TY - JOUR
T1 - The vertebrate mitotic checkpoint protein BUBR1 is an unusual pseudokinase
AU - Suijkerbuijk, S.J.E.
AU - van Dam, T.J.P.
AU - Karagoz, G.E.
AU - von Castelmur, E.
AU - Hubner, N.
AU - dos santos Duarte, A.M.
AU - Vleugel, M.
AU - Perrakis, A.
AU - Rudiger, S.G.D.
AU - Snel, B.
AU - Kops, G.J.P.L.
PY - 2012
Y1 - 2012
N2 - Chromosomal stability is safeguarded by a mitotic
checkpoint, of which BUB1 and Mad3/BUBR1 are
core components. These paralogs have similar, but
not identical, domain organization. We show that
Mad3/BUBR1 and BUB1 paralogous pairs arose by
nine independent gene duplications throughout
evolution, followed by parallel subfunctionalization
in which preservation of the ancestral, aminoterminal
KEN box or kinase domain was mutually
exclusive. In one exception, vertebrate BUBR1—
defined by the KEN box—preserved the kinase
domain but allowed nonconserved degeneration of
catalytic motifs. Although BUBR1 evolved to a typical
pseudokinase in some vertebrates, it retained the
catalytic triad in humans. However, we show that
putative catalysis by human BUBR1 is dispensable
for error-free chromosome segregation. Instead,
residues that interact with ATP in conventional
kinases are essential for conformational stability in
BUBR1. We propose that parallel evolution of
BUBR1 orthologs rendered its kinase function
dispensable in vertebrates, producing an unusual,
triad-containing pseudokinase.
AB - Chromosomal stability is safeguarded by a mitotic
checkpoint, of which BUB1 and Mad3/BUBR1 are
core components. These paralogs have similar, but
not identical, domain organization. We show that
Mad3/BUBR1 and BUB1 paralogous pairs arose by
nine independent gene duplications throughout
evolution, followed by parallel subfunctionalization
in which preservation of the ancestral, aminoterminal
KEN box or kinase domain was mutually
exclusive. In one exception, vertebrate BUBR1—
defined by the KEN box—preserved the kinase
domain but allowed nonconserved degeneration of
catalytic motifs. Although BUBR1 evolved to a typical
pseudokinase in some vertebrates, it retained the
catalytic triad in humans. However, we show that
putative catalysis by human BUBR1 is dispensable
for error-free chromosome segregation. Instead,
residues that interact with ATP in conventional
kinases are essential for conformational stability in
BUBR1. We propose that parallel evolution of
BUBR1 orthologs rendered its kinase function
dispensable in vertebrates, producing an unusual,
triad-containing pseudokinase.
U2 - 10.1016/j.devcel.2012.03.009
DO - 10.1016/j.devcel.2012.03.009
M3 - Article
C2 - 22698286
SN - 1534-5807
VL - 22
SP - 1321
EP - 1329
JO - Developmental Cell
JF - Developmental Cell
IS - 6
ER -