Arabinose-leucine deletion mutants of Escherichia coli B-r

The control of ara gene expression was studied in mutants of Escherichia coli B/r containing deletions which fused the l-arabinose gene complex with the leucine operon (the normal gene order being araDABIOC...leuDCBAO). Complementation experiments with stable merodiploids showed that expression of ara genes cis to araC-leu deletions was controlled by the trans-acting product of the araC gene. Expression of ara genes cis to araB-leu deletions was under leucine control. These studies confirm the existence of a region between genes araC and araB essential for normal activator controlled expression of the ara structural genes. One deletion was characterized as an araO-leu deletion. Its effect on ara gene expression was unique in that ara genes were susceptible to potential regulation by both l-arabinose and leucine. These experiments suggest that two different species of messenger ribonucleic acid (mRNA) may be produced for the ara-leu region as a result of this deletion. One, under l-arabinose-activator control, is initiated in the l-arabinose region; the other, under leucine control, is initiated in the leucine region. The latter indicates that araI can be transcribed. Whether araI is transcribed in the former instance (mRNA made under activator control) remains to be established.     

Constitutive mutations in the controlling site region of the araBAD operon of Escherichia coli B/r that decrease sensitivity to catabolite repression.

Strains of Escherichia coli B/r containing a deletion of the regulatory gene araC are Ara-. Slow-growing revertants of these strains were isolated and designated aralc because they contain a second mutation in a controlling site, aral, that allows for a low level of constitutive expression of the araBAD operon (Englesbert et al., 1969). We mutagenized aralc delta C strains and selected mutants that grow faster in mineral L-arabinose medium. The new mutations, called araXc, map very close to the original aralc mutations and are in the controlling site region between araB and araC. The aralcXc delta C strains have a higher constitutive level of expression of the araBAD operon than the aralc delta C parents. The araXc mutations are cis acting and decrease the araBAD operon's sensitivity to catabolite repression. The araBAD operon is expressed equally well in ara delta C and ara C cya crp backgrounds. The repressor form of ara C protein is able to repress the constitutive synthesis due to the ara Xc allele.     

Determining residue-base interactions between AraC protein and araI DNA

Depurination/depyrimidation binding-interference experiments (missing contact probing) identified specific candidate residue-base interactions lost by mutants of Escherichia coli L-arabinose operon regulatory protein, AraC, to one of its binding sites, araI. These candidates were then checked more rigorously by comparing the affinities of wild-type and alanine-substituted AraC protein to variants of araI with alterations in the candidate contacted positions. Residues 208 and 212 apparently contact DNA and support, but do not prove the existence of a helix-turn-helix structure in this region of AraC protein whereas contacts by mutants with alterations at positions 256, 257 and 261 which are within another potential helix-turn-helix region do not support the existence of such a structure there. The missing contacts displayed by three AraC mutants are found within two major groove regions of the DNA and are spaced 21 base-pairs apart in a pattern indicating a direct repeat orientation for the subunits of AraC.     

Mutations in the L-arabinose operon of Escherichia coli B-r that result in hypersensitivity to catabolite repression

Two independent mutants resistant to l-arabinose inhibition only in the presence of d-glucose were isolated from an l-arabinose-sensitive strain containing the araD139 mutation. Preliminary mapping studies indicate that these mutations are closely linked to the araIOC region. Addition of d-glucose to growing cultures of these mutants results in a 95 to 98% repression of ara operon expression, as compared to a 50% repression of the parental control. Since cultures of both mutant and parental strains undergo a 50% repression of lac operon expression upon addition of glucose, the hypersensitivity to catabolite repression exhibited by these mutants is specific for the ara operon. Addition of cyclic adenosine monophosphate reverses the catabolite repression of the ara operon in both mutant and parent strains to 70 to 80% of the control. It is suggested that in these mutants the affinity of the ara operon initiator region for the cAMP-catabolite-activator protein complex may have been altered.     

Negative regulation of L-arabinose metabolism in Bacillus subtilis: characterization of the araR (araC) gene.

The Bacillus subtilis araC locus, mapped at about 294 degrees on the genetic map, was defined by mutations conferring an Ara- phenotype to strains bearing the metabolic araA, araB, and araD wild-type alleles (located at about 256 degrees on the genetic map) and by mutants showing constitutive expression of the three genes. In previous work, it has been postulated that the gene in which these mutations lie exerts its effect on the ara metabolic operon in trans, and this locus was named araC by analogy to the Escherichia coli regulatory gene. Here, we report the cloning and sequencing of the araC locus. This region comprises two open reading frames with divergently arranged promoters, the regulatory gene, araC, encoding a 41-kDa polypeptide, and a partially cloned gene, termed araE, which most probably codes for a permease involved in the transport of L-arabinose. The DNA sequence of araC revealed that its putative product is very similar to a number of bacterial negative regulators (the GalR-LacI family). However, a helix-turn-helix motif was identified in the N-terminal region by its identity to the consensus signature sequence of another group of repressors, the GntR family. The lack of similarity between the predicted primary structure of the product encoded by the B. subtilis regulatory gene and the AraC regulator from E. coli and the apparently different modes of action of these two proteins lead us to propose a new name, araR, for this gene. The araR gene is monocistronic, and the promoter region contains -10 and -35 regions (as determined by primer extension analysis) similar to those recognized by RNA polymerase containing the major vegetative cell sigma factor sigmaA. An insertion-deletion mutation in the araR gene leads to constitutive expression of the L-arabinose metabolic operon. We demonstrate that the araR gene codes for a negative regulator of the ara operon and that the expression of araR is repressed by its own product.     

