Molecular basis for the maximum growth temperature of an obligately psychrophilic yeast, Leucosporidium stokesii.

Cells of the obligately psychrophilic yeast Leucosporidium stokesii were subjected to permissive (15 and 20 degrees C) and restrictive (23 and 25 degrees C) temperatures to determine the event(s) responsible for the low maximum growth temperature of this organism. An investigation of subcellular morphology by nuclear staining revealed that buds formed at 20 degrees C were anucleate but showed nuclear migration within the parent cell. Cells incubated initially at 23 degrees C and then shifted down to a permissive growth temperature of 15 degrees C in the presence of a deoxyribonucleic acid (DNA) synthesis inhibitor, hydroxyurea, confirmed the observation that the anucleate condition of atypical buds was the result of temperature-sensitive DNA synthesis. Concomitantly, the incorporation of labeled adenine into DNA was inhibited at 23 and 25 degrees C. The synthesis of ribonucleic acid, however, was enhanced at 23 degrees C but impaired at 25 degres C. Similarly, protein synthesis was unaffected at either restrictive temperature.

Partial purification and characterization of S-adenosylhomocysteine hydrolase isolated from Saccharomyces cerevisiae.

S-Adenosylhomocysteine (SAH) hydrolase was purified 25-fold from bakers' yeast by chemical methods and column chromatography. The purified enzyme could readily synthesize SAH from adenosine and homocysteine, but could hydrolyze only negligible amounts of SAH. The purified enzyme showed no activity towards S-adenosylmethionine, methylthioadenosine, or adenosine. Several nucleotides, sulfhydryl compounds, and ribose could not replace adenosine or homocysteine in the reaction mixture. SAH could be hydrolyzed by SAH hydrolase if commercial adenosine deaminase was included in the reaction mixture. Under these conditions l-homocysteine could act as a product inhibitor. A number of compounds structurally similar to adenosine and homocysteine were found to inhibit synthesis of SAH from adenosine and homocysteine. The strongest inhibitors were adenine, adenosine-3'-monophosphate, adenosine-2'-monophosphate, adenosine diphosphate, adenosine triphosphate, and adenosine-5'-monophosphate. The biosynthetic and hydrolytic activity of SAH hydrolase in yeast cell ghosts was similar to the activity of the enzyme in vitro.

Metabolic factors affecting enhanced phosphorus uptake by activated sludge.

Activated sludges obtained from the Rilling Road plant located at San Antonio, Tex., and from the Hyperion treatment plant located at Los Angeles, Calif., have the ability to remove all of the orthophosphate normally present in Tucson sewage within 3 hr after being added to the waste water. Phosphorus removal was independent of externally supplied sources of energy and ions, since orthophosphate and (32)P radioactivity were readily removed from tap water, glass-distilled water, and deionized water. Phosphorus uptake by Rilling sludge in the laboratory appears to be wholly biological, as it has an optimum pH range (7.7 to 9.7) and an optimum temperature range (24 to 37 C). It was inhibited by HgCl(2), iodoacetic acid, p-chloromercuribenzoic acid, NaN(3), and 2, 4-dinitrophenol (compounds that affect bacterial membrane permeability, sulfhydryl enzymes, and adenosine triphosphate synthesis). Uptake was inhibited by 1% NaCl but was not affected by 10(-3)m ethylenediaminetetraacetic acid disodium salt (a chelating agent for many metallic ions).

Biological uptake of phosphorus by activated sludge.

The ability of activated sludge to remove phosphates was studied by adding carrier-free (32)P to raw sewage and measuring incorporation of the radioactivity into the cells over a period of time. Radioisotope determinations indicated that 48% of the (32)P radioactivity was removed by 12 hr. However, chemical methods indicated that only 30% of the orthophosphate apparently disappeared from the sewage during this period. Experiments with sludge prelabeled with (32)P indicated that considerable phosphate turnover occurred. The cells released large amounts of radioactivity as they were incorporating fresh phosphates. Starvation in isotonic saline for 18 hr caused the sludge to dump phosphate. When introduced into fresh sewage containing (32)P, the starved sludge removed about 60% of the radioactivity in 6 hr with little phosphate turnover. The ability of sludge to remove (32)P was inhibited approximately 83% by 10(-3)m 2,4-dinitrophenol. This inhibition was at the expense of the cell fraction that contained ribonucleic acid and deoxyribonucleic acid. The sludge cells released orthophosphate when exposed to the chemical agent. Experiments using (45)Ca indicated that calcium phosphate precipitation plays a minor role in phosphate removal under our experimental conditions.

