DcrA, a c-type heme-containing methyl-accepting protein from Desulfovibrio vulgaris Hildenborough, senses the oxygen concentration or redox potential of the environment.

The amino acid sequence of DcrA from Desulfovibrio vulgaris Hildenborough, a strictly anaerobic, sulfate-reducing bacterium, indicated homology with the methyl-accepting chemotaxis proteins from enteric bacteria (A. Dolla, R. Fu, M. J. Brumlik, and G. Voordouw, J. Bacteriol. 174:1726-1733, 1992). The homology is restricted to the cytoplasmic C-terminal signaling domain. The periplasmic N-terminal sensor domain was found to contain a unique sequence, CHHCH, corresponding to a consensus c-type heme binding site. A pretreated, DcrA-specific polyclonal antiserum, generated against DcrA protein overproduced in Escherichia coli, was used for immunoprecipitation of 35S-labeled DcrA from D. vulgaris and Desulfovibrio desulfuricans G200(pJRFR2), a transconjugant that overexpresses functional DcrA. Labeling of the latter with the heme precursor 5-amino-[4-14C]levulinic acid, followed by immunoprecipitation, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and fluorography, confirmed the presence of c-type heme, while labeling with L-[methyl-3H]methionine in the absence of protein synthesis confirmed that DcrA is a methyl-accepting protein. The base liability of the incorporated radioactivity indicated methyl ester formation like that occurring in the methyl-accepting chemotaxis proteins of enteric bacteria. L-[methyl-3H]methionine labeling of D. desulfuricans G200(pJRFR2) under different conditions indicated that methyl labeling of DcrA decreased upon addition of oxygen and increased upon subsequent addition of the reducing agent dithionite. These results indicate that DcrA may serve as a sensor of oxygen concentration and/or redox potential.     

Membrane topology of the methyl-accepting chemotaxis protein DcrA fromDesulfovibrio vulgaris Hildenborough

Alkaline phosphatase fusions were used to study the membrane topology of DcrA, a protein of 668 amino acids fromDesulfovibrio vulgaris Hildenborough, which has two potentially membrane-spanning hydrophobic sequences at residues 11 to 29 and 188 to 207. A fusion at amino acid residue 170 in the proposed periplasmic domain exhibited high alkaline phosphatase activity, while low activity was observed for a fusion at amino acid residue 284 in the proposed cytoplasmic domain. The data support a topological model for DcrA similar to that of the methyl-accepting chemotaxis proteins of the enteric bacteria.     

Unique precursor structure of an extracellular protease, aqualysin I, with NH2- and COOH-terminal pro-sequences and its processing in Escherichia coli

Aqualysin I is a subtilisin-type serine protease which is secreted into the culture medium by Thermus aquaticus YT-1, an extremely thermophilic Gram-negative bacterium. The nucleotide sequence of the entire gene for aqualysin I was determined, and the deduced amino acid sequence suggests that aqualysin I is produced as a large precursor, consisting of at least three portions, an NH2-terminal pre-pro-sequence (127 amino acid residues), the protease (281 residues), and a COOH-terminal pro-sequence (105 residues). When the cloned gene was expressed in Escherichia coli cells, aqualysin I was not secreted. However, a precursor of aqualysin I lacking the NH2-terminal pre-pro-sequence (38-kDa protein) accumulated in the membrane fraction. On treatment of the membrane fraction at 65 degrees C, enzymatically active aqualysin I (28-kDa protein) was produced in the soluble fraction. When the active site Ser residue was replaced with Ala, cells expressing the mutant gene accumulated a 48-kDa protein in the outer membrane fraction. The 48-kDa protein lacked the NH2-terminal 14 amino acid residues of the precursor, and heat treatment did not cause any subsequent processing of this precursor. These results indicate that the NH2-terminal signal sequence is cleaved off by a signal peptidase of E. coli, and that the NH2- and COOH-terminal pro-sequences are removed through the proteolytic activity of aqualysin I itself, in that order. These findings indicate a unique four-domain structure for the aqualysin I precursor; the signal sequence, the NH2-terminal pro-sequence, mature aqualysin I, and the COOH-terminal pro-sequence, from the NH2 to the COOH terminus.     

