Identification and Characterization of the Single-Stranded DNA-Binding Protein of Bacteriophage P1

The genome of bacteriophage P1 harbors a gene coding for a 162-amino-acid protein which shows 66% amino acid sequence identity to the Escherichia coli single-stranded DNA-binding protein (SSB). The expression of the P1 gene is tightly regulated by P1 immunity proteins. It is completely repressed during lysogenic growth and only weakly expressed during lytic growth, as assayed by an ssb-P1/lacZ fusion construct. When cloned on an intermediate-copy-number plasmid, the P1 gene is able to suppress the temperature-sensitive defect of an E. coli ssb mutant, indicating that the two proteins are functionally interchangeable. Many bacteriophages and conjugative plasmids do not rely on the SSB protein provided by their host organism but code for their own SSB proteins. However, the close relationship between SSB-P1 and the SSB protein of the P1 host, E. coli, raises questions about the functional significance of the phage protein.     

Large-scale overproduction and rapid purification of the Escherichia coli ssb gene product. Expression of the ssb gene under lambda PL control

We report a rapid procedure for the large-scale purification of the Escherichia coli encoded single-strand binding (SSB) protein, helix-destabilizing protein which is essential for replication, recombination, and repair processes in E. coli. To facilitate the isolation of large quantities of the ssb gene product, we have subcloned the ssb gene into a temperature-inducible expression vector, pPLc28 [Remaut, E., Stanssens, P., & Fiers, W. (1981) Gene 15, 81-93], carrying the bacteriophage lambda PL promoter. A large overproduction of the ssb gene product results upon shifting the temperature of E. coli strains which carry the plasmid and also produce the thermolabile lambda cI857 repressor. After 5 h of induction, the ssb gene product represents approximately 10% of the total cell protein. The overexpression of the ssb gene and the purification protocol reported here enable one to isolate SSB protein (greater than 99% pure) with final yields of approximately 3 mg of SSB protein/g of cell paste. In fact, very pure (greater than 99%) SSB protein can be obtained after approximately 8 h, starting from frozen cells in the absence of any columns, although inclusion of a single-stranded DNA-cellulose column is generally recommended to ensure that the purified SSB protein possesses DNA binding activity. The ability to easily purify 1 g of SSB protein from 300-350 g of induced cells will facilitate physical studies requiring large quantities of this important protein.     

SSB蛋白的高效表达及其与ssDNA的相互作用

大肠杆菌单链结合蛋白SSB在DNA复制、重组和修复中起着重要作用。为研究单链结合蛋白SSB的体外生物功能构建了融合蛋白SSB的表达载体并使其高效表达及易于纯化。ssb基因片段是以E.coli K-12基因组为模板经PCR扩增获得,并通过基因的体外拼接成功构建了表达载体pQE30-ssb。重组菌株M15/ pQE30-ssb经过IPTG的诱导表达了蛋白SSB。收集菌体细胞、超声波破碎后离心取上清进行SDS-PAGE分析,结果表明有一与预期分子量（20.6 kD）相应的诱导表达条带出现,其表达量约占全细胞蛋白的30％且以可溶形式存在。利用固定化金属离子（Ni2+）配体亲和层析柱纯化融合蛋白SSB,其纯度达到90％。通过凝胶层析和等离子共振技术对SSB的生物功能进行了系统研究分析。结果表明,SSB蛋白以四聚体形式与单链DNA分子结合,其亲和力常数（KD）为4.79×10-7 M。     

The ssb gene of plasmid ColIb-P9.

