The ovarian, ecdysterone, and heat-shock-responsive promoters of the Drosophila melanogaster hsp27 gene react very differently to perturbations of DNA sequence.

The effect of various types of DNA sequence alterations on the activity of the ovarian, ecdysterone, and heat-shock-responsive promoters of the Drosophila melanogaster hsp27 gene was studied by P element-mediated germ line transformation. Regions of DNA required for proper expression of the gene under these different conditions were identified. Wild-type levels of transcription during oogenesis are dependent on two elements respectively located within a 64-base-pair (bp) fragment in the transcribed untranslated region and between -227 and -958 bp upstream of the transcription start site. This ovarian expression is particularly sensitive to both chromosomal position effects and an increased distance between the distal upstream promoter element and the TATAA homology. The ecdysterone-mediated expression during metamorphosis is dependent on a 145-bp domain including the TATAA box and additional upstream sequences that augment transcription by two- to five-fold. Finally, sequences necessary for heat shock expression are located much further upstream from hsp27 than those previously found for hsp70, although basal expression was correlated with the presence of more proximal heat shock consensus sequences.

Mitotic chromosome transmission fidelity mutants in Saccharomyces cerevisiae.

We have isolated 136 independent mutations in haploid yeast strains that exhibit decreased chromosome transmission fidelity in mitosis. Eighty-five percent of the mutations are recessive and 15% are partially dominant. Complementation analysis between MATa and MAT alpha isolates identifies 11 chromosome transmission fidelity (CTF) complementation groups, the largest of which is identical to CHL1. For 49 independent mutations, no corresponding allele has been recovered in the opposite mating type. The initial screen monitored the stability of a centromere-linked color marker on a nonessential yeast chromosome fragment; the mitotic inheritance of natural yeast chromosome III is also affected by the ctf mutations. Of the 136 isolates identified, seven were inviable at 37 degrees and five were inviable at 11 degrees. In all cases tested, these temperature conditional lethalities cosegregated with the chromosome instability phenotype. Five additional complementation groups (ctf12 through ctf16) have been defined by complementation analysis of the mutations causing inviability at 37 degrees. Twenty-three of the 136 isolates exhibited growth defects at concentrations of benomyl permissive for the parent strain, and nine appeared to be tolerant of inhibitory levels of benomyl. All of the mutant strains showed normal sensitivity to ultraviolet and gamma-irradiation. Further characterization of these mutant strains will describe the functions of gene products crucial to the successful execution of processes required for aspects of the chromosome cycle that are important for chromosome transmission fidelity in mitosis.

Effects of denaturants at low concentrations on the reversible denaturation of staphylococcal nuclease.

Three very unstable mutant forms of staphylococcal nuclease were used to quantitate the change in the apparent equilibrium constant for reversible denaturation (Kapp) as a function of denaturant concentration for a variety of different denaturing solutes. The value of this equilibrium constant in the absence of denaturant (Kapp,0) was determined by renaturation of the mutant proteins with a combination of glycerol and calcium ion, the latter of which binds at the active site in the native conformation. Because Kapp,0 fell in the easily measurable range between 0.1 and 1, the change in Kapp, and thus the change in free energy (delta Gapp), at very low concentrations of denaturants could be accurately measured. With guanidine hydrochloride (GuHCl), the rate of change of the apparent free energy of denaturation with respect to denaturant concentration (d(delta Gapp)/dCGuHCl or mGuHCl) was found to be remarkably constant down to zero denaturant concentration, even though this value was different for each of the three proteins. Unlike GuHCl, urea exhibited a slightly reduced value of d delta Gapp/dCurea at low concentrations. Results with a number of thiocyanate, perchlorate, and iodide salts confirmed that the Hofmeister series holds for concentrations below 0.1 M; that is, with regard to efficacy as a denaturant SCN- greater than ClO4- greater than I- and Li+,NH4+ greater than Na+,K+. However, all of the chaotropic salts analyzed exhibited markedly increased values of d(delta Gapp)/dCsalt at concentrations below 0.2 M. One possible explanation for these large deviations from a linear relationship between delta Gapp and salt concentration is that weak binding or adsorption of chaotropic anions is occurring at a saturable number of sites in hydrophobic regions of the denatured state.

The CHL 1 (CTF 1) gene product of Saccharomyces cerevisiae is important for chromosome transmission and normal cell cycle progression in G2/M.

We have analyzed the CTF1 gene, identified in a screen for mutants with decreased chromosome transmission fidelity and shown to correspond to the previously identified chl1 mutation. Chl1 null mutants exhibited a 200-fold increase in the rate of chromosome III missegregation per cell division, and near wild-type rates of marker homozygosis on this chromosome by mitotic recombination. Analysis of the segregation of a marker chromosome indicated that sister chromatid loss (1:0 segregation) and sister chromatid non-disjunction (2:0 segregation) contributed equally to chromosome missegregation. A genomic clone of CHL1 was isolated and used to map its physical position on chromosome XVI. Nucleotide sequence analysis of CHL1 revealed a 2.6 kb open reading frame with a 99 kd predicted protein sequence that contained two PEST sequences and was 23% identical to the coding region of a nucleotide excision repair gene, RAD3. Domains of homology between these two predicted protein sequences included a helix-turn-helix motif and an ATP binding site containing a helicase consensus. Mutants lacking the CHL1 gene product are viable and display two striking, and perhaps interrelated, phenotypes: extreme chromosome instability and a delay in cell cycle progression in G2/M. This delay is independent of the cell cycle checkpoint that requires the function of the RAD9 gene.

Beta subunit of rat liver mitochondrial ATP synthase: cDNA cloning, amino acid sequence, expression in Escherichia coli, and structural relationship to adenylate kinase.

The amino acid sequence of all but a few N-terminal residues of the beta subunit of rat liver ATP synthase has been determined from cDNA clones. Rat liver F1-beta is shown to contain 17 amino acid differences from that reported for F1-beta of bovine heart, 2 differences of which involve differences in charge. This may account in part for the observation that bovine heart F1 binds nucleotides with much greater affinity than the rat liver enzyme. Rat liver F1-beta also contains homologous regions with another nucleotide binding protein, adenylate kinase, for which high-resolution structural studies are available. Adjacent to one of these homologous regions is an eight amino acid stretch which bears striking homology to the phosphorylation region of the (Na+,K+)-ATPase. The combination of these two homology regions may constitute at least part of a nucleotide binding domain in F1-beta. Significantly, both rat liver and bovine heart beta contain these regions of homology, whereas the 17 amino acid differences between the two enzymes lie outside this region. The possibility of a second nucleotide binding domain which differs between the two enzymes is discussed. A cDNA clone containing all the regions of homology as well as 11 of the 17 amino acid differences between the bovine heart and rat liver beta subunits has been ligated into the bacterial expression vector pKK223-3. After transformation of a protease-deficient strain of Escherichia coli, this cDNA clone is expressed as a 36-kilodalton protein.(ABSTRACT TRUNCATED AT 250 WORDS)