monensin and Starvation

monensin has been researched along with Starvation* in 2 studies

Other Studies

2 other study(ies) available for monensin and Starvation

Article	Year
Rumen ciliated protozoa decrease generation time and adjust 18S ribosomal DNA copies to adapt to decreased transfer interval, starvation, and monensin. Journal of dairy science, 2009, Volume: 92, Issue:1 Defaunation studies have documented decreased ammonia concentrations associated with reduced microbial protein recycling and wastage of dietary protein, whereas many methods to suppress protozoa can reduce feed intake or depress ruminal organic matter or fiber digestibility. Therefore, more research is needed to optimize dietary conditions that improve protozoal growth and ruminal outflow relative to autolysis and recycling. Response in growth rate to ruminal outflow was simulated by abrupt changes in transfer interval of batch cultures, and substrate availability was evaluated by feeding without or with abrupt addition of monensin, which was postulated to inhibit digestive vacuole function. In experiment 1, Entodinium caudatum, a mix of Entodinium species, Epidinium caudatum, or Ophryoscolex caudatus cultures rapidly adjusted their generation times to approach respective changes in transfer interval from 3 to 2 or 1 d (cultures were always fed at 24-h intervals). Monensin (0.25 microM) consistently delayed this response. To evaluate a metabolic upshift associated with feeding or a downshift associated with substrate depletion, experiment 2 used real-time PCR to quantify protozoal 18S rRNA gene (rDNA) copies that were expressed relative to cell numbers or to the cellular constituents N and nucleic acids after feeding without or with monensin (0.5 microM). The 18S rDNA copies per milligram of nucleic acids were least for Ophryoscolex compared with the other cultures. When averaged over cultures (no culture x treatment interaction), 18S rDNA copies per unit of nucleic acids decreased at 16 h when cultures were starved but increased with feeding unless monensin uncoupled availability of consumed substrate. Rumen protozoal growth increased in response to decreased transfer interval in experiment 1. Substrate availability appeared to initiate metabolic responses preparing for cell growth, explaining how cultures could rapidly adjust to decreasing transfer interval in experiment 2. Because feeding was not coupled with transfer in experiment 2, however, a metabolic control probably arrested cell division to prevent overgrowth relative to substrate availability. Topics: Animals; Antiprotozoal Agents; Cattle; Cell Division; Ciliophora; Culture Techniques; DNA, Ribosomal; Gene Dosage; Monensin; Regression Analysis; RNA, Ribosomal, 18S; Rumen; Starvation; Time Factors	2009
Transit of alpha-mannosidase during its maturation in Dictyostelium discoideum. The Journal of cell biology, 1985, Volume: 101, Issue:6 We proposed that Dictyostelium discoideum contains two linked pools of mature alpha-mannosidase (Wood, L., R. N. Pannell, and A. Kaplan, 1983, J. Biol. Chem., 258:9426-9430). To obtain physical evidence for these pools, cells were pulse-labeled with [35S]methionine, homogenized, and subjected to Percoll gradient centrifugation. After immune precipitation of alpha-mannosidase, its polypeptides were separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and detected by fluorography. After a 30-min pulse with [35S]methionine, the precursor and small amounts of cleaved enzyme were detected in a low density fraction (1.04 g/ml). Subsequently, cleaved enzyme was transferred to higher density fractions (1.05 and 1.07 g/ml) that were enriched in lysosomal enzymes. The half time for formation of the 1.07 g/ml pool was approximately 45 min, whereas formation of the 1.05 g/ml pool was not detected until 1.5 h after the pulse. The transfer of mature forms out of the 1.04 g/ml pool was inhibited by monensin (3.5 microM). Thus, alpha-mannosidase precursor appears to be cleaved in a prelysosomal organelle. The data also indicate that starving cells secrete precursor directly from this organelle to the extracellular space, whereas cleaved forms are first transferred into lysosomes before they are secreted. Furthermore, 2 h after starvation, the secretion of mature forms ceases even though both transit of mature forms between the two pools and secretion of precursor continues. From this we inferred that the cessation of secretion of mature forms is due to a halt in fusion of lysosomes with the plasma membrane and that precursor follows a different route to the plasma membrane. Topics: alpha-Mannosidase; Biological Transport; Cell Compartmentation; Dictyostelium; Enzyme Precursors; Exocytosis; Kinetics; Lysosomes; Mannosidases; Monensin; Protein Processing, Post-Translational; Starvation; Subcellular Fractions	1985

Article

Year

Rumen ciliated protozoa decrease generation time and adjust 18S ribosomal DNA copies to adapt to decreased transfer interval, starvation, and monensin.

