Structural elucidation of the O-antigenic polysaccharides from Escherichia coli O21 and the enteroaggregative Escherichia coli strain 105.

The structure of the O-antigen polysaccharide of the lipopolysaccharide from an enteroaggregative Escherichia coli (strain 105) has been elucidated, using primarily one-dimensional and two-dimensional NMR experiments. The sequence of residues was deduced with heteronuclear multiple-bond correlation and NOESY experiments. The structure of the repeating unit of the polysaccharide from the enteroaggregative E. coli is as follows:[sequence: see text] The structure of the O-antigen from enteroaggregative E. coli strain 105 was shown to be identical with that of E. coli O21 by sugar and methylation analyses as well as by 1H-NMR and 13C-NMR spectroscopy.     

Molecular cloning and expression in Escherichia coli K-12 of the rfb gene cluster determining the O antigen of an E. coli O111 strain

The O antigen of Escherichia coli O111 is identical in structure to that of Salmonella enterica serovar adelaide. Another O-antigen structure, similar to that of E. coli O111 and S. enterica serovar adelaide is found in both E. coli O55 and S. enterica serovar greenside. Both O-antigen structures contain colitose, a 3,6 dideoxyhexose found only rarely in the Enterobacteriaceae. The O-antigen structure is determined by genes generally located in the rfb gene cluster. We cloned the rfb gene cluster from an E. coli O111 strain (M92), and the clone expressed O antigen in both E. coli K-12 and a K-12 strain deleted for rfb. Lipopolysaccharide analysis showed that the O antigen produced by strains containing the cloned DNA is polymerized. The chain length of O antigen was affected by a region outside of rfb but linked to it and present on some of the plasmids containing rfb. The rfb region of M92 was analysed and compared, by DNA hybridization, with that of strains with related O antigens. The possible evolution of the rfb genes in these O antigen groups is discussed.     

3-methyladenine-DNA glycosylase II: the crystal structure of an AlkA-hypoxanthine complex suggests the possibility of product inhibition

Escherichia coli (E. coli) protein 3-methyladenine-DNA glycosylase II (AlkA) functions primarily by removing alkylation damage from duplex and single stranded DNA. A crystal structure of AlkA was refined to 2.0 A resolution. This structure in turn was used to refine an AlkA-hypoxanthine (substrate) complex structure to 2.4 A resolution. The complex structure shows hypoxanthine located in AlkA's active site stacked between residues W218 and Y239. The structural analysis of the AlkA and AlkA-hypoxanthine structures indicate that free hypoxanthine binding in the active site may inhibit glycosylase activity.     

Structural analysis of the O-antigen polysaccharide from Escherichia coli O152

The structure of the O-antigen polysaccharide (PS) from Escherichia coli O152 has been determined. Component analysis together with 1H, 13C and 31P NMR spectroscopy were used to elucidate the structure. Inter-residue correlations were determined by 1H,31P COSY, 1H,1H NOESY and 1H,13C heteronuclear multiple-bond correlation experiments. The PS is composed of pentasaccharide repeating units with the following structure: [structure: see text]. The structure is similar to that of the O-antigen polysaccharide from E. coli O173. The cross-reactivity between E. coli O152 and E. coli O3 may be explained by structural similarities in the branching region of their O-antigen polysaccharides.     

Common protein architecture and binding sites in proteases utilizing a Ser/Lys dyad mechanism

Escherichia coli signal peptidase (SPase) and E. coli UmuD protease are members of an evolutionary clan of serine proteases that apparently utilize a serine-lysine catalytic dyad mechanism. Recently, the crystallographic structure of a SPase inhibitor complex was solved elucidating the catalytic residues and the substrate binding subsites. Here we show a detailed comparison of the E. coli SPase structure to the native E. coli UmuD' structure. The comparison reveals that despite a very low sequence identity these functionally diverse enzymes share the same protein fold within their catalytic core and allows by analogy for the assignment of the cleavage-site orientation and substrate binding subsites in the UmuD(D') protease. The structural alignment of SPase and UmuD' predicts important mechanistic and structural similarities and differences within these newly characterized families of serine proteases.     

