Ribitol dehydrogenase of Klebsiella aerogenes. Sequence of the structural gene.

The ribitol dehydrogenase gene was cloned from wild-type Klebsiella aerogenes and also from a transducing phage lambda prbt which expresses the rbt operon constitutively. The coding sequence for 249 amino acids is separated from the following D-ribulokinase gene by 31 base pairs containing three stop codons, one of which overlaps the ribosome binding site for D-ribulokinase. Three residues in the amino acid sequence differ from that predicted from the DNA sequence: Asp-212 for Asn-212 is probably a protein sequencing error, but -Ala-Val- for -Ser-Ser- at 146-147 appears to be a 'neutral mutation' that may have arisen during prolonged chemostat selection of a strain that superproduces the enzyme from which the protein sequence was determined.     

Structure of wild-type and mutant repressors and of the control region of the rbt operon of Klebsiella aerogenes.

Pentitol metabolism in Klebsiella aerogenes is encoded by continuous ribitol (rbt) and D-arabitol (dal) operons transcribed in bipolar fashion and sandwiched between long stretches of homologous DNA. The operons are separated by a central control region (2.2 kb) which encodes both the repressors and all the control sequences. The rbt repressor (270 amino acids) shows homology to the Escherichia coli lac repressor and other DNA-binding proteins. It is transcribed from the strand opposite the rbt operon and the intervening control region (254-bp) contains features which reflect the complex regulation. A rbt-constitutive mutant strain used in previous studies of experimental enzyme evolution encodes a truncated rbt-peptide of 133 residues due to a frameshift mutation.     

Engineering of the methylmalonyl-CoA metabolite node of Saccharopolyspora erythraea for increased erythromycin production

Engineering of the methylmalonyl-CoA (mmCoA) metabolite node of the Saccharopolyspora erythraea wild-type strain through duplication of the mmCoA mutase (MCM) operon led to a 50% increase in erythromycin production in a high-performance oil-based fermentation medium. The MCM operon was carried on a 6.8kb DNA fragment in a plasmid which was inserted by homologous recombination into the S. erythraea chromosome. The fragment contained one uncharacterized gene, ORF1; three MCM related genes, mutA, mutB, meaB; and one gntR-family regulatory gene, mutR. Additional strains were constructed containing partial duplications of the MCM operon, as well as a knockout of ORF1. None of these strains showed any significant alteration in their erythromycin production profile. The combined results showed that increased erythromycin production only occurred in a strain containing a duplication of the entire MCM operon including mutR and a predicted stem-loop structure overlapping the 3' terminus of the mutR coding sequence.     

Population changes in a culture of Escherichia coli K12 1EA growing in a ribitol-limited chemostat

Summary The growth of the strain Escherichia coli K12 1EA in a chemostat was limited by ribitol as the source of carbon and energy. Specific activities of ribitol dehydrogenase and D-arabinitol dehydrogenase were assayed to measure expression of the two closely linked catabolic operons rbt and dal. Population changes occuring in a chemostat were analyzed by testing single colony isolates in batch cultures: double constitutive mutant 1EA-A was first selected while later hyperproducing strains of the type 11EA and 111EA synthesizing constitutively 4 times and 8 times more ribitol dehydrogenase, respectively, prevail in the chemostat.     

Molecular structure and genetic stability of human hypoxanthine phosphoribosyltransferase (HPRT) gene duplications.

We have determined the genetic stability of three independent intragenic human HPRT gene duplications and the structure of each duplication at the nucleotide sequence level. Two of the duplications were isolated as spontaneous mutations from the HL60 human myeloid leukemia cell line, while the third was originally identified in a Lesch-Nyhan patient. All three duplications are genetically unstable and have a reversion rate approximately 100-fold higher than the rate of duplication formation. The molecular structures of these duplications are similar, with direct duplication of HPRT exons 2 and 3 and of 6.8 kb (HL60 duplications) or 13.7 kb (Lesch-Nyhan duplication) of surrounding HPRT sequence. Nucleotide sequence analyses of duplication junctions revealed that the HL60-derived duplications were generated by unequal homologous recombination between clusters of Alu repeats contained in HPRT introns 1 and 3, while the Lesch-Nyhan duplication was generated by the nonhomologous insertion of duplicated HPRT DNA into HPRT intron 1. These results suggest that duplication substrates of different lengths can be generated from the human HPRT exon 2-3 region and can undergo either homologous or nonhomologous recombination with the HPRT locus to form gene duplications.     

