Nucleotide sequence and analysis of the Vibrio alginolyticus sucrase gene (scrB)

The nucleotide sequence of a 2.119-kb DNA fragment containing the Vibrio alginolyticus sucrase gene (scrB) was determined. The complete sequence (484 aa residues) of the sucrase was deduced and homology was detected between the sucrase enzymes from V. alginolyticus and the Gram-positive bacteria Bacillus subtilis and Streptococcus mutans. In Escherichia coli cells the cloned V. alginolyticus sucrase is translocated to the periplasm. Transposon phoA mutagenesis experiments strongly suggested that V. alginolyticus sucrase in E. coli is not exported across the cytoplasmic membrane by means of a typical signal sequence.     

Molecular analysis of sucrose metabolism of Erwinia amylovora and influence on bacterial virulence

Sucrose is an important storage and transport sugar of plants and an energy source for many phytopathogenic bacteria. To analyze regulation and biochemistry of sucrose metabolism of the fire blight pathogen Erwinia amylovora, a chromosomal fragment which enabled Escherichia coli to utilize sucrose as sole carbon source was cloned. By transposon mutagenesis, the scr regulon of E. amylovora was tagged, and its nucleotide sequence was determined. Five open reading frames, with the genes scrK, scrY, scrA, scrB, and scrR, had high homology to genes of the scr regulons from Klebsiella pneumoniae and plasmid pUR400. scrB and scrR of E. amylovora were fused to a histidine tag and to the maltose-binding protein (MalE) of E. coli, respectively. ScrB (53 kDa) catalyzed the hydrolysis of sucrose with a K(m) of 125 mM. Binding of a MalE-ScrR fusion protein to an scrYAB promoter fragment was shown by gel mobility shifts. This complex dissociated in the presence of fructose but not after addition of sucrose. Expression of the scr regulon was studied with an scrYAB promoter-green fluorescent protein gene fusion and measured by flow cytometry and spectrofluorometry. The operon was affected by catabolite repression and induced by sucrose or fructose. The level of gene induction correlated to the sucrose concentration in plant tissue, as shown by flow cytometry. Sucrose mutants created by site-directed mutagenesis did not produce significant fire blight symptoms on apple seedlings, indicating the importance of sucrose metabolism for colonization of host plants by E. amylovora.     

文山松毛虫质型多角体病毒S8片段cDNA克隆与原核表达

文山松毛虫质型多角体病毒(DpwCPV)S8片段被克隆和测序,该片段全长1332bp,编码390个氨基酸组成的分子量大约为43kDa的蛋白P44。根据本实验室测定出的马尾松毛虫质型多角体病毒(DpCPV)基因组全序列,设计引物,扩增出文山松毛虫质型多角体病毒s8部分片段,并亚克隆出p44基因序列,然后将p44基因序列cDNA克隆到表达载体pET-28a中,构建成表达质粒pET-S8,用IPTG诱导大肠杆菌BL21,经SDS-PAGE证明p44基因在大肠杆菌中获得成功表达,并对其编码蛋白序列进行了分析。     

Cloning and sequencing of the sacA gene: characterization of a sucrase from Zymomonas mobilis.

The Zymomonas mobilis gene (sacA) encoding a protein with sucrase activity has been cloned in Escherichia coli and its nucleotide sequence has been determined. Potential ribosome-binding site and promoter sequences were identified in the region upstream of the gene which were homologous to E. coli and Z. mobilis consensus sequences. Extracts from E. coli cells, containing the sacA gene, displayed a sucrose-hydrolyzing activity. However, no transfructosylation activity (exchange reaction or levan formation) could be detected. This sucrase activity was different from that observed with the purified extracellular protein B46 from Z. mobilis. These two proteins showed different electrophoretic mobilities and molecular masses and shared no immunological similarity. Thus, the product of sacA (a polypeptide of 58.4-kDa molecular mass) is a new sucrase from Z. mobilis. The amino acid sequence, deduced from the nucleotide sequence of sacA, showed strong homologies with the sucrases from Bacillus subtilis, Salmonella typhimurium, and Vibrio alginolyticus.     

