The araC gene of Citrobacter freundii

The araC gene of Citrobacter freundii was cloned into plasmid pBR322 and expressed in Escherichia coli and Salmonella typhimurium. The nucleotide sequence and the predicted translational product were determined and compared to those of E. coli, S. typhimurium and Erwinia carotovora. The predicted translational product is 281 amino acids (aa) long, identical in size to that of S. typhimurium, and is 11 and 29 aa shorter than that of E. coli and E. carotovora, respectively. The nucleotide sequence of the araC gene of C. freundii is 83% homologous to the araC genes of both E. coli and S. typhimurium, but only 60% homologous to that of E. carotovora with respect to the regions they share. The predicted amino acid sequence is highly conserved and shows 96% and 94% homology to S. typhimurium and E. coli, respectively. E. carotovora shows only a 58% aa homology. The activator and autoregulatory activities of each plasmid encoded AraC protein in a S. typhimurium araC::lacZ protein fusion strain were examined.     

DNA sequence of the araBAD-araC controlling region in Salmonella typhimurium LT2

The araB and araC genes of Salmonella typhimurium have been cloned onto the plasmid pBR322. Restriction analysis and subcloning of restriction fragments localized these genes to a 4.4 kb DNA fragment. Complementation analysis revealed that the cloned araB and araC genes from S. typhimurium complemented araB and araC mutant strains of Escherichia coli. Conversely, cloned araB and araC genes from E. coli complemented araB and araC mutant strains of S. typhimurium. The DNA sequences was determined for the S. typhimurium araB and araC controlling region and for the initially translated portions of these genes. The nucleotide sequence of the araB promoter was 87% homologous with the same region in E. coli and contained no deletions or insertions relative to the E. coli sequence. The presumed AUG codon corresponding to the amino terminus of the S. typhimurium araC protein was in the same location as in E. coli. There was, however, considerable divergence from the E. coli sequence preceding the translation start site. The nucleotide sequence of the initial 237 bp in the open reading frame of the S. typhimurium araC gene was 78% homologous with the same sequence in E. coli. By comparison, the amino acid sequence for this region was 91% conserved.     

Herbicide resistance-endowing ACCase gene mutations in hexaploid wild oat (Avena fatua): insights into resistance evolution in a hexaploid species

Many herbicide-resistant weed species are polyploids, but far too little about the evolution of resistance mutations in polyploids is understood. Hexaploid wild oat (Avena fatua) is a global crop weed and many populations have evolved herbicide resistance. We studied plastidic acetyl-coenzyme A carboxylase (ACCase)-inhibiting herbicide resistance in hexaploid wild oat and revealed that resistant individuals can express one, two or three different plastidic ACCase gene resistance mutations (Ile-1781-Leu, Asp-2078-Gly and Cys-2088-Arg). Using ACCase resistance mutations as molecular markers, combined with genetic, molecular and biochemical approaches, we found in individual resistant wild-oat plants that (1) up to three unlinked ACCase gene loci assort independently following Mendelian laws for disomic inheritance, (2) all three of these homoeologous ACCase genes were transcribed, with each able to carry its own mutation and (3) in a hexaploid background, each individual ACCase resistance mutation confers relatively low-level herbicide resistance, in contrast to high-level resistance conferred by the same mutations in unrelated diploid weed species of the Poaceae (grass) family. Low resistance conferred by individual ACCase resistance mutations is likely due to a dilution effect by susceptible ACCase expressed by homoeologs in hexaploid wild oat and/or differential expression of homoeologous ACCase gene copies. Thus, polyploidy in hexaploid wild oat may slow resistance evolution. Evidence of coexisting non-target-site resistance mechanisms among wild-oat populations was also revealed. In all, these results demonstrate that herbicide resistance and its evolution can be more complex in hexaploid wild oat than in unrelated diploid grass weeds. Our data provide a starting point for the daunting task of understanding resistance evolution in polyploids.     

The regulatory region of the L-arabinose operon: its isolation on a 1000 base-pair fragment from DNA heteroduplexes.

