The osmZ (bglY) gene encodes the DNA-binding protein H-NS (H1a), a component of the Escherichia coli K12 nucleoid

Summary A class of trans-acting mutations, which alter the osmoregulated expression of the Escherichia coli proU operon, maps at 27 min on the chromosome in a locus we have called osmZ. Mutations in osmZ are allelic to bglY, pilG and virR, affect gene expression, increase the frequency of the site-specific DNA inversion mediating fimbrial phase variation, stimulate the formation of deletions, and influence in vivo supercoiling of reporter plasmids. We have cloned the osmZ ⁺ gene, mapped it at 1307 kb of the E. coli restriction map, identified its gene product as a 16 kDa protein, and determined the nucleotide sequence of the osmZ ⁺ gene. The deduced amino acid sequence for OsmZ predicts a protein of 137 amino acid residues with a calculated molecular weight of 15 530. The primary sequence of OsmZ is identical to that of H-NS (H1a), a DNA-binding protein that affects DNA topology and is known to be associated with the bacterial nucleoid. Thus, osmZ is the structural gene for the H-NS (H1a) protein. The nucleotide sequence of osmZ is almost identical to that of hns; however, hns was incorrectly located at 6.1 min on the E. coli linkage map. Increased osmZ gene dosage leads to cell filament formation, altered gene expression, and reduced frequency of fimbrial phase variation. Our results suggest that the nucleoid-associated DNA-binding protein H-NS (H1a) plays a critical role in gene expression and in determining the structure of the genetic material.     

Molecular analysis of the Escherichia coli hns gene encoding a DNA-binding protein, which preferentially recognizes curved DNA sequences.

Summary We previously demonstrated that the E. coli protein, H-NS (or Hla), encoded by the gene hns (or osmZ or bglY preferentially recognizes curved DNA sequences in vitro. In order to gain further insight into the complex function of H-NS and the significance of DNA curvature, we constructed a structurally defined hns deletion mutant on the E. coli chromosome. The hns deletion mutant thus obtained showed a variety of phenotypes previously for other lesions in hns. It was further demonstrated that, in this hns deletion background, numerous E. coli cellular proteins were either strongly expressed or remarkably repressed, as compared to their expression levels in wild-type cells.     

The nucleoid-associated DNA-binding protein H-NS is required for the efficient adaptation of Escherichia coli K-12 to a cold environment

The hns gene is a member of the cold-shock regulon, indicating that the nucleoid-associated, DNA-binding protein H-NS plays an important role in the adaptation of Escherichia coli to low temperatures. We show here that the ability to cope efficiently with a cold environment (12°C and 25°C) is strongly impaired in E. coli strains carrying hns mutations. Growth inhibition is much more pronounced in strains carrying the hns-206 allele (an ampicillin resistance cassette inserted after codon 37) than in those carrying the hns-205 mutation (a Tn10 insertion located in codon 93). A protein fragment (H-NS^*) is synthesized in strains carrying the hns-205::Tn10 mutation, suggesting that this truncated polypeptide is partially functional in the cold adaptation process. Analysis of the growth properties of strains harbouring four different low-copy-number plasmid-encoded hns genes that result in the production of C-terminally truncated H-NS proteins supports this proposal. H-NS^* proteins composed of 133, 117 or 94 amino-terminal amino acids partially complemented the severe cold-sensitive growth phenotype of the hns-206 mutant. In contrast, synthesis of a truncated H-NS protein with only 75 amino-terminal amino acids was insufficient to restore growth at low temperature.     

Phenotypic Analysis of Random hns Mutations Differentiate DNA-Binding Activity from Properties of fimA Promoter Inversion Modulation and Bacterial Motility

