Rtf1-mediated eukaryotic site-specific replication termination.

The molecular mechanisms mediating eukaryotic replication termination and pausing remain largely unknown. Here we present the molecular characterization of Rtf1 that mediates site-specific replication termination at the polar Schizosaccharomyces pombe barrier RTS1. We show that Rtf1 possesses two chimeric myb/SANT domains: one is able to interact with the repeated motifs encoded by the RTS1 element as well as the elements enhancer region, while the other shows only a weak DNA binding activity. In addition we show that the C-terminal tail of Rtf1 mediates self-interaction, and deletion of this tail has a dominant phenotype. Finally, we identify a point mutation in Rtf1 domain I that converts the RTS1 element into a replication barrier of the opposite polarity. Together our data establish that multiple protein DNA and protein-protein interactions between Rtf1 molecules and both the repeated motifs and the enhancer region of RTS1 are required for site-specific termination at the RTS1 element.

Electron donation to the flavoprotein NifL, a redox-sensing transcriptional regulator.

Transcriptional control of the nitrogen fixation (nif) genes in response to oxygen in Azotobacter vinelandii is mediated by nitrogen fixation regulatory protein L (NifL), a regulatory flavoprotein that modulates the activity of the transcriptional activator nitrogen fixation regulatory protein A (NifA). CD spectra of purified NifL indicate that FAD is bound to NifL in an asymmetric environment and the protein is predominantly alpha-helical. The redox potential of NifL is -226 mV at pH 8 as determined by the enzymic reduction of NifL by xanthine oxidase/xanthine in the presence of appropriate mediators. The reduction of NifL by xanthine oxidase prevented NifL from acting as an inhibitor of NifA. In the absence of electron mediators NifL could also be reduced by Escherichia coli flavohaemoprotein (Hmp) with NADH as reductant. Hmp contains a globin-like domain with haem B as prosthetic group and an FAD-containing oxidoreductase module. The carboxyferrohaem form of Hmp was competent to reduce NifL, suggesting that electron donation to NifL originates from the flavin in Hmp rather than by direct electron transfer from the haem. Spinach ferredoxin:NAD(P) oxidoreductase, which adopts a folding similar to the FAD- and NAD-binding domains of Hmp, also reduced NifL with NADH as reductant. Re-oxidation of NifL occurs rapidly in the presence of air, raising the possibility that NifL might sense intracellular oxygen. We propose a physiological redox cycle in which the oxidation of NifL by oxygen and hence the activation of its inhibitory properties occurs rapidly, in contrast with the switch from the active to the reduced form of NifL, which occurs more slowly.

The redox- and fixed nitrogen-responsive regulatory protein NIFL from Azotobacter vinelandii comprises discrete flavin and nucleotide-binding domains.

Azotobacter vinelandii NIFL is a nitrogen fixation-specific regulatory flavoprotein that modulates the activity of the transcriptional activator NIFA in response to oxygen and fixed nitrogen in vivo. NIFL is also responsive to ADP in vitro. Limited proteolysis of NIFL indicates that it comprises a relatively stable N-terminal domain and a C-terminal domain that is protected from trypsin digestion in the presence of adenosine nucleotides. ATP protects the protein from cleavage in the vicinity of potential nucleotide-binding sites in the C-terminus, whereas ADP protects the entire C-terminal domain. NIFL has an apparent Kd of 130 microM for ATP and 16 microM for ADP. The purified N-terminal domain has an identical UV/visible absorption spectrum to the wild-type protein and is reduced by sodium dithionite, demonstrating that it is a flavin-binding domain. The isolated N-terminal domain does not inhibit NIFA activity. A subdomain fragment containing 160 residues of the C-terminal region, including the nucleotide-binding sites, is also not competent to inhibit NIFA. Removal of the first 146 residues of NIFL, which includes a conserved S-motif (PAS-like domain), found in a large family of sensory proteins from eubacteria, archea and eukarya eliminates the redox response. However, this truncated protein remains competent to inhibit NIFA activity in response to ADP in vitro and to the level of fixed nitrogen in vivo. The redox and nitrogen-sensing functions of A. vinelandii NIFL are therefore separable and are discrete functions of the protein.

