Structure-activity relationships of the yeast alpha-factor

The yeast Saccharomyces cerevisiae produces a peptide pheromone, termed the alpha-factor, as a prelude to sexual conjugation. Haploid MAT alpha-cells, but not haploid MAT a-cells or MAT a/alpha-diploids, produce this tridecapeptide of the structure: Trp-His-Trp-Leu-Gln-Leu-Lys-Pro-Gly-Gln-Pro-Met-Tyr. Structural analogues of the alpha-factor have been prepared with alterations in many of the residues, derivatized peptides have been synthesized, and truncated and elongated peptides have been studied. These peptides have been analyzed for their biological activities by various assays. Mutants of S. cerevisiae have been isolated that do not respond to alpha-factor or are supersensitive to the pheromone and its analogues. The mating system of S. cerevisiae provides a powerful model in which genetics, biochemistry, and molecular biology can be used to unravel the mysteries of peptide hormone structure and function.     

Electrorotation of lymphocytes—The influence of membrane events and nucleus

Electrorotation—the spin of cells in rotating high frequency electric fields—has been used to investigate properties of human peripheral blood lymphocytes. The rotation spectra of lymphocytes deviate from those of single shell spheres. The deviations are caused by the electrical properties of the nucleus in the cell interior.Electrorotation allows the distinction between successfully stimulated lymphocytes and unstimulated cells after application of concanavalin A. Notwithstanding the fact that only a proportion of the cells will be mitogenically stimulated we detected an enhanced cell membrane conductivity for the whole cell population immediately after the addition of mitogen.     

Rate theory models for ion transport through rigid pores. I. Time-dependent analysis in the case of vanishing interactions

In this first of a series of papers concerning the theoretical analysis of rate theory models for ion transport through rigid pores, the case of vanishing interactions is investigated. "Rigidity" means that ions crossing membranes through pores see a fixed structure of the pores, not changing in time. A single pore is considered to be a sequence of (n + 1) activation barriers separated by n energy minima. The explicit analytical treatment is restricted to pores with regular internal barrier structure, including the nonequilibrium situation of an applied electric field. In this case the connection with continuum diffusion models is demonstrated by performing in the limit n leads to infinity (n = number of binding sites within the pores) the transition to continuum. Thus, from diffusion equations describing a discrete number of jumps, the corresponding diffusion-like partial differential equations and boundary conditions are generated. For regular pores, from the time dependent solutions of the discrete equations, the corresponding solutions of the continuum equations are explicitly generated. The time-dependent relaxation behaviour of the discrete model is in good agreement with the continuum model if one assumes more than two binding sites in the pores.     

Purification and characterization of hydroxypyruvate reductase from cucumber cotyledons

Hydroxypyruvate reductase (HPR), a marker enzyme of peroxisomes, has been purified to homogeneity from cotyledons of light-grown cucumber seedlings (Cucumis sativus var. Improved Long Green). In addition, the peroxisomal location of both HPR and serine-glyoxylate aminotransferase has been confirmed in cucumber cotyledons. The isolation procedure involved Polymin-P precipitation, a two-step precipitation with ammonium sulfate (35 and 50% saturation), affinity chromatography on Cibacron Blueagarose, and ion-exchange chromatography on DEAE-cellulose. HPR was purified 541-fold to a final specific activity of 525 ± 19 micromoles per minute per milligram of protein. Enzyme homogeneity was established by native and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The native molecular weight was 91 to 95 kilodaltons, approximately double the apparent subunit molecular weight of 40,500 ± 1,400. With hydroxypyruvate as substrate, the pH optimum was 7.1 and K_m values were 62 ± 6 and 5.8 ± 0.7 micromolar for hydroxypyruvate and NADH, respectively. With glyoxylate as substrate, the pH optimum was 6.0, and the K_m values for glyoxylate and NADH were 5700 ± 600 and 2.9 ± 0.5 micromolar, respectively. Antibodies to HPR were raised in mice (by the ascites tumor method) and in rabbits, and their monospecificity was demonstrated by a modified Western blot immunodetection technique.     

Microbodies (Glyoxysomes and Peroxisomes) in Cucumber Cotyledons: Correlative Biochemical and Ultrastructural Study in Light- and Dark-grown Seedlings

The changes in activities of glyoxysomal and peroxisomal enzymes have been correlated with the fine structure of microbodies in cotyledons of the cucumber (Cucumis sativus L.) during the transition from fat degradation to photosynthesis in light-grown plants, and in plants grown in the dark and then exposed to light. During early periods of development in the light (days 2 through 4), the microbodies (glyoxysomes) are interspersed among lipid bodies and contain relatively high activities of glyoxylate cycle enzymes involved in lipid degradation. Thereafter, these activities decrease rapidly as the cotyledons expand and become photosynthetic, and the activity of glycolate oxidase rises to a peak (day 7); concomitantly the microbodies (peroxisomes) become preferentially associated with chloroplasts.     

The Use of Nucleoside Phosphotransferase and (P) p-Nitrophenyl Phosphate in the Determination of the 5'-Linked Termini of Ribosomal RNA

A method for the identification of the 5′-linked termini of ribosomal RNA is described. The method involves the phosphorylation of the nucleosides released from the 5′-linked termini after hydrolysis of the ribonucleic acid chain with alkali. The radioactive 5′-nucleotide derivatives are formed by a nucleoside phosphotransferase mediated phosphoryl transfer from (³²P) p-nitrophenyl phosphate to the nucleosides. The sensitivity of the method allows the use of small amounts of ribosomal RNA.