H-NS is a major Escherichia coli nucleoid-associated protein involved in bacterial DNA condensation and global modulation of gene expression. This protein exists in cells as at least two different isoforms separable by isoelectric focusing. Among other phenotypes, mutations in hns result in constitutive expression of the proU and fimB genes, increased fimA promoter inversion rates, and repression of the flhCD master operon required for flagellum biosynthesis. To understand the relationship between H-NS structure and function, we transformed a cloned hns gene into a mutator strain and collected a series of mutant alleles that failed to repress proU expression. Each of these isolated hns mutant alleles also failed to repress fimB expression, suggesting that H-NS-specific repression of proU and fimB occurs by similar mechanisms. Conversely, alleles encoding single amino acid substitutions in the C-terminal DNA-binding domain of H-NS resulted in significantly reduced affinity for DNA yet conferred a wild-type fimA promoter inversion frequency, indicating that the mechanism of H-NS activity in modulating promoter inversion is independent of DNA binding. Furthermore, two specific H-NS amino acid substitutions resulted in hypermotile bacteria, while C-terminal H-NS truncations exhibited reduced motility. We also analyzed H-NS isoform composition expressed by various hns mutations and found that the N-terminal 67 amino acids were sufficient to support posttranslational modification and that substitutions at positions 18 and 26 resulted in the expression of a single H-NS isoform. These results are discussed in terms of H-NS domain organization and implications for biological activity.     

H-NS controls metabolism and stress tolerance in Escherichia coli O157:H7 that influence mouse passage

Background  

H-NS is a DNA-binding protein with central roles in gene regulation and nucleoid structuring in Escherichia coli. There are over 60 genes that are influenced by H-NS many of which are involved in metabolism. To determine the significance of H-NS-regulated genes in metabolism and stress tolerance, an hns mutant of E. coli O157:H7 was generated (hns::nptI, FRIK47001P) and its growth, metabolism, and gastrointestinal passage compared to the parent strain (43895) and strain FRIK47001P harboring pSC0061 which contains a functional hns and 90-bp upstream of the open-reading frame.     

The nucleoid-associated DNA-binding protein H-NS is required for the efficient adaptation of Escherichia coli K-12 to a cold environment

The hns gene is a member of the cold-shock regulon, indicating that the nucleoid-associated, DNA-binding protein H-NS plays an important role in the adaptation of Escherichia coli to low temperatures. We show here that the ability to cope efficiently with a cold environment (12°C and 25°C) is strongly impaired in E. coli strains carrying hns mutations. Growth inhibition is much more pronounced in strains carrying the hns-206 allele (an ampicillin resistance cassette inserted after codon 37) than in those carrying the hns-205 mutation (a Tn10 insertion located in codon 93). A protein fragment (H-NS^*) is synthesized in strains carrying the hns-205::Tn10 mutation, suggesting that this truncated polypeptide is partially functional in the cold adaptation process. Analysis of the growth properties of strains harbouring four different low-copy-number plasmid-encoded hns genes that result in the production of C-terminally truncated H-NS proteins supports this proposal. H-NS^* proteins composed of 133, 117 or 94 amino-terminal amino acids partially complemented the severe cold-sensitive growth phenotype of the hns-206 mutant. In contrast, synthesis of a truncated H-NS protein with only 75 amino-terminal amino acids was insufficient to restore growth at low temperature.     

Cloning and sequencing of an Escherichia coli K12 gene which encodes a polypeptide having similarity to the human ferritin H subunit

Summary Using lambda phage clones containing segments of the Escherichia coli K12 chromosome as hybridization probes, we found one gene at 42 min on the E. coli chromosome map, the expression of which was affected by RNase III. The sequence of the DNA fragment containing this gene (gen-165) revealed the presence of an open reading frame encoding a polypeptide of 165 amino acid residues. The amino acid sequence deduced from the nucleotide sequence exhibited a remarkable similarity to that of the human ferritin H chain.     

Expression of the hemolysin operon in Escherichia coli is modulated by a nucleoid-protein complex that includes the proteins Hha and H-NS

The Escherichia coli protein Hha is a temperature- and osmolarity-dependent modulator of the expression of the hemolysin operon. The Hha protein was purified and its DNA-binding properties analyzed. Hha binds in a non-specific manner throughout the upstream regulatory region of the hemolysin operon in the recombinant hemolytic plasmid pANN202-312. A search for interacting proteins revealed that Hha interacts with H-NS. DNA-binding studies showed that, in vitro, Hha and H-NS together form a complex with DNA that differs from those formed with either protein alone. These data, together with the effects of hha and hns mutations on the expression of the hemolysin genes, suggest that in vivo H-NS and Hha form a nucleoid-protein complex that accounts for the thermo-osmotic regulation of the hemolysin operon in E. coli. Received. 18 October 1999 / Accepted: 21 December 1999     