Volutin granules in Zoogloea ramigera.

Zoogloea ramigera, a gram-negative bacterium found in activated sludge, formed volutin granules when excess orthophosphate was added to a phosphate-starved culture. These volutin granules were stainable by hydrogen sulfide after lead acetate treatment and extractable by N-perchloric acid but were not adsorbed by activated charcoal. They appeared to consist of inorganic polyphosphate. Optimum granule formation in the arginine broth required 10 g of glucose, 3 mg of phosphate, and 1 to 20 mg of magnesium per liter of medium. At an Mg(2+) concentration of 1 mg/liter, very large granules appeared which often appeared to fill the cell. An excess of glucose, orthophosphate, or magnesium reduced granule formation. In the absence of sulfate, moderate granulation occurred in arginine broth before the addition of excess orthophosphate; granulation did not increase after the addition of phosphate.

Uptake and utilization of S-adenosyl-L-methionine and S-adenosyl-L-homocysteine in an adenine mutant of Saccharomyces cerevisiae.

An adenine mutant of Saccharomyces cerevisiae was able to utilize S-adenosyl-l-methionine (SAM), S-adenosyl-l-homocysteine (SAH), or adenine as sources for growth and ribonucleic acid (RNA) synthesis. Exogenous SAM or SAH was degraded after entering the cell, and the adenine moiety was reutilized in the endogenous synthesis of the thionium compounds. Part of this endogenous synthesis proceeds from an undetermined de novo system of purine synthesis which contributes significantly to the synthesis of SAM and less so to the RNA purines. Some of the methyl groups of exogenous SAM-methyl-(3)H were incorporated into ribosomal and transfer RNA. Methionine partially antagonized this incorporation. The uptake of SAM-adenine-8-(14)C was not affected by the presence of equal quantities of SAH or adenine in the medium. Exogenous SAM affected the uptake of exogenous SAH-adenine-8-(14)C or adenine-8-(14)C. Exogenous SAH inhibited the uptake of exogenous adenine-8-(14)C.

Effect of L-methionine and S-adenosylmethionine on growth of an adenine mutant of Saccharomyces cerevisiae.

A pink, adenine-requiring yeast utilized adenine, hypoxanthine, or S-adenosylmethionine (SAM), in quantities up to 3 mumoles per 100 ml of medium, as equivalent sources of purine for cell growth, but not methylthioadenosine or S-adenosylhomocysteine. Utilization of SAM for growth was inhibited by the presence of l-methionine in quantities greater than 0.6 mumole per 100 ml of medium. However, 6 mumoles of l-methionine had no effect on growth when adenine or hypoxanthine was the source of purine. These sources also reversed the inhibitory effects of 6 mumoles of the amino acid on the utilization of SAM. The presence of 400 mumoles of the amino acid resulted in some inhibition of growth when the organisms were grown with adenine, hypoxanthine, or adenine plus SAM but had no effect on the total uptake of adenine-8-(14)C. Studies on the uptake of radioactivity from a mixture of SAM-adenine-8-(14)C and (3)H-labeled SAM-methyl indicated that these components were taken into the cells at different rates which were altered by the presence of l-methionine. The fixation of (35)S from (35)S-labeled adenosylmethionine into the cells was inhibited by the presence of the amino acid. The cells synthesized and accumulated SAM in the presence of 400 mumoles of l-methionine plus adenine even when exogenous SAM was supplied. Approximately 47% of radioactivity fixed from exogenous SAM-adenine-8-(14)C and 12% from (3)H-labeled SAM-methyl were found in reisolated SAM.