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W2050386368 abstract "Glycerol dehydrogenase (GDH) is an important polyol dehydrogenase for glycerol metabolism in diverse microorganisms and for value-added utilization of glycerol in the industry. Two GDHs from Klebsiella pneumoniae, DhaD and GldA, were expressed in Escherichia coli, purified and characterized for substrate specificity and kinetic parameters. Both DhaD and GldA could catalyze the interconversion of (3R)-acetoin/(2R,3R)-2,3-butanediol or (3S)-acetoin/meso-2,3-butanediol, in addition to glycerol oxidation. Although purified GldA appeared more active than DhaD, in vivo inactivation and quantitation of their respective mRNAs indicate that dhaD is highly induced by glycerol and plays a dual role in glycerol metabolism and 2,3-butanediol formation. Complementation in K. pneumoniae further confirmed the dual role of DhaD. Promiscuity of DhaD may have vital physiological consequences for K. pneumoniae growing on glycerol, which include balancing the intracellular NADH/NAD+ ratio, preventing acidification, and storing carbon and energy. According to the kinetic response of DhaD to modified NADH concentrations, DhaD appears to show positive homotropic interaction with NADH, suggesting that the physiological role could be regulated by intracellular NADH levels. The co-existence of two functional GDH enzymes might be due to a gene duplication event. We propose that whereas DhaD is specialized for glycerol utilization, GldA plays a role in backup compensation and can turn into a more proficient catalyst to promote a survival advantage to the organism. Revelation of the dual role of DhaD could further the understanding of mechanisms responsible for enzyme evolution through promiscuity, and guide metabolic engineering methods of glycerol metabolism. Glycerol dehydrogenase (GDH) is an important polyol dehydrogenase for glycerol metabolism in diverse microorganisms and for value-added utilization of glycerol in the industry. Two GDHs from Klebsiella pneumoniae, DhaD and GldA, were expressed in Escherichia coli, purified and characterized for substrate specificity and kinetic parameters. Both DhaD and GldA could catalyze the interconversion of (3R)-acetoin/(2R,3R)-2,3-butanediol or (3S)-acetoin/meso-2,3-butanediol, in addition to glycerol oxidation. Although purified GldA appeared more active than DhaD, in vivo inactivation and quantitation of their respective mRNAs indicate that dhaD is highly induced by glycerol and plays a dual role in glycerol metabolism and 2,3-butanediol formation. Complementation in K. pneumoniae further confirmed the dual role of DhaD. Promiscuity of DhaD may have vital physiological consequences for K. pneumoniae growing on glycerol, which include balancing the intracellular NADH/NAD+ ratio, preventing acidification, and storing carbon and energy. According to the kinetic response of DhaD to modified NADH concentrations, DhaD appears to show positive homotropic interaction with NADH, suggesting that the physiological role could be regulated by intracellular NADH levels. The co-existence of two functional GDH enzymes might be due to a gene duplication event. We propose that whereas DhaD is specialized for glycerol utilization, GldA plays a role in backup compensation and can turn into a more proficient catalyst to promote a survival advantage to the organism. Revelation of the dual role of DhaD could further the understanding of mechanisms responsible for enzyme evolution through promiscuity, and guide metabolic engineering methods of glycerol metabolism." @default.
W2050386368 created "2016-06-24" @default.
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W2050386368 date "2014-02-01" @default.
W2050386368 modified "2023-10-14" @default.
W2050386368 title "Glycerol Dehydrogenase Plays a Dual Role in Glycerol Metabolism and 2,3-Butanediol Formation in Klebsiella pneumoniae" @default.
W2050386368 cites W1492178041 @default.
W2050386368 cites W1546729927 @default.
W2050386368 cites W1548296793 @default.
W2050386368 cites W1552421050 @default.
W2050386368 cites W1572651712 @default.
W2050386368 cites W1597833756 @default.
W2050386368 cites W1665267701 @default.
W2050386368 cites W176207218 @default.
W2050386368 cites W1839302127 @default.
W2050386368 cites W1938885369 @default.
W2050386368 cites W1965432666 @default.
W2050386368 cites W1969100331 @default.
W2050386368 cites W1970764403 @default.
W2050386368 cites W1971080541 @default.
W2050386368 cites W1971231926 @default.
W2050386368 cites W1974329558 @default.
W2050386368 cites W1977932968 @default.
W2050386368 cites W1978053930 @default.
W2050386368 cites W1978183957 @default.
W2050386368 cites W1983995167 @default.
W2050386368 cites W1984180361 @default.
W2050386368 cites W1994648539 @default.
W2050386368 cites W1997585861 @default.
W2050386368 cites W2000502765 @default.
W2050386368 cites W2002778647 @default.
W2050386368 cites W2006201076 @default.
W2050386368 cites W2013606850 @default.
W2050386368 cites W2027229485 @default.
W2050386368 cites W2027778481 @default.
W2050386368 cites W2034141747 @default.
W2050386368 cites W2034182301 @default.
W2050386368 cites W2040607414 @default.
W2050386368 cites W2043055543 @default.
W2050386368 cites W2047310551 @default.
W2050386368 cites W2066456328 @default.
W2050386368 cites W2074386261 @default.
W2050386368 cites W2077039846 @default.
W2050386368 cites W2077631222 @default.
W2050386368 cites W2087331674 @default.
W2050386368 cites W2091341764 @default.
W2050386368 cites W2103731920 @default.
W2050386368 cites W2110198171 @default.
W2050386368 cites W2123504916 @default.
W2050386368 cites W2132632499 @default.
W2050386368 cites W2134441341 @default.
W2050386368 cites W2135900956 @default.
W2050386368 cites W2143902746 @default.
W2050386368 cites W2148238625 @default.
W2050386368 cites W2149262008 @default.
W2050386368 cites W2153076508 @default.
W2050386368 cites W2156407455 @default.
W2050386368 cites W2159346837 @default.
W2050386368 cites W2164579471 @default.
W2050386368 cites W2164618978 @default.
W2050386368 cites W2165334600 @default.
W2050386368 cites W2177399548 @default.
W2050386368 cites W4238238834 @default.
W2050386368 doi "https://doi.org/10.1074/jbc.m113.525535" @default.
W2050386368 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/3937674" @default.
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