Single-stranded DNA binding proteins (SSBs) from prokaryotic transmissible plasmids

The DNA and protein sequences of single-stranded DNA binding proteins (SSBs) encoded by the plP71a, plP231a, and R64 conjugative plasmids have been determined and compared to Escherichia coli SSB and the SSB encoded by F-plasmid. Although the amino acid sequences of all of these proteins are highly conserved within the NH2-terminal two-thirds of the protein, they diverge in the COOH-terminal third region. A number of amino acid residues which have previously been implicated as being either directly or indirectly involved in DNA binding are conserved in all of these SSBs. These residues include Trp-40, Trp-54, Trp-88, His-55, and Phe-60. On the basis of these sequence comparisons and DNA binding studies, a role for Tyr-70 in DNA binding is suggested for the first time. Although the COOH-terminal third of these proteins diverges more than their NH2-terminal regions, the COOH-terminal five amino acid residues of all five of these proteins are identical. In addition, all of these proteins share the characteristic property of having a protease resistant, NH2-terminal core and an acidic COOH-terminal region. Despite the high degree of sequence homology among the plasmid SSB proteins, the F-plasmid SSB appears unique in that it was the only SSB tested that neither bound well to poly(dA) nor was able to stimulate DNA polymerase III holoenzyme elongation rates. Poly [d(A-T)] melting studies suggest that at least three of the plasmid encoded SSBs are better helix-destabilizing proteins than is the E. coli SSB protein.     

Primary structure of T4 DNA polymerase. Evolutionary relatedness to eucaryotic and other procaryotic DNA polymerases

Bacteriophage T4 gene 43 codes for the viral DNA polymerase. We report here the sequence of gene 43 and about 70 nucleotides of 5'- and 3'-flanking sequences, determined by both DNA and RNA sequencing. We have also purified T4 DNA polymerase from T4 infected Escherichia coli and from E. coli containing a gene 43 overexpression vector. A major portion of the deduced amino acid sequence has been verified by peptide mapping and sequencing of the purified DNA polymerase. All these results are consistent with T4 DNA polymerase having 898 amino acids with a calculated Mr = 103,572. Comparison of the primary structure of T4 DNA polymerase with the sequence of other procaryotic and eucaryotic DNA polymerases indicates that T4 DNA polymerase has regions of striking similarity with animal virus DNA polymerases and human DNA polymerase alpha. Surprisingly, T4 DNA polymerase shares only limited similarity with E. coli polymerase I and no detectable similarity with T7 DNA polymerase. Based on the location of specific mutations in T4 DNA polymerase and the conservation of particular sequences in T4 and eucaryotic DNA polymerases, we propose that the NH2-terminal half of T4 DNA polymerase forms a domain that carries out the 3'----5' exonuclease activity whereas the COOH-terminal half of the polypeptide contains the dNTP-binding site and is necessary for DNA synthesis.     

Genetic control of the resistance to phage C1 of Escherichia coli K-12.

Escherichia coli K-12 lytic phage C1 was earlier isolated in our laboratory. Its adsorption is controlled by at least three bacterial genes: dcrA, dcrB, and btuB. Our results provide evidence that the dcrA gene located at 60 min on the E. coli genetic map is identical to the sdaC gene. This gene product is an inner membrane protein recently identified as a putative specific serine transporter. The dcrB gene, located at 76.5 min, encodes a 20-kDa processed periplasmic protein, as determined by maxicell analysis, and corresponds to a recently determined open reading frame with a previously unknown function. The btuB gene product is known to be an outer membrane receptor protein responsible for adsorption of BF23 phage and vitamin B12 uptake. According to our data the DcrA and DcrB proteins are not involved in these processes. However, the DcrA protein probably participates in some cell division steps.     