A DNA fragment containing the l-arabinose operon regulatory region of Escherichia coli was purified from DNA heteroduplexes formed between opposite strands of two non-defective ara transducing phage. The phage and arabinose gene orientation is such that the heteroduplex contains two single-stranded “bubbles”. The ara regulatory region and short portions of the flanking araB and araC genes are in the short duplex between the “bubbles”. Extensive regions of homology between the phage genomes allowed nearly half of the DNA renatured from a mixture of the two phage DNAs to be in the form of heteroduplexes. Digestion of the reannealed DNA containing heteroduplexes and homoduplexes with the easily purified, single-strand specific nuclease S₁ yielded the 1000 (1017 ± 20, n = 36) base-pair ara DNA duplex plus half and whole phage-length duplexes. The larger DNA duplexes were selectively precipitated by polyethylene glycol before the final purification by preparative electrophoresis on polyacryl-amide gels. By these methods 10 to 20 μg of the 1000 base-pair DNA fragment were purified.     

Dominant constitutive mutations in malT, the positive regulator gene of the maltose regulon in Escherichia coli.

A series of Escherichia coli strains in which the lacZ gene is fused to any of the three maltose operons were previously isolated (Silhavy et al, 1976, 1977). Starting from one such strain, in which β-galactosidase synthesis is induced by maltose, mutants could be selected which synthesize this enzyme constitutively. Several of these mutants carry a mutation in malT, the positive regulator gene of the maltose system. The mutations, called malT^c, are both cis and trans dominant over wild type. The failure of the malT⁺ product to repress the constitutive expression resulting either from a malT^c mutation (this paper) or from initiator constitutive mutations (Hofnung &; Schwartz 1971) strongly suggests that, in contrast to the l-arabinose system, the maltose system is regulated in a strictly positive manner.     

Sex and the fixation of single favourable mutations

Sexual populations will accumulate favourable mutations more rapidly than asexual populations. This is true if it is often the case that two different favourable mutations can be found to be spreading simultaneously through populations. It is argued here that sexual species will incorporate single favourable mutations more quickly than asexual “species”, if the latter are multi-clonal. Thus one mutation can spread to fixation within a sexual species but in an asexual “species” with N_c clones at least N_c mutations must occur if the mutation is to be subsequently found in every member of the “species”. Asexual “species” may minimise this disadvantage by evolving polyploidy or occasional episodes of hybridisation. Both are in fact common in asexual “species”.     

EnzyBase: a novel database for enzybiotic studies

Background

Staphylococcus aureus (S. aureus) is a major nosocomial pathogen that causes a variety of infections and toxicoses. In recent years, the percentage of rifampicin-resistant S. aureus has increased rapidly in China. The aims of this study were to analyze 1) the level of rifampicin resistance in S. aureus and its correlation with mutations in the rpoB gene, and 2) the molecular characterization of rifampicin-resistant S. aureus isolates.

Results

88 rifampicin-resistant S. aureus isolates were collected for this study. Of the 88 isolates, 83 (94.3%) were high-level rifampicin resistant (MIC??8 mg/L) while the remaining 5 isolates (5.7%) had a low-level resistance to rifampicin (MIC, 2 to 4 mg/L). Four amino acid substitutions were found in the 88 isolates, which were 481His/Asn (95.5%), 466Leu/Ser (87.5%), 477Ala/Asp (6.8%) and 486Ser/Leu (4.5%) respectively. All mutations were found to be present in cluster I of the rpoB gene. The low-level resistant isolates were found to have only one mutation, while the high-level resistant isolates had at least two or more mutations. The most common multiple mutations were 481His/Asn+466Leu/Ser(92.8%,77/83). The other multiple mutations found were 481His/Asn+477Ala/Asp (6.0%,5/83), and 481His/Asn+466Leu/Ser+477Ala/Asp (1.2%,1/83). Out of 28 high-level rifampicin-resistant S. aureus isolates, three molecular types were found, namely, ST239-MRSA-III-spa t030 (25/28, 89.3%), ST239-MRSA-III-spa t021 (2/28, 7.1%), and ST239-MRSA-III-spa t045 (1/28, 3.6%).