Molecular structure of the locus for sucrose utilization by Lactobacillus plantarum: comparison with Pediococcus pentosaceus

Structure of the sucrose utilization locus in a Lactobacillus plantarum type strain was studied using PCR and Southern hybridization. Restriction map analysis revealed its high similarity to the sequenced sucrose utilization locus of Pediococcus pentosaceus pSRQ1. The L. plantarum locus proved containing oppositely oriented scrA and the scrBRagl operon, but not agaS. The L. plantarum sucrase gene (scrB) was partly sequenced. A higher (98.6%) homology was revealed between scrB than between the 16S rRNA genes of L. plantarum and P. pentosaceus, suggesting horizontal transfer of the sucrose utilization locus between the genera of lactic acid bacteria. Amino acid sequence analysis showed that the ScrB proteins of the two species belong to a subfamily of glycosyl hydrolase family GH32 which includes various beta-fructosidases.     

Purification, cloning, and DNA sequence analysis of a chitinase from an overproducing mutant of Streptomyces peucetius defective in daunorubicin biosynthesis

Extracellular chitinases of Streptomyces peucetius and a chitinase overproducing mutant, SPVI, were purified to homogeneity by ion exchange and gel filtration chromatography. The purified enzyme has a molecular mass of 42 kDa on SDS-PAGE, and the N-terminal amino acid sequence of the protein from the wild type showed homology to catalytic domains (Domain IV) of several other Streptomyces chitinases such as S. lividans 66, S. coelicolor A3(2), S. plicatus, and S. thermoviolaceus OPC-520. Purified SPVI chitinase cross-reacted to anti-chitinase antibodies of wild-type S. peucetius chitinase. A genomic library of SPVI constructed in E. coli using lambda DASH II was probed with chiC of S. lividans 66 to screen for the chitinase gene. A 2.7 kb fragment containing the chitinase gene was subcloned from a lambda DASH II clone, and sequenced. The deduced protein had a molecular mass of 68 kDa, and showed domain organization similar to that of S. lividans 66 chiC. The N-terminal amino acid sequence of the purified S. peucetius chitinase matched with the N-terminus of the catalytic domain, indicating the proteolytic processing of 68 kDa chitinase precursor protein to 42 kDa mature chitinase containing the catalytic domain only. A putative chiR sequence of a two-component regulatory system was found upstream of the chiC sequence.     

Isolation of DNA encoding sucrase genes from Streptococcus salivarius and partial characterization of the enzymes expressed in Escherichia coli.

Restriction enzyme fragments containing two sucrase genes have been isolated from a cosmid library of Streptococcus salivarius DNA. The genes were expressed in Escherichia coli cells, and the properties of both enzymes were studied in partially purified protein extracts from E. coli. One gene encoding an invertase-type sucrase was subcloned on a 2.4-kilobase-pair fragment. The sucrase enzyme had a Km for sucrose of 48 mM and a pH optimum of 6.5. The S. salivarius sucrase clone showed no detectable hybridization to a yeast invertase clone. Two overlapping subclones which had 1 kilobase pair of DNA in common were used to localize a fructosyltransferase gene. The fructosyltransferase had a Km of 93 mM and a pH optimum of 7.0. The product of the fructosyltransferase was a levan. A fructosyltransferase clone from Bacillus subtilis did not hybridize to S. salivarius DNA. The properties of the enzymes were compared with those of previously characterized sucrases.     

Expression and regulation of a Vibrio alginolyticus sucrose utilization system cloned in Escherichia coli.

A halotolerant collagenolytic Vibrio alginolyticus strain isolated from salted hides had intracellular sucrase activity and did not secret sucrase into the medium. The strain actively transported sucrose by a sucrose-inducible, Na+-independent process. A 10.4-kilobase DNA fragment of V. alginolyticus DNA was cloned into Escherichia coli. The recombinant E. coli(pVS100) could utilize sucrose as a sole carbon source. In contrast to V. alginolyticus, the recombinant E. coli produced both intra- and extracellular sucrase activities. Up to 20% of the total sucrase activity was in the supernatant. Sucrase synthesis in E. coli(pVS100) was inducible and was subject to glucose repression, which was relieved by cyclic AMP. Sucrose was actively transported by a sucrose-inducible, Na+-independent system in E. coli(pVS100). Sucrose uptake was inhibited by the addition of a proton conductor. The maximum velocity and apparent Km values of sucrose uptake for the V. alginolyticus strain and E. coli(pVS100) were 130 nmol/mg of protein per min and 50 microM and 6 nmol/mg of protein per min and 275 microM, respectively.     

Murein-metabolizing enzymes from Escherichia coli: existence of a second lytic transglycosylase.