Mammalian heterogeneous nuclear ribonucleoprotein complex protein A1. Large-scale overproduction in Escherichia coli and cooperative binding to single-stranded nucleic acids

Characterization of mammalian heterogeneous nuclear ribonucleoprotein complex protein A1 is reported after large-scale overproduction of the protein in Escherichia coli and purification to homogeneity. A1 is a single-stranded nucleic acid binding protein of 320 amino acids and 34,214 Da. The protein has two domains. The NH2-terminal domain is globular, whereas the COOH-terminal domain of about 120 amino acids has low probability of alpha-helix structure and is glycinerich. Nucleic acid binding properties of recombinant A1 were compared with those of recombinant and natural proteins corresponding to the NH2-terminal domain. A1 bound to single-stranded DNA-cellulose with higher affinity than the NH2-terminal domain peptides. Protein-induced fluorescence enhancement was used to measure equilibrium binding properties of the proteins. A1 binding to poly (ethenoadenylate) was cooperative with the intrinsic association constant of 1.5 X 10(5) M-1 at 0.4 M NaCl and a cooperativity parameter of 30. The NH2-terminal domain peptides bound noncooperatively and with a much lower association constant. With these peptides and with intact A1, binding was fully reversed by increasing [NaCl]; yet. A1 binding was much less salt-sensitive than binding by the NH2-terminal domain peptides. A synthetic polypeptide analog of the COOH-terminal domain was prepared and was found to bind tightly to poly-(ethenoadenylate). The results are consistent with the idea that the COOH-terminal domain contributes to A1 binding through both cooperative protein-protein interaction and direct interaction with the nucleic acid.     

Bovine heart mitochondrial F6: HPLC purification, NH2-terminal sequence and the possible structural relatedness to other components of ATPase complexes

The mitochondrial factor F6 has been purified by reverse-phase HPLC and the molecular weight (8500), amino acid composition and about 25% of the amino acid sequence determined. In the NH2-terminal sequence of the first 18 amino acids (NKELDPVQKLFVDKIREY), six identities with the NH2-terminal sequence of the oligomycin-sensitivity conferring protein (OSCP) are apparent, as well as less striking similarities with the OSCP related subunit delta of E. coli F1. The possibility that F6, OSCP and subunit delta of E. coli F1 could have evolved from a common ancestral gene is supported by apparent gene duplication within the OSCP and subunit delta sequences.     

Glutamyl-tRNA synthetase of Escherichia coli. Isolation and primary structure of the gltX gene and homology with other aminoacyl-tRNA synthetases

The gltX gene encoding the glutamyl-tRNA synthetase of Escherichia coli and adjacent regulatory regions was isolated and sequenced. The structural gene encodes a protein of 471 amino acids whose molecular weight is 53,810. The codon usage is that of genes highly expressed in E. coli. The amino acid sequence deduced from the nucleotide sequence of the gltX gene was confirmed by mass spectrometry of large peptides derived from the glutamyl-tRNA synthetase. The observed peptides confirm 73% of the predicted sequence, including the NH2-terminal and the COOH-terminal segments. Sequence homology between the glutamyl-tRNA synthetase and other aminoacyl-tRNA synthetases of E. coli was found in four segments. Three of them are aligned in the same order in all the synthetases where they are present, but the intersegment spacings are not constant; these ordered segments may come from a progenitor to which other domains were added. Starting from the NH2-end, the first two segments are part of a longer region of homology with the glutaminyl-tRNA synthetase, without need for gaps; its size, about 100 amino acids, is typical of a single folding domain. In the first segment, containing sequences homologous to the HIGH consensus, the homology is consistent with the following evolutionary linkage: gltX----glnS----metS----ileS and tyrS.     

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.     

Molecular cloning, sequencing, deletion, and overexpression of a methionine aminopeptidase gene from Saccharomyces cerevisiae.