Torsional constraints on the formation of open promoter complexes on DNA minicircles carrying sigma 54-dependent promoters.

A topoisomer gel retardation assay has been used to examine the topological requirements for the formation of open promoter complexes on DNA minicircles carrying sigma 54-dependent promoters. In the absence of intercalators, individual topoisomers carrying both the nifL and nifF promoters could be resolved as discrete species by electrophoresis, but exhibited anomalous electrophoretic behavior at relatively high negative superhelical density, indicative of a structural transition. In the presence of phosphorylated activator protein NTRC, ATP, and sigma 54 RNA polymerase holoenzyme, discrete topoisomer shifts were detected associated with the formation of open promoter complexes. At the nifL promoter open complexes could be formed on all negatively supercoiled topoisomers examined as well as on nicked circular DNA, but not on the DeltaLk = 0 topoisomer or positively supercoiled DNA. Minicircles carrying the sigma 54-dependent glnAp2 promoter could not be resolved in the electrophoresis system, but using a combination of potassium permanganate footprinting and topoisomerase I relaxation assays, we found in contrast to the nifL promoter, that open complexes were formed not only on negatively supercoiled topoisomers but also on relaxed minicircles and the Delta Lk = +1 topoisomer. These results indicate there is a thermodynamic barrier to the formation of open complexes on DNA minicircles carrying the nifL promoter which is not evident at glnAp2.

Azotobacter vinelandii NIFL is a flavoprotein that modulates transcriptional activation of nitrogen-fixation genes via a redox-sensitive switch.

The NIFL regulatory protein controls transcriptional activation of nitrogen fixation (nif) genes in Azotobacter vinelandii by direct interaction with the enhancer binding protein NIFA. Modulation of NIFA activity by NIFL, in vivo occurs in response to external oxygen concentration or the level of fixed nitrogen. Spectral features of purified NIFL and chromatographic analysis indicate that it is a flavoprotein with FAD as the prosthetic group, which undergoes reduction in the presence of sodium dithionite. Under anaerobic conditions, the oxidized form of NIFL inhibits transcriptional activation by NIFA in vitro, and this inhibition is reversed when NIFL is in the reduced form. Hence NIFL is a redox-sensitive regulatory protein and may represent a type of flavoprotein in which electron transfer is not coupled to an obvious catalytic activity. In addition to its ability to act as a redox sensor, the activity of NIFL is also responsive to adenosine nucleotides, particularly ADP. This response overrides the influence of redox status on NIFL and is also observed with refolded NIFL apoprotein, which lacks the flavin moiety. These observations suggest that both energy and redox status are important determinants of nif gene regulation in vivo.

Transcriptional activation of the nitrogenase promoter in vitro: adenosine nucleotides are required for inhibition of NIFA activity by NIFL.

The enhancer-binding protein NIFA is required for transcriptional activation of nif promoters by the alternative holoenzyme form of RNA polymerase, which contains the sigma factor sigma 54 (sigma N). NIFA hydrolyzes nucleoside triphosphates to catalyze the isomerization of closed promoter complexes to transcriptionally competent open complexes. The activity of NIFA is antagonized by the regulatory protein NIFL in response to oxygen and fixed nitrogen in vivo. We have investigated the requirement for nucleotides in the formation and stability of open promoter complexes by NIFA and inhibition of its activity by NIFL at the Klebsiella pneumoniae nifH promoter. Open complexes formed by sigma 54-containing RNA polymerase are considerably more stable to heparin challenge in the presence of GTP than in the presence of ATP. This differential stability is most probably a consequence of GTP being the initiating nucleotide at this promoter. Adenosine nucleosides are specifically required for Azotobacter vinelandii NIFL to inhibit open complex formation by native NIFA, and the nucleoside triphosphatase activity of NIFA is strongly inhibited by NIFL under these conditions. We propose a model in which NIFL modulates the activity of NIFA via an adenosine nucleotide switch.

Purification and in vitro activities of the native nitrogen fixation control proteins NifA and NifL.

