Structural Insights on the Bacteriolytic and Self-protection Mechanism of Muramidase Effector Tse3 in Pseudomonas aeruginosa

The warfare among microbial species as well as between pathogens and hosts is fierce, complicated, and continuous. In Pseudomonas aeruginosa, the muramidase effector Tse3 (Type VI secretion exported 3) can be injected into the periplasm of neighboring bacterial competitors by a Type VI secretion apparatus, eventually leading to cell lysis and death. However, P. aeruginosa protects itself from lysis by expressing immune protein Tsi3 (Type six secretion immunity 3). Here, we report the crystal structure of the Tse3-Tsi3 complex at 1.8 Å resolution, revealing that Tse3 possesses one open accessible, goose-type lysozyme-like domain with peptidoglycan hydrolysis activity. Calcium ions bind specifically in the Tse3 active site and are identified to be crucial for its bacteriolytic activity. In combination with biochemical studies, the structural basis of self-protection mechanism of Tsi3 is also elucidated, thus providing an understanding and new insights into the effectors of Type VI secretion system.     

Crystal structure of type VI effector Tse1 from Pseudomonas aeruginosa

The type VI secretion systems (T6SS) have emerging roles in interspecies competition. In order to have an advantage in defense against other organisms, this system in Pseudomonas aeruginosa delivers a peptidoglycan amidase (Tse1) to the periplasmic space of a competitor. An immune protein (Tsi1) is also produced by the bacterium to protect itself from damage caused by Tse1. Tsi1 directly interacts with Tse1. We report that the crystal structure of Tse1 displays a common CHAP protein fold. Strikingly, our structures showed that the third residue in the catalytic triad may be novel as this residue type has not been observed previously.     

Crystal structure of afadin PDZ domain–nectin‐3 complex shows the structural plasticity of the ligand‐binding site

Afadin, a scaffold protein localized in adherens junctions (AJs), links nectins to the actin cytoskeleton. Nectins are the major cell adhesion molecules of AJs. At the initial stage of cell–cell junction formation, the nectin–afadin interaction plays an indispensable role in AJ biogenesis via recruiting and tethering other components. The afadin PDZ domain (AFPDZ) is responsible for binding the cytoplasmic C‐terminus of nectins. AFPDZ is a class II PDZ domain member, which prefers ligands containing a class II PDZ‐binding motif, X‐Φ‐X‐Φ (Φ, hydrophobic residues); both nectins and other physiological AFPDZ targets contain this class II motif. Here, we report the first crystal structure of the AFPDZ in complex with the nectin‐3 C‐terminal peptide containing the class II motif. We engineered the nectin‐3 C‐terminal peptide and AFPDZ to produce an AFPDZ–nectin‐3 fusion protein and succeeded in obtaining crystals of this complex as a dimer. This novel dimer interface was created by forming an antiparallel β sheet between β2 strands. A major structural change compared with the known AFPDZ structures was observed in the α2 helix. We found an approximately 2.5 Å‐wider ligand‐binding groove, which allows the PDZ to accept bulky class II ligands. Apparently, the last three amino acids of the nectin‐3 C‐terminus were sufficient to bind AFPDZ, in which the two hydrophobic residues are important.     

Anchorage‐dependent binding of integrin I‐domain to adhesion ligands

The dynamic interactions between leukocyte integrin receptors and ligands in the vascular endothelium, extracellular matrix, or invading pathogens result in leukocyte adhesion, extravasation, and phagocytosis. This work examined the mechanical strength of the connection between iC3b, a complement component that stimulates phagocytosis, and the ligand‐binding domain, the I‐domain, of integrin α_Mβ₂. Single‐molecule force measurements of α_M I‐domain–iC3b complexes were conducted by atomic force microscope. Strikingly, depending on loading rates, immobilization of the I‐domain via its C‐terminus resulted in a 1.3‐fold to 1.5‐fold increase in unbinding force compared with I‐domains immobilized via the N‐terminus. The force spectra (unbinding force versus loading rate) of the I‐domain–iC3b complexes revealed that the enhanced mechanical strength is due to a 2.4‐fold increase in the lifetime of the I‐domain–iC3b bond. Given the structural and functional similarity of all integrin I‐domains, our result supports the existing allosteric regulatory model by which the ligand binding strength of integrin can be increased rapidly when a force is allowed to stretch the C‐terminus of the I‐domain. This type of mechanism may account for the rapid ligand affinity adjustment during leukocyte migration. Copyright © 2015 John Wiley & Sons, Ltd.     

