Isolation and characterization of the C-terminal nuclease domain from the RecB protein of Escherichia coli.

The RecB subunit of the Escherichia coli RecBCD enzyme has been shown in previous work to have two domains: an N-terminal 100 kDa domain with ATP-dependent helicase activity, and a C-terminal 30 kDa domain. The 30 kDa domain had nuclease activity when linked to a heterologous DNA binding protein, but by itself it appeared unable to bind DNA and lacked detectable nuclease activity. We have expressed and isolated this 30 kDa domain, called RecB(N), and show that it does have nuclease activity detectable at high protein concentration in the presence of polyethylene glycol, added as a molecular crowding agent. The activity is undetectable in a mutant RecB(N)protein in which an aspartate residue has been changed to alanine. Structural analysis of the wild-type and mutant RecB(N)proteins by second derivative absorbance and circular dichroism spectroscopy indicates that both are folded proteins with very similar secondary and tertiary structures. The results show that the Asp-->Ala mutation has not caused a significant structural change in the isolated domain and they support the conclusion that the C-terminal domain of RecB has the sole nuclease active site of RecBCD.     

YcdY protein of Escherichia coli, an atypical member of the TorD chaperone family

The TorD family of specific chaperones is divided into four subfamilies dedicated to molybdoenzyme biogenesis and a fifth one, exemplified by YcdY of Escherichia coli, for which no defined partner has been identified so far. We propose that YcdY is the chaperone of YcdX, a zinc protein involved in the swarming motility process of E. coli, since YcdY interacts with YcdX and increases its activity in vitro.     

Crystallographic structure of the nuclease domain of 3'hExo, a DEDDh family member, bound to rAMP

A human 3'-5'-exoribonuclease (3'hExo) has recently been identified and shown to be responsible for histone mRNA degradation. Functionally, 3'hExo and a stem-loop binding protein (SLBP) target opposite faces of a unique highly conserved stem-loop RNA scaffold towards the 3' end of histone mRNA, which is composed of a 6 bp stem and a 4 nt loop, followed by an ACCCA sequence. Its Caenorhabditis elegans homologue, ERI-1, has been shown to degrade small interfering RNA in vitro and to function as a negative regulator of RNA interference in neuronal cells. We have determined the structure of the nuclease domain (Nuc) of 3'hExo complexed with rAMP in the presence of Mg2+ at 1.6 A resolution. The Nuc domain adopts an alpha/beta globular fold, with four acidic residues coordinating a binuclear metal cluster within the active site, whose topology is related to DEDDh exonuclease family members, despite a very low level of primary sequence identity. The two magnesium cations in the Nuc active site are coordinated to D134, E136, D234 and D298, and together with H293, which can potentially act as a general base, provide a platform for hydrolytic cleavage of bound RNA in the 3' --> 5' direction. The bound rAMP is positioned within a deep active-site pocket, with its purine ring close-packed with the hydrophobic F185 and L189 side-chains and its sugar 2'-OH and 3'-OH groups hydrogen bonded to backbone atoms of Nuc. There are striking similarities between the active sites of Nuc and epsilon186, an Escherichia coli DNA polymerase III proofreading domain, providing a common hydrolytic cleavage mechanism for RNA degradation and DNA editing, respectively.     

Structure and function of the middle domain of ClpB from Escherichia coli

ClpB belongs to the Hsp100/Clp ATPase family. Whereas a homologue of ClpB, ClpA, interacts with and stimulates the peptidase ClpP, ClpB does not associate with peptidases and instead cooperates with DnaK/DnaJ/GrpE in an efficient reactivation of severely aggregated proteins. The major difference between ClpA and ClpB is located in the middle sequence region (MD) that is much longer in ClpB than in ClpA and contains several segments of coiled-coil-like heptad repeats. The function of MD is unknown. We purified the isolated MD fragment of ClpB from Escherichia coli (residues 410-570). Circular dichroism (CD) detected a high population of alpha-helical structure in MD. Temperature-induced changes in CD showed that MD is a thermodynamically stable folding domain. Sedimentation equilibrium showed that MD is monomeric in solution. We produced four truncated variants of ClpB with deletions of the following heptad-repeat-containing regions in MD: 417-455, 456-498, 496-530, and 531-569. We found that the removal of each heptad-repeat region within MD strongly inhibited the oligomerization of ClpB, which produced low ATPase activity of the truncated ClpB variants as well as their low chaperone activity in vivo. Only one ClpB variant (Delta417-455) could partially complement the growth defect of the clpB-null E. coli strain at 50 degrees C. Our results show that heptad repeats in MD play an important role in stabilization of the active oligomeric form of ClpB. The heptad repeats are likely involved in stabilization of an intra-MD helical bundle rather than an intersubunit coiled coil.     