The IncI1 plasmid ColIb-P9 was found to carry a single-stranded DNA-binding (SSB) protein gene (ssb) that maps about 11 kilobase pairs from the origin of transfer in the region transferred early during bacterial conjugation. The cloned gene was able to suppress the UV and temperature sensitivity of an ssb-1 strain of Escherichia coli K-12. The nucleotide sequence of the ColIb ssb gene was determined, giving a predicted molecular weight of 19,110 for the SSB protein. Sequence data show that ColIb ssb is very similar to the ssb gene on plasmid F, which is also known to map in the leader region. High-level expression of ssb on ColIb required derepression of the transfer (tra) genes and the activity of the positive regulatory system controlling these genes, suggesting that the SSB protein contributes to the conjugative processing of DNA. A mutant of ColIbdrd-1 carrying a Tn903-derived insertion in ssb was constructed, but it was unaffected in the ability to generate plasmid transconjugants and it was maintained apparently stably in donor cells both following mating and during vegetative growth. Hence, no biological role of ColIb SSB protein was detected. However, unlike the parental plasmid, such ColIb ssb mutants conferred a marked Psi+ (plasmid-mediated SOS inhibition) phenotype on recA441 and recA730 strains, implying a functional relationship between SSB and Psi proteins.     

The single-stranded-DNA-binding protein encoded by the Escherichia coli F factor can complement a deletion of the chromosomal ssb gene.

Genes encoding single-stranded-DNA-binding proteins (SSBs) are carried by a variety of large self-transmissible plasmids, and it previously has been shown that these plasmid-borne genes can complement conditional lethal alleles of the ssb gene on the Escherichia coli chromosome for cellular viability. We have tested one of the plasmid-borne ssb genes, the ssf gene from the E. coli F factor, for its ability to complement total deletion of the chromosomal ssb gene for viability. We have found that ssf can complement the ssb deletion, but only when it is present on a high-copy-number plasmid. Cells that are totally dependent on the F-factor-encoded SSB for viability manifest growth properties indicative of problems in DNA replication.     

Analysis of ssb mutations in vivo implicates SSB protein in two distinct pathways of SOS induction and in recombinational DNA repair

Site-directed mutations in the Escherichia coli ssb gene were tested for the ability to complement a chromosomal ssb deletion for viability, and only the ssb W54→G mutation failed to do so at the pSC101 copy level. Non-aromatic amino acid substitutions for SSB Trp-54 ( ssb W54→L and ssb W54→S) produced the greatest effects on in vivo protein function including altered marker linkage subsequent to generalized transduction, extreme UV sensitivity, and a lack of ability to support SOS induction. Additionally, the ssb-113 ( ssb P176→S) mutation demonstrated the existence of both uvrA -dependent and uvrA -independent components of SOS induction. Although nucleotide excision repair appeared unaffected by alterations in the SSB protein, the mutational analysis suggests a direct role for SSB in recombinational repair.     

Functional Interactions between the DNA Ligase of ESCHERICHIA COLI and Components of the DNA Metabolic Apparatus of T4 Bacteriophage

T4 phage completely defective in both gene 30 (DNA ligase) and the rII gene (function unknown) require at least normal levels of host-derived DNA ligase (E. coli lig gene) for growth. Viable E. coli mutant strains that harbor less than 5% of the wild-type level of bacterial ligase do not support growth of T4 doubly defective in genes 30 and rII (T4 30- rII- mutants). We describe here two classes of secondary phage mutations that permit the growth of T4 30- rII- phage on ligase-defective hosts. One class mapped in T4 gene su30 (Krylov 1972) and improved T4 30- rII- phage growth on all E. coli strains, but to varying degrees that depended on levels of residual host ligase. Another class mapped in T4 gene 32 (helix-destabilizing protein) and improved growth specifically on a host carrying the lig2 mutation, but not on a host carrying another lig- lesion (lig4). Two conclusions are drawn from the work: (1) the role of DNA ligase in essential DNA metabolic processes in T4-infected E. coli is catalytic rather than stoichiometric, and (2) the E. coli DNA ligase is capable of specific functional interactions with components of the T4 DNA replication and/or repair apparatus.     

Specific and cooperative binding of E. coli single-stranded DNA binding protein to mRNA.

Fluorometric titration of E. coli single-stranded DNA binding protein with various RNAs showed that the protein specifically and cooperatively binds to its own mRNA. The binding inhibited in vitro expression of ssb and bla but not nusA. This inhibition takes place at a physiological concentration of SSB. The function of the protein in gene regulation is discussed.     

