Abstract
Based on allosteric regulatory properties, NAD+-specific isocitrate dehydrogenase (IDH) is believed to control flux through the tricarboxylic acid cycle in vivo. To distinguish growth phenotypes associated with regulatory dysfunction of this enzyme in Saccharomyces cerevisiae, we analyzed strains expressing well defined mutant forms of IDH or a non-allosteric bacterial NAD+-specific isocitrate dehydrogenase (IDHa). As previously reported, expression of mutant forms of IDH with severe catalytic defects but intact regulatory properties produced an inability to grow with acetate as the carbon source and a dramatic increase in the frequency of generation of petite colonies, phenotypes also exhibited by a strain (idh1Deltaidh2Delta) lacking IDH. Reduced growth rates on acetate medium were also observed with expression of enzymes with severe regulatory defects or of the bacterial IDHa enzyme, suggesting that allosteric regulation is also important for optimal growth on this carbon source. However, expression of IDHa produced no effect on petite frequency, suggesting that the intermediate petite frequencies observed for strains expressing regulatory mutant forms of IDH are likely to correlate with the slight reductions in catalytic efficiency observed for these enzymes. Finally, rates of increase in oxygen consumption were measured during culture shifts from medium with glucose to medium with ethanol as the carbon source. Strains expressing wild-type or catalytically deficient mutant forms of IDH exhibited rapid respiratory transitions, whereas strains expressing regulatory mutant forms of IDH or the bacterial IDHa enzyme exhibited much slower respiratory transitions. This suggests an important physiological role for allosteric activation of IDH during changes in environmental conditions.
Highlights
Yeast isocitrate dehydrogenase (IDH) is an octamer composed of four IDH1 (Mr ϭ 38,001) and four IDH2 (Mr ϭ 37,755) subunits [4]
We have further demonstrated that binding of isocitrate at the catalytic site of IDH2 is necessary for subsequent binding of NADϩ and, analogously, binding of isocitrate at the cooperative site of IDH1 is necessary for subsequent binding of and allosteric activation by AMP [12]
The primary kinetic defect exhibited by the IDH2D286A,I287A mutant enzyme is a ϳ300-fold decrease in apparent Vmax due to a dramatic decrease in affinity for the cofactor NADϩ, whereas the primary kinetic defect exhibited by the IDH1D279A,I280A mutant enzyme is a loss of allosteric regulation by AMP [12, 13]
Summary
Yeast Strains and Cultivation Conditions—The parental yeast strain was MMY011 (MAT␣ ade his leu112, trp can1–100 [22]). Protein Analyses—For affinity purification, transformants of the idh1⌬idh2⌬ strain carrying multicopy plasmids for expression of IDHa with a carboxyl-terminal hexa-histidine tag (pRS426IDHa) or of IDH with a carboxyl-terminal penta-histidine tag on IDH1 (pRS426IDH1/ IDH2 [13]) were precultivated overnight in 150 ml of YNB glucose medium lacking uracil to select for plasmid retention. These cultures were used to inoculate 2.0-liter cultures in YP ethanol medium, a condition that maximizes expression of IDH gene promoters [20]. Protein concentrations were determined using the Bradford method [28] with bovine serum albumin as the standard
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
