Nucleotide sequence of AMS1, the structure gene of vacuolar alpha-mannosidase of Saccharomyces cerevisiae

AMS1, a structure gene of the vacuolar membrane alpha-mannosidase of Saccharomyces cerevisiae, has been characterized and found to encode both constituent polypeptides of the enzyme, a 107 kDa polypeptide and a 73 kDa polypeptide. The nucleotide sequence of AMS1 demonstrates that the gene encodes 1083 amino acids with a molecular weight 124,497. Although the enzyme is considered to exist on the inner surface of the vacuolar membrane, the predicted primary amino acid sequence does not have a hydrophobic stretch suitable for a signal sequence in its N-terminal region.     

DNA sequence of the gene (tyrP) encoding the tyrosine-specific transport system of Escherichia coli.

The nucleotide sequence of 1,947 bases of DNA containing the tyrP structural gene was determined, and an open reading frame of 1,260 nucleotides was identified. The putative structural gene encodes an extremely hydrophobic protein which comprises 404 amino acids, 70% of which are nonpolar, and which has a molecular weight of 43,261.     

Sequence and expression of the Escherichia coli K1 neuC gene product.

The nucleotide sequence of the neuC gene of the Escherichia coli K1 capsule gene cluster encodes a protein with a predicted molecular weight of 44,210 containing 391 amino acids. A chimeric protein with beta-galactosidase fused to the carboxy terminus of the neuC gene product (P7) was constructed and purified. Its amino-terminal sequence confirmed the prediction from the nucleotide sequence that the neuC gene overlaps the distal end of the neuA gene by a single base pair. Both the neuA and neuC genes are coexpressed under the control of a single upstream T7 or tac promoter, suggesting that neuA and neuC are part of an operon.     

Genetic analysis of potassium transport loci in Escherichia coli: evidence for three constitutive systems mediating uptake potassium.

The analysis of mutants of Escherichia coli that require elevated concentrations of K+ for growth has revealed two new genes, trkG, near minute 30 within the cryptic rac prophage, and trkH, near minute 87, the products of which affect constitutive K+ transport. The analysis of these and other trk mutations suggests that high rates of transport, previously considered to represent the activity of a single system, named TrkA, appear to be the sum of two systems, here named TrkG and TrkH. Each of these two is absolutely dependent on the product of the trkA gene, a cytoplasmic protein associated with the inner membrane (D. Bossemeyer, A. Borchard, D. C. Dosch, G. C. Helmer, W. Epstein, I. R. Booth, and E. P. Bakker, J. Biol. Chem. 264:16403-16410, 1989). The TrkH system is also dependent on the products of the trkH and trkE genes, while the TrkG system is also dependent on the product of the trkG gene and partially dependent on the product of the trkE gene. It is suggested that the trkH and trkG products are membrane proteins that form the transmembrane path for the K+ movement of the respective systems. Two mutations altering the trkA product reduce the affinity for K+ of both TrkG and TrkH, indicating that changes in peripheral protein can alter the conformation of the sites at which K+ is bound prior to transport. The TrkD system has a relatively modest rate of transport, is dependent solely on the product of the trkD gene, and is the sole saturable system for Cs+ uptake in this species (D. Bossemeyer, A. Schl?sser, and E. P. Bakker, J. Bacteriol. 171:2219-2221, 1989).     

Nucleotide sequences of the fecBCDE genes and locations of the proteins suggest a periplasmic-binding-protein-dependent transport mechanism for iron(III) dicitrate in Escherichia coli.

The fec region of the Escherichia coli chromosome determines a citrate-dependent iron(III) transport system. The nucleotide sequence of fec revealed five genes, fecABCDE, which are transcribed from fecA to fecE. The fecA gene encodes a previously described outer membrane receptor protein. The fecB gene product is formed as a precursor protein with a signal peptide of 21 amino acids; the mature form, with a molecular weight of 30,815, was previously found in the periplasm. The fecB genes of E. coli B and E. coli K-12 differed in 3 nucleotides, of which 2 gave rise to conservative amino acid exchanges. The fecC and fecD genes were found to encode very hydrophobic polypeptides with molecular weights of 35,367 and 34,148, respectively, both of which are localized in the cytoplasmic membrane. The fecE product was a rather hydrophilic but cytoplasmic membrane-bound protein of Mr 28,189 and contained regions of extensive homology to ATP-binding proteins. The number, structural characteristics, and locations of the FecBCDE proteins were typical for a periplasmic-binding-protein-dependent transport system. It is proposed that after FecA- and TonB-dependent transport of iron(III) dicitrate across the outer membrane, uptake through the cytoplasmic membrane follows the binding-protein-dependent transport mechanism. FecC and FecD exhibited homologies to each other, to the N- and C-terminal halves of FhuB of the iron(III) hydroxamate transport system, and to BtuC of the vitamin B12 transport system. FecB showed some homology to FhuD, suggesting that the latter may function in the same manner as a binding protein in iron(III) hydroxamate transport. The close homology between the proteins of the two iron transport systems and of the vitamin B12 transport system indicates a common evolution for all three systems.     