Cloning and analysis of the gene (rpoDA) for the principal sigma factor of Pseudomonas aeruginosa

A gene (rpoDA) of Pseudomonas aeruginosa whose gene product has a homologous function and structure with the principal sigma factor of Escherichia coli was cloned and sequenced. The DNA region corresponding to one of the two hybridization signals found in P. aeruginosa DNA with a synthetic oligonucleotide probe (rpoD probe) was shown to be able to complement a temperature sensitive mutation of Escherichia coli rpoD gene. The amino acid sequence deduced from the nucleotide sequence of rpoDA showed an extensive homology with that of the principal sigma factor of E. coli throughout the entire region, which indicates that the two gene products have an essentially identical domain structure. A common basic structure observed among principal sigma factors of different eubacterial strains was proposed. RpoDA protein was identified in the extract of the cell carrying a plasmid clone with the rpoDA gene insert by Western blot analysis.     

Monomeric solution structure of the helicase-binding domain of Escherichia coli DnaG primase

DnaG is the primase that lays down RNA primers on single-stranded DNA during bacterial DNA replication. The solution structure of the DnaB-helicase-binding C-terminal domain of Escherichia coli DnaG was determined by NMR spectroscopy at near-neutral pH. The structure is a rare fold that, besides occurring in DnaG C-terminal domains, has been described only for the N-terminal domain of DnaB. The C-terminal helix hairpin present in the DnaG C-terminal domain, however, is either less stable or absent in DnaB, as evidenced by high mobility of the C-terminal 35 residues in a construct comprising residues 1-171. The present structure identifies the previous crystal structure of the E. coli DnaG C-terminal domain as a domain-swapped dimer. It is also significantly different from the NMR structure reported for the corresponding domain of DnaG from the thermophile Bacillus stearothermophilus. NMR experiments showed that the DnaG C-terminal domain does not bind to residues 1-171 of the E. coli DnaB helicase with significant affinity.     

Two different O-polysaccharides from Escherichia coli O86 are produced by different polymerization of the same O-repeating unit

The structure of a new O-polysaccharide from Escherichia coli O86:K62:B7 was determined using NMR and methylation analysis. The structure is as follows: [carbohydrate: see text]. Comparison with the previously published structure from E. coli O86:K2:H2 revealed that the O-polysaccharides from these two E. coli O86 serotypes share the same branched pentasaccharide repeating unit. However, they differ in the anomeric configuration of the linkage, the linkage position, and the identity of the residue through which polymerization occurs. The immunochemical activity of these two forms of LPS toward anti-B antibody was studied and compared. The results showed that LPS from E. coli O86:K2:H2 strain possesses higher blood group B reactivity. The immunoreactivity difference was explained by modeling of the O-repeating unit tetrasaccharide fragments. This finding provides a good system for the further study of O-polysaccharide biosynthesis especially the repeating unit polymerization mechanism.     

Accelerated Adsorption of Bacteriophage T5 to Escherichia coli F, Resulting from Reversible Tail Fiber-Lipopolysaccharide Binding

A dual specificity for phage T5 adsorption to Escherichia coli cells is shown. The tail fiber-containing phages T5(+) and mutant hd-3 adsorbed rapidly to E. coli F (1.2 x 10(-9) ml min(-1)), whereas the adsorption rate of the tail fiber-less mutants hd-1, hd-2, and hd-4 was low (7 x 10(-11) ml min(-1)). The differences in adsorption rates were due to the particular lipopolysaccharide structure of E. coli F. Phage T4-resistant mutants of E. coli F with an altered lipopolysaccharide structure exhibited similar low adsorption for all phage strains with and without tail fibers. The same held true for E. coli K-12 and B which also differ from E. coli F in their lipopolysaccharide structures. Only the tail fiber-containing phages reversibly bound to isolated lipopolysaccharides of E. coli F. Infection by all phage strains strictly depended on the tonA-coded protein in the outer membrane of E. coli. We assume that the reversible preadsorption by the tail fibers to lipopolysaccharide accelerates infection which occurs via the highly specific irreversible binding of the phage tail to the tonA-coded protein receptor. The difference between rapid and slow adsorption was also revealed by the competition between ferrichrome and T5 for binding to their common tonA-coded receptor in tonB strains of E. coli. Whereas binding of T5(+) to E. coli K-12 and of the tail-fiber-less mutant hd-2 to E. coli F and K-12 was inhibited 50% by about 0.01 muM ferrichrome, adsorption of T5 to E. coli F was inhibited only 40% by even 1,000-fold higher ferrichrome concentrations.     