The translation machinery and 70 kd heat shock protein cooperate in protein synthesis.

The function of the yeast SSB 70 kd heatshock proteins (hsp70s) was investigated by a variety of approaches. The SSB hsp70s (Ssb1/2p) are associated with translating ribosomes. This association is disrupted by puromycin, suggesting that Ssb1/2p may bind directly to the nascent polypeptide. Mutant ssb1 ssb2 strains grow slowly, contain a low number of translating ribosomes, and are hypersensitive to several inhibitors of protein synthesis. The slow growth phenotype of ssb1 ssb2 mutants is suppressed by increased copy number of a gene encoding a novel translation elongation factor 1 alpha (EF-1 alpha)-like protein. We suggest that cytosolic hsp70 aids in the passage of the nascent polypeptide chain through the ribosome in a manner analogous to the role played by organelle-localized hsp70 in the transport of proteins across membranes.     

Identification and characterization of ssb and uup mutants with increased frequency of precise excision of transposon Tn10 derivatives: nucleotide sequence of uup in Escherichia coli.

A Lac+ papillation assay was used to identify mutants (tex) of Escherichia coli that exhibit an increased frequency of precise excision of a lacZ::Tn10dKan insertion. Three tex strains had suffered mutations in the gene (ssb) encoding the essential single-stranded DNA-binding protein SSB, which resulted in the following alterations in the 177-residue protein: G4D; L10F, P24S; and V102M. The phenotypes of these ssb mutants indicated that they were largely unaffected in other functions mediated by SSB, such as DNA replication, recombination, and repair. Strains with multicopy ssb+ exhibited a decreased frequency of Tn10dKan precise excision. Three other tex mutants had insertion mutations in the locus designated uup at 21.75 min on the linkage map. The nucleotide sequence of uup was determined, and the gene was inferred to encode a 625-amino-acid hydrophilic protein that belongs to the superfamily of ABC-domain proteins (with two pairs of the Walker A and B motifs), which are postulated to be involved in coupling ATP hydrolysis with other biological processes. The uup gene product shares extensive homology with the deduced sequences of two proteins of Haemophilus influenzae. The uup gene is also situated immediately upstream of (and is transcribed in the same direction as) the paraquat-inducible SoxRS-regulated pqi-5 gene, two reported promoters for which are situated within the uup coding sequence.     

Differential expression of two paralogous genes of Bacillus subtilis encoding single-stranded DNA binding protein

The Bacillus subtilis genome comprises two paralogous single-stranded DNA binding protein (SSB) genes, ssb and ywpH, which show distinct expression patterns. The main ssb gene is strongly expressed during exponential growth and is coregulated with genes encoding the ribosomal proteins S6 and S18. The gene organization rpsF-ssb-rpsR as observed in B. subtilis is found in many gram-positive as well as some gram-negative bacteria, but not in Escherichia coli. The ssb gene is essential for cell viability, and like other SSBs its expression is elevated during SOS response. In contrast, the paralogous ywpH gene is transcribed from its own promoter at the onset of stationary phase in minimal medium only. Its expression is ComK dependent and its gene product is required for optimal natural transformation.     

Isolation and characterization of dnaJ null mutants of Escherichia coli.