Mannitol-specific enzyme II of the bacterial phosphotransferase system. III. The nucleotide sequence of the permease gene

The nucleotide sequence of the mtlA gene, which codes for the mannitol-specific Enzyme II of the Escherichia coli phosphotransferase system, is presented. From the gene sequence, the primary translation product is predicted to consist of 637 amino acids (Mr = 67,893). This result is compared to the amino acid composition and molecular weight of the purified mannitol Enzyme II protein. The hydrophobic and hydrophilic properties of the enzyme were evaluated along its amino acid sequence using a computer program (Kyte, J., and Doolittle, R. F. (1982) J. Mol. Biol. 157, 105-132). The computer analysis predicts that the NH2-terminal half of the enzyme resides within the membrane, whereas the COOH-terminal half of the enzyme has the properties of a soluble protein. The possible functions of such a protein structure are discussed. RNA mapping has identified the promoter and mRNA start point for the mtl operon.     

Cloning and nucleotide sequence of the gene (citA) encoding a citrate carrier from Salmonella typhimurium.

A cryptic citrate transport gene (citA) from Salmonella typhimurium chromosome was cloned and its nucleotide sequence was determined. The cloned plasmid conferred citrate-utilizing ability on wild-type Escherichia coli, which cannot grow on citrate as the sole source of carbon. The resultant E. coli transformant was able to transport citrate. A 1,302-base-pair open reading frame with a preceding ribosomal binding site was found in the cloned DNA fragment. The 434-amino-acid protein that could be translated from this open reading frame is highly hydrophobic (69% nonpolar amino acid residues), consistent with the fact that the transport protein is an intrinsic membrane protein. The molecular weight of this protein was calculated to be 47,188. The gene sequence determined is highly homologous to those of Cit+ plasmid-mediated citrate transport gene, citA, from E. coli, the chromosomal citA gene from Citrobacter amalonaticus and the chromosomal cit+ gene from Klebsiella pneumoniae. The hydropathy profile of the deduced amino acid sequence suggests that this carrier has 12 hydrophobic segments, which may span the membrane lipid bilayer.     

Cloning and nucleotide sequence of the aspartase gene of Escherichia coli W.

The aspA gene of Escherichia coli W which encodes aspartase was cloned into the plasmid vector pBR322. The nucleotide sequences of aspA and its flanking regions were determined. The aspA gene encodes a protein with a molecular weight of 52,224 consisted of 477 amino acid residues. The amino acid sequence of the protein predicted from the nucleotide sequence was consistent with those of the NH2- and COOH-terminal regions and also with the amino acid composition of the purified aspartase determined previously. Potential promoter and terminator sequences for aspA were also found in the determined sequence.     

The complete nucleotide sequence of the adenylate cyclase gene of Escherichia coli

The complete nucleotide sequence of the cya gene from E. coli was determined. The gene encodes a polypeptide consisting of 848 amino acid residues with a calculated molecular weight of 97,542. The deduced protein structure reveals that cyclase is comprised of two domains, an amino-terminal region exhibiting catalytic activity and a carboxy-terminal region possibly carrying regulatory function. The frequent appearance of rare codons in the beginning of the gene as well as the sequence duplication in the promoter-initiator region suggest possible regulation(s) at the translational level. An unknown gene (cyaX) which seems to code for a very hydrophobic protein was found following the cya gene. Sequence analysis suggests that the cyax is a part of the cya operon.     