A mutational study of Cnu reveals attractive forces between Cnu and H-NS

Cnu is a small 71-amino acid protein that complexes with H-NS and binds to a specific sequence in the replication origin of the E. coli chromosome. To understand the mechanism of interaction between Cnu and H-NS, we used bacterial genetics to select and analyze Cnu variants that cannot complex with H-NS. Out of 2,000 colonies, 40 Cnu variants were identified. Most variants (82.5%) had a single mutation, but a few variants (17.5%) had double amino acid changes. An in vitro assay was used to identify Cnu variants that were truly defective in H-NS binding. The changes in these defective variants occurred exclusively at charged amino acids (Asp, Glu, or Lys) on the surface of the protein. We propose that the attractive force that governs the Cnu-H-NS interaction is an ionic bond, unlike the hydrophobic interaction that is the major attractive force in most proteins.     

The Corynebacterium glutamicum cglIM gene encoding a 5-cytosine methyltransferase enzyme confers a specific DNA methylation pattern in an McrBC-deficient Escherichia coli strain

The cglIM gene of the coryneform soil bacterium Corynebacterium glutamicum ATCC 13032 has been cloned and characterized. The coding region comprises 1092 nucleotides and specifies a protein of 363 amino acid residues with a deduced M_r of 40 700. The amino acid sequence showed striking similarities to methyltransferase enzymes generating 5-methylcytosine residues, especially to M·NgoVII from Neisseria gonorrhoeae recognizing the sequence GCSGC. The cglIM gene is organized in an unusual operon which contains, in addition, two genes encoding stress-sensitive restriction enzymes. Using PCR techniques the entire gene including the promoter region was amplified from the wild-type chromosome and cloned in Escherichia coli. Expression of the cglIM gene in E. coli under the control of its own promoter conferred the C. glutamicum-specific methylation pattern to co-resident shuttle plasmids and led to a 260-fold increase in the transformation rate of C. glutamicum. In addition, the methylation pattern produced by this methyltransferase enzyme is responsible for the sensitivity of DNA from C. glutamicum to the modified cytosine restriction (Mcr) system of E. coli.     

The VANA glycopeptide resistance protein is related to d-alanyl-d-alanine ligase cell wall biosynthesis enzymes

Summary Inducible resistance to the glycopeptide antibiotics vancomycin and teicoplanin is mediated by plasmid pIP816 in Enterococcus faecium strain BM4147. Vancomycin induced the synthesis of a ca. 40 kDa membrane-associated protein designated VANA. The resistance protein was partially purified and its N-terminal sequence was determined. A 1761 by DNA restriction fragment of pIP816 was cloned into Escherichia coli and sequenced. When expressed in E. coli, this fragment encoded a ca. 40 kDa protein that comigrated with VANA from enterococcal membrane fractions. The ATG translation initiation codon for VANA specified the methionine present at the N-terminus of the protein indicating the absence of signal peptide processing. The amino acid sequence deduced from the sequence of the vanA gene consisted of 343 amino acids giving a protein with a calculated Mr of 37400. VANA was structurally related to the d-alanyl-d-alanine (d-ala-d-ala) ligases of Salmonella typhimurium (36% amino acid identity) and of E. coli (28%). The vanA gene was able to transcomplement an E. coli mutant with thermosensitive d-ala-d-ala ligase activity. Thus, the inducible resistance protein VANA was structurally and functionally related to cytoplasmic enzymes that synthesize the target of glycopeptide antibiotics. Based on these observations we discuss the possibility that resistance is due to modification of the glycopeptide target.     

Redesign, synthesis and functional expression of the 6-deoxyerythronolide B polyketide synthase gene cluster

A generic design of Type I polyketide synthase genes has been reported in which modules, and domains within modules, are flanked by sets of unique restriction sites that are repeated in every module [1]. Using the universal design, we synthesized the six-module DEBS gene cluster optimized for codon usage in E. coli, and cloned the three open reading frames into three compatible expression vectors. With one correctable exception, the amino acid substitutions required for restriction site placements were compatible with polyketide production. When expressed in E. coli the codon-optimized synthetic gene cluster produced significantly more protein than did the wild-type sequence. Indeed, for optimal polyketide production, PKS expression had to be down-regulated by promoter attenuation to achieve balance with expression of the accessory proteins needed to support polyketide biosynthesis.     