In addition to the soluble lytic transglycosylase, a murein-metabolizing enzyme with a molecular mass of 70 kDa (Slt70), Escherichia coli possesses a second lytic transglycosylase, which has been described as a membrane-bound lytic transglycosylase (Mlt; 35 kDa; EC 3.2.1.-). The mlt gene, which supposedly encodes Mlt, was cloned, and the complete nucleotide sequence was determined. The open reading frame, identified on a 1.7-kb SalI-PstI fragment, codes for a protein of 323 amino acids (M(r) = 37,410). Two transmembrane helices and one membrane-associated helix were predicted in the N-terminal half of the protein. Lysine and arginine residues represent up to 15% of the amino acids, resulting in a calculated isoelectric point of 10.0. The deduced primary structure did not show significant sequence similarity to Slt70 from E. coli. High-level expression of the presumed mlt gene was not paralleled by an increase in murein hydrolase activity. To clarify the identity of the second transglycosylase, we purified an enzyme with the specificity of a transglycosylase from an E. coli slt deletion strain. The completely soluble transglycosylase, with a molecular mass of approximately 35 kDa, was designated Slt35. Its determined 26 N-terminal amino acids showed similarity to a segment in the middle of the Slt70 primary structure. Polyclonal anti-Mlt antibodies, which had been used for the isolation of the mlt gene, were found to cross-react with Mlt as well as with Slt35, suggesting that the previously described Mlt preparation was contaminated with Slt35. We conclude that the second transglycosylase of E. coli is not a membrane-bound protein but rather is a soluble protein.     

The intracellular sucrase (SacA) of Zymomonas mobilis is not involved in sucrose assimilation

The intracellular sucrase SacA from Zymomonas mobilis was purified to homogeneity from a recombinant E. coli strain containing the SacA gene under an expression system. The protein was monomeric with a molecular mass of 58 kDa. The sucrase activity was maximal at 25 °C and thermal stability of the purified protein was low (50% recovery after 30 min at 46 °C ). The activation energy was low at 33 kJ mol^–1. Maximum activity was at pH 6.5. Activity was strongly inhibited (>99%) by SH blocking reagents and reducing agents slightly (10–60%) increased the activity of purified SacA. The sucrase showed a low K _M (42 mM) and k _cat (125 s^–1) which indicated its very low efficiency for sucrose hydrolysis. A mutant strain of Z. mobilis not able to grow on sucrose was isolated. This strain (ZM4S) lacked the two sucrases SacB and SacC but SacA was present in the intracellular fraction. Therefore, SacA alone is unable to allow growth Z. mobilis on sucrose.     

Cloning of the argF gene encoding the ornithine carbamoyltransferase from Corynebacterium glutamicum.

The argF gene encoding ornithine carbamoyl-transferase (OTCase; EC2.1.3.3) has been cloned from Corynebacterium glutamicum by transforming the Escherichia coli arginine auxotroph with the genomic DNA library. The cloned DNA also complements the E. coli argG mutant, suggesting a clustered organization of the genes in the genome. We have determined the DNA sequence of the minimal fragment complementing the E. coli argF mutant. The coding region of the cloned gene is 957 nucleotides long with a deduced molecular mass of about 35 kDa polypeptide. The enzyme activity and size of the expressed protein in the E. coli auxotroph carrying the argF gene revealed that the cloned gene indeed codes for OTCase. Analysis of the amino acid sequence of the predicted protein revealed a strong similarity to the corresponding protein of other bacteria.     

Deletion analysis of sucrose metabolic genes from a Salmonella plasmid cloned in Escherichia coli K12

The sucrose operon from pUR400, a 78-kbp conjugative Salmonella plasmid, was cloned in Escherichia coli K12. The operon was located in a 5.7-kbp SalI restriction fragment and was subcloned, in each of two possible orientations, using the expression vector pUC18. The insert DNA was restriction mapped and duplicate restriction sites in the insert and in the polylinker of the vector were used to create various deletions promoter distal in the operon sequence. Additional deletions were made with the restriction exonuclease Bal31. Cells containing hybrid plasmids with specified deletions lacked the ability to transport sucrose or were constitutive for hydrolase and/or uptake activities. The scrA (enzyme IIScr) and scrR (regulatory) genes resided within 2900-bp SmaI-SalI DNA fragment and were assigned the order scrB, scrA, scrR. An amplified sucrose-inducible gene product, Mr 68,000, was detected only in the membrane fraction from recombinant cells that contained plasmid with the intact operon sequence. This protein represented 11% of the total membrane protein and was resistant to extraction with 0.5 M sodium chloride, 2% Triton X-100, and 0.5% sodium deoxycholate. The protein did not appear to be the product of either the scrA, scrB, or scrR gene and may therefore represent a previously unidentified membrane-bound sucrose protein. A new gene, scrC, is proposed. In addition, the cloned 5.7-kbp SalI and 2.5-kbp SmaI-SalI DNA fragments failed to hybridize to chromosomal DNA from Bacillus subtilis, Streptococcus lactis, Streptococcus mutans, and Lactobacillus acidophilus as well as to DNA from a sucrose plasmid from Salmonella tennessee. However, the probes showed weak homology with a 20-kbp EcoRI restriction fragment from Klebsiella pneumoniae.     

