Deletion of the Leader Peptide of the Mitochondrially Encoded Precursor of Saccharomyces Cerevisiae Cytochrome C Oxidase Subunit II

Cytochrome c oxidase subunit II (Cox2p) of Saccharomyces cerevisiae is synthesized within mitochondria as a precursor, pre-Cox2p. The 15-amino acid leader peptide is processed after export to the intermembrane space. Leader peptides are relatively unusual in mitochondrially coded proteins: indeed mammalian Cox2p lacks a leader peptide. We generated two deletions in the S. cerevisiae COX2 gene, removing either the leader peptide (cox2-20) or the leader peptide and processing site (cox2-21) without altering either the promoter or the mRNA-specific translational activation site. When inserted into mtDNA, both deletions substantially reduced the steady-state levels of Cox2p and caused a tight nonrespiratory phenotype. A respiring pseudorevertant of the cox2-20 mutant was heteroplasmic for the original mutant mtDNA and a ρ(-) mtDNA whose deletion fused the first 251 codons of the mitochondrial gene encoding cytochrome b to the cox2-20 sequence. The resulting fusion protein was processed to yield functional Cox2p. Thus, the presence of amino-terminal cytochrome b sequence bypassed the need for the pre-Cox2p leader peptide. We propose that the pre-Cox2p leader peptide contains a targeting signal necessary for membrane insertion, without which it remains in the matrix and is rapidly degraded.     

Sequence and deletion analysis of the recombination enhancement gene (ref) of bacteriophage P1: evidence for promoter-operator and attenuator-antiterminator control.

The ref gene of bacteriophage P1 stimulates recombination between two defective lacZ genes in the Escherichia coli chromosome (lac x lac recombination) and certain other RecA-dependent recombination processes. We determined the DNA sequence of the 5' portion of the ref gene and tested various regions for functionality by inserting DNA fragments lacking increasing amounts of 5' sequence into plasmid and lambda phage vectors and measuring the ability of the constructs to stimulate lac x lac recombination. The region found essential for Ref activity in the absence of external heterologous promoters encodes two presumptive promoters, pref-1 and pref-2, whose -10 regions fall in a nearly perfect 13-base-pair (bp) tandem repeat. The -10 region of the putative pref-1 is part of a phage P1 c1 repressor recognition sequence. The first two ATG codons in the ref reading frame are, respectively, 90 and 216 bp downstream from the putative promoter-operator region. Deletion analysis indicated that translation can initiate at either ATG (although neither is associated with a canonical ribosome-binding sequence) and that the 42 amino acids in between are not indispensable for Ref stimulation of lac x lac recombination. However, the shorter reading frame appears to encode a less active polypeptide. The 91-bp leader region between the putative promoter-operator and the first ATG contains 30 codons in frame with the ref structural sequence, but its frame can be shifted without affecting Ref activity. The leader region ends with an apparent rho-independent termination sequence (attenuator). Deletion of 18 bp of early leader sequence drastically reduced Ref activity, even when ref was driven by a heterologous promoter (plac). An 8-bp internal deletion in the putative attenuator sequence relieved this requirement for the early leader sequence. This latter observation, along with nucleotide complementarity between portions of the early leader and attenuator sequences, are consistent with preemption of attenuation by the early leader.     

Sequence comparison of single-stranded DNA binding proteins and its structural implications

The primary sequences were compared among several proteins: gene product 5 protein (GP5) from phage M13; PIKE from phage Ike; gene product 32 protein (GP32) from phage T4; RecA, SSB and SSF from Escherichia coli. These proteins bind strongly and cooperatively to single-stranded DNA with no sequence specificity. GP5 is the smallest in this group and its three-dimensional structure is well-characterized. Using the entire sequence of GP5 as a template we searched for the regions in other single-stranded DNA binding proteins yielding the best alignment of aromatic and basic residues. The identified domains show alignment of five aromatic and four charged residues in these proteins. The domains in PIKE, GP32 and RecA exhibit statistically significant sequence homology with GP5. These observations strongly favor the hypothesis that the protein-single-stranded DNA complex in this class of proteins is stabilized by the stacking interaction of the aromatic residues with the bases of the DNA, and by the electrostatic interaction of the basic residues with the phosphate groups of the DNA. We also find that the DNA binding domains of these proteins have similar secondary structural preferences, mainly beta structures. The triple-stranded beta-sheet may be a common motif in the DNA binding domains of these proteins.     