A yeast gene for a methionine aminopeptidase, one of the central enzymes in protein synthesis, was cloned and sequenced. The DNA sequence encodes a precursor protein containing 387 amino acid residues. The mature protein, whose NH2-terminal sequence was confirmed by Edman degradation, consists of 377 amino acids. The function of the 10-residue sequence at the NH2 terminus, containing 1 serine and 6 threonine residues, remains to be established. In contrast to the structure of the prokaryotic enzyme, the yeast methionine aminopeptidase consists of two functional domains: a unique NH2-terminal domain containing two motifs resembling zinc fingers, which may allow the protein to interact with ribosomes, and a catalytic COOH-terminal domain resembling other prokaryotic methionine aminopeptidases. Furthermore, unlike the case for the prokaryotic gene, the deletion of the yeast MAP1 gene is not lethal, suggesting for the first time that alternative NH2-terminal processing pathway(s) exist for cleaving methionine from nascent polypeptide chains in eukaryotic cells.     

Human hexokinase: sequences of amino- and carboxyl-terminal halves are homologous

cDNA clones encoding human hexokinase have been isolated from an adult kidney library. Analysis of this 917 amino acid protein (Mr = 102,519) indicates that the sequences of the NH2- and COOH-terminal halves, corresponding to the regulatory and catalytic domains, respectively, are homologous; and that eukaryotic hexokinases evolved by duplication of a gene encoding a protein of 450 amino acids. The COOH-terminal half of the protein created by this gene duplication retained the glucose binding site and glucose phosphorylating activity while the substrate binding sites of the NH2-terminal half evolved into a new allosteric effector site.     

Purification of receptor protein Trg by exploiting a property common to chemotactic transducers of Escherichia coli

The methyl-accepting chemotactic transducers of Escherichia coli were found to bind strongly to Cibacron blue-Sepharose. Among potential elutants tested, only S-adenosylmethionine at moderate concentrations and NaCl at concentrations greater than 1.5 M caused dissociation of these detergent-solubilized transmembrane proteins from the dye. Release by S-adenosylmethionine may be a generalized effect rather than the result of a specific binding site for that compound on transducers. A truncated trg gene was created that coded for the carboxyl-terminal three-fifths of the transducer, which constitutes the cytoplasmic domain common to all four transducers in E. coli. This domain bound to Cibacron blue-Sepharose and was eluted in a pattern similar to that exhibited by intact Trg, indicating that interaction with the dye occurred in this conserved domain. Adherence to Cibacron blue and elution by high salt formed the core of an efficient purification scheme, developed for Trg but applicable to all transducers in E. coli and perhaps to methyl-accepting chemotaxis proteins in other species. Determination of the amino acid sequence at the beginning of purified Trg confirmed that it contained a longer hydrophilic segment at its amino terminus than other transducers of E. coli. The initial methionine of Trg is neither cleaved nor modified, in contrast to the Tar transducer in which the amino terminus was found previously to be blocked. Circular dichroic measurements of purified Trg indicated that the secondary structural organization of the protein is predominantly alpha-helix.     

Escherichia coli heat-labile enterotoxin. Nucleotide sequence of the A subunit gene

We report the complete DNA sequence of the Escherichia coli elt A gene, which codes for the A subunit of the heat-labile enterotoxin, LT. The amino acid sequence of the LT A subunit has been deduced from the DNA sequence of elt A. The LT A subunit starts with methionine, ends with leucine, and comprises 254 amino acids. The computed molecular weight of LT A is 29,673. The A subunit of cholera toxin (CT A) has been shown to be structurally and functionally related to the LT A subunit. Comparison of the primary structure of LT A with the known partial amino acid sequence of CT A indicates that the 2 polypeptides share considerable homology throughout their sequences. The NH2-terminal regions exhibit the highest degree of homology (91%), while the COOH-terminal region, containing the sole cystine residue in each toxin is less conserved (approximately 52%). Alignment of homologous residues in the COOH-terminal regions of LT A and CT A indicates that a likely site for proteolytic cleavage of LT A is after Arg residue 188. The resulting A2 polypeptide would be 46 amino acids long, would contain a single cysteine residue, and have Mr = 5261. The elt A nucleotide sequence further predicts that the LT A protein is synthesized in a precursor form, possessing an 18-amino acid signal sequence at its NH2 terminus.     

