Premium
Yeast nitrogen catabolite repression is sustained by signals distinct from glutamine and glutamate reservoirs
Author(s) -
FayyadKazan Mohammad,
Feller A.,
Bodo E.,
Boeckstaens M.,
Marini A. M.,
Dubois E.,
Georis I.
Publication year - 2016
Publication title -
molecular microbiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.857
H-Index - 247
eISSN - 1365-2958
pISSN - 0950-382X
DOI - 10.1111/mmi.13236
Subject(s) - catabolite repression , biology , glutamine , glutamate dehydrogenase , psychological repression , glutamine synthetase , glutamate receptor , fed batch culture , biochemistry , yeast , gene , transcriptional regulation , microbiology and biotechnology , amino acid , transcription factor , gene expression , mutant , fermentation , receptor
Summary Nitrogen catabolite repression ( NCR ) is a wide transcriptional regulation program enabling baker's yeast to downregulate genes involved in the utilization of poor nitrogen sources when preferred ones are available. Nowadays, glutamine and glutamate, the major nitrogen donors for biosyntheses, are assumed to be key metabolic signals regulating NCR . NCR is controlled by the conserved TORC 1 complex, which integrates nitrogen signals among others to regulate cell growth. However, accumulating evidence indicate that the TORC 1‐mediated control of NCR is only partial, arguing for the existence of supplementary regulatory processes to be discovered. In this work, we developed a genetic screen to search for new players involved in NCR signaling. Our data reveal that the NADP ‐glutamate dehydrogenase activity of G dh1 negatively regulates NCR ‐sensitive gene transcription. By determining the total, cytoplasmic and vacuolar pools of amino acids, we show that there is no positive correlation between glutamine/glutamate reservoirs and the extent of NCR . While our data indicate that glutamine could serve as initial trigger of NCR , they show that it is not a sufficient signal to sustain repression and point to the existence of yet unknown signals. Providing additional evidence uncoupling TORC 1 activity and NCR , our work revisits the dogmas underlying NCR regulation.