Tandem duplication. A novel type of triplet repeat instability

Triplet repeat sequence (TRS) inserts containing (CTG.CAG)(n) (17-175 units in length) were tandemly duplicated when propagated in plasmids in Escherichia coli. The products of this novel type of TRS genetic instability are tracts of as many as 34 multiple units, which contain the entire TRS as well as 129 base pairs of nonrepetitive flanking sequence. The duplication process required the presence of two or more TRS-containing units. Close proximity (170 base pairs) of the TRS to the R6K gamma origin of replication of the pUTminiTn5Cm-derived constructs stimulated the tandem duplication process. These events are proposed to occur due to secondary structure formation, stalling of DNA synthesis, and slippage-mediated misalignment of the complementary strands relative to each other during DNA replication. This mechanism may account for the TRS-associated duplications in protein kinase and metalloprotease genes in neuroblastomas and melanomas, as well as the massive repeat expansions in type II triplet repeat neurological diseases.     

Duplication of DNA regions carrying repetitive sequence RSα in Bradyrhizobium japonicum 110

L. D. Kuykendall, M. E. Barnett and J. N. Mathis. 1997. RSα is a repeated DNA sequence found within the nitrogen-fixation gene cluster of Bradyrhizobium japonicum , a symbiotic nitrogen-fixing bacterium that nodulates soybean. Bradyrhizobium japonicum strain 110 spc 4 contains 12 repeats, each located on a separate Xho I DNA restriction fragment between 1.2 and 14 kb in length. Although Fix⁺ and Fix⁻ derivatives of B. japonicum USDA 110 were first reported more than two decades ago, genotypic differentiation, on the basis of RSα hybridization pattern, was reported only recently. Bradyrhizobium japonicum strain USDA 110 had only single copies of the RSα-hybridizing bands, but a particular Fix⁻ derivative, MSDJGl, carried doublets of two distinct Xho I fragments that carry RSα3 and RSα4. In this study, RSα hybridization patterns were analysed further in both Fix⁺ and Fix⁻ derivatives of strain 110 to test for duplication of these particular genomic regions. It was concluded that the duplication, or not, of genetic regions carrying RSα3 and RSα4 in strain USDA 110 derivatives is unrelated to symbiotic nitrogen-fixation ability. Like Fix⁻ MSDJGl, Fix⁺ strain 110 derivatives I-110 and MN-110 had duplications of the Xho I DNA restriction fragments carrying RSα3 and RSα4, but Fix⁻ strain 110 derivative L2–110 lacked these duplications. Thus, it is now clear that Fix⁻ derivatives MSDJG1 and L2–110 arose via distinct genetic mechanisms. Interestingly, Fix⁺ derivatives of strain 110 from the laboratories of Elkan and Hennecke differed in RSα hybridization profile.     

Lowered induction of genetic tandem duplications in Salmonella by the pKM101 plasmid

Summary Selection for 3-amino-1,2,4-triazole (AT) resistance in certain strains of Salmonella typhimurium has been previously shown to select for genetic tandem duplications of the histidine operon. We show here that agents which induce tandem duplications are less effective in such induction in the presence of the pKM101 plasmid. The presence of the plasmid also produces an increase in AT-resistance due to mechanisms other than duplication, presumably because pKM101 produces high levels of error-prone repair. We suggest that high levels of error-prone repair may cause decreases in tandem duplication induction and propose that error-prone repair and tandem duplication may be alternative cellular responses to certain DNA lesions.     

Ribitol and D-arabitol catabolism in Escherichia coli.

In Escherichia coli C, the catabolism of the pentitols ribitol and D-arabitol proceeds through separate, inducible operons, each consisting of a dehydrogenase and a kinase. The ribitol operon is induced in response to ribulose, and the D-arabitol operon is induced in response to D-arabitol. Each operon is under negative control. The genes of the ribitol and D-arabitol operons are very closely linked and lie in a mirror image arrangement, rtlB-rtlA-rtlC-atlC-atlA-atlB, between metG and his on the E. coli chromosome.     

Isolation of novel herpes simplex virus type 1 derivatives with tandem duplications of DNA sequences encoding immediate-early mRNA-5 and an origin of replication.

Two naturally occurring variations of herpes simplex virus type 1 (Patton strain) with novel tandem DNA sequence duplications in the S component were isolated, and the DNA was characterized. These variants were identified among a number of plaque isolates by the appearance of new restriction enzyme fragments that hybridized with radiolabeled DNA from the BamHI Z fragment (map coordinates 0.936 to 0.949) located in the unique S region. One isolate, SP26-3, carried a 3.1-kilobase-pair duplication defined by recombination between a site in the BamHI Z fragment and a site near the origin of replication in the inverted repeat sequence of the S component carried by the EcoRI H fragment. The other isolate, SP22-4, carried a 3.5-kilobase-pair duplication defined by a recombination event between a tandem repeat array in the BamHI Z fragment and a site near the amino terminus of the Vmw175 gene in the S-region inverted repeat sequence contained in the EcoRI K fragment. Both duplicated segments contained the entire immediate early mRNA-5 coding region as well as the origin of replication located in the inverted repeat sequence of the S component. The DNA sequence of each duplication joint was determined.     