Characterisation of YtfM, a second member of the Omp85 family in Escherichia coli

Omp85 proteins form a ubiquitous protein family, members of which are found in all Gram-negative bacteria. Omp85 of Neisseria meningitidis and YaeT of Escherichia coli are shown to be essential for outer membrane biogenesis. Interestingly, there exists a homologue to YaeT in E. coli and many proteobacteria, denoted YtfM, the function of which has not been described yet. Like YaeT, YtfM is predicted to consist of an amino-terminal periplasmic domain and a membrane-located carboxy-terminal domain. In this study, we present a first characterisation of YtfM by comparison to YaeT concerning structural, biochemical and electrophysiological properties. Furthermore, a knockout strain revealed that ytfM is a non-essential gene and lack of the protein had no effect on outer membrane composition and integrity. The only observable phenotype was strongly reduced growth, indicating an important role of YtfM in vivo.     

Structure and function of a model member of the SulP transporter family

SHST1 is a sulfate transporter that belongs to a large and diverse family of anion transporters. Little is known about the structure and function of any member of the family. Site-directed mutagenesis of SHST1 is being used to understand the function of particular amino acids. We have mutated highly conserved amino acid residues and the results suggest that the first two helices play an important role in the transport pathway. Furthermore, mutation of equivalent residues to those altered in human genetic diseases produces deleterious effects in SHST1. These results suggest that there are similarities in the molecular mechanism of transport throughout the family and the information obtained with SHST1 may be applicable to the entire family.     

UpaG, a new member of the trimeric autotransporter family of adhesins in uropathogenic Escherichia coli

The ability of Escherichia coli to colonize both intestinal and extraintestinal sites is driven by the presence of specific virulence factors, among which are the autotransporter (AT) proteins. Members of the trimeric AT adhesin family are important virulence factors for several gram-negative pathogens and mediate adherence to eukaryotic cells and extracellular matrix (ECM) proteins. In this study, we characterized a new trimeric AT adhesin (UpaG) from uropathogenic E. coli (UPEC). Molecular analysis of UpaG revealed that it is translocated to the cell surface and adopts a multimeric conformation. We demonstrated that UpaG is able to promote cell aggregation and biofilm formation on abiotic surfaces in CFT073 and various UPEC strains. In addition, UpaG expression resulted in the adhesion of CFT073 to human bladder epithelial cells, with specific affinity to fibronectin and laminin. Prevalence analysis revealed that upaG is strongly associated with E. coli strains from the B2 and D phylogenetic groups, while deletion of upaG had no significant effect on the ability of CFT073 to colonize the mouse urinary tract. Thus, UpaG is a novel trimeric AT adhesin from E. coli that mediates aggregation, biofilm formation, and adhesion to various ECM proteins.     

Structure and dimerization of the kinase domain from yeast Snf1, a member of the Snf1/AMPK protein family

The Snf1/AMPK kinases are intracellular energy sensors, and the AMPK pathway has been implicated in a variety of metabolic human disorders. Here we report the crystal structure of the kinase domain from yeast Snf1, revealing a bilobe kinase fold with greatest homology to cyclin-dependant kinase-2. Unexpectedly, the crystal structure also reveals a novel homodimer that we show also forms in solution, as demonstrated by equilibrium sedimentation, and in yeast cells, as shown by coimmunoprecipitation of differentially tagged intact Snf1. A mapping of sequence conservation suggests that dimer formation is a conserved feature of the Snf1/AMPK kinases. The conformation of the conserved alphaC helix, and the burial of the activation segment and substrate binding site within the dimer, suggests that it represents an inactive form of the kinase. Taken together, these studies suggest another layer of kinase regulation within the Snf1/AMPK family, and an avenue for development of AMPK-specific activating compounds.     

Growth-phase-dependent expression of cspD, encoding a member of the CspA family in Escherichia coli.

The cspD gene of Escherichia coli encodes a protein of high sequence similarity with the cold shock protein CspA, but cspD expression is not induced by cold shock. In this study, we analyzed the regulation of cspD gene expression. By using a cspD-lacZ fusion and primer extension analysis, the expression of cspD was found to be dramatically induced by stationary-phase growth. However, this induction does not depend on the stationary-phase sigma factor sigmaS. Moreover, the expression of cspD is inversely dependent on growth rates and induced upon glucose starvation. Using a (p)ppGpp-depleted strain, we found that (p)ppGpp is one of the positive factors for the regulation of cspD expression.     

Analysis of the membrane organization of an Escherichia coli protein translocator, HlyB, a member of a large family of prokaryote and eukaryote surface transport proteins

Haemolysin B (HlyB) is essential for secretion of the 107 x 10(3) Mr haemolysin A protein from Escherichia coli and is a member of a family of highly conserved, apparently ATP-dependent surface proteins in many organisms. We have shown in this study that both HlyB and HlyD fractionate primarily with the cytoplasmic membrane of E. coli and are accessible to proteases after removal of the outer membrane. We have measured experimentally the topological organization of HlyB within the membrane by construction of fusions to beta-lactamase as a reporter. The predicted folding of HlyB, with a minimum of six transmembrane segments, does not always coincide with regions of highest average hydrophobicity. This suggests that HlyB may have a novel organization within the bilayer. From our data and comparative sequence analysis, we have been able to predict very similar topological models for the other members of the HlyB family.     