Cloning and characterization of recA genes froM Proteus vulgaris, Erwinia carotovora, Shigella flexneri, and Escherichia coli B/r

The recA genes of Proteus vulgaris, Erwinia carotovora, Shigella flexneri and Escherichia coli B/r have been isolated and introduced into Escherichia coli K-12. All the heterologous genes restore resistance to killing by UV irradiation and the mutagen 4-nitroquinoline-1-oxide in RecA- E. coli K-12 hosts. Recombination proficiency is also restored as measured by formation of Lac+ recombinants from duplicated mutant lacZ genes and the ability to propagate phage lambda derivatives requiring host recombination functions for growth (Fec-). The cloned heterologous genes increase the spontaneous induction of lambda prophage in lysogens of a recA strain. Addition of mitomycin C stimulates phage production in cells carrying the E. coli B/r and S. flexneri recA genes, but little or no stimulation is seen in cells carrying the E. carotovora and P. vulgaris recA genes. After treatment with nalidixic acid, the heterologous RecA proteins are synthesized at elevated levels, a result consistent with their regulation by the E. coli K-12 LexA repressor. Southern hybridization and preliminary restriction analysis indicate divergence among the coding sequences, but antibodies prepared against the E. coli K-12 RecA protein cross-react with the heterologous enzymes, indicating structural conservation among these proteins.     

Cysteine residues in the transmembrane regions of M13 procoat protein suggest that oligomeric coat proteins assemble onto phage progeny

The M13 phage assembles in the inner membrane of Escherichia coli. During maturation, about 2,700 copies of the major coat protein move from the membrane onto a single-stranded phage DNA molecule that extrudes out of the cell. The major coat protein is synthesized as a precursor, termed procoat protein, and inserts into the membrane via a Sec-independent pathway. It is processed by a leader peptidase from its leader (signal) peptide before it is assembled onto the phage DNA. The transmembrane regions of the procoat protein play an important role in all these processes. Using cysteine mutants with mutations in the transmembrane regions of the procoat and coat proteins, we investigated which of the residues are involved in multimer formation, interaction with the leader peptidase, and formation of M13 progeny particles. We found that most single cysteine residues do not interfere with the membrane insertion, processing, and assembly of the phage. Treatment of the cells with copper phenanthroline showed that the cysteine residues were readily engaged in dimer and multimer formation. This suggests that the coat proteins assemble into multimers before they proceed onto the nascent phage particles. In addition, we found that when a cysteine is located in the leader peptide at the -6 position, processing of the mutant procoat protein and of other exported proteins is affected. This inhibition of the leader peptidase results in death of the cell and shows that there are distinct amino acid residues in the M13 procoat protein involved at specific steps of the phage assembly process.     

The Cox protein is a modulator of directionality in bacteriophage P2 site-specific recombination.

The P2 Cox protein is known to repress the Pc promoter, which controls the expression of the P2 immunity repressor C. It has also been shown that Cox can activate the late promoter PLL of the unrelated phage P4. By this process, a P2 phage infecting a P4 lysogen is capable of inducing replication of the P4 genome, an example of viral transactivation. In this report, we present evidence that Cox is also directly involved in both prophage excision and phage integration. While purified Cox, in addition to P2 Int and Escherichia coli integration host factor, was required for attR x attL (excisive) recombination in vitro, it was inhibitory to attP x attB (integrative) recombination. The same amounts of Int and integration host factor which mediated optimal excisive recombination in vitro also mediated optimal integrative recombination. We quantified and compared the relative efficiencies of attB, attR, and attL in recombination with attP and discuss the functional implications of the results. DNase I protection experiments revealed an extended 70-bp Cox-protected region on the right arm of attP, centered at about +60 bp from the center of the core sequence. Gel shift assays suggest that there are two Cox binding sites within this region. Together, these data support the theory that in vivo, P2 can exert control over the direction of recombination by either expressing Int alone or Int and Cox together.     

Outer membrane protein H1 of Pseudomonas aeruginosa: purification of the protein and cloning and nucleotide sequence of the gene.