Regulatory properties of araC(c) mutants in the L-arabinose operon of escherichia coliB/r.

Merodiploids containing a high-constitutive and a low-constitutive araC(c) allele were assayed for constitutive expression of the ara operon. Low-constitutive araC(c) alleles either were unable to repress the constitutive rate of ara operon expression exhibited by by high-constitutive araC(c) alleles or achieved a partial repression of the high-constitutive rate of operon expression. Either mutation to a low-constitutive araC(c) mutant resulted in a partial or complete loss of repressor function, or subunit mixing between the two araC(c) mutant proteins resulted in a partial or complete dominance of the high-constitutive araC(c) allele. Five of the six araC(c) alleles tested allowed a partial induction of the ara operon in cya crp background. In general, a higher level of ara operon induction was achieved in the cya crp background by high araC(c) alleles than by low araC(c) alleles. Furthermore, several araC(c) mutants exhibited decreased sensitivity to catabolite repression, particularly in the presence of inducer. The results suggest a model in which certain araC(c) gene products can achieve ara operon induction in the presence of either arabinose (inducer) or catabolite activator protein-cyclic adenosine monophosphate, whereas the wild-type araC gene product requires the presence of both of these factors for operon expression.     

Characterization of strong polar mutations in a region immediately adjacent to the L-arabinose operator in Escherichia coli B-r

Seven l-arabinose-negative mutations are described that map in three genetically distinct regions immediately adjacent to the araO (operator) region of the l-arabinose operon. All seven mutants revert spontaneously, exhibit a cis-dominant, trans-recessive polarity effect upon the expression of l-arabinose isomerase (gene araA), and fail to respond to amber, ochre, or UGA suppressors. Three of these mutants exhibit absolute polarity and are not reverted by the mutangens 2-aminopurine, diethyl sulfate, and ICR-191. These may have arisen as a consequence of an insertion mutation in gene araB or in the initiator region of the l-arabinose operon. The four remaining mutants exhibit strong but not absolute polarity on gene araA and respond to the mutagens diethyl sulfate and ICR-191. Three of these mutants are suppressible by two independently isolated suppressors that fail to suppress known nonsense codons. Partially polar Ara(+) revertants with lesions linked to ara are obtained from three of the same four mutants. These polar mutants, their external suppressors, and their partially polar revertants are discussed in terms of the mechanism of initiation of expression of the l-arabinose operon.     

The effect of genomic position on reversion of a lac frameshift mutation (lacIZ33) during non-lethal selection (adaptive mutation)

In a system described by Cairns and Foster, starvation of a particular leaky lac mutant (lacIZ33) in the presence of lactose appears to direct mutation in non-growing cells to sites that allow growth (adaptive mutation). This behaviour requires that the lac operon be located on an F' plasmid. This position effect was investigated by placing the mutant lac operon at many sites in the genome of Salmonella enterica (Typhimurium; LT2) and testing reversion behaviour. Genomic position did not affect reversion during non-selective growth. When lac was at any of 550 chromosomal sites, starvation caused little or no enhancement of reversion. In the 28 strains with the lac on Salmonella's conjugative plasmid (pSLT), selection enhanced reversion strongly, just as seen for strains with lac on an F' plasmid. In 46 strains, the lac operon was inserted within a small chromosomal duplication, and selection stimulated RecA-dependent partial reversion by simple amplification (about 8x) of the mutant lac region. The position of lac on a conjugative plasmid is important to reversion because it allows more frequent gene duplication and amplification. These events are central to growth and reversion under selection because they increase the number of replicating lac alleles within each developing revertant clone.     

Interaction between mutant alleles of araC of the Escherichia coli B/r L-arabinose operon.

Strains were constructed that contain mutational alterations affecting two distinct functional domains within the araC gene protein. The araCi (catabolite repression insensitivity) and araCh (catabolite repression hypersensitivity) mutations were used to alter the catabolite repression sensitivity domain, and mutation to D-fucose resistance was used to alter the inducer binding domain. araCh, D-fucose-resistant double mutants never exhibited constitutive ara operon expression, whereas all of the araCi, D-fucose-resistant double mutants did exhibit constitutivity. When L-arabinose was used as an inducer, most of the double mutants exhibited the sensitivity to catabolite repression associated with the araCi or araCh mutation. However, when D-fucose was used as an inducer, changes in sensitivity to catabolite repression were observed that were attributed to interactions between the two protein domains. The roles of catabolite activator protein and araC gene protein in the induction of the araBAD operon were discussed.     