Bacteriophage lambda requires the lambda O and P proteins for its DNA replication. The rest of the replication proteins are provided by the Escherichia coli host. Some of these host proteins, such as DnaK, DnaJ, and GrpE, are heat shock proteins. Certain mutations in the dnaK, dnaJ, or grpE gene block lambda growth at all temperatures and E. coli growth above 43 degrees C. We have isolated bacterial mutants that were shown by Southern analysis to contain a defective, mini-Tn10 transposon inserted into either of two locations and in both orientations within the dnaJ gene. We have shown that these dnaJ-insertion mutants did not grow as well as the wild type at temperatures above 30 degrees C, although they blocked lambda DNA replication at all temperatures. The dnaJ-insertion mutants formed progressively smaller colonies at higher temperatures, up to 42 degrees C, and did not form colonies at 43 degrees C. The accumulation of frequent, uncharacterized suppressor mutations allowed these insertion mutants to grow better at all temperatures and to form colonies at 43 degrees C. None of these suppressor mutations restored the ability of the host to propagate phage lambda. Radioactive labeling of proteins synthesized in vivo followed by immunoprecipitation or immunoblotting with anti-DnaJ antibodies demonstrated that no DnaJ protein could be detected in these mutants. Labeling studies at different temperatures demonstrated that these dnaJ-insertion mutations resulted in altered kinetics of heat shock protein synthesis. An additional eight dnaJ mutant isolates, selected spontaneously on the basis of blocking phage lambda growth at 42 degrees C, were shown not to synthesize DnaJ protein as well. Three of these eight spontaneous mutants had gross DNA alterations in the dnaJ gene. Our data provide evidence that the DnaJ protein is not absolutely essential for E. coli growth at temperatures up to 42 degrees C under standard laboratory conditions but is essential for growth at 43 degrees C. However, the accumulation of extragenic suppressors is necessary for rapid bacterial growth at higher temperatures.     

Ribosome-messenger recognition: mRNA target sites for ribosomal protein S1.

Ribosomal protein S1 is known to play an important role in translational initiation, being directly involved in recognition and binding of mRNAs by 30S ribosomal particles. Using a specially developed procedure based on efficient crosslinking of S1 to mRNA induced by UV irradiation, we have identified S1 binding sites on several phage RNAs in preinitiation complexes. Targets for S1 on Q beta and fr RNAs are localized upstream from the coat protein gene and contain oligo(U)-sequences. In the case of Q beta RNA, this S1 binding site overlaps the S-site for Q beta replicase and the site for S1 binding within a binary complex. It is reasonable that similar U-rich sequences represent S1 binding sites on bacterial mRNAs. To test this idea we have used E. coli ssb mRNA prepared in vitro with the T7 promoter/RNA polymerase system. By the methods of toeprinting, enzymatic footprinting, and UV crosslinking we have shown that binding of the ssb mRNA to 30S ribosomes is S1-dependent. The oligo(U)-sequence preceding the SD domain was found to be the target for S1. We propose that S1 binding sites, represented by pyrimidine-rich sequences upstream from the SD region, serve as determinants involved in recognition of mRNA by the ribosome.     

Investigation of the role of individual tryptophan residues in the binding of Escherichia coli single-stranded DNA binding protein to single-stranded polynucleotides. A study by optical detection of magnetic resonance and site-selected mutagenesis

Fluorescence and optical detection of triplet state magnetic resonance (ODMR) spectroscopy have been employed to study the complexes formed between single-stranded polynucleotides and Escherichia coli ssb gene products (SSB) in which tryptophans 40, 54, and 88 are selectively, one residue at a time, replaced by phenylalanine using site-specific oligonucleotide mutagenesis. Fluorescence titrations and ODMR results indicate that tryptophans 40 and 54 are the only tryptophan residues in E. coli single-stranded DNA binding protein that are involved in stabilizing the protein-nucleic acid complexes via stacking interactions. Wavelength-selected ODMR measurements on E. coli SSB reveal the presence of two spectrally distinct tryptophan sites (Khamis, M. I., Casas-Finet, J. R., and Maki, A. H. (1987) J. Biol. Chem. 262, 1725-1733). Our present results indicate that tryptophan 54 belongs to the blue-shifted site, while tryptophan 40 belongs to the red-shifted site of the protein.     