Conclusions

Rifampicin resistance in S. aureus was closely associated with mutations in the rpoB gene. High-level rifampicin-resistant S. aureus is one of the most important features in Anhui Provincial Hospital, and high-level rifampicin resistance in S. aureus is associated with multiple mutations of rpoB gene. The prevalence of high-level rifampicin-resistant S. aureus in Anhui may be associated with the spread of the ST239-MRSA III-spa t030 clone.     

Primary structure of the hip gene of Escherichia coli and of its product,the β subunit of integration host factor

We describe the isolation and sequencing of the hip gene of Escherichia coli and show that it encodes the β subunit of integration host factor (IHFβ). In order to locate the coding region, we constructed a set of deletion mutants by exonucleolytic digestion of a fragment containing hip, determined which mutants were hip⁺ and which hip^? by complementation, and then sequenced the ends of the critical deletions. The 5′ end of the coding region was located precisely by comparing the deduced amino acid sequence to the actual N-terminal amino acid sequence of IHF. Our assignment of the coding region was further substantiated by the nucleotide sequences of a hip point mutant and of internal replacement mutations. We found a probable promoter for hip located about 85 base-pairs upstream from the initial AUG codon and about 75 base-pairs downstream from the 3′ end of the neighboring gene. rpsA, and we constructed an IHFβ overproducer by fusing the coding sequences to the λp_L promoter. A survey of known protein sequences revealed a close relationship between IHFβ and the type II prokaryotic DNA binding proteins (the “histone-like” proteins). This relationship is shared to a considerable extent by the other subunit of IHF, IHFα. A hip missense mutation that replaces a completely conserved glycine with aspartate has a null phenotype, suggesting that the conserved regions are functionally important.     

Intragenic and Extragenic Suppressors of Temperature Sensitive Mutations in the Replication Initiation Genes dnaD and dnaB of Bacillus subtilis

Background

The Bacillus subtilis genes dnaD and dnaB are essential for the initiation of DNA replication and are required for loading of the replicative helicase at the chromosomal origin of replication oriC. Wild type DnaD and DnaB interact weakly in vitro and this interaction has not been detected in vivo or in yeast two-hybrid assays.

Methodology/Principal Findings

We isolated second site suppressors of the temperature sensitive phenotypes caused by one dnaD mutation and two different dnaB mutations. Five different intragenic suppressors of the dnaD23ts mutation were identified. One intragenic suppressor was a deletion of two amino acids in DnaD. This deletion caused increased and detectable interaction between the mutant DnaD and wild type DnaB in a yeast two-hybrid assay, similar to the increased interaction caused by a missense mutation in dnaB that is an extragenic suppressor of dnaD23ts. We isolated both intragenic and extragenic suppressors of the two dnaBts alleles. Some of the extragenic suppressors were informational suppressors (missense suppressors) in tRNA genes. These suppressor mutations caused a change in the anticodon of an alanine tRNA so that it would recognize the mutant codon (threonine) in dnaB and likely insert the wild type amino acid (alanine).

Conclusions/Significance

The intragenic suppressors should provide insights into structure-function relationships in DnaD and DnaB, and interactions between DnaD and DnaB. The extragenic suppressors in the tRNA genes have important implications regarding the amount of wild type DnaB needed in the cell. Since missense suppressors are typically inefficient, these findings indicate that production of a small amount of wild type DnaB, in combination with the mutant protein, is sufficient to restore some DnaB function.     