Journal of dairy science, 2009, Volume: 92, Issue:1

Defaunation studies have documented decreased ammonia concentrations associated with reduced microbial protein recycling and wastage of dietary protein, whereas many methods to suppress protozoa can reduce feed intake or depress ruminal organic matter or fiber digestibility. Therefore, more research is needed to optimize dietary conditions that improve protozoal growth and ruminal outflow relative to autolysis and recycling. Response in growth rate to ruminal outflow was simulated by abrupt changes in transfer interval of batch cultures, and substrate availability was evaluated by feeding without or with abrupt addition of monensin, which was postulated to inhibit digestive vacuole function. In experiment 1, Entodinium caudatum, a mix of Entodinium species, Epidinium caudatum, or Ophryoscolex caudatus cultures rapidly adjusted their generation times to approach respective changes in transfer interval from 3 to 2 or 1 d (cultures were always fed at 24-h intervals). Monensin (0.25 microM) consistently delayed this response. To evaluate a metabolic upshift associated with feeding or a downshift associated with substrate depletion, experiment 2 used real-time PCR to quantify protozoal 18S rRNA gene (rDNA) copies that were expressed relative to cell numbers or to the cellular constituents N and nucleic acids after feeding without or with monensin (0.5 microM). The 18S rDNA copies per milligram of nucleic acids were least for Ophryoscolex compared with the other cultures. When averaged over cultures (no culture x treatment interaction), 18S rDNA copies per unit of nucleic acids decreased at 16 h when cultures were starved but increased with feeding unless monensin uncoupled availability of consumed substrate. Rumen protozoal growth increased in response to decreased transfer interval in experiment 1. Substrate availability appeared to initiate metabolic responses preparing for cell growth, explaining how cultures could rapidly adjust to decreasing transfer interval in experiment 2. Because feeding was not coupled with transfer in experiment 2, however, a metabolic control probably arrested cell division to prevent overgrowth relative to substrate availability.

Topics: Animals; Antiprotozoal Agents; Cattle; Cell Division; Ciliophora; Culture Techniques; DNA, Ribosomal; Gene Dosage; Monensin; Regression Analysis; RNA, Ribosomal, 18S; Rumen; Starvation; Time Factors

2009

Transit of alpha-mannosidase during its maturation in Dictyostelium discoideum.

The Journal of cell biology, 1985, Volume: 101, Issue:6

We proposed that Dictyostelium discoideum contains two linked pools of mature alpha-mannosidase (Wood, L., R. N. Pannell, and A. Kaplan, 1983, J. Biol. Chem., 258:9426-9430). To obtain physical evidence for these pools, cells were pulse-labeled with [35S]methionine, homogenized, and subjected to Percoll gradient centrifugation. After immune precipitation of alpha-mannosidase, its polypeptides were separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis and detected by fluorography. After a 30-min pulse with [35S]methionine, the precursor and small amounts of cleaved enzyme were detected in a low density fraction (1.04 g/ml). Subsequently, cleaved enzyme was transferred to higher density fractions (1.05 and 1.07 g/ml) that were enriched in lysosomal enzymes. The half time for formation of the 1.07 g/ml pool was approximately 45 min, whereas formation of the 1.05 g/ml pool was not detected until 1.5 h after the pulse. The transfer of mature forms out of the 1.04 g/ml pool was inhibited by monensin (3.5 microM). Thus, alpha-mannosidase precursor appears to be cleaved in a prelysosomal organelle. The data also indicate that starving cells secrete precursor directly from this organelle to the extracellular space, whereas cleaved forms are first transferred into lysosomes before they are secreted. Furthermore, 2 h after starvation, the secretion of mature forms ceases even though both transit of mature forms between the two pools and secretion of precursor continues. From this we inferred that the cessation of secretion of mature forms is due to a halt in fusion of lysosomes with the plasma membrane and that precursor follows a different route to the plasma membrane.

Topics: alpha-Mannosidase; Biological Transport; Cell Compartmentation; Dictyostelium; Enzyme Precursors; Exocytosis; Kinetics; Lysosomes; Mannosidases; Monensin; Protein Processing, Post-Translational; Starvation; Subcellular Fractions

1985