Insights into PG‐binding,conformational change,and dimerization of the OmpA C‐terminal domains from Salmonella enterica serovar Typhimurium and Borrelia burgdorferi

Salmonella enterica serovar Typhimurium can induce both humoral and cell‐mediated responses when establishing itself in the host. These responses are primarily stimulated against the lipopolysaccharide and major outer membrane (OM) proteins. OmpA is one of these major OM proteins. It comprises a N‐terminal eight‐stranded β‐barrel transmembrane domain and a C‐terminal domain (OmpA^CTD). The OmpA^CTD and its homologs are believed to bind to peptidoglycan (PG) within the periplasm, maintaining bacterial osmotic homeostasis and modulating the permeability and integrity of the OM. Here we present the first crystal structures of the OmpA^CTD from two pathogens: S. typhimurium (STOmpA^CTD) in open and closed forms and causative agent of Lyme Disease Borrelia burgdorferi (BbOmpA^CTD), in closed form. In the open form of STOmpA^CTD, an aspartate residue from a long β2‐α3 loop points into the binding pocket, suggesting that an anion group such as a carboxylate group from PG is favored at the binding site. In the closed form of STOmpA^CTD and in the structure of BbOmpA^CTD, a sulfate group from the crystallization buffer is tightly bound at the binding site. The differences between the closed and open forms of STOmpA^CTD, suggest a large conformational change that includes an extension of α3 helix by ordering a part of β2‐α3 loop. We propose that the sulfate anion observed in these structures mimics the carboxylate group of PG when bound to STOmpA^CTD suggesting PG‐anchoring mechanism. In addition, the binding of PG or a ligand mimic may enhance dimerization of STOmpA^CTD, or possibly that of full length STOmpA.     

Interaction between the C‐terminal domains of measles virus nucleoprotein and phosphoprotein: A tight complex implying one binding site

The intrinsically disordered C‐terminal domain (N_TAIL) of the measles virus (MeV) nucleoprotein undergoes α‐helical folding upon binding to the C‐terminal X domain (XD) of the phosphoprotein. The N_TAIL region involved in binding coupled to folding has been mapped to a conserved region (Box2) encompassing residues 489–506. In the previous studies published in this journal, we obtained experimental evidence supporting a K_D for the N_TAIL–XD binding reaction in the nM range and also showed that an additional N_TAIL region (Box3, aa 517–525) plays a role in binding to XD. In striking contrast with these data, studies published in this journal by Kingston and coworkers pointed out a much less stable complex (K_D in the μM range) and supported lack of involvement of Box3 in complex formation. The objective of this study was to critically re‐evaluate the role of Box3 in N_TAIL–XD binding. Since our previous studies relied on N_TAIL‐truncated forms possessing an irrelevant Flag sequence appended at their C‐terminus, we, herein, generated an N_TAIL devoid of Box3 and any additional C‐terminal residues, as well as a form encompassing only residues 482–525. We then used isothermal titration calorimetry to characterize the binding reactions between XD and these N_TAIL forms. Results effectively argue for the presence of a single XD‐binding site located within Box2, in agreement with the results by Kingston et al., while providing clear experimental support for a high‐affinity complex. Altogether, the present data provide mechanistic insights into the replicative machinery of MeV and clarify a hitherto highly debated point.     

