The ADP-dependent Sugar Kinase Family: Kinetic and Evolutionary Aspects
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2009-03-28Metadata
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Guixé Leguía, Victoria Cristina
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The ADP-dependent Sugar Kinase Family: Kinetic and Evolutionary Aspects
Abstract
Some archaea of the Euryarchaeota present a unique version
of the Embden–Meyerhof pathway where glucose and fructose-
6-phosphate are phoshporylated using ADP instead of ATP as
the phosphoryl donor. These are the only ADP-dependent kinases
known to date. Although initially they were believed to
represent a new protein family, they can be classified as members
of the ribokinase superfamily, which also include several
ATP-dependent kinases. As they were first identified in members
of the thermococcales it was proposed that the presence of these
ADP-dependent kinases is an adaptation to high temperatures.
Later, homologs of these enzymes were identified in the genomes
of mesophilic and thermophilic methanogenic archaea and even
in the genomes of higher eukaryotes, suggesting that the presence
of these proteins is not related to the hyperthermophilic
life. The ADP-dependent kinases are very restrictive to their
ligands being unable to use triphosphorylated nucleotides such
as ATP. However, it has been shown that they can bind ATP by
competition kinetic experiments. The hyperthermophilic methanogenic
archaeon Methanocaldococcus jannaschii has a homolog
of these genes, which can phosphorylate glucose and fructose-6-
phosphate. For this reason, it was proposed as an ancestral form
for the family. However, recent studies have shown that the ancestral
activity in the group is glucokinase, and a combination of
gene duplication and lateral gene transfer could have originated
the two paralogs in this member of the Euryarchaeota. Interestingly,
based on structural comparisons made within the superfamily
it has been suggested that the ADP-dependent kinases are
the newest in the group. In several members of the superfamily,
the presence of divalent metal cations has been shown to be crucial
for catalysis, so its role in the ADP-dependent family was
investigated through molecular dynamics. The simulation shows
that, in fact, the metal coordinates the catalytic ensemble and
interacts with crucial residues for catalysis.
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This work was supported by grant from Fondo Nacional de
Desarrollo Científico y Tecnológico (Fondecyt) 1070111.
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IUBMB LIFE, Volume: 61, Issue: 7, Pages: 753-761, 2009
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