Analysis of signals for secretion in the staphylococcal protein A gene.

Different constructs of the gene encoding staphylococcal protein A were introduced in Staphylococcus aureus and S. xylosus as well as Escherichia coli. The product of the gene without the cell wall anchoring domain was efficiently secreted in all three hosts. N-terminal sequencing of the affinity-purified mature protein revealed a common processing site after the alanine residue at position 36. In contrast, when an internal IgG-binding fragment of protein A (region B) was inserted after the protein A signal sequence, the product was poorly secreted and N-terminal sequencing revealed no processing at the normal site. This demonstrates that the structure of the polypeptide chain beyond the signal peptide cleavage site can affect cleavage. Another construct, containing the N-terminal IgG-binding part of the mature protein A (region E) followed by region B, gave correct processing and efficient secretion. Unexpectedly, the gene product, EB, was not only secreted and correctly processed, but was also excreted to the culture medium of E. coli. Secretion vectors containing the protein A signal sequence were constructed to facilitate secretion of foreign gene products. Insertion of the E. coli gene phoA, lacking its own promoter and signal sequence, led to efficient secretion of alkaline phosphatase both in E. coli and S. aureus.     

Cloning and characterization of a Schistosoma mansoni 1H and 30S clones as two tegumental vaccine candidate antigens

Two Schistosoma mansoni cDNA clones 30S and 1H were identified by immunoscreening of sporocyst lambdagt11 library and by random sequencing of clones from lambdaZap libraries, respectively. Clone 30S was one of 30 clones identified by an antibody raised against tegument of 3-h schistosomules. The clone was found to encode an 81 amino-acid protein fragment. It was expressed in Escherichia coli as a fusion protein of calculated molecular mass of about 35 kDa with C-terminus of Schistosoma japonicum glutathione-S-transferase (Sj26; about 26 kDa). The recombinant fusion protein was specifically recognized by serum of rabbits immunized with irradiated cercariae. Clone 1H is one of 76 expressed sequence tags derived from an adult worm library. It encodes the complete sequence of a tegumental membrane protein, Sm13. The 104 amino-acid open reading frame encodes a protein with a calculated molecular mass of about 11.9 kDa. Clone 1H was expressed in E. coli as an insoluble fusion protein with Sj26 of about 40 kDa. In Western blots, the fusion protein was recognized by serum from rabbits vaccinated with irradiated cercariae but not by preimmune rabbit sera. The cloning, characterization and expression of those proteins are therefore potentially usefull for vaccine development.     

Characteristic of saccharose fermentation by pathogenic Escherichia coli strains--phenotypic and genotypic elements

The purpose of the study was to characterize fermentation of sucrose by Escherichia coli strains and to answer why some of these strains doesn't utilize this disaccharide. Investigations included 16 E. coli strains. Only 5 of these strains utilized sucrose. Genotypic analysis demonstrated the presence of cscB gene (encoding the sucrase permease which catalyzes transport of sucrose through the plasma membrane of the cell) in 5 strains of E. coli and cscA gene (encoding an enzyme sucrase that catalyzes the utilization of sucrose) in 6 strains of E. coli. These 5 of E. coli strains which possessed a chromosomally encoded sucrose metabolic pathway utilized sucrose with a different time. 3 of them destroyed this disaccharide after 24 h and 2 of them destroyed it after 48 h. Ten of E. coli strains hadn't cscA gene and 11 of them had not cscB genes. The lack of these genes can be the prove that it is not possible for 11 of E. coli strains to synthesize sucrose permease and for 10 of them to synthesize sucrase and it may be the reason of not utilize disaccharide sucrose by these bacteria.