Fatty acylation is important but not essential for Saccharomyces cerevisiae RAS function.

Two proteins in the yeast Saccharomyces cerevisiae that are encoded by the genes RAS1 and RAS2 are structurally and functionally homologous to proteins of the mammalian ras oncogene family. We examined the role of fatty acylation in the maturation of yeast RAS2 protein by creating mutants in the putative palmitate addition site located at the carboxyl terminus of the protein. Two mutations, Cys-318 to an opal termination codon and Cys-319 to Ser-319, were created in vitro and substituted in the chromosome in place of the normal RAS2 allele. These changes resulted in a failure of RAS2 protein to be acylated with palmitate and a failure of RAS2 protein to be localized to a membrane fraction. The mutations yielded a Ras2- phenotype with respect to the ability of the resultant mutants to grow on nonfermentable carbon sources and to complement ras1- mutants. However, overexpression of the ras2Ser-319 product yielded a Ras+ phenotype without a corresponding association of the mutant protein with the membrane fraction. We conclude that the presence of a fatty acyl moiety is important for localizing RAS2 protein to the membrane where it is active but that the fatty acyl group is not an absolute requirement of RAS2 protein function.     

Site-specific recombination promotes plasmid amplification in yeast

All stable, naturally occurring circular yeast DNA plasmids contain a pair of long, nontandem inverted repeats that undergo frequent reciprocal recombination. This yields two plasmid inversion isomers that exist in the cell in equal numbers. In the 2 mu circle plasmid of S. cerevisiae such inversion is catalyzed by a plasmid-encoded site-specific recombinase, FLP. We show that the site-specific recombination system of 2 mu circle enables the plasmid to increase its mean intracellular copy number in yeast cells growing under nonselective conditions. This apparently occurs by a FLP-induced transient shift in the mode of replication from theta to double rolling circle as initially proposed by Futcher. This capability may ensure stable maintenance of the plasmid by enabling it to correct downward deviations in copy number that result from imprecision of the plasmid-encoded partitioning system.     

Identification of the crossover site during FLP-mediated recombination in the Saccharomyces cerevisiae plasmid 2 microns circle.

The FLP protein of the Saccharomyces cerevisiae plasmid 2 microns circle catalyzes site-specific recombination between two repeated segments present on the plasmid. In this paper we present results of experiments we performed to define more precisely the features of the FLP recognition target site, which we propose to designate FRT, and to determine the actual recombination crossover point in vivo. We found that essential sequences for the recombination event are limited to an 8-base-pair core sequence and two 13-base-pair repeated units immediately flanking it. This is the region identified as the FLP binding site in vitro and at which FLP protein promotes specific single-strand cleavages (B. J. Andrews, G. A. Proteau, L. G. Beatty, and P. D. Sadowski, Cell 40:795-803, 1985; J. F. Senecoff, R. C. Bruckner, and M. M. Cox, Proc. Natl. Acad. Sci. USA 82:7270-7274, 1985). Mutations within the core domain can be suppressed by the presence of the identical mutation in the chromatid with which it recombines. However, mutations outside the core are not similarly suppressed. We found that strand exchange during FLP recombination occurs most of the time within the core region, proceeding through a heteroduplex intermediate. Finally, we found that most FLP-mediated events are reciprocal exchanges and that FLP-catalyzed gene conversions occur at low frequency. The low level of gene conversion associated with FLP recombination suggests that it proceeds by a breakage-joining reaction and that the two events are concerted.     

Galactose regulation in Saccharomyces cerevisiae. The enzymes encoded by the GAL7, 10, 1 cluster are co-ordinately controlled and separately translated.

The enzymes for galactose metabolism in Saccharomyces cerevisiae are encoded by three tightly linked genes. Data presented in this paper show that, in contrast to enzymes encoded by other gene clusters in yeast, these three enzymes are translated as separate polypeptides. First, two of the enzymes encoded by the cluster, galactokinase and uridylyl transferase. purified to near homogeneity, are separate polypeptides. Second, no precursor polypeptide-containing sequences common to both these enzymes is detectable in extracts from galactose-induced yeast cells. Third, no partial or absolute polarity of expression of the enzymes is observed in strains containing nonsense mutations in any of the genes of the cluster.Expression of the three galactose metabolic enzymes is co-ordinate, both during induction and during steady-state synthesis. This is true both for wild-type yeast strains and for strains carrying the long-term galactose adaptation mutation, gal3. In GAL3⁺ strains mutations within the galactose gene cluster have no effect on this co-ordinate expression. However, in gal3^? strains, mutations in any of the genes of the cluster completely eliminate expression of the other two genes. These results suggest that the GAL3 gene product is responsible for inducer synthesis and that the actual inducer is an intermediate in galactose metabolism.     

Donor Locus Selection during Saccharomyces Cerevisiae Mating Type Interconversion Responds to Distant Regulatory Signals

Mating type interconversion in homothallic strains of the yeast Saccharomyces cerevisiae results from directed transposition of a mating type allele from one of the two silent donor loci, HML and HMR, to the expressing locus, MAT. Cell type regulates the selection of the particular donor locus to be utilized during mating type interconversion: MATa cells preferentially select HML alpha and MAT alpha cells preferentially select HMRa. Such preferential selection indicates that the cell is able to distinguish between HML and HMR during mating type interconversion. Accordingly, we designed experiments to identify those features perceived by the cell to discriminate HML and HMR. We demonstrate that discrimination does not derive from the different structures of the HML and HMR loci, from the unique sequences flanking each donor locus nor from any of the DNA distal to the HM loci on chromosome III. Moreover, we find that the sequences flanking the MAT locus do not function in the preferential selection of one donor locus over the other. We propose that the positions of the donor loci on the left and right arms of chromosome III is the characteristic utilized by the cell to distinguish HML and HMR. This positional information is not generated by either CEN3 or the MAT locus, but probably derives from differences in the chromatin structure, chromosome folding or intranuclear localization of the two ends of chromosome III.     

Microbial adaptive evolution

Bacterial species can adapt to significant changes in their environment by mutation followed by selection, a phenomenon known as “adaptive evolution.” With the development of bioinformatics and genetic engineering, research on adaptive evolution has progressed rapidly, as have applications of the process. In this review, we summarize various mechanisms of bacterial adaptive evolution, the technologies used for studying it, and successful applications of the method in research and industry. We particularly highlight the contributions of Dr. L. O. Ingram. Microbial adaptive evolution has significant impact on our society not only from its industrial applications, but also in the evolution, emergence, and control of various pathogens.     

Two silicone nontoxic fouling release coatings: Hydrosilation cured PDMS and CaCO3 filled,ethoxysiloxane cured RTV11

Two silicone coatings have been evaluated for barnacle adhesion. One coating is an unfilled hydrosilation cured polydimethylsiloxane (PDMS) network, while the other is a room temperature vulcanized (RTV), filled, ethoxysiloxane cured PDMS elastomer, RTV11^?. The adhesion strength of one species of barnacle, Balanus eburneus, to the hydrosilation coatings is in the range of 0.37–0.60 kg cm^‐2 while the corresponding range for RTV11 is 0.64–0.90 kg cm^‐2. The easier release of B. eburneus from the hydrosilation cured network compared to RTV11 is discussed in relationship to differences in bulk and surface properties. Preliminary results suggest bulk modulus may be the most important parameter in determining barnacle adhesion strength. In light or mechanical property analysis, a re‐evaluation of surface properties and chemical stability is presented.