Domain structure of 3-hydroxy-3-methylglutaryl coenzyme A reductase, a glycoprotein of the endoplasmic reticulum

We present and evaluate a model for the secondary structure and membrane orientation of 3-hydroxy-3-methylglutaryl coenzyme A reductase, the glycoprotein of the endoplasmic reticulum that controls the rate of cholesterol biosynthesis. This model is derived from proteolysis experiments that separate the 97-kilodalton enzyme into two domains, an NH2-terminal membrane-bound domain of 339 residues and a COOH-terminal water-soluble domain of 548 residues that projects into the cytoplasm and contains the catalytic site. These domains were identified by reaction with antibodies against synthetic peptides corresponding to specific regions in the molecule. Computer modeling of the reductase structure, based on the amino acid sequence as determined by molecular cloning, predicts that the NH2-terminal domain contains 7 membrane-spanning regions. Analysis of the gene structure reveals that each proposed membrane-spanning region is encoded in a separate exon and is separated from the adjacent membrane-spanning region by an intron. The COOH-terminal domain of the reductase is predicted to contain two beta-structures flanked by a series of amphipathic helices, which together may constitute the active site. The NH2-terminal membrane-bound domain of the reductase bears some resemblance to rhodopsin, the photoreceptor protein of retinal rod disks and the only other intracellular glycoprotein whose amino acid sequence is known.     

Structure function relationships in the ribosomal stalk proteins of archaebacteria.

The ribosomal L12 protein gene of Sulfolobus solfataricus (SsoL12) has been subcloned and overexpressed in Escherichia coli. Five protein L12 mutants were designed: two NH2-terminal and two COOH-terminal truncated mutants and one mutant lacking the highly charged part of the COOH-terminal region. The mutant protein genes were overexpressed in E. coli and the products purified. The amino acid composition was verified and the NH2 terminally truncated mutants were subjected to Edman degradation. The SsoL12 protein was selectively removed from entire S. solfataricus ribosomes by an ethanol wash. The remaining ribosomal core particles showed a substantial decrease in the in vitro translational activity. S. solfataricus L12 protein overexpressed in E. coli (SsoL12e) was incorporated into these ribosomal cores and restored their translational activity. Mutants lacking any part of the COOH-terminal region could be incorporated into these cores, as proven by two-dimensional polyacrylamide gels of the reconstituted particles. Mutant SsoL12 MC2 (residue 1-70) was sufficient for dimerization and incorporation into ribosomes. In contrast to the COOH terminally truncated mutants, L12 proteins lacking the 12 highly conserved NH2-terminal residues or the entire NH2-terminal region (44 amino acids) are unable to bind to ribosomes, suggesting that the SsoL12 protein binds with its NH2-terminal portion to the ribosome. None of the mutants could significantly increase the translational activity of the core particles suggesting that every deleted part of the protein was needed directly or indirectly for translational activity. Our results suggest that the COOH terminally truncated mutants were bound to ribosomes but not functional for translation. Cores preincubated with these COOH terminally truncated mutants regained activity when a second incubation with the entire overexpressed SsoL12e protein followed. This finding suggests that archaebacterial L12 proteins are freely exchanged on the ribosome.     