The prokaryotic enhancer-binding protein NifA stimulates transcription at a distance by binding to sequences upstream of nitrogen fixation (nif) promoters and catalyzing the formation of open promoter complexes by RNA polymerase containing the alternative sigma factor, sigma 54. The activity of NifA in vivo is modulated by the negative regulatory protein NifL in response to environmental oxygen and fixed nitrogen. To date, a detailed biochemical analysis of these proteins from the model diazotroph Klebsiella pneumoniae has been hindered by their insolubility. We have now purified NifA and NifL from Azotobacter vinelandii in their native form. NifA is competent in specific DNA binding, transcriptional activation, and response to negative regulation by NifL in vitro. In contrast to the conserved mechanism of phosphotransfer demonstrated by other two-component regulatory systems, our results support a model in which NifL regulates the activity of NifA via a protein-protein steric block interaction rather than a catalytic modification of NifA.

Substitutions at a single amino acid residue in the nitrogen-regulated activator protein NTRC differentially influence its activity in response to phosphorylation.

Four substitutions at serine residue 160 which increase the activity of the sigma 54-dependent activator protein NTRC in the absence of NTRB have been analysed in detail. Mutagenesis of the putative phosphoacceptor site of NTRC and analysis of double mutants indicate that the positive control function of the S160W and S160C mutants is phosphorylation-dependent, whereas the activity of the S160Y and S160F mutants is phosphorylation-independent. This was confirmed with two purified mutant proteins in vitro. Occupancy of tandem NTRC-binding sites upstream of the Klebsiella pneumoniae nifL promoter by S160W protein is also phosphorylation-dependent in contrast to occupancy by S160F protein, confirming that both the DNA-binding and activator functions of NTRC are influenced by phosphorylation. The S160W and S160C mutants are apparently more responsive than wild-type protein to 'cross-talk' by other members of the histidine protein kinase family but are less responsive to phosphorylation and dephosphorylation mediated by NTRB.

Mouse strain differences in resident peritoneal cells: a flow cytometric analysis.

A flow-cytometric study of resident peritoneal cells among 8 mouse strains showed a more than twofold variation in the ratio of macrophages to macrophages plus lymphocytes, ranging from 27% in A/J to 62% in C57B/L10, with significant strain differences in a number of other cellular parameters. There was a particular deficiency of lymphocytes in strain CBA/N, which carries the xid mutation. Studies of the phagocytosis of fluorescent beads also revealed large differences in the number of beads taken up, ranging from 0.99 per cell in MFI to 1.64 per cell in BALB/c mice in a 20-min period. The total number of peritoneal cells collected also varied between strains, ranging from 2.75 x 10(6) in CBA/Ca to 5.85 x 10(6) in MF1. The total yield of macrophages per mouse ranged from 0.93 x 10(6) in A/J to 3.16 x 10(6) in C57BL/10. These differences should be taken into account when designing experiments which use resident peritoneal cells.

Genetic variation in the response of mice to xenobiotics in vitro. I. General methodology and response to some model compounds.

A new method for studying genetic variation in the response of laboratory mice to xenobiotics using in vitro cultures of somatic cells has been developed. When resident peritoneal cells from ten mouse strains were cultured with methanol, ethanol, dimethylsulphoxide, sodium butyrate, aspirin or trypan blue, each at two dose levels, significant strain differences in response (total protein) were noted for each xenobiotic except methanol, showing that responses are under genetic control. Strain differences in final protein (growth) were also noted. The two alcohols were least toxic, but aspirin was most toxic to strains with fast-growing cells. Most strain means had a gaussian distribution suggesting polygenic control. However a non-gaussian distribution, possibly due to a single dominant resistance gene in C57BL/6 mice, was seen with the 0.6 mm-butyrate. Differential strain responses to various alternatives to foetal bovine serum were also noted. In another study involving 19 mouse strains, the five strains with the Coh(h) or Coh(i) (strain CBA) genotype ranked 1, 2, 3, 4 and 6 in sensitivity to 2.5 mm-coumarin (P < 0.001) and were significantly more sensitive (49.2 +/- 5.9% of controls) than the 13 strains known to have the Coh(l) genotype (65.0 +/- 8.8% of controls). This economical and humane in vitro method may provide a useful new tool for studying the genetics of response to xenobiotics at the cellular level.