Structural aspects of the inhibition of DNase and rRNase colicins by their immunity proteins

Nuclease E colicins that exert their cytotoxic activity through either non-specific DNase or specific rRNase action are inhibited by immunity proteins in a high affinity interaction that gives complete protection to the producing host cell from the deleterious effects of the toxin. Previous X-ray crystallographic analysis of these systems has revealed that in both cases, the immunity protein inhibitor forms its highly stable complex with the enzyme by binding as an exosite inhibitor-adjacent to, but not obscuring, the enzyme active site. The structures of the free E9 DNase domain and its complex with an ssDNA substrate now show that inhibition is achieved without deformation of the enzyme and by occlusion of a limited number of residues of the enzyme critical in recognition and binding of the substrate that are 3' to the cleaved scissile phosphodiester. No sequence or structural similarity is evident between the two classes of cytotoxic domain, and the heterodimer interfaces are also dissimilar. Thus, whilst these structures suggest the basis for specificity in each case, they give few indications as to the basis for the remarkably strong binding that is observed. Structural analyses of complexes bearing single site mutations in the immunity protein at the heterodimer interface reveal further differences. For the DNases, a largely plastic interface is suggested, where optimal binding may be achieved in part by rigid body adjustment in the relative positions of inhibitor and enzyme. For the rRNases, a large solvent-filled cavity is found at the immunity-enzyme interface, suggesting that other considerations, such as that arising from the entropy contribution from bound water molecules, may have greater significance in the determination of rRNase complex affinity than for the DNases.     

Glutathione biosynthesis in bacteria by bifunctional GshF is driven by a modular structure featuring a novel hybrid ATP-grasp fold

Glutathione is an intracellular redox-active tripeptide thiol with a central role in cellular physiology across all kingdoms of life. Glutathione biosynthesis has been traditionally viewed as a conserved process relying on the sequential activity of two separate ligases, but recently, an enzyme (GshF) that unifies both necessary reactions in one platform has been identified and characterized in a number of pathogenic and free-living bacteria. Here, we report crystal structures of two prototypic GshF enzymes from Streptococcus agalactiae and Pasteurella multocida in an effort to shed light onto the structural determinants underlying their bifunctionality and to provide a structural framework for the plethora of biochemical and mutagenesis studies available for these enzymes. Our structures reveal how a canonical bacterial GshA module that catalyzes the condensation of L-glutamate and L-cysteine to γ-glutamylcysteine is linked to a novel ATP-grasp-like module responsible for the ensuing formation of glutathione from γ-glutamylcysteine and glycine. Notably, we identify an unprecedented subdomain in the ATP-grasp module of GshF at the interface of the GshF dimer, which is poised to mediate intersubunit communication and allosteric regulation of enzymatic activity. Comparison of the two GshF structures and mapping of structure-function relationships reveal that the bifunctional GshF structural platform operates as a dynamic dimeric assembly.     

Global structural rearrangement of the cell penetrating ribonuclease colicin E3 on interaction with phospholipid membranes

Nuclease type colicins and related bacteriocins possess the unprecedented ability to translocate an enzymatic polypeptide chain across the Gram-negative cell envelope. Here we use the rRNase domain of the cytotoxic ribonuclease colicin E3 to examine the structural changes on its interaction with the membrane. Using phospholipid vesicles as model membranes we show that anionic membranes destabilize the nuclease domain of the rRNase type colicin E3. Intrinsic tryptophan fluorescence and circular dichroism show that vesicles consisting of pure DOPA act as a powerful protein denaturant toward the rRNase domain, although this interaction can be entirely prevented by the addition of salt. Binding of E3 rRNase to DOPA vesicles is an endothermic process (DeltaH=24 kcal mol-1), reflecting unfolding of the protein. Consistent with this, binding of a highly destabilized mutant of the E3 rRNase to DOPA vesicles is exothermic. With mixed vesicles containing anionic and neutral phospholipids at a ratio of 1:3, set to mimic the charge of the Escherichia coli inner membrane, destabilization of E3 rRNase is lessened, although the melting temperature of the protein at pH 7.0 is greatly reduced from 50 degrees C to 30 degrees C. The interaction of E3 rRNase with 1:3 DOPA:DOPC vesicles is also highly dependent on both ionic strength and temperature. We discuss these results in terms of the likely interaction of the E3 rRNase and the related E9 DNase domains with the E. coli inner membrane and their subsequent translocation to the cell cytoplasm.     

