1.How does transmembrane electrochemical potential drive the rotation of Fo motor in an ATP synthase?
Xuejun C ZHANG ; Min LIU ; Yan ZHAO
Protein & Cell 2015;6(11):784-791
While the field of ATP synthase research has a long history filled with landmark discoveries, recent structural works provide us with important insights into the mechanisms that links the proton movement with the rotation of the Fo motor. Here, we propose a mechanism of unidirectional rotation of the Fo complex, which is in agreement with these new structural insights as well as our more general ΔΨ-driving hypothesis of membrane proteins: A proton path in the rotor-stator interface is formed dynamically in concert with the rotation of the Fo rotor. The trajectory of the proton viewed in the reference system of the rotor (R-path) must lag behind that of the stator (S-path). The proton moves from a higher energy site to a lower site following both trajectories simultaneously. The two trajectories meet each other at the transient proton-binding site, resulting in a relative rotation between the rotor and stator. The kinetic energy of protons gained from ΔΨ is transferred to the c-ring as the protons are captured sequentially by the binding sites along the proton path, thus driving the unidirectional rotation of the c-ring. Our ΔΨ-driving hypothesis on Fo motor is an attempt to unveil the robust mechanism of energy conversion in the highly conserved, ubiquitously expressed rotary ATP synthases.
Membrane Potentials
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physiology
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Membrane Proteins
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chemistry
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metabolism
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Mitochondrial Proton-Translocating ATPases
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chemistry
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metabolism
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Protein Conformation
3.An open conformation determined by a structural switch for 2A protease from coxsackievirus A16.
Yao SUN ; Xiangxi WANG ; Shuai YUAN ; Minghao DANG ; Xuemei LI ; Xuejun C ZHANG ; Zihe RAO
Protein & Cell 2013;4(10):782-792
Coxsackievirus A16 belongs to the family Picornaviridae, and is a major agent of hand-foot-and-mouth disease that infects mostly children, and to date no vaccines or antiviral therapies are available. 2A protease of enterovirus is a nonstructural protein and possesses both self-cleavage activity and the ability to cleave the eukaryotic translation initiation factor 4G. Here we present the crystal structure of coxsackievirus A16 2A protease, which interestingly forms hexamers in crystal as well as in solution. This structure shows an open conformation, with its active site accessible, ready for substrate binding and cleavage activity. In conjunction with a previously reported "closed" state structure of human rhinovirus 2, we were able to develop a detailed hypothesis for the conformational conversion triggered by two "switcher" residues Glu88 and Tyr89 located within the bll2-cII loop. Substrate recognition assays revealed that amino acid residues P1', P2 and P4 are essential for substrate specificity, which was verified by our substrate binding model. In addition, we compared the in vitro cleavage efficiency of 2A proteases from coxsackievirus A16 and enterovirus 71 upon the same substrates by fluorescence resonance energy transfer (FRET), and observed higher protease activity of enterovirus 71 compared to that of coxsackievirus A16. In conclusion, our study shows an open conformation of coxsackievirus A16 2A protease and the underlying mechanisms for conformational conversion and substrate specificity. These new insights should facilitate the future rational design of efficient 2A protease inhibitors.
Coxsackievirus Infections
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virology
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Crystallography, X-Ray
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Cysteine Endopeptidases
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chemistry
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genetics
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Fluorescence Resonance Energy Transfer
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Hand, Foot and Mouth Disease
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enzymology
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pathology
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virology
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Humans
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Picornaviridae
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chemistry
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enzymology
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genetics
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Protein Conformation
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Structure-Activity Relationship
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Substrate Specificity
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Viral Proteins
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chemistry
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genetics
4.Proton transfer-mediated GPCR activation.
Xuejun C ZHANG ; Can CAO ; Ye ZHOU ; Yan ZHAO
Protein & Cell 2015;6(1):12-17
G-protein coupled receptors (GPCRs) play essential roles in signal transduction from the environment into the cell. While many structural features have been elucidated in great detail, a common functional mechanism on how the ligand-binding signal is converted into a conformational change on the cytoplasmic face resulting in subsequent activation of downstream effectors remain to be established. Based on available structural and functional data of the activation process in class-A GPCRs, we propose here that a change in protonation status, together with proton transfer via conserved structural elements located in the transmembrane region, are the key elements essential for signal transduction across the membrane.
Amino Acid Motifs
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Humans
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Membrane Potentials
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Membrane Proteins
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chemistry
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metabolism
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Protons
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Receptors, G-Protein-Coupled
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agonists
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metabolism
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Signal Transduction
5.Structure analysis of the extracellular domain reveals disulfide bond forming-protein properties of Mycobacterium tuberculosis Rv2969c.