Membrane integration and intracellular transport of the coronavirus glycoprotein E1, a class III membrane glycoprotein

The E1-glycoprotein (Mr = 26,014; 228 amino acids) of mouse hepatitis virus A59 is a class III membrane glycoprotein which has been used in this study as a model system in the study of membrane integration and protein transport. The protein lacks an NH2-terminal cleavable signal sequence and spans the viral membrane three times. Hydrophobic domains I and III could serve as signal sequences for cotranslational membrane integration. Domain I alone was sufficient to translocate the hydrophilic NH2 terminus of E1 across the membranes as evidenced by glycosylation of a newly introduced N-glycosylation site. The COOH-terminal part of E1 involving amino acids Leu124 to Thr228 was found to associate tightly with membranes at the post-translational level, although this part of the molecule lacks pronounced hydrophobic sequences. Membrane protection assays with proteinase K showed that a 2-kDa hydrophilic fragment was removed from the COOH terminus of E1 indicating that the protein is largely embedded into the membrane. Microinjection of in vitro transcribed capped and polyadenylated mRNA into CV-1 cells or into secretory AtT20 pituitary tumor cells showed that the E1-protein accumulated in the Golgi but was not detectable at the plasma membrane or in secretory granules. The 28 NH2-terminal hydrophilic amino acid residues play no role in membrane assembly or in intracellular targeting. Various NH2-terminal portions of E1 were fused to Ile145 of the cytoplasmic N-protein of mouse hepatitis virus. The resulting hybrid proteins were shown to assemble into membranes in vitro and were detected either in the rough endoplasmic reticulum or transient vesicles of microinjected cells.     

A novel FK506- and rapamycin-binding protein (FPR3 gene product) in the yeast Saccharomyces cerevisiae is a proline rotamase localized to the nucleolus

The gene (FPR3) encoding a novel type of peptidylpropyl-cis-trans- isomerase (PPIase) was isolated during a search for previously unidentified nuclear proteins in Saccharomyces cerevisiae. PPIases are thought to act in conjunction with protein chaperones because they accelerate the rate of conformational interconversions around proline residues in polypeptides. The FPR3 gene product (Fpr3) is 413 amino acids long. The 111 COOH-terminal residues of Fpr3 share greater than 40% amino acid identity with a particular class of PPIases, termed FK506-binding proteins (FKBPs) because they are the intracellular receptors for two immunosuppressive compounds, rapamycin and FK506. When expressed in and purified from Escherichia coli, both full-length Fpr3 and its isolated COOH-terminal domain exhibit readily detectable PPIase activity. Both fpr3 delta null mutants and cells expressing FPR3 from its own promoter on a multicopy plasmid have no discernible growth phenotype and do not display any alteration in sensitivity to the growth-inhibitory effects of either FK506 or rapamycin. In S. cerevisiae, the gene for a 112-residue cytosolic FKBP (FPR1) and the gene for a 135-residue ER-associated FKBP (FPR2) have been described before. Even fpr1 fpr2 fpr3 triple mutants are viable. However, in cells carrying an fpr1 delta mutation (which confers resistance to rapamycin), overexpression from the GAL1 promoter of the C-terminal domain of Fpr3, but not full-length Fpr3, restored sensitivity to rapamycin. Conversely, overproduction from the GAL1 promoter of full- length Fpr3, but not its COOH-terminal domain, is growth inhibitory in both normal cells and fpr1 delta mutants. In fpr1 delta cells, the toxic effect of Fpr3 overproduction can be reversed by rapamycin. Overproduction of the NH2-terminal domain of Fpr3 is also growth inhibitory in normal cells and fpr1 delta mutants, but this toxicity is not ameliorated in fpr1 delta cells by rapamycin. The NH2-terminal domain of Fpr3 contains long stretches of acidic residues alternating with blocks of basic residues, a structure that resembles sequences found in nucleolar proteins, including S. cerevisiae NSR1 and mammalian nucleolin. Indirect immunofluorescence with polyclonal antibodies raised against either the NH2- or the COOH-terminal segments of Fpr3 expressed in E. coli demonstrated that Fpr3 is located exclusively in the nucleolus.