Mycobacterium tuberculosis class II apurinic/apyrimidinic‐endonuclease/3′‐5′ exonuclease III exhibits DNA regulated modes of interaction with the sliding DNA β‐clamp

The class‐II AP‐endonuclease (XthA) acts on abasic sites of damaged DNA in bacterial base excision repair. We identified that the sliding DNA β‐clamp forms in vivo and in vitro complexes with XthA in Mycobacterium tuberculosis. A novel ₂₃₉QLRFPKK₂₄₅ motif in the DNA‐binding domain of XthA was found to be important for the interactions. Likewise, the peptide binding‐groove (PBG) and the C‐terminal of β‐clamp located on different domains interact with XthA. The β‐clamp‐XthA complex can be disrupted by clamp binding peptides and also by a specific bacterial clamp inhibitor that binds at the PBG. We also identified that β‐clamp stimulates the activities of XthA primarily by increasing its affinity for the substrate and its processivity. Additionally, loading of the β‐clamp onto DNA is required for activity stimulation. A reduction in XthA activity stimulation was observed in the presence of β‐clamp binding peptides supporting that direct interactions between the proteins are necessary to cause stimulation. Finally, we found that in the absence of DNA, the PBG located on the second domain of the β‐clamp is important for interactions with XthA, while the C‐terminal domain predominantly mediates functional interactions in the substrate's presence.     

Virulence of Agrobacterium tumefaciens requires lipid homeostasis mediated by the lysyl‐phosphatidylglycerol hydrolase AcvB

Agrobacterium tumefaciens transfers oncogenic T‐DNA via the type IV secretion system (T4SS) into plants causing tumor formation. The acvB gene encodes a virulence factor of unknown function required for plant transformation. Here we specify AcvB as a periplasmic lysyl‐phosphatidylglycerol (L‐PG) hydrolase, which modulates L‐PG homeostasis. Through functional characterization of recombinant AcvB variants, we showed that the C‐terminal domain of AcvB (residues 232–456) is sufficient for full enzymatic activity and defined key residues for catalysis. Absence of the hydrolase resulted in ~10‐fold increase in L‐PG in Agrobacterium membranes and abolished T‐DNA transfer and tumor formation. Overproduction of the L‐PG synthase gene (lpiA) in wild‐type A. tumefaciens resulted in a similar increase in the L‐PG content (~7‐fold) and a virulence defect even in the presence of intact AcvB. These results suggest that elevated L‐PG amounts (either by overproduction of the synthase or absence of the hydrolase) are responsible for the virulence phenotype. Gradually increasing the L‐PG content by complementation with different acvB variants revealed that cellular L‐PG levels above 3% of total phospholipids interfere with T‐DNA transfer. Cumulatively, this study identified AcvB as a novel virulence factor required for membrane lipid homeostasis and T‐DNA transfer.     

Structural Basis for Type VI Secretion Effector Recognition by a Cognate Immunity Protein

The type VI secretion system (T6SS) has emerged as an important mediator of interbacterial interactions. A T6SS from Pseudomonas aeruginosa targets at least three effector proteins, type VI secretion exported 1–3 (Tse1–3), to recipient Gram-negative cells. The Tse2 protein is a cytoplasmic effector that acts as a potent inhibitor of target cell proliferation, thus providing a pronounced fitness advantage for P. aeruginosa donor cells. P. aeruginosa utilizes a dedicated immunity protein, type VI secretion immunity 2 (Tsi2), to protect against endogenous and intercellularly-transferred Tse2. Here we show that Tse2 delivered by the T6SS efficiently induces quiescence, not death, within recipient cells. We demonstrate that despite direct interaction of Tsi2 and Tse2 in the cytoplasm, Tsi2 is dispensable for targeting the toxin to the secretory apparatus. To gain insights into the molecular basis of Tse2 immunity, we solved the 1.00 Å X-ray crystal structure of Tsi2. The structure shows that Tsi2 assembles as a dimer that does not resemble previously characterized immunity or antitoxin proteins. A genetic screen for Tsi2 mutants deficient in Tse2 interaction revealed an acidic patch distal to the Tsi2 homodimer interface that mediates toxin interaction and immunity. Consistent with this finding, we observed that destabilization of the Tsi2 dimer does not impact Tse2 interaction. The molecular insights into Tsi2 structure and function garnered from this study shed light on the mechanisms of T6 effector secretion, and indicate that the Tse2–Tsi2 effector–immunity pair has features distinguishing it from previously characterized toxin–immunity and toxin–antitoxin systems.     