Autoprocessing of Drosophila copia gag precursor to generate a unique laminate structure in Escherichia coli.

Drosophila copia protease is likely to be encoded in the gag gene. We have expressed copia gag polyprotein precursor in E. coli. The gag precursor was correctly processed to generate a unique laminate structure in E. coli. The processing was almost completely blocked by a mutation at the putative active site of copia protease, and resulted in accumulation of the precursor. Furthermore, the laminate structure was not found in E. coli expressing the mutant precursor. These results indicate that the protease is involved in cleaving the gag precursor itself. Also, the assembly of copia gag protein should correlate to the autoprocessing of copia gag polyprotein precursor.     

mLST8在大肠杆菌中的表达、纯化及鉴定

目的:表达并纯化mLST8蛋白。方法:PCR扩增mLST8的编码cDNA,克隆到pET-28a(+)表达载体,将重组质粒pET-28a-mLST8转化大肠杆菌BL21(DE3)感受态细胞,在IPTG诱导下表达目的蛋白;提取包涵体,用Ni2+亲和层析纯化目的蛋白,稀释和透析相结合进行复性,对复性蛋白进行阴离子交换层析、分子筛层析,将纯的复性mLST8进行肽指纹质谱鉴定和圆二色谱分析。结果:酶切和DNA测序证明pET-28a-mLST8表达质粒构建无误,并在大肠杆菌中得到高效表达;通过Ni2+亲和层析、复性、离子交换层析和分子筛层析获得了较高纯度的复性蛋白,肽指纹质谱鉴定为mLST8;mLST8蛋白的二级结构[α螺旋为18.2%,β折叠为52.3%(其中平行结构为12.1%,反向平行结构为40.2%),β转角为20.7%,无规则卷曲为39.9%]表明其为典型的β折叠结构。结论:在大肠杆菌中表达了重组mLST8蛋白,复性获得了二级结构准确的mLST8,为进一步研究mLST8的晶体结构与功能奠定了基础。     

The effect of surface charge property on Escherichia coli initial adhesion and subsequent biofilm formation

Polyethylene (PE) sheets were modified by radiation-induced graft polymerization (RIGP) of an epoxy-group containing monomer glycidyl methacrylate (GMA). The epoxy group of GMA was opened by introducing sodium sulfite (SS) and diethylamine (DEA) as representatives of negatively and positively charged functional groups, respectively. These modified surfaces by RIGP, termed GMA, SS, and DEA sheets, were investigated to elucidate their effects on initial adhesion and subsequent biofilm formation of Escherichia coli. Initial adhesion test revealed that E. coli density and viability were governed by sheet surface electrostatic property: E. coli cell density on the DEA sheet was 23 times higher than that on the SS sheet after 8 h incubation. The viability of E. coli cells dramatically decreased after contact with the DEA sheet, but remained high on the SS sheet. E. coli biofilm structure on the DEA sheet was dense, homogeneous, and uniform, with biomass higher than that of the GMA and SS sheets by factors of 14.0 and 37.5, respectively. On the contrary, biofilm structure on the SS sheet was sparse, heterogeneous, and mushroom-shaped. More than 40% of E. coli biofilm on the DEA sheet was retained under a high liquid shear force condition (5,000 s(-1)), whereas 97% and 100% of biofilms on the GMA and SS sheets were sloughed, indicating that E. coli biofilm robustness depends on surface charge property of the substratum. This suggests that substratum surface fabrication by RIGP may enhance or suppress biofilm formation, a finding with potentially important practical implications.     