Lu WANG ; Jun LI ; Xiangxi WANG ; Wu LIU ; Xuejun C ZHANG ; Xuemei LI ; Zihe RAO
Protein & Cell 2013;4(8):628-640
Disulfide bond-forming (Dsb) protein is a bacterial periplasmic protein that is essential for the correct folding and disulfide bond formation of secreted or cell wallassociated proteins. DsbA introduces disulfide bonds into folding proteins, and is re-oxidized through interaction with its redox partner DsbB. Mycobacterium tuberculosis, a Gram-positive bacterium, expresses a DsbA-like protein ( Rv2969c), an extracellular protein that has its Nterminus anchored in the cell membrane. Since Rv2969c is an essential gene, crucial for disulfide bond formation, research of DsbA may provide a target of a new class of anti-bacterial drugs for treatment of M.tuberculosis infection. In the present work, the crystal structures of the extracellular region of Rv2969c (Mtb DsbA) were determined in both its reduced and oxidized states. The overall structure of Mtb DsbA can be divided into two domains: a classical thioredoxin-like domain with a typical CXXC active site, and an α-helical domain. It largely resembles its Escherichia coli homologue EcDsbA, however, it possesses a truncated binding groove; in addition, its active site is surrounded by an acidic, rather than hydrophobic surface. In our oxidoreductase activity assay, Mtb DsbA exhibited a different substrate specificity when compared to EcDsbA. Moreover, structural analysis revealed a second disulfide bond in Mtb DsbA, which is rare in the previously reported DsbA structures, and is assumed to contribute to the overall stability of Mtb DsbA. To investigate the disulphide formation pathway in M.tuberculosis, we modeled Mtb Vitamin K epoxide reductase (Mtb VKOR), a binding partner of Mtb DsbA, to Mtb DsbA.
Amino Acid Sequence
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Bacterial Proteins
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chemistry
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metabolism
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Catalytic Domain
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Crystallography, X-Ray
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Disulfides
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chemistry
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Escherichia coli
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metabolism
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Escherichia coli Proteins
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chemistry
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metabolism
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Molecular Docking Simulation
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Molecular Sequence Data
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Mycobacterium tuberculosis
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metabolism
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Oxidation-Reduction
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Protein Disulfide-Isomerases
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chemistry
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metabolism
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Protein Folding
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Protein Structure, Tertiary
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Sequence Alignment
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Static Electricity
6.Crystal structures and biochemical studies of human lysophosphatidic acid phosphatase type 6.
Jun LI ; Yu DONG ; Xingru LÜ ; Lu WANG ; Wei PENG ; Xuejun C ZHANG ; Zihe RAO
Protein & Cell 2013;4(7):548-561
Lysophosphatidic acid (LPA) is an important bioactive phospholipid involved in cell signaling through Gprotein-coupled receptors pathways. It is also involved in balancing the lipid composition inside the cell, and modulates the function of lipid rafts as an intermediate in phospholipid metabolism. Because of its involvement in these important processes, LPA degradation needs to be regulated as precisely as its production. Lysophosphatidic acid phosphatase type 6 (ACP6) is an LPA-specific acid phosphatase that hydrolyzes LPA to monoacylglycerol (MAG) and phosphate. Here, we report three crystal structures of human ACP6 in complex with malonate, L-(+)-tartrate and tris, respectively. Our analyses revealed that ACP6 possesses a highly conserved Rossmann-foldlike body domain as well as a less conserved cap domain. The vast hydrophobic substrate-binding pocket, which is located between those two domains, is suitable for accommodating LPA, and its shape is different from that of other histidine acid phosphatases, a fact that is consistent with the observed difference in substrate preferences. Our analysis of the binding of three molecules in the active site reveals the involvement of six conserved and crucial residues in binding of the LPA phosphate group and its catalysis. The structure also indicates a water-supplying channel for substrate hydrolysis. Our structural data are consistent with the fact that the enzyme is active as a monomer. In combination with additional mutagenesis and enzyme activity studies, our structural data provide important insights into substrate recognition and the mechanism for catalytic activity of ACP6.
Amino Acid Sequence
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Catalytic Domain
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Crystallography, X-Ray
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Humans
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Malonates
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metabolism
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Models, Molecular
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Molecular Sequence Data
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Nitrophenols
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metabolism
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Organophosphorus Compounds
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metabolism
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Phosphoric Monoester Hydrolases
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chemistry
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classification
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metabolism
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Tartrates
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metabolism
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Water
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metabolism
7.Structural study of the Cdc25 domain from Ral-specific guanine-nucleotide exchange factor RalGPS1a.