Crystal structure of the N‐terminal methyltransferase‐like domain of anamorsin

Anamorsin is a recently identified molecule that inhibits apoptosis during hematopoiesis. It contains an N‐terminal methyltransferase‐like domain and a C‐terminal Fe‐S cluster motif. Not much is known about the function of the protein. To better understand the function of anamorsin, we have solved the crystal structure of the N‐terminal domain at 1.8 Å resolution. Although the overall structure resembles a typical S‐adenosylmethionine (SAM) dependent methyltransferase fold, it lacks one α‐helix and one β‐strand. As a result, the N‐terminal domain as well as the full‐length anamorsin did not show S‐adenosyl‐l ‐methionine (AdoMet) dependent methyltransferase activity. Structural comparisons with known AdoMet dependent methyltransferases reveals subtle differences in the SAM binding pocket that preclude the N‐terminal domain from binding to AdoMet. The N‐terminal methyltransferase‐like domain of anamorsin probably functions as a structural scaffold to inhibit methyl transfers by out‐competing other AdoMet dependant methyltransferases or acts as bait for protein–protein interactions.Proteins 2014; 82:1066–1071. © 2013 Wiley Periodicals, Inc.     

Crystal structure of Pseudomonas aeruginosa Tsi2 reveals a stably folded superhelical antitoxin

In the competition for niches in natural resources, Pseudomonas aeruginosa utilizes the type VI secretion system to inject the toxic protein effector Tse2 into bacteria on cell–cell contact. The cytoplasm toxin immunity protein Tsi2 can neutralize Tse2 by physical interaction with the toxin, providing essential protection from toxin activity. Except for orthologues in P. aeruginosa, Tsi2 antitoxin does not share detectable sequence homology with known proteins in public databases. The mechanism underlying toxin neutralization by Tsi2 remains unknown. We report here the crystal structure of Tsi2 at 2.28 Å resolution. Our structural and biophysical analyses demonstrate that the antitoxin adopts a previously unobserved superhelical conformation. Tsi2 is highly thermostable in the absence of the toxin in solution. Tsi2 assembles a dimer with 2-fold rotational symmetry, similar to that observed in other toxin–antitoxin systems. Dimerization is essential for the stable folding of Tsi2.     

Structural Insights into the Pseudomonas aeruginosa Type VI Virulence Effector Tse1 Bacteriolysis and Self-protection Mechanisms

Recently, it was identified that Pseudomonas aeruginosa competes with rival cells to gain a growth advantage using a novel mechanism that includes two interrelated processes as follows: employing type VI secretion system (T6SS) virulence effectors to lyse other bacteria, and at the same time producing specialized immunity proteins to inactivate their cognate effectors for self-protection against mutual toxicity. To explore the structural basis of these processes in the context of functional performance, the crystal structures of the T6SS virulence effector Tse1 and its complex with the corresponding immunity protein Tsi1 were determined, which, in association with mutagenesis and Biacore analyses, provided a molecular platform to resolve the relevant structural questions. The results indicated that Tse1 features a papain-like structure and conserved catalytic site with distinct substrate-binding sites to hydrolyze its murein peptide substrate. The immunity protein Tsi1 interacts with Tse1 via a unique interactive recognition mode to shield Tse1 from its physiological substrate. These findings reveal both the structural mechanisms for bacteriolysis and the self-protection against the T6SS effector Tse1. These mechanisms are significant not only by contributing to a novel understanding of niche competition among bacteria but also in providing a structural basis for antibacterial agent design and the development of new strategies to fight P. aeruginosa.     

Structural insights into the recognition of β3 integrin cytoplasmic tail by the SH3 domain of Src kinase

Src kinase plays an important role in integrin signaling by regulating cytoskeletal organization and cell remodeling. Previous in vivo studies have revealed that the SH3 domain of c‐Src kinase directly associates with the C‐terminus of β₃ integrin cytoplasmic tail. Here, we explore this binding interface with a combination of different spectroscopic and computational methods. Chemical shift mapping, PRE, transferred NOE and CD data were used to obtain a docked model of the complex. This model suggests a different binding mode from the one proposed through previous studies wherein, the C‐terminal end of β3 spans the region in between the RT and n‐Src loops of SH3 domain. Furthermore, we show that tyrosine phosphorylation of β₃ prevents this interaction, supporting the notion of a constitutive interaction between β₃ integrin and Src kinase.     

