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Regulation of sulfate transport by trans inhibition and inositol limitation in neurospora crassa


, : Regulation of sulfate transport by trans inhibition and inositol limitation in neurospora crassa. Abstracts of the Annual Meeting of the American Society for Microbiology 73: 173



Accession: 027288786

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Related references

Reinert, W.R.; Marzluf, G.A., 1974: Regulation of sulfate metabolism in Neurospora crassa: transport and accumulation of glucose 6-sulfate. Biochemical Genetics 12(2): 97-108

Jarai, G.; Marzluf, G.A., 1991: Sulfate transport in Neurospora crassa: regulation, turnover, and cellular localization of the CYS-14 protein. Uptake of inorganic sulfate in Neurospora crassa is governed by the sulfur regulatory circuit and is under the control of positively and negatively acting regulatory genes. Two genetically and biochemically distinct systems are responsible for the...

Marzluf, G.A., 1973: Regulation of sulfate transport in neurospora by transinhibition and by inositol depletion. Neurospora possesses two distinct sulfate transport systems, a low-affinity form (Permease I) which is the only type found in conidia, and a second species (Permease II) which predominates during the mycelial stage. Although methionine represses t...

Scarborough, Ga, 1971: Sugar transport in Neurospora crassa. III. An inositol requirement for the function of the glucose active transport system. Germination of conidia of an inositol-requiring strain of Neurospora crassa on fructose plus inositol leads to the appearance of a previously described glucose active transport system. Removal of inositol from the growth medium leads to a decline...

Scarborough, G.A., 1971: Sugar transport in Neurospora crassa. 3. An inositol requirement for the function of the glucose active transport system. Biochemical and Biophysical Research Communications 43(5): 968-975

Scarborough G.A., 1971: Sugar transport in neurospora crassa part 3 an inositol requirement for the function of the glucose active transport system. Biochemical & Biophysical Research Communications 43(5): 968-975

Reinert, W.; Marzluf, G., 1974: Regulation of sulfate metabolism in Neurospora crassa: Tra nsport and accumulation of glucose 6-sulfate. Biochemical genetics: 12 (2) 97-108

Huschka, H.G.; Winkelmann, G., 1989: Iron limitation and its effect on membrane proteins and siderophore transport in Neurospora crassa. Cells of the fungus Neurospora crassa were grown under iron-deficient and iron-sufficient conditions and their plasma membrane proteins were compared. Three strains were studied: N. crassa 74A (wild type), a siderophore-free mutant N. crassa (arg-...

Marzluf, G.A., 1970: Genetic and metabolic controls for sulfate metabolism in neurospora crassa isolation and study of chromate resistant and sulfate transport negative mutants. Journal of Bacteriology 102(3): 716-721

Marzluf, G.A., 1970: Genetic and metabolic controls for sulfate metabolism in Neurospora crassa: isolation and study of chromate-resistant and sulfate transport-negative mutants. Mutants of Neurospora resistant to chromate were selected and all were found to map at a single genetic locus designated as cys-13. The chromate-resistant mutants grow at a wild-type rate on minimal media but are partially deficient in the transpo...