Characterization of Rhodobacter capsulatus genes encoding a molybdenum transport system and putative molybdenum-pterin-binding proteins.

The alternative, heterometal-free nitrogenase of Rhodobacter capsulatus is repressed by traces of molybdenum in the medium. Strains carrying mutations located downstream of nifB copy II were able to express the alternative nitrogenase even in the presence of high molybdate concentrations. DNA sequence analysis of a 5.5-kb fragment of this region revealed six open reading frames, designated modABCD, mopA, and mopB. The gene products of modB and modC are homologous to ChlJ and ChlD of Escherichia coli and represent an integral membrane protein and an ATP-binding protein typical of high-affinity transport systems, respectively. ModA and ModD exhibited no homology to known proteins, but a leader peptide characteristic of proteins cleaved during export to the periplasm is present in ModA, indicating that ModA might be a periplasmic molybdate-binding protein. The MopA and MopB proteins showed a high degree of amino acid sequence homology to each other. Both proteins contained a tandem repeat of a domain encompassing 70 amino acid residues, which had significant sequence similarity to low-molecular-weight molybdenum-pterin-binding proteins from Clostridium pasteurianum. Compared with that for the parental nifHDK deletion strain, the molybdenum concentrations necessary to repress the alternative nitrogenase were increased 4-fold in a modD mutant and 500-fold in modA, modB, and modC mutants. No significant inhibition of the heterometal-free nitrogenase by molybdate was observed for mopA mopB double mutants. The uptake of molybdenum by mod and mop mutants was estimated by measuring the activity of the conventional molybdenum-containing nitrogenase. Molybdenum transport was not affected in a mopA mopB double mutant, whereas strains carrying lesions in the binding-protein-dependent transport system were impaired in molybdenum uptake.     

Mutational analysis of genes of the mod locus involved in molybdenum transport, homeostasis, and processing in Azotobacter vinelandii.

DNA sequencing of the region upstream from the Azotobacter vinelandii operon (modEABC) that contains genes for the molybdenum transport system revealed an open reading frame (modG) encoding a hypothetical 14-kDa protein. It consists of a tandem repeat of an approximately 65-amino-acid sequence that is homologous to Mop, a 7-kDa molybdopterin-binding protein of Clostridium pasteurianum. The tandem repeat is similar to the C-terminal half of the product of modE. The effects of mutations in the mod genes provide evidence for distinct high- and low-affinity Mo transport systems and for the involvement of the products of modE and modG in the processing of molybdate. modA, modB, and modC, which encode the component proteins of the high-affinity Mo transporter, are required for 99Mo accumulation and for the nitrate reductase activity of cells growing in medium with less than 10 microM Mo. The exchange of accumulated 99Mo with nonradioactive Mo depends on the presence of modA, which encodes the periplasmic molybdate-binding protein. 99Mo also exchanges with tungstate but not with vanadate or sulfate. modA, modB, and modC mutants exhibit nitrate reductase activity and 99Mo accumulation only when grown in more than 10 microM Mo, indicating that A. vinelandii also has a low-affinity Mo uptake system. The low-affinity system is not expressed in a modE mutant that synthesizes the high-affinity Mo transporter constitutively or in a spontaneous tungstate-tolerant mutant. Like the wild type, modG mutants only show nitrate reductase activity when grown in > 10 nM Mo. However, a modE modG double mutant exhibits maximal nitrate reductase activity at a 100-fold lower Mo concentration. This indicates that the products of both genes affect the supply of Mo but are not essential for nitrate reductase cofactor synthesis. However, nitrogenase-dependent growth in the presence or absence of Mo is severely impaired in the double mutant, indicating that the products of modE and modG may be involved in the early steps of nitrogenase cofactor biosynthesis in A. vinelandii.     

Regulation of the Escherichia coli glyA gene by the purR gene product.

The purine regulon repressor protein, PurR, was shown to be a purine component involved in glyA regulation in Escherichia coli. Expression of glyA, encoding serine hydroxymethyltransferase activity, was elevated in a purR mutant compared with a wild-type strain. When the purR mutant was transformed with a plasmid carrying the purR gene, the serine hydroxymethyltransferase levels returned to the wild-type level. The PurR protein bound specifically to a DNA fragment carrying the glyA control region, as determined by gel retardation. In a DNase I protection assay, a 24-base-pair region was protected from DNase I digestion by PurR. The glyA operator sequence for PurR binding is similar to that reported for several pur regulon genes.     