Overexpression of the divalent cation-regulated outer membrane protein H1 of Pseudomonas aeruginosa is associated with resistance to polymyxin B, aminoglycosides, and EDTA. Protein H1 is believed to act by replacing divalent cations at binding sites on lipopolysaccharide, thereby preventing disruption of the sites and subsequent self-promoted uptake of the antibiotics. Protein H1 purified by two cycles of anion-exchange chromatography was apparently associated with lipopolysaccharide. Lipopolysaccharide-free protein H1 was purified in high yield by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis and was subjected to N-terminal amino sequencing. Complementary oligodeoxyribonucleotides were used to clone the structural gene for protein H1, oprH, into Escherichia coli. Successful cloning was confirmed by nucleotide sequence analysis. Southern hybridization suggested that oprH was present as a single-copy gene in P. aeruginosa. The deduced amino acid sequence revealed that H1 was a slightly basic polypeptide of 178 residues, with a leader sequence typical of an exported procaryotic protein. It had little similarity, however, to other bacterial surface proteins for which sequence data were available. No expression of protein H1, from its own or the lac promoter, was detected in E. coli. We concluded that, as for some other regulated Pseudomonas genes, expression of oprH, at least under some conditions, is blocked in E. coli.     

Complete nucleotide sequence of the prophage VT1-Sakai carrying the Shiga toxin 1 genes of the enterohemorrhagic Escherichia coli O157:H7 strain derived from the Sakai outbreak

Shiga toxins 1 and 2 (Stx1 and Stx2) are encoded by prophages lysogenized in enterohemorrhagic Escherichia coli (EHEC) O157:H7 strains. Lytic growth of the phage particles carrying the stx1 genes (stx1A and stx1B) of the EHEC O157:H7 strain RIMD 0509952, which was derived from the Sakai outbreak in 1996 in Japan, was induced after treatment with mitomycin C, but the plaque formation of the phage was not detected. We have determined the complete nucleotide sequence of the prophage VT1-Sakai. The integration site of the prophage was identified within the yehV gene at 47.7 min on the chromosome. The stx1 genes were downstream of the Q gene in the prophage genome, suggesting that their expression was regulated by the Q protein, the regulator of the late gene expression of the phage, which is similar to that of the stx1 or stx2 genes carried by the lambdoid phages reported previously. The sequences of the N gene and its recognition sites, nutL and nutR, were not homologous to those of the phages carrying the stx genes thus far reported, but they were very similar to those of bacteriophage phi21. The sequences of the repressor proteins, CI and Cro, that regulate expression of the early genes had low similarities with those of the known repressors of other phages, and their operator sequences were different from any sequence reported. These data suggest that multiple genetic recombination among bacteriophages with different immunities took place to generate the prophage VT1-Sakai. Comparison between the sequences of VT1-Sakai and lambda suggests that the ancestor of VT1-Sakai was produced by illegitimate excision, like lambda gal and bio phages.     

Characterization of the DNA binding protein encoded by the N-specific filamentous Escherichia coli phage IKe. Binding properties of the protein and nucleotide sequence of the gene

A DNA binding protein encoded by the filamentous single-stranded DNA phage IKe has been isolated from IKe-infected Escherichia coli cells. Fluorescence and in vitro binding studies have shown that the protein binds co-operatively and with a high specificity to single-stranded but not to double-stranded DNA. From titration of the protein to poly(dA) it has been calculated that approximately four bases of the DNA are covered by one monomer of protein. These binding characteristics closely resemble those of gene V protein encoded by the F-specific filamentous phages M13 and fd. The nucleotide sequence of the gene specifying the IKe DNA binding protein has been established. When compared to the nucleotide sequence of gene V of phage M13 it shows an homology of 58%, indicating that these two phages are evolutionarily related. The IKe DNA binding protein is 88 amino acids long which is one amino acid residue larger than the gene V protein sequence. When the IKe DNA binding protein sequence is compared with that of gene V protein it was found that 39 amino acid residues have identical positions in both proteins. The positions of all five tyrosine residues, a number of which are known to be involved in DNA binding, are conserved. Secondary structure predictions indicate that the two proteins contain similar structural domains. It is proposed that the tyrosine residues which are involved in DNA binding are the ones in or next to a beta-turn, at positions 26, 41 and 56 in gene V protein and at positions 27, 42 and 57 in the IKe DNA binding protein.