DISSECT Method Using PNA-LNA Clamp Improves Detection of EGFR T790m Mutation

Non-small cell lung cancer (NSCLC) patients treated with small molecule EGFR inhibitors, such as gefitinib, frequently develop drug resistance due to the presence of secondary mutations like the T790M mutation on EGFR exon 20. These mutations may originate from small subclonal populations in the primary tumor that become dominant later on during treatment. In order to detect these low-level DNA variations in the primary tumor or to monitor their progress in plasma, it is important to apply reliable and sensitive mutation detection methods. Here, we combine two recently developed methodologies, Differential Strand Separation at Critical Temperature (DISSECT), with peptide nucleic acid-locked nucleic acid (PNA-LNA) polymerase chain reaction (PCR) for the detection of T790M EGFR mutation. DISSECT pre-enriches low-abundance T790M EGFR mutations from target DNA prior to implementing PNA-LNA PCR, a method that can detect 1 mutant allele in a background of 100–1000 wild type alleles. The combination of DISSECT and PNA-LNA PCR enables the detection of 1 mutant allele in a background of 10,000 wild type alleles. The combined DISSECT-PNA-LNA PCR methodology is amenable to adaptation for the sensitive detection of additional emerging resistance mutations in cancer.     

Point mutations in tox promoter/operator and diphtheria toxin repressor (DTXR) gene associated with the level of toxin production by Corynebacterium diphtheriae strains isolated in Belarus

DNA fragments 129 bp in length containing promoter region of the tox gene from 81 toxigenic strains Corynebacterium diphtheriae were analyzed using the SSCP (single strand conformational polymorphism). We found that only two strains had mutations; the strains also had highest levels of toxin production (over 5120 Vero CD50/ml). Other strains were characterized either as high-level toxin-producing (640-5120 Vero CD50/ml, 41 strains) or low-level toxin-producing (40-320 Vero CD50/ml, 38 strains). Nucleotide sequence analysis revealed single T to C mutations at positions -54 and -184 within -232 - +85 region of tox operon. The first mutation at the -184 position was mapped outside the tox promoter/operator, whereas the second substitution at the -54 position modified the 9-base-pair interrupted palindromic sequence of the tox promoter/operator from ATAATTAGG in the wild-type bacteriophage (to ACAATTAGG in strains with enhanced level of toxin production. Nucleotide sequence analysis of -76 - +681 region of diphtheria toxin repressor (dtxR) gene from 15 strains of C. diphtheriae revealed two missense mutations resulting in amino acid substitutions A 147 V; and L 214 I in the C-terminal region of the DtxR protein. Seven of these strains were identified as high-level toxin-producing and 4 strains, as low-level toxin-producing. In addition, one low-level toxin-producing strain was shown to contain a missense mutation leading to amino acid substitution I 221 T. Three strains, including two highest-level toxin producing strains contained no nucleotide substitutions, as well as the C7(-) strain. The 10 strains belonging to the Sankt-Peterburg and Rossija epidemic ribotypes as well as NCTC 13129 strain (etiologic agent of the diphtheria epidemic outbreak in the Eastern Europe) was shown to contain two mutations A 147 V and L 214 I in the C-terminal region of the DtxR protein.     

Suppressors of the temperature sensitivity of DNA polymerase α mutations in Saccharomyces cerevisiae

We have isolated two high copy, allele-specific suppressors of the temperature sensitivity of mutations in POL1, the gene that encodes the catalytic subunit of DNA polymerase α in the yeast Saccharomyces cerevisiae. Both genes, PSP1 and PSP2, also partially suppressed a mutation in POL3 which encodes DNA polymerase δ, and both also affected a mutation in CDC6, which acts in initiation of DNA replication. Suppression was not general, since ts mutations in several genes unrelated to replication were not affected. PSP1 was partially effective on low-copy-number vectors, while PSP2 required high copy numbers. The presence of suppressing plasmids did not alter the steady-state level of Pol1 protein, so suppression does not appear to be due to an increase in production or stability of Pol1p. Deletion of either PSP gene or both in combination resulted in apparently normal viable cells. While neither gene is homologous to genes with known functions, PSP1 and PSP2 both have unusual amino acid compositions: PSP1 is rich in asparagine and glutamine, while PSP2 is rich in asparagine and contains “RGG” motifs that have been associated with RNA-binding proteins. We also describe a transposon-mediated strategy that should be generally effective for rapid characterization of multicopy suppressors.     