Molecular cloning and sequencing of mcrA locus and identification of McrA protein inEscherichia coli

The Mcr systems (previously known as Rgl systems) ofEscherichia coli recognize and cleave specific sequences carrying methylated or hydroxymethylated cytosines. We have cloned the mcrA gene and determined its nucleotide sequence. An 831 base pair sequence encodes the McrA protein. Analysis of the sequence data reveals that there arc additional ORFs internal to the above. A phage T7 expression system was used to determine the protein products encoded by the cloned mcrA gene. The results clearly show that a 31 kDa polypeptide is responsible for McrA activity. This is in agreement with the molecular weight deduced from sequence data. McrA protein was found to be localized in the outer membrane ofEscherichia coli. To our knowledge this is the first restriction enzyme localized in the outer membraneof Escherichia coli. Presented in part at the Second New England Biolabs Workshop on Biological DNA Modification, September, 1990, Berlin     

Nucleotide sequence of the btuCED genes involved in vitamin B12 transport in Escherichia coli and homology with components of periplasmic-binding-protein-dependent transport systems.

The products of the btuCED region of the Escherichia coli chromosome participate in the transport of vitamin B12 across the cytoplasmic membrane. The nucleotide sequence of the 3,410-base-pair HindIII-HincII DNA fragment carrying a portion of the himA gene and the entire btuCED region was determined. Comparison of the location of the open reading frames with the gene boundaries defined by transposon insertions allowed the assignment of polypeptide products to gene sequences. The btuC product is a highly nonpolar integral membrane protein of molecular weight 31,683. The distribution of hydrophobic regions suggests the presence of numerous membrane-spanning domains. The btuD product is a relatively polar but membrane-associated polypeptide of Mr 27,088 and contains segments bearing extensive homology to the ATP-binding peripheral membrane constituents of periplasmic binding protein-dependent transport systems. Other regions of this protein are similar to portions of the outer membrane vitamin B12 receptor. The btuE product (Mr 20,474) appears to have a periplasmic location. It has the mean hydropathy of a soluble protein but lacks an obvious signal sequence. The cellular locations and structural and sequence homologies of the Btu polypeptides point to the similarity of these three proteins to components of binding protein-dependent transport systems. However, the dependence on a periplasmic vitamin B12-binding protein has not yet been demonstrated.     

Cloning and characterization of a Bacillus subtilis gene homologous to E. coli secY

A 3.5-kb HindIII DNA fragment containing the secY gene of Bacillus subtilis has been cloned into plasmid pUC13 using the Escherichia coli secY gene as a probe. The complete nucleotide sequence of the cloned DNA indicated that it contained five open reading frames, and their order in the region, given by the gene product, was suggested to be L30-L15-SecY-Adk-Map by their similarity to the products of the E. coli genes. The region was similar to a part of the spc operon of the E. coli chromosome, although the genes for Adk and Map were not included. The gene product of the B. subtilis secY homologue was composed of 423 amino acids and its molecular weight was calculated to be 46,300. The distribution of hydrophobic amino acids in the gene product suggested that the protein is a membrane integrated protein with ten transmembrane segments. The total deduced amino acid sequence of the B. subtilis SecY homologue shows 41.3% homology with that of E. coli SecY, but remarkably higher homologous regions (more than 80% identity) are present in the four cytoplasmic domains.     

Identification of the membrane component of the anion pump encoded by the arsenical resistance operon of R-factor R773

The arsenical resistance (ars) operon of the conjugative R-factor R773 encodes an ATP-driven anion extrusion pump, producing bacterial resistance to arsenicals. There are three structural genes, of which the product of the middle gene, arsB, has not previously been identified. From nucleotide sequence data, the ArsB protein is predicted to be a 45577 Dalton hydrophobic protein. A mini-Mu transposition procedure was used to construct an arsB-lacZ gene fusion, producing a hybrid ArsB-beta-galactosidase protein which was localized in the inner membrane. The operon was cloned into a T7 RNA polymerase expression vector. In addition to the previously identified ArsA and ArsC proteins, the cells synthesized an inner membrane protein with an apparent mass of 36 kD identified as the ArsB protein.     

TrkH and its homolog, TrkG, determine the specificity and kinetics of cation transport by the Trk system of Escherichia coli.

The corrected sequence of the trkH gene of Escherichia coli predicts that the TrkH protein is a hydrophobic membrane protein of 483 amino acid residues, of which 41% are identical to those of the homologous and functionally analogous TrkG protein. These two proteins form the transmembrane component of the Trk system for the uptake of K+. Each protein alone is sufficient for high-level Trk activity. When Trk is assembled with the TrkG protein, Rb+ and K+ are transported with a Km near or below 1 mM; however, the Vmax for Rb+ is only about 7% of that for K+. When Trk is formed with TrkH, the affinities for both for K+ and Rb+ are somewhat lower, and the Vmax for Rb+ is only 1% of that for K+ transport. The kinetics of transport in strains with wild-type alleles at trkG and at trkH suggest that both products participate in transport.