Molecular characterization of a plant mitochondrial chaperone GrpE

Escherichia coli DnaK (Hsp70) cooperates with DnaJ and GrpE in its essential role as a molecular chaperone. Function of mitochondrial Hsp70 (mHsp70) in protein folding and organellar import in eukaryotes is critically dependent on GrpE. We cloned two genes from tobacco (Nicotiana tabacum) BY2 cells based on peptide sequences from a purified protein. The predicted amino acid sequences of both clones resembled that of GrpE from E. coli and its homologues from eukaryotes, and a cDNA clone from Arabidopsis thaliana. One gene (Type 1) encoded a deduced protein that was identical to the purified protein while the other (Type 2) encoded a deduced protein that has 80% sequence identity to Type 1. Both tobacco and Arabidopsis thaliana GrpE homologues bound to DnaK and ATP inhibited this binding. The tobacco GrpE homologue contained a typical N-terminal mitochondrial target presequence of 64 residues and the presequence directed the green fluorescent protein to tobacco mitochondria. The tobacco GrpE homologue also associated with mHsp70 when reintroduced into BY2 protoplasts, and this association was disrupted by ATP. A three-dimensional structure for the tobacco GrpE homologue was modeled based on the X-ray structure of E. coli GrpE complexed with DnaK. The modeled structure has the same overall structure as E. coli GrpE. We propose that the tobacco GrpE homologue interacts with mHsp70 in a manner analogous to E. coli GrpE with DnaK and designate it as tobacco mitochondrial GrpE (NtmGrpE).     

Structural and immunochemical relationship between the O-antigenic polysaccharides from the enteroaggregative Escherichia coli strain 396/C-1 and Escherichia coli O126

The structure of the O-antigen polysaccharide (PS) from the enteroaggregative Escherichia coli strain 396/C-1 has been determined. Sugar and methylation analyses together with 1H and 13C NMR spectroscopy were the main methods used. Inter-residue correlations were determined by 1H,1H-NOESY, 1H,13C-heteronuclear multiple-bond correlation and dipole-dipole cross-correlated relaxation experiments. The PS is composed of pentasaccharide repeating units with the following structure: [structure: see text]. Analysis of NMR data reveals that on average the PS consists of approximately 13 repeating units and indicates that the biological repeating unit contains an N-acetylglucosamine residue at its reducing end. This structure is different to that reported for the O-antigen polysaccharide from E. coli O126. Monospecific anti-E. coli O126 rabbit serum from The International Escherichia and Klebsiella Centre did not distinguish between the E. coli strain 396/C-1 and the E. coli O126 reference strain, neither in slide agglutination nor in an indirect enzyme immunoassay. Subsequent successful serotyping of the E. coli strain 396/C-1 showed it to be E. coli O126:K+:H27.     

Structural, thermodynamic, and mutational analyses of a psychrotrophic RNase HI

Ribonuclease (RNase) HI from the psychrotrophic bacterium Shewanella oneidensis MR-1 was overproduced in Escherichia coli, purified, and structurally and biochemically characterized. The amino acid sequence of MR-1 RNase HI is 67% identical to that of E. coli RNase HI. The crystal structure of MR-1 RNase HI determined at 2.0 A resolution was highly similar to that of E. coli RNase HI, except that the number of intramolecular ion pairs and the fraction of polar surface area of MR-1 RNase HI were reduced compared to those of E. coli RNase HI. The enzymatic properties of MR-1 RNase HI were similar to those of E. coli RNase HI. However, MR-1 RNase HI was much less stable than E. coli RNase HI. The stability of MR-1 RNase HI against heat inactivation was lower than that of E. coli RNase HI by 19 degrees C. The conformational stability of MR-1 RNase HI was thermodynamically analyzed by monitoring the CD values at 220 nm. MR-1 RNase HI was less stable than E. coli RNase HI by 22.4 degrees C in Tm and 12.5 kJ/mol in DeltaG(H2O). The thermodynamic stability curve of MR-1 RNase HI was characterized by a downward shift and increased curvature, which results in an increased DeltaCp value, compared to that of E. coli RNase HI. Site-directed mutagenesis studies suggest that the difference in the number of intramolecular ion pairs partly accounts for the difference in stability between MR-1 and E. coli RNases HI.     