Mechanism of formation of the C‐terminal β‐hairpin of the B3 domain of the immunoglobulin binding protein G from Streptococcus. II. Interplay of local backbone conformational dynamics and long‐range hydrophobic interactions in hairpin formation

Two peptides, corresponding to the turn region of the C‐terminal β‐hairpin of the B3 domain of the immunoglobulin binding protein G from Streptococcus, consisting of residues 51–56 [IG(51–56)] and 50–57 [IG(50–57)], respectively, were studied by circular dichroism and NMR spectroscopy at various temperatures and by differential scanning calorimetry. Our results show that the part of the sequence corresponding to the β‐turn in the native structure (DDATKT) of the B3 domain forms bent conformations similar to those observed in the native protein. The formation of a turn is observed for both peptides in a broad range of temperatures (T = 283–323 K), which confirms the conclusion drawn from our previous studies of longer sequences from the C‐terminal β‐hairpin of the B3 domain of the immunoglobulin binding protein G (16, 14, and 12 residues), that the DDATKT sequence forms a nucleation site for formation of the β‐hairpin structure of peptides corresponding to the C‐terminal part of all the B domains of the immunoglobulin binding protein G. We also show and discuss the role of long‐range hydrophobic interactions as well as local conformational properties of polypeptide chains in the mechanism of formation of the β‐hairpin structure. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Mapping of the chaperone AcrH binding regions of translocators AopB and AopD and characterization of oligomeric and metastable AcrH‐AopB‐AopD complexes in the type III secretion system of Aeromonas hydrophila

In the type III secretion system (T3SS) of Aeromonas hydrophila, AcrH acts as a chaperone for translocators AopB and AopD. AcrH forms a stable 1:1 monomeric complex with AopD, whereas the 1:1 AcrH‐AopB complex exists mainly as a metastable oligomeric form and only in minor amounts as a stable monomeric form. Limited protease digestion shows that these complexes contain highly exposed regions, thus allowing mapping of intact functional chaperone binding regions of AopB and AopD. AopD uses the transmembrane domain (DF1, residues 16–147) and the C‐terminal amphipathic helical domain (DF2, residues 242–296) whereas AopB uses a discrete region containing the transmembrane domain and the putative N‐terminal coiled coil domain (BF1, residues 33–264). Oligomerization of the AcrH‐AopB complex is mainly through the C‐terminal coiled coil domain of AopB, which is dispensable for chaperone binding. The three proteins, AcrH, AopB, and AopD, can be coexpressed to form an oligomeric and metastable complex. These three proteins are also oligomerized mainly through the C‐terminal domain of AopB. Formation of such an oligomeric and metastable complex may be important for the proper formation of translocon of correct topology and stoichiometry on the host membrane.     

Crystal structure of Streptococcus pneumoniae Sp1610, a putative tRNA methyltransferase,in complex with S‐adenosyl‐L‐methionine

Streptococcus pneumoniae Sp1610, a Class‐I fold S‐adenosylmethionine (AdoMet)‐dependent methyltransferase, is a member of the COG2384 family in the Clusters of Orthologous Groups database, which catalyzes the methylation of N¹‐adenosine at position 22 of bacterial tRNA. We determined the crystal structure of Sp1610 in the ligand‐free and the AdoMet‐bound forms at resolutions of 2.0 and 3.0 Å, respectively. The protein is organized into two structural domains: the N‐terminal catalytic domain with a Class I AdoMet‐dependent methyltransferase fold, and the C‐terminal substrate recognition domain with a novel fold of four α‐helices. Observations of the electrostatic potential surface revealed that the concave surface located near the AdoMet binding pocket was predominantly positively charged, and thus this was predicted to be an RNA binding area. Based on the results of sequence alignment and structural analysis, the putative catalytic residues responsible for substrate recognition are also proposed.