Topic
Growth medium
About: Growth medium is a research topic. Over the lifetime, 1889 publications have been published within this topic receiving 59171 citations. The topic is also known as: culture medium & culture media.
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TL;DR: These studies indicated that MI and glucose shared the same transporter system and the uptake and function of solutes such as MI in tissues that operate on the glucose carrier system may be severely impaired in diabetes.
Abstract: Long term and acute effects of glucose on myo-inositol (MI) uptake were studied in primary cultures of bovine retinal pigment epithelial (RPE) cells. RPE cells were grown under low (5 mM) or high (20, 40, or 50 mM) glucose levels in the growth medium for up to 18 days. The concentrative capacity of confluent RPE cells to accululate [3H]MI (10 microM) was reduced up to 41% as the glucose concentration in the growth medium increased. When the growth medium glucose was switched from 5 to 40 mM, or vice versa, the capacity of cells to accumulate MI was reversed. Treatment of cells grown in 40 or 50 mM glucose with 0.1 mM Sorbinil (an aldose reductase inhibitor) minimally reversed the ability of cells to accumulate MI. RPE cells, grown in 5 mM glucose, were incubated with 10-60 mM D-glucose or its nonmetabolizable analogues (acute effect). Kinetics of MI uptake inhibition by alpha-methyl glucose according to Dixon plots were characteristic of competitive inhibition (Ki = 28 mM). MI uptake was strongly inhibited by phlorizin. The ability of RPE cells to bind 5 microM [3H]phlorizin also was reduced by increased glucose levels in the growth medium. These studies indicated that MI and glucose shared the same transporter system. Glucose in the incubation medium directly interfered with MI binding to the transporter. High glucose feeding of the cells also down-regulated the transporter density. The uptake and function of solutes such as MI in tissues that operate on the glucose carrier system may be severely impaired in diabetes.
20 citations
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TL;DR: It is concluded that cells of E. coli growing in minimal medium normally possess a functional excess of valyl-tRNA synthetase with respect to protein synthesis and to repression of threonine deaminase.
Abstract: Escherichia coli strain NP2907 was isolated as a spontaneous mutant of strain NP29, which possesses a thermolabile valyl-transfer ribonucleic acid (tRNA) synthetase. The valyl-tRNA synthetase of the new mutant, unlike that of its immediate parent, retains enzymatic activity in vitro but differs from the wild-type enzyme in stability and apparent Km for adenosine triphosphate. The new mutant locus, valS-102, cotransduces with pyrB at the same frequency as does the parental locus, valS-1. Cultures of strain NP29 cease growth immediately in any medium when shifted from 30 to 40 C. The new mutant grows normally at 30 C, and upon a shift to 40 C growth quickly accelerates exactly as for normal cells. Exponential growth, however, cannot be sustained at 40 C. At a point characteristic for each medium, growth becomes linear with time. This transition occurs almost immediately in rich media and after 1.5 generations in glucose minimal medium. Net synthesis of valyl-tRNA synthetase ceases in the new mutant as soon as the temperature is raised to 40 C, irrespective of the growth medium. We conclude that it is the amount of valyl-tRNA synthetase activity that limits the rate of growth in the linear phase at 40 C. This property of the mutant makes it possible to evaluate the in vivo efficiency of this enzyme at different growth rates and thereby to determine the concentration that is necessary for a given rate of protein synthesis. The results of our measurements indicate that cells of E. coli growing in minimal medium normally possess a functional excess of valyl-tRNA synthetase with respect to protein synthesis and to repression of threonine deaminase.
20 citations
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TL;DR: Results indicate that the genetic regulatory system operates to express the structural genes even at low pH, though the expression of repressible acid phosphatase is interrupted, and combined experiments of temperature and pH shifts with the temperature-sensitive mutants of the regulatory genes suggest that the acidic pH affects the function of the cytoplasmic products of those genes in the expression the structural gene.
Abstract: When the pH of growth medium containing a limited amount of inorganic phosphate is kept below 3.0, cells of Saccharomyces cerevisiae produce repressible alkaline phosphatase but no repressible acid phosphatase. The same cells produce acid phosphatase immediately on shifting the medium pH to 4.0 or above. Like intact cells, spheroplasts prepared from cells grown at pH 3.0 or 4.5 in medium with a limited amount of inorganic phosphate in suspension begin production of acid phosphatase immediately after pH shift from below 3.0 to 4.0 whereas sheroplasts from cells grown in inorganic phosphate-rich medium showed a prolonged lag period (3 h). The enzyme formation on the pH shift was sensitive to cycloheximide. No significant differences could be detected in cellular growth or in incorporation of 3H-L-lysine or 14C-adenine between cells cultivated at pH 3.0 and 4.5. These results along with the fact that the expression of structural genes of repressible acid and alkaline phosphatases is controlled by a common genetic regulatory system, at least in part, indicate that the genetic regulatory system operates to express the structural genes even at low pH, though the expression of repressible acid phosphatase is interrupted. Coupled experiments of temperature and pH shifts with the temperature-sensitive mutants of the regulatory genes suggest that the acidic pH affects the function of the cytoplasmic products of those genes in the expression of the structural gene. Based on these observations, a revised model involving the simultaneous functioning of the regulatory factors was suggested for the genetic regulation of repressible acid phosphatase synthesis.
20 citations
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TL;DR: The results suggest that the growth medium of S. anulatus has a fundamental role in the ability of the spores to induce inflammatory responses and cytotoxicity in mammalian cells.
Abstract: Epidemiological studies have shown an association between microbial growth in buildings and increased risk of respiratory symptoms and disease related to inflammatory reactions in the inhabitants96. The current study examined the affects of growth conditions of Streptomyces anulatus, isolated from indoor air of a moldy building, on the inflammatory potential of spores of this microbe. Spores were harvested from 15 growth media formulations, applied to RAW264.7 macrophages (10(5), 10(6), or 10(7) spores/million cells), and evaluated for the ability to stimulate production of inflammatory mediators and cytotoxicity in these cells 24 h after exposure. Streptomyces anulatus spores induced dose-dependent production of nitric oxide (NO) in macrophages, reaching a level from 4.2 microM to 39.2 microM depending on the composition of the growth medium of the microbe. Expression of inducible NO synthase (iNOS) was detected in macrophages after exposure to spores collected from all growth media. Production of reactive oxygen species (ROS) was significantly increased only by the highest dose of S. anulatus spores grown on glycerol-arginine agar. Furthermore production of cytokines was affected by growth medium; the highest dose-dependent levels of interleukin 6 (IL-6) ranged from 900 to 7800 pg/ml, and the levels of tumor necrosis factor alpha (TNFalpha) varied from 490 to 3200 pg/ml. The amount of dead macrophages after the exposure varied from 11% to 96%, depending also on the growth media of the microbe. Altogether, our results suggest that the growth medium of S. anulatus has a fundamental role in the ability of the spores to induce inflammatory responses and cytotoxicity in mammalian cells.
20 citations
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TL;DR: It is proposed that cellular proteolysis involves at least three mechanisms: induced autophagy; basal proteolysin occurring in lysosomes; and a neutral proteolytic mechanism that insulin inhibits the first at the initial presequestration stage, and NH 4 + inhibits thefirst two at a final intravacuolar proteolyses step.
20 citations