Directed evolution of a second xylitol catabolic pathway in Klebsiella pneumoniae.

Klebsiella pneumoniae PRL-R3 has inducible catabolic pathways for the degradation of ribitol and D-arabitol but cannot utilize xylitol as a growth substrate. A mutation in the rbtB regulatory gene of the ribitol operon permits the constitutive synthesis of the ribitol catabolic enzymes and allows growth on xylitol. The evolved xylitol catabolic pathway consists of an induced D-arabitol permease system that also transports xylitol, a constitutively synthesized ribitol dehydrogenase that oxidizes xylitol at the C-2 position to produce D-xylulose, and an induced D-xylulokinase from either the D-arabitol or D-xylose catabolic pathway. To investigate the potential of K. pneumoniae to evolve a different xylitol catabolic pathway, strains were constructed which were unable to synthesize ribitol dehydrogenase or either type of D-xylulokinase but constitutively synthesized the D-arabitol permease system. These strains had an inducible L-xylulokinase; therefore, the evolution of an enzyme which oxidized xylitol at the C-4 position to L-xylulose would establish a new xylitol catabolic pathway. Four independent xylitol-utilizing mutants were isolated, each of which had evolved a xylitol-4-dehydrogenase activity. The four dehydrogenases appeared to be identical because they comigrated during nondenaturing polyacrylamide gel electrophoresis. This novel xylitol dehydrogenase was constitutively synthesized, whereas L-xylulokinase remained inducible. Transductional analysis showed that the evolved dehydrogenase was not an altered ribitol or D-arabitol dehydrogenase and that the evolved dehydrogenase structural gene was not linked to the pentitol gene cluster. This evolved dehydrogenase had the highest activity with xylitol as a substrate, a Km for xylitol of 1.4 M, and a molecular weight of 43,000.     

Carcinogens induce genetic tandem duplications in Salmonella

Extensive studies have shown that chemical carcinogenesis involves an initiation-promotion pattern. A gene amplification model of carcinogenesis predicts that initiation involves induction of a genetic tandem duplication. We use a system developed by Anderson and Roth to select for tandem duplication of the histidine operon of Salmonella typhimurium by selection for resistance to 3-amino-1,2,4-triazole. Evidence reported here shows that, consistent with prediction, 10 carcinogens are all active in inducing tandem duplications. Two toxic noncarcinogens show little or no activity under the conditions used in inducing tandem duplication but azide, a mutagenic noncarcinogen, did show some activity. 9 types of evidence now support the gene amplification initiation-promotion model of carcinogenesis.     

Comprehensive detection of genomic duplications and deletions in the DMD gene,by use of multiplex amplifiable probe hybridization

Duplications and deletions are known to cause a number of genetic disorders, yet technical difficulties and financial considerations mean that screening for these mutations, especially duplications, is often not performed. We have adapted multiplex amplifiable probe hybridization (MAPH) for the screening of the DMD gene, mutations in which cause Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy. MAPH involves the quantitative recovery of specifically designed probes following hybridization to immobilized genomic DNA. We have engineered probes for each of the 79 exons of the DMD gene, and we analyzed them by using a 96-capillary sequencer. We screened 24 control individuals, 102 patients, and 23 potential carriers and detected a large number of novel rearrangements, especially small, one- and two-exon duplications. A duplication of exon 2 alone was the most frequently occurring mutation identified. Our analysis indicates that duplications occur in 6% of patients with DMD. The MAPH technique as modified here is simple, quick, and accurate; furthermore, it is based on existing technology (i.e., hybridization, PCR, and electrophoresis) and should not require new equipment. Together, these features should allow easy implementation in routine diagnostic laboratories. Furthermore, the methodology should be applicable to any genetic disease, it should be easily expandable to cover >200 probes, and its characteristics should facilitate high-throughput screening.     

Length Variation in Mitochondrial DNA of the Minnow Cyprinella Spiloptera

Length differences in animal mitochondrial DNA (mtDNA) are common, frequently due to variation in copy number of direct tandem duplications. While such duplications appear to form without great difficulty in some taxonomic groups, they appear to be relatively short-lived, as typical duplication products are geographically restricted within species and infrequently shared among species. To better understand such length variation, we have studied a tandem and direct duplication of approximately 260 bp in the control region of the cyprinid fish, Cyprinella spiloptera. Restriction site analysis of 38 individuals was used to characterize population structure and the distribution of variation in repeat copy number. This revealed two length variants, including individuals with two or three copies of the repeat, and little geographic structure among populations. No standard length (single copy) genomes were found and heteroplasmy, a common feature of length variation in other taxa, was absent. Nucleotide sequence of tandem duplications and flanking regions localized duplication junctions in the phenylalanine tRNA and near the origin of replication. The locations of these junctions and the stability of folded repeat copies support the hypothesized importance of secondary structures in models of duplication formation.     