Energy-dependent Immunity Protein Release during tol-dependent Nuclease Colicin Translocation

Nuclease colicins bind their target receptor in the outer membrane of sensitive cells in the form of a high affinity complex with their cognate immunity proteins. Upon cell entry the immunity protein is lost from the complex by means that are poorly understood. We have developed a sensitive fluorescence assay that has enabled us to study the molecular requirements for immunity protein release. Nuclease colicins use members of the tol operon for their translocation across the outer membrane. We have demonstrated that the amino-terminal 80 residues of the colicin E9 molecule, which is the region that interacts with TolB, are essential for immunity protein release. Using tol deletion strains we analyzed the cellular components necessary for immunity protein release and found that in addition to a requirement for tolB, the tolA deletion strain was most affected. Complementation studies showed that the mutation H22A, within the transmembrane segment of TolA, abolishes immunity protein release. Investigation of the energy requirements demonstrated that the proton motive force of the cytoplasmic membrane is critical. Taken together these results demonstrate for the first time a clear energy requirement for the uptake of a nuclease colicin complex and suggest that energy transduced from the cytoplasmic membrane to the outer membrane by TolA could be the driving force for immunity protein release and concomitant translocation of the nuclease domain.Membrane translocation is a formidable challenge for folded proteins. Eukaryotes have an array of dedicated translocation machineries to accomplish this feat, for example during mitochondrial import of cytosolic precursor proteins for which it has recently become clear that there is a surprising diversity in targeting signals, import routes, and translocation complexes (1, 2). It is now widely accepted that the mitochondrial genome originated from within the (eu)bacterial domain of life, so it should perhaps not come as a surprise that certain features of mitochondrial import have evolved from these ancestors.Gram-negative bacteria possess two membranes to protect them from the external world, separated by a layer of peptidoglycan and the periplasmic space. Their outer membrane, with its asymmetrical composition of lipopolysaccharide (LPS)² and phospholipids, forms an impressive barrier to most substances with the exception of small hydrophilic nutrients that can diffuse through the resident porins (3). Processes that require an energy input at the outer membrane, such as iron siderophore uptake, therefore often rely on energy generated by ion gradients at the cytoplasmic membrane (4). Energy-transducing systems such as the ton and tol systems in Escherichia coli harvest energy generated at the cytoplasmic membrane and transduce it to the outer membrane. These two systems have a number of features in common, and cross-complementation between the two systems has been observed (5).The energy transducing capacity of the ton system is somewhat better defined and is accomplished by three proteins: the cytoplasmic membrane proteins ExbB and ExbD, which form a heteromultimeric complex that interacts with TonB (4). As a result, TonB undergoes a conformational change in response to the PMF of the cytoplasmic membrane, which allows it to traverse the periplasm and make contact with nutrient-loaded outer membrane receptors, thereby facilitating active import (6). The homology between ExbB/D, TolQ/R, and the PMF-responsive flagellar motor proteins MotA and MotB is well established, and the cumulative evidence now suggests that they act as energy-harvesting complexes (7–9). Evidence of an evolutionary relationship between TolA and TonB comes from work demonstrating structural similarities between the Pseudomonas aeruginosa TolAIII globular domain and the carboxyl-terminal domain of E. coli TonB despite the very low sequence conservation (10). The activities of TonB and TolA are also critically dependent on a conserved SHLS motif in their transmembrane region, the mutation of which affects the interaction with their respective energy-harvesting complexes (11, 12). The cellular function of the tol system in E. coli is, however, less clear. It is thought that the Tol proteins play a role in maintaining cell envelope integrity through a network of interactions spanning the cytoplasmic membrane, periplasm, and outer membrane (13).Both energy-transducing systems have been parasitized by the colicins, plasmid-encoded antibacterial proteins produced by E. coli, and phages for their translocation into the cell, but the energy requirements for these processes are not unequivocal (14). Group A colicins use the tol system and group B colicins the ton system in a process whereby interactions of their amino-terminal translocation domains with the Tol or Ton proteins in the periplasm ultimately lead to the entry of their carboxyl-terminal cytotoxic domain into the cell (15, 16). In common with most colicins, the DNase-type colicin E9 consists of three functional domains: the killing activity is contained in its carboxyl-terminal DNase domain; the central section contains the receptor-binding domain, which binds the vitamin B₁₂ receptor, BtuB, in the outer membrane; and the amino-terminal translocation domain is needed for the entry of the cytotoxic domain into the target cell. The first 83 residues of this translocation domain, commonly referred to as the NDR, contain the OmpF and TolB binding sites (17, 18). Upon synthesis colicin E9 forms a high affinity interaction with its cognate immunity protein, Im9, also encoded by the colicin operon. This heterodimeric complex formation protects colicin-producing cells against DNA damage and potential suicide prior to release of the complex in the environment. The nature of the complex formation between colicin E9 and Im9 and other colicin-immunity complexes has been well characterized, and in the case of colicin E9-Im9 the interaction is strong, as reflected by its dissociation constant on the order of 10⁻¹⁴ m under physiological conditions (19). Despite the high avidity of this interaction, the DNase domain of colicin E9 appears to have only a marginally stabilizing effect on Im9 (20).Currently much progress is being made to unravel the early events that take place after receptor binding, where it has been shown that the colicin E9 NDR enters the periplasm through the OmpF lumen where it interacts with TolB, possibly displacing it from its interaction with Pal (18, 21–24). It was also recently demonstrated that the receptor binding and translocation domains remain in contact with their binding partners in the outer membrane and the periplasm, respectively, when the DNase domain gains access to the cytoplasm (25). In contrast, the molecular mechanisms that govern the loss of the immunity protein from the colicin complex and the cell entry of the DNase domain are less well documented. Because of the strength of the interaction between the colicin and its cognate immunity protein, it has been proposed that removal of the immunity protein from the complex would require a cellular energy source. One recent report investigating immunity protein loss from the colicin E2-Im2 complex qualitatively concluded that receptor binding alone does not lead to immunity protein release and that a functional tol translocation complex is required to establish immunity protein release (26).Here we have presented data that for the first time demonstrate a role for the individual Tol proteins and address the issue of energy requirements for immunity protein release. We observed, by using a previously described disulfide-“locked” colicin construct and domain deletion mutants thereof, that entry of the amino-terminal 80 residues of the colicin translocation domain and its interaction with TolB are essential factors for immunity protein release. We have also demonstrated a crucial role for TolA and its transmembrane region in this process, showing that immunity protein release from the colicin complex is an energy-dependent process governed by the cytoplasmic membrane PMF. Finally we have provided a rationale for how an energized Tol system might lead to immunity protein loss and concomitant colicin uptake in sensitive cells.     

