Identification and Characterization of a Bidirectional Promoter from the Intergenic Region between the Human DDX13 and RD Genes

The human DDX13 gene encodes a putative RNA helicase of the DExH-box family. In an earlier report we showed that the human DDX13 and RD genes were arranged head-to-head in the class III MHC complex and their ATG start codons were separated by 745 base pairs. We have now analyzed the common 745 bp intergenic region in detail and characterized their promoters. Northern blot analysis revealed that DDX13 and RD exhibit distinct patterns of steady-state expression among multiple human tissues. The promoter regions for DDX13 and RD genes were identified by deletion analysis from 740 bp to 176 bp of the intergenic region fused to a chloramphenicol acetyltransferase (CAT) reporter gene using transient transfection assays. Results indicated that a promoter sequence as small as 176 bp is sufficient for basal expression of both genes in HeLa and HepG2 cells. Functional analysis using a bidirectional reporter system demonstrates that the sequence 262 bp proximal to the DDX13 gene is sufficient for concurrent expression in both directions. However, the common 740 bp intergenic region showed promoter activity in DDX13 only, suggesting the presence of a negatively acting region for the RD gene within the region -267 to -744. It appears that RD expression is controlled by a complex system of positively and negatively acting elements present on distant portions of both genes.     

Physical mapping of the Escherichia coli D-serine deaminase region: contiguity of the dsd structural and regulatory genes.

The genes dsdA, dsdO, and dsdC have been located on a 3.0-kilobase pair (kb) fragment of the Escherichia coli chromosome by a combination of techniques. The loci were first cloned onto lambda and various plasmid vectors. dsd hybrid plasmids were then digested with restriction enzymes, and the fragments were recloned to test for the presence of dsdC or dsdA. In one case, a 4.2-kb restriction fragment containing the dsdA operon was used to form a heteroduplex with a well-defined lambda dsd deoxyribonucleic acid. The results show that dsdA, dsdO, and at least 0.6 kb of dsdC are present on this piece of deoxyribonucleic acid. On the basis of the mapping analysis and the molecular weight of D-serine deaminase, 1.9 kb of the 4.2-kb fragment is accounted for by the three dsd loci. We conclude that dsdO and dsdC are contiguous. A detailed dsd restriction map is presented.     

Identification of a Binding Region for Human Origin Recognition Complex Proteins 1 and 2 That Coincides with an Origin of DNA Replication

We investigated the binding regions of components of the origin recognition complex (ORC) in the human genome. For this purpose, we performed chromatin immunoprecipitation assays with antibodies against human Orc1 and Orc2 proteins. We identified a binding region for human Orc proteins 1 and 2 in a <1-kbp segment between two divergently transcribed human genes. The region is characterized by CpG tracts and a central sequence rich in AT base pairs. Both, Orc1 and Orc2 proteins are found at the intergenic region in the G(1) phase, but S-phase chromatin contains only Orc2 protein, supporting the notion that Orc1p dissociates from its binding site in the S phase. Sequences corresponding to the intergenic region are highly abundant in a fraction of nascent DNA strands, strongly suggesting that this region not only harbors the binding sites for Orc1 protein and Orc2 protein but also serves as an origin of bidirectional DNA replication.     

Dominance studies with stable merodiploids in the D-serine deaminase system of Escherichia coli K-12

An episome, F32, which carries the genetic markers dsdA(+), the presumed structural gene for d-serine deaminase, dsdC(+), a regulatory locus governing the synthesis of d-serine deaminase, aroC(+), and purC(+) was obtained from strain AB311 of Escherichia coli K-12, and was used to construct appropriate merodiploids with dsdC markers. In all dsdC / dsdC(+) diploids examined, dsdC was found to be cis dominant, trans recessive, to dsdC(+). In two cases, however, the cis dominance was only partial. Moreover, complementation was observed between one of the dsdC markers which is fully cis dominant and one which is partially cis dominant. Because of the size of the dsdC region, the phenotypes of the mutants, and the partial trans dominance of dsdC(+) over some of the dsdC mutations, it is suggested that the dsdC region specifies a product, but that this product does not move with facility through the cytoplasm     

Intergenic DNA sequences flanking the pseudo alpha globin genes of human and chimpanzee.

We have determined the sequence of 2400 base pairs upstream from the human pseudo alpha globin (psi alpha) gene, and for comparison, 1100 base pairs of DNA within and upstream from the chimpanzee psi alpha gene. The region upstream from the promoter of the psi alpha gene shows no significant homology to the intergenic regions of the adult alpha 2 and alpha 1 globin genes. The chimpanzee gene has a coding defect in common with the human psi alpha gene, showing that the product of this gene, if any, was inactivated before the divergence of human and chimpanzee. However the chimpanzee gene contains a normal ATG initiation codon in contrast to the human gene which has GTG as the initiation codon. The psi alpha genes of both human and chimpanzee are flanked by the same Alu family member. The structure and position of this repeat have not been altered since the divergence of human and chimpanzee, and it is at least as well conserved as its immediate flanking sequence. Comparing human and chimpanzee, the 300 bp Alu repeat has accumulated only two base substitutions and one length mutation; the adjacent 300 bp flanking region has accumulated five base substitutions and twelve length mutations.     

Transposon mutagenesis identifies genes which control antimicrobial drug tolerance in stationary-phase Escherichia coli

Tolerance to antimicrobial agents is a universal phenomenon in bacteria which are no longer multiplying or whose growth rate slows. Since slowly multiplying bacteria occur in clinical infections, extended periods of antimicrobial chemotherapy are needed to eradicate these organisms and to achieve cure. In this study, the molecular basis of antibiotic tolerance was investigated using transposon mutagenesis. We screened 5000 Escherichia coli Tn10Cam mutants for reduction of kanamycin tolerance in late stationary phase and found that 4935 mutants were able to grow to late stationary phase. Reduced tolerance was observed in nine mutants which became sensitive to killing by kanamycin. The mutant KS639 was the most sensitive one to kanamycin, and its genome was disrupted in an intergenic region which lies between aldB and yiaW open reading frames. This mutant showed increased sensitivity not only to kanamycin but also to gentamicin, ciprofloxacin and rifampicin. Reduced tolerance of KS639 to kanamycin was also observed in a murine thigh infection model. P1 transduction to the wild type strains confirmed that the intergenic region was responsible for the tolerance of the bacterium to antibiotics. Using PCR-directed one-step gene replacement, we inactivated the genes aldB, yiaW and yiaV. We also deleted the intergenic region. There was no difference in kanamycin tolerance between each mutant (DeltaaldB, DeltayiaW and DeltayiaV) and the parental strain. But the mutant lacking the intergenic region showed reduced tolerance to kanamycin. These data suggest that the intergenic region between aldB and yiaW genes may be involved in tolerance to antimicrobial agents in E. coli. Furthermore, they show that it is important in murine infection during antibiotic treatment and lead to a faster kill of the mutant bacteria.