insertion, suggesting a novel syringe-like mechanism of protein translocation. Our results demonstrate how ABC-type toxin complexes bridge a membrane to insert their lethal components into the cytoplasm of the host cell. We believe that the proposed mechanism is characteristic of the whole ABC-type toxin family. This explanation of toxin translocation is a step towards understanding the host-pathogen interaction and the complex life cycle of P. luminescens and other pathogens, including human pathogenic bacteria, and serves as a strong foundation for the development of biopesticides.

Published

2013

43. Fluorescent and photo-oxidizing TimeSTAMP tags track protein fates in light and electron microscopy.

Author

Butko MT, Yang J, Geng Y, Kim HJ, Jeon NL, Shu X, Mackey MR, Ellisman MH, Tsien RY, and Lin MZ

Subjects

Animals, Animals, Newborn, Bacterial Proteins ultrastructure, Cells, Cultured, Disks Large Homolog 4 Protein, Epitopes analysis, Epitopes ultrastructure, HEK293 Cells, Humans, Luminescent Proteins ultrastructure, Microscopy, Electron methods, Microscopy, Fluorescence methods, Rats, Rats, Sprague-Dawley, Time Factors, Bacterial Proteins analysis, Fluorescent Dyes, Intracellular Signaling Peptides and Proteins metabolism, Luminescent Proteins analysis, Membrane Proteins metabolism, Membrane Proteins ultrastructure

Abstract

Protein synthesis is highly regulated throughout nervous system development, plasticity and regeneration. However, tracking the distributions of specific new protein species has not been possible in living neurons or at the ultrastructural level. Previously we created TimeSTAMP epitope tags, drug-controlled tags for immunohistochemical detection of specific new proteins synthesized at defined times. Here we extend TimeSTAMP to label new protein copies by fluorescence or photo-oxidation. Live microscopy of a fluorescent TimeSTAMP tag reveals that copies of the synaptic protein PSD95 are synthesized in response to local activation of growth factor and neurotransmitter receptors, and preferentially localize to stimulated synapses in rat neurons. Electron microscopy of a photo-oxidizing TimeSTAMP tag reveals new PSD95 at developing dendritic structures of immature neurons and at synapses in differentiated neurons. These results demonstrate the versatility of the TimeSTAMP approach for visualizing newly synthesized proteins in neurons.

Published

2012

44. Type VI secretion requires a dynamic contractile phage tail-like structure.

Author

Basler M, Pilhofer M, Henderson GP, Jensen GJ, and Mekalanos JJ

Subjects

Bacterial Proteins metabolism, Bacteriophages physiology, Cell Membrane metabolism, Cryoelectron Microscopy, Electron Microscope Tomography, Microscopy, Fluorescence, Vibrio cholerae cytology, Vibrio cholerae ultrastructure, Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Bacterial Secretion Systems physiology, Bacteriophages chemistry, Vibrio cholerae chemistry, Vibrio cholerae metabolism

Abstract

Type VI secretion systems are bacterial virulence-associated nanomachines composed of proteins that are evolutionarily related to components of bacteriophage tails. Here we show that protein secretion by the type VI secretion system of Vibrio cholerae requires the action of a dynamic intracellular tubular structure that is structurally and functionally homologous to contractile phage tail sheath. Time-lapse fluorescence light microscopy reveals that sheaths of the type VI secretion system cycle between assembly, quick contraction, disassembly and re-assembly. Whole-cell electron cryotomography further shows that the sheaths appear as long tubular structures in either extended or contracted conformations that are connected to the inner membrane by a distinct basal structure. These data support a model in which the contraction of the type VI secretion system sheath provides the energy needed to translocate proteins out of effector cells and into adjacent target cells.