Silicon supply in soilless cultivations of zucchini alleviates stress induced by salinity and powdery mildew infections

In the present study, the hypothesis was tested as to whether silicon supplied via the nutrient solution is capable of enhancing the tolerance of hydroponically grown zucchini squash (Cucurbita pepo L. cv. ‘Rival’) to salinity and powdery mildew infections. Two experiments were conducted involving a low (2.2 dS m^?1, 0.8 mM NaCl) and a high salinity level (6.2 dS m^?1, 35 mM NaCl) in combination with a low (0.1 mM) and a high (1.0 mM) Si level in the nutrient solution supplied to the crop. The exposure of the plants to high external salinity restricted significantly the vegetative growth as well as the fruit yield of zucchini due to a reduction of both the number of fruits per plant and the mean fruit weight. However, the inclusion of 1 mM of Si in the salinized nutrient solution mitigated the salinity-associated suppression of both growth and yield. Part of the growth and fruit yield suppression at high salinity was due to restriction of net photosynthesis. The stomatal conductance was also restricted by salinity, whereas the substomatal CO₂ concentration was not affected by the NaCl or Si treatments. The supply of 1 mM of Si via the nutrient solution mitigated the inhibitory effect of salinity on net photosynthesis and this effect was associated with lower Na and Cl translocation to the epigeous plant tissues. Furthermore, the supply of Si via the nutrient solution suppressed appreciably the expansion of a powdery mildew (Podosphaera xanthii) infection in the leaves at both salinity levels. These results indicate that the supply of at least 1 mM of Si via the nutrient solution is capable of enhancing both tolerance to salinity and resistance to powdery mildew in soilless cultivations of zucchini squash.     