Wei PENG ; Jiwei XU ; Xiaotao GUAN ; Yao SUN ; Xuejun C ZHANG ; Xuemei LI ; Zihe RAO
Protein & Cell 2011;2(4):308-319
The guanine-nucleotide exchange factor (GEF) RalGPS1a activates small GTPase Ral proteins such as RalA and RalB by stimulating the exchange of Ral bound GDP to GTP, thus regulating various downstream cellular processes. RalGPS1a is composed of an Nterminal Cdc25-like catalytic domain, followed by a PXXP motif and a C-terminal pleckstrin homology (PH) domain. The Cdc25 domain of RalGPS1a, which shares about 30% sequence identity with other Cdc25-domain proteins, is thought to be directly engaged in binding and activating the substrate Ral protein. Here we report the crystal structure of the Cdc25 domain of RalGPS1a. The bowl shaped structure is homologous to the Cdc25 domains of SOS and RasGRF1. The most remarkable difference between these three Cdc25 domains lies in their active sites, referred to as the helical hairpin region. Consistent with previous enzymological studies, the helical hairpin of RalGPS1a adopts a conformation favorable for substrate binding. A modeled RalGPS1a-RalA complex structure reveals an extensive binding surface similar to that of the SOS-Ras complex. However, analysis of the electrostatic surface potential suggests an interaction mode between the RalGPS1a active site helical hairpin and the switch 1 region of substrate RalA distinct from that of the SOS-Ras complex.
Amino Acid Sequence
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Binding Sites
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Catalytic Domain
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Cloning, Molecular
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Crystallography, X-Ray
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Escherichia coli
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Guanosine Diphosphate
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metabolism
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Guanosine Triphosphate
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metabolism
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Humans
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Models, Molecular
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Molecular Conformation
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Molecular Sequence Data
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Plasmids
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metabolism
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Protein Binding
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Protein Structure, Tertiary
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genetics
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Recombinant Proteins
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chemistry
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genetics
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metabolism
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ral GTP-Binding Proteins
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chemistry
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genetics
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metabolism
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ral Guanine Nucleotide Exchange Factor
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chemistry
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genetics
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metabolism
8.GPCR activation: protonation and membrane potential.
Xuejun C ZHANG ; Kening SUN ; Laixing ZHANG ; Xuemei LI ; Can CAO
Protein & Cell 2013;4(10):747-760
GPCR proteins represent the largest family of signaling membrane proteins in eukaryotic cells. Their importance to basic cell biology, human diseases, and pharmaceutical interventions is well established. Many crystal structures of GPCR proteins have been reported in both active and inactive conformations. These data indicate that agonist binding alone is not sufficient to trigger the conformational change of GPCRs necessary for binding of downstream G-proteins, yet other essential factors remain elusive. Based on analysis of available GPCR crystal structures, we identified a potential conformational switch around the conserved Asp2.50, which consistently shows distinct conformations between inactive and active states. Combining the structural information with the current literature, we propose an energy-coupling mechanism, in which the interaction between a charge change of the GPCR protein and the membrane potential of the living cell plays a key role for GPCR activation.
Binding Sites
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GTP-Binding Proteins
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chemistry
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genetics
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metabolism
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Humans
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Hydrogen Bonding
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Membrane Potentials
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Models, Molecular
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Protein Conformation
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Receptors, G-Protein-Coupled
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chemistry
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genetics
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metabolism
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Signal Transduction
10.Crystal structure of cytotoxin protein suilysin from Streptococcus suis.
Lingfeng XU ; Bo HUANG ; Huamao DU ; Xuejun C ZHANG ; Jianguo XU ; Xuemei LI ; Zihe RAO
Protein & Cell 2010;1(1):96-105
Cholesterol-dependent cytolysins (CDC) are pore forming toxins. A prototype of the CDC family members is perfringolysin O (PFO), which directly binds to the cell membrane enriched in cholesterol, causing cell lysis. However, an exception of this general observation is intermedilysin (ILY) of Streptococcus intermedius, which requires human CD59 as a receptor in addition to cholesterol for its hemolytic activity. A possible explanation of this functional difference is the conformational variation between the C-terminal domains of the two toxins, particularly in the highly conserved undecapeptide termed tryptophan rich motif. Here, we present the crystal structure of suilysin, a CDC toxin from the infectious swine pathogen Streptococcus suis. Like PFO, suilysin does not require a host receptor for hemolytic activity; yet the crystal structure of suilysin exhibits a similar conformation in the tryptophan rich motif to ILY. This observation suggests that the current view of the structure-function relationship between CDC proteins and membrane association is far from complete.
Amino Acid Sequence
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Animals
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Bacterial Toxins
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chemistry
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Bacteriocins
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chemistry
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Cholesterol
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chemistry
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Crystallography, X-Ray
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Cytotoxins
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chemistry
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Hemolysin Proteins
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chemistry
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genetics
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Molecular Sequence Data
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Point Mutation
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Protein Structure, Tertiary
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Sequence Alignment
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Streptococcus suis
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metabolism
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Swine