Binding of purified wild-type and mutant pi initiation proteins to a replication origin region of plasmid R6K

The three replication origins of the antibiotic resistance plasmid R6K require for their activity in Escherichia coli a DNA segment containing seven 22 base-pair direct repeats and a plasmid-encoded initiation protein (pi). The pi protein functions in the negative control of R6K replication, in addition to its requirement for the initiation of replication. Construction of a plasmid containing the pi structural gene (pir) downstream from the inducible pR promoter of bacteriophage lambda provided high levels of production of pi protein in E. coli. The pi protein was purified and shown to possess general DNA binding properties with a preference for DNA fragments containing the gamma origin of replication, the operator region of the pir gene and the R6K beta-origin region. Velocity sedimentation analysis indicates that the pi protein exists as a dimer in its native form. Agarose gel electrophoresis analysis of pi-gamma-origin complexes suggests that one pi dimer binds to each copy of the 22 base-pair direct repeats in the gamma origin region. Purified mutant pi protein obtained from a temperature-sensitive initiation mutant (pir 105-ts) exhibited temperature-sensitive binding activity to the gamma-origin region, whereas two mutant proteins exhibiting a high copy number phenotype were unaltered (pir104-cop) or slightly reduced (pir1-cop) in binding activity. The patterns of DNase I protection and enhancement were similar for the wild-type and mutant proteins examined.     

Cloning and expression of the human substance K receptor and analysis of its role in mitogenesis.

The primary structure of the human substance K receptor was established from the sequences of complementary DNA clones isolated from a human jejunal complementary DNA library. It consists of 398 amino acids, including seven putative transmembrane regions. The gene for the human substance K receptor was localized to chromosome region 10p13-10q23, a region with frequent chromosomal abnormalities. The human substance K receptor was expressed in transfected NIH-3T3 cells lacking endogenous substance K receptors, and Scatchard analysis of 125I-labeled substance K binding indicates approximately 100,000 receptors/cell with a single dissociation constant of 12 nM. Covalent cross-linking experiments utilizing 125I-substance K and three different chemical cross-linking reagents (disuccinimidyl suberate, disuccinimidyl tartrate, or 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide-HCl) demonstrate an apparent molecular weight of 45,000, consistent with little or no N-linked glycosylation. The binding of substance K to its receptor on transfected cells led to a rapid increase in the production of total inositol phosphates and the release of Ca2+ from internal stores. Growth of the cells transfected with the human substance K receptor is stimulated by the addition of substance K to the medium to a level similar to 10% serum. Therefore, the human substance K receptor can function as a growth factor receptor when expressed in mouse 3T3 cells.     

Adenovirus-induced inhibition of cellular DNase.

During the productive infection of KB cells by adenovirus type 5 (Ad5), there is a progressive decrease in the level of cellular DNase activity towards single-stranded DNA, in contrast to DNA polymerase which remains relatively constant throughout the infection. This decrease is prevented by the inhibition of protein synthesis by cycloheximide. The inhibition of DNase activity does not occur after infection by Ad5 ts125, a DNA-negative mutant which fails to induce the adenovirus-specific DNA binding protein. In contrast, infection by Ad5 ts36, a DNA-negative mutant which complements ts125, does result in decreased levels of DNase. A mechanism is discussed in which the DNA binding protein protects viral replicative intermediates from degradation by cellular DNase.     

Mode of DNA binding by SopA protein of Escherichia coli F plasmid

The binding of SopA to the promoter region of its own gene, in which four copies of SopA's recognition sequence, 5'-CTTTGC-3', are arrayed asymmetrically, was examined in vitro. Titration using electrophoretic mobility shift assay showed that the stoichiometry of SopA protomers to the promoter-region DNA is 4 and that the binding is highly co-operative. The co-operativity was corroborated by EMSA and DNase I footprinting for a number of mutant DNA fragments in which 5'-CTTTGC-3' was changed to 5'-CTTACG-3'. EMSA in the style of circular permutation showed that SopA bends DNA. Mutation at either outermost binding site had a different effect on DNA bending by SopA, reflecting the asymmetry in the arrangement of the binding sites, for which the results of DNase I footprinting were in agreement. Gel filtration chromatography and analytical ultracentrifugation of free SopA showed that the protein can exist as a monomer and oligomers in the absence of ATP. Hence, the results indicate that the co-operativity in SopA's DNA binding is based on its intrinsic protein-protein interaction modified by DNA interaction.