Published

2012

45. Structural basis for iron piracy by pathogenic Neisseria.

Author

Noinaj N, Easley NC, Oke M, Mizuno N, Gumbart J, Boura E, Steere AN, Zak O, Aisen P, Tajkhorshid E, Evans RW, Gorringe AR, Mason AB, Steven AC, and Buchanan SK

Subjects

Animals, Apoproteins chemistry, Apoproteins metabolism, Bacterial Proteins metabolism, Bacterial Proteins ultrastructure, Binding Sites, Biological Transport, Cattle, Crystallography, X-Ray, Humans, Mice, Models, Molecular, Molecular Dynamics Simulation, Neisseria pathogenicity, Protein Conformation, Scattering, Small Angle, Species Specificity, Structure-Activity Relationship, Transferrin chemistry, Transferrin metabolism, Transferrin ultrastructure, Transferrin-Binding Protein A ultrastructure, Transferrin-Binding Protein B ultrastructure, X-Ray Diffraction, Bacterial Proteins chemistry, Iron metabolism, Neisseria metabolism, Transferrin-Binding Protein A chemistry, Transferrin-Binding Protein A metabolism, Transferrin-Binding Protein B chemistry, Transferrin-Binding Protein B metabolism

Abstract

Neisseria are obligate human pathogens causing bacterial meningitis, septicaemia and gonorrhoea. Neisseria require iron for survival and can extract it directly from human transferrin for transport across the outer membrane. The transport system consists of TbpA, an integral outer membrane protein, and TbpB, a co-receptor attached to the cell surface; both proteins are potentially important vaccine and therapeutic targets. Two key questions driving Neisseria research are how human transferrin is specifically targeted, and how the bacteria liberate iron from transferrin at neutral pH. To address these questions, we solved crystal structures of the TbpA-transferrin complex and of the corresponding co-receptor TbpB. We characterized the TbpB-transferrin complex by small-angle X-ray scattering and the TbpA-TbpB-transferrin complex by electron microscopy. Our studies provide a rational basis for the specificity of TbpA for human transferrin, show how TbpA promotes iron release from transferrin, and elucidate how TbpB facilitates this process.

Published

2012

46. Structure and function of the AAA+ protein CbbX, a red-type Rubisco activase.

Author

Mueller-Cajar O, Stotz M, Wendler P, Hartl FU, Bracher A, and Hayer-Hartl M

Subjects

Adenosine Triphosphate metabolism, Allosteric Regulation drug effects, Bacterial Proteins genetics, Bacterial Proteins ultrastructure, Carbon Dioxide metabolism, Crystallography, X-Ray, Enzyme Activation drug effects, Models, Molecular, Protein Multimerization drug effects, Protein Structure, Quaternary drug effects, Ribulosephosphates metabolism, Ribulosephosphates pharmacology, Structure-Activity Relationship, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Rhodobacter sphaeroides enzymology, Ribulose-Bisphosphate Carboxylase metabolism

Abstract

Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) catalyses the fixation of atmospheric CO(2) in photosynthesis, but tends to form inactive complexes with its substrate ribulose 1,5-bisphosphate (RuBP). In plants, Rubisco is reactivated by the AAA(+) (ATPases associated with various cellular activities) protein Rubisco activase (Rca), but no such protein is known for the Rubisco of red algae. Here we identify the protein CbbX as an activase of red-type Rubisco. The 3.0-Å crystal structure of unassembled CbbX from Rhodobacter sphaeroides revealed an AAA(+) protein architecture. Electron microscopy and biochemical analysis showed that ATP and RuBP must bind to convert CbbX into functionally active, hexameric rings. The CbbX ATPase is strongly stimulated by RuBP and Rubisco. Mutational analysis suggests that CbbX functions by transiently pulling the carboxy-terminal peptide of the Rubisco large subunit into the hexamer pore, resulting in the release of the inhibitory RuBP. Understanding Rubisco activation may facilitate efforts to improve CO(2) uptake and biomass production by photosynthetic organisms.

Published

2011

47. Streptococcal M1 protein constructs a pathological host fibrinogen network.

Author

Macheboeuf P, Buffalo C, Fu CY, Zinkernagel AS, Cole JN, Johnson JE, Nizet V, and Ghosh P

Subjects

Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins ultrastructure, Binding Sites, Crystallography, X-Ray, Fibrinogen metabolism, Fibrinogen ultrastructure, Humans, Models, Molecular, Neutrophil Activation, Protein Binding, Protein Conformation, Shock, Septic microbiology, Shock, Septic physiopathology, Streptococcus pyogenes chemistry, Virulence, Virulence Factors chemistry, Bacterial Proteins metabolism, Fibrinogen chemistry, Streptococcus pyogenes pathogenicity, Virulence Factors metabolism