Unequal genetic exchange in Escherichia coli tandem duplications may represent a special pathway of homologous recombination

Heterozygous tandem duplications that appear in Escherichia coli conjugation matings segregate different types of haploid and diploid recombinants because of unequal crossing over between sister chromosomes. As shown previously, the frequency of segregants in the extended duplication D104 (approximately 150 kb or more than 3 min of the genetic map) heterozygous for E. coli deo-operon genes (deoA deoB::Tn5/deoC deoD) is not decreased in strains with defective RecBCD and RecF recombination pathways. Analysis of a shorter duplication of this type (approximately 46 kb) showed that the frequency of segregants in the strain recBC sbcBC recF was similar to that in a strain with undamaged system of recombination. Thus, genetic exchange between direct DNA repeats in tandem duplications may follow a special pathway of homologous recombination, which is independent of the recBC and recF genes.     

Isolation of Plaque-Forming, Galactose-Transducing Strains of Phage Lambda

Plaque-forming, galactose-transducing lambda strains have been isolated from lysogens in which bacterial genes have been removed from between the galactose operon and the prophage by deletion mutation.—A second class has been isolated starting with a lysogenic strain which carries a deletion of the genes to the right of the galactose operon and part of the prophage. This strain was lysogenized with a second lambda phage to yield a lysogen from which galactose-transducing, plaque-forming phages were obtained. These plaque-forming phages were found to be genetically unstable, due to a duplication of part of the lambda chromosome. The genetic instability of these partial diploid strains is due to homologous genetic recombindation between the two identical copies of the phage DNA comprising the duplication. The galactose operon and the duplication of phage DNA carried by these strains is located between the phage lambda P and Q genes.     

Genetic and Segregation Analysis of Escherichia coli Strains Containing a Tandem Duplication of the trpD-purB Region of the Chromosome

Genetic and segregation analysis of Escherichia coli strains containing a partial duplication of the trp operon reveal that the 2.5-min-long region trpD-purB is duplicated in tandem in the chromosome. The adjacent loci cysB and fabD are not duplicated. Although one copy of the duplicated region is longer than the maximum size of bacteriophage P1kc transducing fragments, the frequency at which the duplicated segment trpDCBA is transferred by transduction to tonB-trp deletion strains is equal to that observed for transfer of the normal trp operon. This suggests that three-point recombination events believed to account for transduction of long duplications occur as frequently as two-point recombination events believed to account for normal transduction. Cotransduction frequencies of trpDCBA with the duplicated loci tonB, galU, tyrT, and hemA are very similar to those for the trp operon with the same loci. This indicates that normal genetic linkage is maintained during the three-point recombination event. However, purB, which is normally unlinked to trp by transduction, is closely linked to trpDCBA and thus must be near the repeat point of the duplication. Transduction tests with point mutations in the trp operon indicated that the repeat point occurs near the normal boundary between trpE and trpD. Segregation analysis of heterogenotes constructed from tonB-trp deletion strains shows that the frequency at which a marker is lost is approximately proportional to its distance from the repeat point. This finding is consistent with a random, singlesite crossover event during segregation. Several observations indicate that non-reciprocal genetic exchange also occurs between copies of the duplication. Analysis of heterogenotes containing dadR1 and dadR(+) demonstrate that the mutant allele is transdominant.     

Tandem duplications of the histidine operon observed following generalized transduction in Salmonella typhimurium

Unstable merodiploid transductants may be observed among the progeny of certain generalized transductional crosses between complementing mutations in the histidine operon of Salmonella typhimurium. In the presence of a functional recombination system, these transductants are unstable and they segregate His^? clones of both parental genotypes. The properties of these His⁺ transductants suggest that they contain tandem duplications of a region of DNA which includes the histidine operon, such that each copy of the duplication contains one of the two complementing mutations involved in the transduction. Transductional duplications have been observed from 14 pairs of his mutations, but only with complementing pairs of parental mutations. The length of duplicated material may be quite large: two duplications were found to include genetic markers ten minutes removed from the histidine operon on the Salmonella chromosomal map.These transductants appear to arise in a subpopulation of recipient cells which contain pre-existing tandem duplications of the histidine operon. As much as 0.01 to 0.1% of the cell population appears to be tandemly duplicated for a chromosomal region which includes the histidine operon.