Cell-free Studies on the Regulation of the Arabinose Operon

A DNA directed, cell-free system which synthesized L-ribulokinase coded by the L-arabinose operon ara OIBAD, has been developed. L-arabinose but not the araC gene product is required for the expression of this operon and, in addition, cyclic AMP and guanosine tetraphosphate are needed for optimal synthesis.     

Expression of E. coli araBAD operon encoding enzymes for metabolizing L-arabinose in Saccharomyces cerevisiae

The Escherichia coli araBAD operon consists of three genes encoding three enzymes that convert L-arabinose to D-xylulose-5 phosphate. In this paper we report that the genes of the E. coli araBAD operon have been expressed in Saccharomyces cerevisiae using strong promoters from genes encoding S. cerevisiae glycolytic enzymes (pyruvate kinase, phosphoglucose isomerase, and phosphoglycerol kinase). The expression of these cloned genes in yeast was demonstrated by the presence of the active enzymes encoded by these cloned genes and by the presence of the corresponding mRNAs in the new host. The level of expression of L-ribulokinase (araB) and L-ribulose-5-phosphate 4-epimerase (araD) in S. cerevisiae was relatively high, with greater than 70% of the activity of the enzymes in wild type E. coli. On the other hand, the expression of L-arabinose isomerase (araA) reached only 10% of the activity of the same enzyme in wild type E. coli. Nevertheless, S. cerevisiae, bearing the cloned L-arabinose isomerase gene, converted L-arabinose to detectable levels of L-ribulose during fermentation. However, S. cerevisiae bearing all three genes (araA, araB, and araD) was not able to produce detectable amount of ethanol from L-arabinose. We speculate that factors such as pH, temperature, and competitive inhibition could reduce the activity of these enzymes to a lower level during fermentation compared to their activity measured in vitro. Thus, the ethanol produced from L-arabinose by recombinant yeast containing the expressed BAD genes is most likely totally consumed by the cell to maintain viability.     

Burkholderia thailandensis: biological properties, identification and taxonomy

Burkholderia pseudomallei-like microorganisms have been isolated from soil and water in regions with endemic melioidosis. These strains have biochemical and antigenic profiles identical to melioidosis agents, except that they differ by virulence and L-arabinose (vir-, ara+). There are minor differences between these species by rRNA sequence. DNA hybridization and, more so, positive transformation of DNA auxotrophic mutants of B. pseudomallei by cell lysates of B. thailandensis and B. mallei confirmed the homology of these species' genomes. These members of the Burkholderia genus (pseudomallei, mallei, and thailandensis) can be regarded as a supraspecies taxon: pseudomallei group. B. thailandensis strains are not virulent for guinea pigs and slightly virulent for golden hamsters. Immunization with live cultures of B. thailandensis protected more than 50% guinea pigs challenged with 200 LD50 B. pseudomallei 100. B. thailandensis is suggested as a potential melioidosis vaccine.     

Multiple loci of Pseudomonas syringae pv. syringae are involved in pathogenicity on bean: restoration of one lesion-deficient mutant requires two tRNA genes.

A mutational analysis of lesion-forming ability was undertaken in Pseudomonas syringae pv. syringae B728a, causal agent of bacterial brown spot disease of bean. Following a screen of 6,401 Tn5-containing derivatives of B728a on bean pods, 26 strains that did not form disease lesions were identified. Nine of the mutant strains were defective in the ability to elicit the hypersensitive reaction (HR) and were shown to contain Tn5 insertions within the P. syringae pv. syringae hrp region. Ten HR+ mutants were defective in the production of the toxin syringomycin, and a region of the chromosome implicated in the biosynthesis of syringomycin was deleted in a subset of these mutants. The remaining seven lesion-defective mutants retained the ability to produce protease and syringomycin. Marker exchange mutagenesis confirmed that the Tn5 insertion was causal to the mutant phenotype in several lesion-defective, HR+ strains. KW239, a lesion- and syringomycin-deficient mutant, was characterized at the molecular level. Sequence analysis of the chromosomal region flanking the Tn5 within KW239 revealed strong similarities to a number of known Escherichia coli gene products and DNA sequences: the nusA operon, including the complete initiator tRNA(Met) gene, metY; a tRNA(Leu) gene; the tpiA gene product; and the MrsA protein. Removal of sequences containing the two potential tRNA genes prevented restoration of mutant KW239 in trans. The Tn5 insertions within the lesion-deficient strains examined, including KW239, were not closely linked to each other or to the lemA or gacA genes previously identified as involved in lesion formation by P. syringae pv. syringae.