Abstract

M1 protein, a major virulence factor of the leading invasive strain of group A Streptococcus, is sufficient to induce toxic-shock-like vascular leakage and tissue injury. These events are triggered by the formation of a complex between M1 and fibrinogen that, unlike M1 or fibrinogen alone, leads to neutrophil activation. Here we provide a structural explanation for the pathological properties of the complex formed between streptococcal M1 and human fibrinogen. A conformationally dynamic coiled-coil dimer of M1 was found to organize four fibrinogen molecules into a specific cross-like pattern. This pattern supported the construction of a supramolecular network that was required for neutrophil activation but was distinct from a fibrin clot. Disruption of this network into other supramolecular assemblies was not tolerated. These results have bearing on the pathophysiology of streptococcal toxic shock., (©2011 Macmillan Publishers Limited. All rights reserved)

Published

2011

48. A bacterial dynamin-like protein.

Author

Low HH and Löwe J

Subjects

Animals, Bacterial Proteins ultrastructure, Crystallography, X-Ray, Dynamins ultrastructure, Liposomes chemistry, Liposomes metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Dynamins chemistry, Dynamins metabolism, Nostoc chemistry

Abstract

Dynamins form a superfamily of large mechano-chemical GTPases that includes the classical dynamins and dynamin-like proteins (DLPs). They are found throughout the Eukarya, functioning in core cellular processes such as endocytosis and organelle division. Many bacteria are predicted by sequence to possess large GTPases with the same multidomain architecture that is found in DLPs. Mechanistic dissection of dynamin family members has been impeded by a lack of high-resolution structural data currently restricted to the GTPase and pleckstrin homology domains, and the dynamin-related human guanylate-binding protein. Here we present the crystal structure of a cyanobacterial DLP in both nucleotide-free and GDP-associated conformation. The bacterial DLP shows dynamin-like qualities, such as helical self-assembly and tubulation of a lipid bilayer. In vivo, it localizes to the membrane in a manner reminiscent of FZL, a chloroplast-specific dynamin-related protein with which it shares sequence similarity. Our results provide structural and mechanistic insight that may be relevant across the dynamin superfamily. Concurrently, we show compelling similarity between a cyanobacterial and chloroplast DLP that, given the endosymbiotic ancestry of chloroplasts, questions the evolutionary origins of dynamins.

Published

2006

49. Structure of the bacterial flagellar hook and implication for the molecular universal joint mechanism.

Author

Samatey FA, Matsunami H, Imada K, Nagashima S, Shaikh TR, Thomas DR, Chen JZ, Derosier DJ, Kitao A, and Namba K

Subjects

Bacterial Proteins ultrastructure, Computer Simulation, Cryoelectron Microscopy, Crystallography, X-Ray, Models, Molecular, Peptide Fragments chemistry, Peptide Fragments ultrastructure, Pliability, Protein Structure, Quaternary, Protein Subunits chemistry, Bacterial Proteins chemistry, Salmonella typhimurium chemistry

Abstract

The bacterial flagellum is a motile organelle, and the flagellar hook is a short, highly curved tubular structure that connects the flagellar motor to the long filament acting as a helical propeller. The hook is made of about 120 copies of a single protein, FlgE, and its function as a nano-sized universal joint is essential for dynamic and efficient bacterial motility and taxis. It transmits the motor torque to the helical propeller over a wide range of its orientation for swimming and tumbling. Here we report a partial atomic model of the hook obtained by X-ray crystallography of FlgE31, a major proteolytic fragment of FlgE lacking unfolded terminal regions, and by electron cryomicroscopy and three-dimensional helical image reconstruction of the hook. The model reveals the intricate molecular interactions and a plausible switching mechanism for the hook to be flexible in bending but rigid against twisting for its universal joint function.

Published

2004

50. Molecular motors: smooth coupling in Salmonella.

Author

Surridge C

Subjects

Bacterial Proteins ultrastructure, Computer Simulation, Cryoelectron Microscopy, Crystallography, X-Ray, Models, Molecular, Pliability, Protein Structure, Quaternary, Salmonella typhimurium physiology, Bacterial Proteins chemistry, Salmonella typhimurium chemistry

Published

2004