Intramolecular recombination of linear DNA catalyzed by the Escherichia coli RecE recombination system

Transformation of different Escherichia coli strains by linear dimers of pBR322 containing different tet alleles was investigated. Linear dimers transformed wild-type strains 0.1 to 1% as efficiently as circular dimers. In contrast, linear dimers transformed recBrecCsbcA strains, where the RecE recombination system is functional, as efficiently as circular dimers. The transformants contained plasmids that had a single recombinant monomer genotype, indicating that transformation was mediated by a recombination-dependent cyclization reaction. Altering the position of the double-strand break changed the frequency of recovering different recombination products, but had no effect on the frequency of transformation. Both the frequency of transformation and the production of Tcr recombinants were decreased by recE mutations, while recA and recF mutations were slightly stimulatory (twofold). Several recombination models consistent with these results are presented.     

Escherichia coli CAN lacks a tRNA-processing nuclease.

Escherichia coli strain CAN is unable to support the growth of bacteriophage T4 strains requiring the suppressor function of T4 tRNASer. Biochemical analysis of the mutant strain revealed that it is deficient in a RNase which acts on the artificial tRNA precursor tRNA-C-U.     

The Escherichia coli FtsH protein is a prokaryotic member of a protein family of putative ATPases involved in membrane functions, cell cycle control, and gene expression.

The ftsH gene is essential for cell viability in Escherichia coli. We cloned and sequenced the wild-type ftsH gene and the temperature-sensitive ftsH1(Ts) gene. It was suggested that FtsH protein was an integral membrane protein of 70.7 kDa (644 amino acid residues) with a putative ATP-binding domain. The ftsH1(Ts) gene was found to have two base substitutions within the coding sequence corresponding to the amino acid substitutions Glu-463 by Lys and Pro-587 by Ala. Homology search revealed that an approximately 200-amino-acid domain, including the putative ATP-binding sequence, is highly homologous (35 to 48% identical) to the domain found in members of a novel, eukaryotic family of putative ATPases, e.g., Sec18p, Pas1p, CDC48p, and TBP-1, which function in protein transport pathways, peroxisome assembly, cell division cycle, and gene expression, respectively. Possible implications of these observations are discussed.     

Structure of a lipid droplet protein; the PAT family member TIP47

The perilipin/ADRP/TIP47 (PAT) proteins localize to the surface of intracellular neutral lipid droplets. Perilipin is essential for lipid storage and hormone regulated lipolysis in adipocytes, and perilipin null mice exhibit a dramatic reduction in adipocyte lipid stores. A significant fraction of the approximately 200 amino acid N-terminal region of the PAT proteins consists of 11-mer helical repeats that are also found in apolipoproteins and other lipid-associated proteins. The C-terminal 60% of TIP47, a representative PAT protein, comprises a monomeric and independently folded unit. The crystal structure of the C-terminal portion of TIP47 was determined and refined at 2.8 A resolution. The structure consists of an alpha/beta domain of novel topology and a four-helix bundle resembling the LDL receptor binding domain of apolipoprotein E. The structure suggests an analogy between PAT proteins and apolipoproteins in which helical repeats interact with lipid while the ordered C-terminal region is involved in protein:protein interactions.     

A C-terminal carbohydrate-binding domain in the endothelial cell regulatory protein, pigpen: new function for an EWS family member

The potential for encoding information in carbohydrate (CHO) structures has long been recognized. Selective CHO-binding proteins known as lectins and the biological events they mediate are well known. However, many lectins were originally discovered for biological activities other than saccharide binding, and only subsequently was it realized that one or more of their key functions were mediated by specific CHO recognition. Our previous observations suggested that the nuclear protein pigpen had an affinity for CHO structures. This would represent a new attribute for proteins of the EWS (Ewing's sarcoma) family, of which pigpen is a member. In this study we demonstrate that a CHO-binding domain resides in the C-terminus of the molecule and can be preferentially inhibited by saccharides, most notably N-acetyl-d-galactosamine (GalNAc) and the GalNAc-containing polysaccharide, chondroitin sulfate. Ligand blotting experiments were subsequently performed with fractionated, [(3)H]galactose-labeled cells to demonstrate the presence of chondroitin sulfate-inhibitable endogenous CHO ligands for pigpen in endothelial nuclei. Finally, microinjection of polysaccharide competitor into the nucleus of cultured endothelial cells resulted in a loss of pigpen focal accumulations, suggesting that the CHO-binding activity may be instrumental in subcellular localization of the protein. In summary, our results show ligand preference and domain specificity for pigpen's CHO affinity and provide initial evidence for physiological ligands and function. They may also shed new light on the mechanisms of oncogenic transformation involving EWS proteins.