Cloning, Sequence, and Expression of the L-(+) Lactate Dehydrogenase of Streptococcus bovis

The ldh gene encoding the fructose-1,6-diphosphate-dependent L-(+) lactate dehydrogenase from the ruminal bacterium Streptococcus bovis was cloned and sequenced. A genomic library of S. bovis JB1 DNA was constructed in lambda ZAP II and screened by use of a heterologous probe derived from the cloned Streptococcus mutans ldh gene. Several clones were isolated that contained a common 2.9-kb fragment as determined by restriction analysis. Nucleotide sequence analysis revealed a 987-bp open reading frame with extensive homology to Streptococcus thermophilus and S. mutans ldh nucleic acid and amino acid sequences. Expression of the cloned S. bovis ldh gene in Escherichia coli was confirmed by the ability to complement the ldh mutation of E. coli FMJ39, by using an in-gel activity screen and by enzymatic assay. Increased LDH activity was observed in S. bovis JB1 containing the cloned ldh genes on a multicopy plasmid. Received: 15 October 1996 / Accepted: 3 December 1996     

Analysis of yeast prp20 mutations and functional complementation by the human homologue RCC1, a protein involved in the control of chromosome condensation

Summary A DNA fragment that codes for the 364 amino-terminal amino acid residues of a putative Bacillus subtilis SecA homologue has been cloned using the Escherichia coli SecA gene as a probe. The deduced amino acid sequence showed 58% identity to the aminoterminus of the E. coli SecA protein. A DNA fragment which codes for 275 amino-terminal amino acid residues of the B. subtilis SecA homologue was expressed in E. coli and the corresponding gene product was shown to be recognized by anti-E. coli SecA antibodies. This polypeptide, although only about 30% the size of the E. coli SecA protein, also restored growth of E. coli MM52 (secA ^ts) at the non-permissive temperature and the translocation defect of proOmpA in this mutant was relieved to a substantial extent.     

Chemical synthesis and in vivo hyperexpression of a modular gene coding for Escherichia coli translational initiation factor IF1

Summary An artificial gene encoding the Escherichia coli translational initiation factor IF1 was synthesized based on the primary structure (71 amino acid residues) of the protein. Codons for individual amino acids were selected on the basis of the preferred codon usage found in the structural genes for the initiation factor IF2 of E. coli and Bacillus stearothermophilus, both of which can be expressed at high levels in E. coli cells. We gave the IF1 gene a modular structure by introducing specific restriction enzyme sites into the sequence, resulting in units of three to ten codons. This was conceived to facilitate site-directed mutagenesis of the gene and thus to obtain IF1 with specific amino acid alterations at desired positions. The IF1 gene was assembled by shot-gun ligation of 9 synthetic oligodeoxyri-bonucleotides ranging in size from 31 to 65 nucleotides and cloned into an expression vector to place the gene under the control of an inducible promoter. Upon induction, E. coli cells harbouring the artificial gene were found to produce large amounts (60 mg/100 g cells) of a protein indistinguishable from natural IF1 in both chemecal and biological properties.     

Two closely linked genes encoding thioredoxin and thioredoxin reductase in Clostridium litorale

The genes encoding thioredoxin and thioredoxin reductase of Clostridium litorale were cloned and sequenced. The thioredoxin reductase gene (trxB) encoded a protein of 33.9 kDa, and the deduced amino acid sequence showed 44% identity to the corresponding protein from Escherichia coli. The gene encoding thioredoxin (trxA) was located immediately downstream of trxB. TrxA and TrxB were each encoded by two gene copies, both copies presumably located on the chromosome. Like other thioredoxins from anaerobic, amino-acid-degrading bacteria investigated to date by N-terminal amino acid sequencing, thioredoxin from C. litorale exhibited characteristic deviations from the consensus sequence, e.g., GCVPC instead of WCGPC at the redox-active center. Using heterologous enzyme assays, neither thioredoxin nor thioredoxin reductase were interchangeable with the corresponding proteins of the thioredoxin system from E. coli. To elucidate the molecular basis of that incompatibility, Gly-31 in C. litorale thioredoxin was substituted with Trp (the W in the consensus sequence) by site-directed mutagenesis. The mutant protein was expressed in E. coli and was purified to homogeneity. Enzyme assays using the G31W thioredoxin revealed that Gly-31 was not responsible for the observed incompatibility with the E. coli thioredoxin reductase, but it was essential for activity of the thioredoxin system in C. litorale. Received: 19 September 1996 / Accepted: 21 May 1997