AUTHOR=Shymansky Christopher M. , Wang George , Baidoo Edward E. K. , Gin Jennifer , Apel Amanda Reider , Mukhopadhyay Aindrila , García Martín Héctor , Keasling Jay D. 

TITLE=Flux-Enabled Exploration of the Role of Sip1 in Galactose Yeast Metabolism

JOURNAL=Frontiers in Bioengineering and Biotechnology

VOLUME=5

YEAR=2017

URL=https://www.frontiersin.org/journals/bioengineering-and-biotechnology/articles/10.3389/fbioe.2017.00031

DOI=10.3389/fbioe.2017.00031

ISSN=2296-4185

ABSTRACT=<p><sup>13</sup>C metabolic flux analysis (<sup>13</sup>C MFA) is an important systems biology technique that has been used to investigate microbial metabolism for decades. The heterotrimer Snf1 kinase complex plays a key role in the preference <italic>Saccharomyces cerevisiae</italic> exhibits for glucose over galactose, a phenomenon known as glucose repression or carbon catabolite repression. The <italic>SIP1</italic> gene, encoding a part of this complex, has received little attention, presumably, because its knockout lacks a growth phenotype. We present a fluxomic investigation of the relative effects of the presence of galactose in classically glucose-repressing media and/or knockout of <italic>SIP1</italic> using a multi-scale variant of <sup>13</sup>C MFA known as 2-Scale <sup>13</sup>C metabolic flux analysis (2S-<sup>13</sup>C MFA). In this study, all strains have the galactose metabolism deactivated (<italic>gal1</italic>Δ background) so as to be able to separate the metabolic effects purely related to glucose repression from those arising from galactose metabolism. The resulting flux profiles reveal that the presence of galactose in classically glucose-repressing conditions, for a CEN.PK113-7D <italic>gal1</italic>Δ background, results in a substantial decrease in pentose phosphate pathway (PPP) flux and increased flow from cytosolic pyruvate and malate through the mitochondria toward cytosolic branched-chain amino acid biosynthesis. These fluxomic redistributions are accompanied by a higher maximum specific growth rate, both seemingly in violation of glucose repression. Deletion of <italic>SIP1</italic> in the CEN.PK113-7D <italic>gal1</italic>Δ cells grown in mixed glucose/galactose medium results in a further increase. Knockout of this gene in cells grown in glucose-only medium results in no change in growth rate and a corresponding decrease in glucose and ethanol exchange fluxes and flux through pathways involved in aspartate/threonine biosynthesis. Glucose repression appears to be violated at a 1/10 ratio of galactose-to-glucose. Based on the scientific literature, we may have conducted our experiments near a critical sugar ratio that is known to allow galactose to enter the cell. Additionally, we report a number of fluxomic changes associated with these growth rate increases and unexpected flux profile redistributions resulting from deletion of <italic>SIP1</italic> in glucose-only medium.</p>