Genetic studies of the lac repressor. X. Analysis of missense mutations in the lacI gene.

Approximately 2000 non-suppressible mutations in the lacI gene of Escherichia coli have been extensively analyzed. The majority consists of missense mutations resulting in amino acid substitutions in the lac repressor. We characterized each mutation with respect to the resulting altered phenotype, and also mapped them against a large set of deletions. The correlation of the genetic and physical map reported previously has been used to localize the part of the protein affected by each mutation with a high degree of precision (within several amino acids). In particular, we examined the distribution of mutational sites along the gene leading to the i^?, i^s, i^r and i^ts phenotypes. Certain regions of the protein, such as the amino-terminal end, are very sensitive to amino acid exchanges with regard to the i^? phenotype, whereas other regions are relatively insensitive to substitutions. Of particular interest is the C-terminal half of the gene-protein map, where many I^s, and I^ts mutational sites cluster in very small regions separated by distinct and nearly regularly spaced intervals. The possible significance of these results with respect to repressor structure and function, and to protein structure in general, is discussed. In the following paper we consider the results reported here together with the data from suppressed nonsense mutations, which are described in the preceding paper.     

Two Novel Mutations on Exon 8 and Intron 65 of COL7A1 Gene in Two Chinese Brothers Result in Recessive Dystrophic Epidermolysis Bullosa

Dystrophic epidermolysis bullosa is an inherited bullous dermatosis caused by the COL7A1 gene mutation in autosomal dominant or recessive mode. COL7A1 gene encodes type VII collagen – the main component of the anchoring fibrils at the dermal–epidermal junction. Besides the 730 mutations reported, we identified two novel COL7A1 gene mutations in a Chinese family, which caused recessive dystrophic epidermolysis bullosa (RDEB). The diagnosis was established histopathologically and ultrastructurally. After genomic DNA extraction from the peripheral blood sample of all subjects (5 pedigree members and 136 unrelated control individuals), COL7A1 gene screening was performed by polymerase chain reaction amplification and direct DNA sequencing of the whole coding exons and flanking intronic regions. Genetic analysis of the COL7A1 gene in affected individuals revealed compound heterozygotes with identical novel mutations. The maternal mutation is a 2-bp deletion at exon 8 (c.1006_1007delCA), leading to a subsequent reading frame-shift and producing a premature termination codon located 48 amino acids downstream in exon 9 (p.Q336EfsX48), consequently resulting in the truncation of 2561 amino acids downstream. This was only present in two affected brothers, but not in the other unaffected family members. The paternal mutation is a 1-bp deletion occurring at the first base of intron 65 (c.IVS5568+1delG) that deductively changes the strongly conserved GT dinucleotide at the 5′ donor splice site, results in subsequent reading-through into intron 65, and creates a stop codon immediately following the amino acids encoded by exon 65 (GTAA→TAA). This is predicted to produce a truncated protein lacking of 1089 C-terminal amino acids downstream. The latter mutation was found in all family members except one of the two unaffected sisters. Both mutations were observed concurrently only in the two affected brothers. Neither mutation was discovered in 136 unrelated Chinese control individuals. This study reveals novel disease-causing mutations in the COL7A1 gene.     