Effects of overproduction of single-stranded DNA-binding protein on RecA protein-dependent processes in Escherichia coli

Overproduction of single-stranded DNA-binding protein (SSB) in Escherichia coli led to a decrease in the basal level of repressor LexA. Expression of the LexA-controlled genes was increased differentially, depending on the affinity of the LexA repressor for each promoter: expression of the recA and sfiA genes was increased 5-fold and 1.5-fold, respectively. Despite only a slight effect on expression of sfiA, which codes for an inhibitor of cell division, bacteria overproducing SSB produced elongated cells. In fact, the effect on cell shape appeared to be essentially independent of the expression of the sfiA and recA genes. Bacteria overproducing SSB were therefore phenotypically similar to bacteria partially starved of thymine, in which filamentation results from both sfiA-dependent and sfiA-recA-independent pathways. These data indicate that excess SSB acts primarily by perturbing DNA replication, thereby favoring gratuitous activation of RecA protein to promote cleavage of LexA protein. When bacteria overproducing SSB were exposed to a DNA-damaging agent such as ultraviolet light or mitomycin C, the recA and sfiA genes were fully induced. Induction of the sfiA gene occurred, however, at higher doses in bacteria overproducing SSB protein than in bacteria with normal levels of SSB. Whereas the efficiency of excision repair was apparently increased by excess SSB, the efficiency of post-replication recombinational repair was reduced as judged by a decrease in the recombination proficiency between a prophage and ultraviolet-irradiated heteroimmune infecting phage. Following induction of ssb+ bacteria with mitomycin C, the cellular content of SSB was slightly increased. These results provide evidence that SSB modulates RecA protein-dependent activities in vivo. It is proposed that SSB favors the formation of short complexes of RecA protein and single-stranded DNA that mediate cleavage of the LexA and lambda repressors, while it delays the formation of long nucleoprotein filaments, thereby slowing down RecA-promoted recombinational events in uninduced as well as in induced bacteria.     

The single-stranded DNA-binding protein of Escherichia coli.

The single-stranded DNA-binding protein (SSB) of Escherichia coli is involved in all aspects of DNA metabolism: replication, repair, and recombination. In solution, the protein exists as a homotetramer of 18,843-kilodalton subunits. As it binds tightly and cooperatively to single-stranded DNA, it has become a prototypic model protein for studying protein-nucleic acid interactions. The sequences of the gene and protein are known, and the functional domains of subunit interaction, DNA binding, and protein-protein interactions have been probed by structure-function analyses of various mutations. The ssb gene has three promoters, one of which is inducible because it lies only two nucleotides from the LexA-binding site of the adjacent uvrA gene. Induction of the SOS response, however, does not lead to significant increases in SSB levels. The binding protein has several functions in DNA replication, including enhancement of helix destabilization by DNA helicases, prevention of reannealing of the single strands and protection from nuclease digestion, organization and stabilization of replication origins, primosome assembly, priming specificity, enhancement of replication fidelity, enhancement of polymerase processivity, and promotion of polymerase binding to the template. E. coli SSB is required for methyl-directed mismatch repair, induction of the SOS response, and recombinational repair. During recombination, SSB interacts with the RecBCD enzyme to find Chi sites, promotes binding of RecA protein, and promotes strand uptake.     

Up-regulation of yggG promotes the survival of Escherichia coli cells containing Era-1 mutant protein

Era is a highly conserved GTPase essential for bacterial growth. Using a digoxigenin-labeled Era protein to screen a phage expression library of Escherichia coli genomic DNA, yggG, a gene that encodes a putative zinc metalloprotease was isolated and characterized. The deduced amino acid sequence of YggG showed high degrees of similarity to some reported heat shock proteins. In this study, the direct interaction between Era and YggG was confirmed, and it was found that the yggG gene, encoding a 25 kDa heat shock protein, was up-regulated at the mRNA level in partially defective Era GTPase mutants (era-1) and in E. coli cells overproducing Era-1. The delta yggG strain displayed the same growth rate as wild-type strain under normal growth conditions and after heat shock. Overexpression of Era-1 in the delta yggG strain resulted in a stronger growth-inhibitory effect than that in the wild-type strain, while coexpression of YggG partially restored the bacterial growth rate. The results indicated that YggG expression is significantly increased in response to stress caused by the Era-1 mutant protein in E. coli, thus promoting the growth of E. coli.