Sequential aldol condensation catalyzed by hyperthermophilic 2-deoxy-d-ribose-5-phosphate aldolase

Genes encoding 2-deoxy-d-ribose-5-phosphate aldolase (DERA) homologues from two hyperthermophiles, the archaeon Pyrobaculum aerophilum and the bacterium Thermotoga maritima, were expressed individually in Escherichia coli, after which the structures and activities of the enzymes produced were characterized and compared with those of E. coli DERA. To our surprise, the two hyperthermophilic DERAs showed much greater catalysis of sequential aldol condensation using three acetaldehydes as substrates than the E. coli enzyme, even at a low temperature (25 degrees C), although both enzymes showed much less 2-deoxy-d-ribose-5-phosphate synthetic activity. Both the enzymes were highly resistant to high concentrations of acetaldehyde and retained about 50% of their initial activities after a 20-h exposure to 300 mM acetaldehyde at 25 degrees C, whereas the E. coli DERA was almost completely inactivated after a 2-h exposure under the same conditions. The structure of the P. aerophilum DERA was determined by X-ray crystallography to a resolution of 2.0 A. The main chain coordinate of the P. aerophilum enzyme monomer was quite similar to those of the T. maritima and E. coli enzymes, whose crystal structures have already been solved. However, the quaternary structure of the hyperthermophilic enzymes was totally different from that of the E. coli DERA. The areas of the subunit-subunit interface in the dimer of the hyperthermophilic enzymes are much larger than that of the E. coli enzyme. This promotes the formation of the unique dimeric structure and strengthens the hydrophobic intersubunit interactions. These structural features are considered responsible for the extremely high stability of the hyperthermophilic DERAs.     

大肠杆菌O138 O-抗原基因簇的破译及Gne的生物信息学鉴定

利用鸟枪法对大肠杆菌E .coliO138O 抗原基因簇进行测序 ,序列全长 14 139bp ,用生物信息学的方法进行序列分析 ,共发现 11个基因 ,分别为鼠李糖合成酶基因 (rmlB ,rmlD ,rmlA ,rmlC)、UDP GalNAcA合成酶基因 (gne ,gna)、糖基转移酶基因 (3个 )、O 抗原转运酶基因 (wzx)和O 抗原聚合酶基因 (wzy)。发现一种稀有单糖UDP Gal NAcA的合成途径 ,对合成该糖的第一种酶Gne进行了生物信息学鉴定 ,另外用PCR方法筛选出了针对大肠杆菌O138的特异基因     

Study of the lipopolysaccharide from a thermosensitive mutant CR-34 T 83 of Escherichia coli K 12]

The structure of the core of the lipopolysaccharide from T 83 mutant of Escherichia coli K 12 CR 34 was partially determined. Using dephosphorylation, enzymic hydrolysis, Smith degradation, methylations and analysis by gas chromatography/mass spectrometry an oligosaccharide sequence was determined with D-glucose, D-galactose and L-glycero-D-mannoheptose as sugar components. The structure which was demonstrated could be that of the characteristic core fragment of the K 12 type lipopolysaccharides from Escherichia coli.     

Translational features of human alpha 2b interferon production in Escherichia coli

The yield of human alpha 2b interferon in Escherichia coli was optimized by replacement of low-usage arginine codons located in the mRNA 5' end. The differences observed among the various gene variants suggest that codon usage, Shine-Dalgarno-like sequences, and mRNA secondary structure contribute to the performance of E. coli translation machinery.