Self‐association of TPR domains: Lessons learned from a designed,consensus‐based TPR oligomer

The tetratricopeptide repeat (TPR) motif is a protein–protein interaction module that acts as an organizing centre for complexes regulating a multitude of biological processes. Despite accumulating evidence for the formation of TPR oligomers as an additional level of regulation there is a lack of structural and solution data explaining TPR self‐association. In the present work we characterize the trimeric TPR‐containing protein YbgF, which is linked to the Tol system in Gram‐negative bacteria. By subtracting previously identified TPR consensus residues required for stability of the fold from residues conserved across YbgF homologs, we identified residues involved in oligomerization of the C‐terminal YbgF TPR domain. Crafting these residues, which are located in loop regions between TPR motifs, onto the monomeric consensus TPR protein CTPR3 induced the formation of oligomers. The crystal structure of this engineered oligomer shows an asymmetric trimer where stacking interactions between the introduced tyrosines and displacement of the C‐terminal hydrophilic capping helix, present in most TPR domains, are key to oligomerization. Asymmetric trimerization of the YbgF TPR domain and CTPR3Y3 leads to the formation of higher order oligomers both in the crystal and in solution. However, such open‐ended self‐association does not occur in full‐length YbgF suggesting that the protein's N‐terminal coiled‐coil domain restricts further oligomerization. This interpretation is borne out in experiments where the coiled‐coil domain of YbgF was engineered onto the N‐terminus of CTPR3Y3 and shown to block self‐association beyond trimerization. Our study lays the foundations for understanding the structural basis for TPR domain self‐association and how such self‐association can be regulated in TPR domain‐containing proteins. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Members of a Novel Protein Family Containing Microneme Adhesive Repeat Domains Act as Sialic Acid-binding Lectins during Host Cell Invasion by Apicomplexan Parasites

Numerous intracellular pathogens exploit cell surface glycoconjugates for host cell recognition and entry. Unlike bacteria and viruses, Toxoplasma gondii and other parasites of the phylum Apicomplexa actively invade host cells, and this process critically depends on adhesins (microneme proteins) released onto the parasite surface from intracellular organelles called micronemes (MIC). The microneme adhesive repeat (MAR) domain of T. gondii MIC1 (TgMIC1) recognizes sialic acid (Sia), a key determinant on the host cell surface for invasion by this pathogen. By complementation and invasion assays, we demonstrate that TgMIC1 is one important player in Sia-dependent invasion and that another novel Sia-binding lectin, designated TgMIC13, is also involved. Using BLAST searches, we identify a family of MAR-containing proteins in enteroparasitic coccidians, a subclass of apicomplexans, including T. gondii, suggesting that all these parasites exploit sialylated glycoconjugates on host cells as determinants for enteric invasion. Furthermore, this protein family might provide a basis for the broad host cell range observed for coccidians that form tissue cysts during chronic infection. Carbohydrate microarray analyses, corroborated by structural considerations, show that TgMIC13, TgMIC1, and its homologue Neospora caninum MIC1 (NcMIC1) share a preference for α2–3- over α2–6-linked sialyl-N-acetyllactosamine sequences. However, the three lectins also display differences in binding preferences. Intense binding of TgMIC13 to α2–9-linked disialyl sequence reported on embryonal cells and relatively strong binding to 4-O-acetylated-Sia found on gut epithelium and binding of NcMIC1 to 6′sulfo-sialyl Lewis^x might have implications for tissue tropism.     

Colicin biology.

Colicins are proteins produced by and toxic for some strains of Escherichia coli. They are produced by strains of E. coli carrying a colicinogenic plasmid that bears the genetic determinants for colicin synthesis, immunity, and release. Insights gained into each fundamental aspect of their biology are presented: their synthesis, which is under SOS regulation; their release into the extracellular medium, which involves the colicin lysis protein; and their uptake mechanisms and modes of action. Colicins are organized into three domains, each one involved in a different step of the process of killing sensitive bacteria. The structures of some colicins are known at the atomic level and are discussed. Colicins exert their lethal action by first binding to specific receptors, which are outer membrane proteins used for the entry of specific nutrients. They are then translocated through the outer membrane and transit through the periplasm by either the Tol or the TonB system. The components of each system are known, and their implication in the functioning of the system is described. Colicins then reach their lethal target and act either by forming a voltage-dependent channel into the inner membrane or by using their endonuclease activity on DNA, rRNA, or tRNA. The mechanisms of inhibition by specific and cognate immunity proteins are presented. Finally, the use of colicins as laboratory or biotechnological tools and their mode of evolution are discussed.