The molecular basis of aminoacylase 1 deficiency

Aminoacylase 1 is a zinc-binding enzyme which hydrolyzes N-acetyl amino acids into the free amino acid and acetic acid. Deficiency of aminoacylase 1 due to mutations in the aminoacylase 1 (ACY1) gene follows an autosomal-recessive trait of inheritance and is characterized by accumulation of N-acetyl amino acids in the urine. In affected individuals neurological findings such as febrile seizures, delay of psychomotor development and moderate mental retardation have been reported. Except for one missense mutation which has been studied in Escherichia coli, mutations underlying aminoacylase 1 deficiency have not been characterized so far. This has prompted us to approach expression studies of all mutations known to occur in aminoacylase 1 deficient individuals in a human cell line (HEK293), thus providing the authentic human machinery for posttranslational modifications. Mutations were inserted using site directed mutagenesis and aminoacylase 1 enzyme activity was assessed in cells overexpressing aminoacylase 1, using mainly the natural high affinity substrate N-acetyl methionine. Overexpression of the wild type enzyme in HEK293 cells resulted in an approximately 50-fold increase of the aminoacylase 1 activity of homogenized cells. Most mutations resulted in a nearly complete loss of enzyme function. Notably, the two newly discovered mutations p.Arg378Trp, p.Arg378Gln and the mutation p.Arg393His yielded considerable residual activity of the enzyme, which is tentatively explained by their intramolecular localization and molecular characteristics. In contrast to aminoacylase 1 variants which showed no detectable aminoacylase 1 activity, aminoacylase 1 proteins with the mutations p.Arg378Trp, p.Arg378Gln and p.Arg393His were also detected in Western blot analysis. Investigations of the molecular bases of additional cases of aminoacylase 1 deficiency contribute to a better understanding of this inborn error of metabolism whose clinical significance and long-term consequences remain to be elucidated.     

Genetic characterization of early amber mutations in the Escherichia coli polA gene and purification of the amber peptides

The PolA1 mutation of Escherichia coli K12 and two further mutations. resA1 and resA2. characterized in E. coli B have been shown to produce enzymatically active nonsense (amber) peptides. These enzymes can be purified to virtual homogeneity by use of the λpolA transducing phage system. The peptides are immunologically related and react weakly hut specifically with antibody to whole DNA polymerase I. In their purified form the peptides are less heat-labile than the whole enzyme or the Klenow fragment produced by proteolysis. Physiological studies indicate that all three alleles are compatible with a number of different streptomycin resistance mutations (rpsL alleles) in a variety of genetic backgrounds. There is, however, clear evidence for slight amounts of “readthrough” of these mutations under these conditions. DNA sequence studies have indicated the exact nucleotides that have been mutated to produce the amber alleles. The resA1 and resA2 alleles appear to be independent isolates of the same mutation both resulting in CAG (Gln) → TAG (amber) at amino acid residue 298. The polA1 mutation results in TGC (Trp) → TAG (amber) at amino acid residue 342. The significance of these findings is discussed with reference to the structure of the whole enzyme as shown by the DNA sequence data of Joyce et al. (1982) and protein chemistry of Brown et al. (1982).     

A Nonadaptive Origin of a Beneficial Trait: In Silico Selection for Free Energy of Folding Leads to the Neutral Emergence of Mutational Robustness in Single Domain Proteins

Proteins are regarded as being robust to the deleterious effects of mutations. Here, the neutral emergence of mutational robustness in a population of single domain proteins is explored using computer simulations. A pairwise contact model was used to calculate the ΔG of folding (ΔG _folding) using the three dimensional protein structure of leech eglin C. A random amino acid sequence with low mutational robustness, defined as the average ΔΔG resulting from a point mutation (ΔΔG _average), was threaded onto the structure. A population of 1,000 threaded sequences was evolved under selection for stability, using an upper and lower energy threshold. Under these conditions, mutational robustness increased over time in the most common sequence in the population. In contrast, when the wild type sequence was used it did not show an increase in robustness. This implies that the emergence of mutational robustness is sequence specific and that wild type sequences may be close to maximal robustness. In addition, an inverse relationship between ??G _average and protein stability is shown, resulting partly from a larger average effect of point mutations in more stable proteins. The emergence of mutational robustness was also observed in the Escherichia coli colE1 Rop and human CD59 proteins, implying that the property may be common in single domain proteins under certain simulation conditions. The results indicate that at least a portion of mutational robustness in small globular proteins might have arisen by a process of neutral emergence, and could be an example of a beneficial trait that has not been directly selected for, termed a “pseudaptation.”