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Query: EC:3.6.4.4 (
kinesin
)
5,033
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have reconstructed the evolution of the anciently derived
kinesin
superfamily using various alignment and tree-building methods. In addition to classifying previously described kinesins from protists, fungi, and animals, we analyzed a variety of
kinesin
sequences from the plant kingdom including 12 from Zea mays and 29 from Arabidopsis thaliana. Also included in our data set were four sequences from the anciently diverged amitochondriate protist Giardia lamblia. The overall topology of the best tree we found is more likely than previously reported topologies and allows us to make the following new observations: (1) kinesins involved in chromosome movement including MCAK, chromokinesin, and CENP-E may be descended from a single ancestor; (2) kinesins that form complex oligomers are limited to a monophyletic group of families; (3) kinesins that crosslink antiparallel microtubules at the spindle midzone including BIMC, MKLP, and CENP-E are closely related; (4) Drosophila
NOD
and human KID group with other characterized chromokinesins; and (5) Saccharomyces SMY1 groups with
kinesin
-I sequences, forming a family of kinesins capable of class V myosin interactions. In addition, we found that one monophyletic clade composed exclusively of sequences with a C-terminal motor domain contains all known minus end-directed kinesins.
...
PMID:Maximum likelihood methods reveal conservation of function among closely related kinesin families. 1173 97
NOD
is a Drosophila chromosome-associated kinesin-like protein that does not fall into the chromokinesin subfamily. Although
NOD
lacks residues known to be critical for
kinesin
function, we show that microtubules activate the ATPase activity of
NOD
>2000-fold. Biochemical and genetic analysis of two genetically identified mutations of
NOD
(
NOD
(DTW) and
NOD
("DR2")) demonstrates that this allosteric activation is critical for the function of
NOD
in vivo. However, several lines of evidence indicate that this ATPase activity is not coupled to vectorial transport, including 1)
NOD
does not produce microtubule gliding; and 2) the substitution of a single amino acid in the Drosophila kinesin heavy chain with the analogous amino acid in
NOD
results in a drastic inhibition of motility. We suggest that the microtubule-activated ATPase activity of
NOD
provides transient attachments of chromosomes to microtubules rather than producing vectorial transport.
...
PMID:Orphan kinesin NOD lacks motile properties but does possess a microtubule-stimulated ATPase activity. 1173 96
Segregation of nonexchange chromosomes during Drosophila melanogaster meiosis requires the proper function of
NOD
, a nonmotile
kinesin
-10. We have determined the X-ray crystal structure of the
NOD
catalytic domain in the ADP- and AMPPNP-bound states. These structures reveal an alternate conformation of the microtubule binding region as well as a nucleotide-sensitive relay of hydrogen bonds at the active site. Additionally, a cryo-electron microscopy reconstruction of the nucleotide-free microtubule-
NOD
complex shows an atypical binding orientation. Thermodynamic studies show that
NOD
binds tightly to microtubules in the nucleotide-free state, yet other nucleotide states, including AMPPNP, are weakened. Our pre-steady-state kinetic analysis demonstrates that
NOD
interaction with microtubules occurs slowly with weak activation of ADP product release. Upon rapid substrate binding,
NOD
detaches from the microtubule prior to the rate-limiting step of ATP hydrolysis, which is also atypical for a
kinesin
. We propose a model for
NOD
's microtubule plus-end tracking that drives chromosome movement.
...
PMID:ATPase cycle of the nonmotile kinesin NOD allows microtubule end tracking and drives chromosome movement. 1913 93
Chromosome biorientation promotes congression and generates tension that stabilizes kinetochore-microtubule (kt-MT) interactions. Forces produced by molecular motors also contribute to chromosome alignment, but their impact on kt-MT attachment stability is unclear. A critical force that acts on chromosomes is the
kinesin
-10-dependent polar ejection force (PEF). PEFs are proposed to facilitate congression by pushing chromosomes away from spindle poles, although knowledge of the molecular mechanisms underpinning PEF generation is incomplete. Here, we describe a live-cell PEF assay in which tension was applied to chromosomes by manipulating levels of the chromokinesin
NOD
(no distributive disjunction; Drosophila melanogaster
kinesin
-10).
NOD
stabilized syntelic kt-MT attachments in a dose- and motor-dependent manner by overwhelming the ability of Aurora B to mediate error correction.
NOD
-coated chromatin stretched away from the pole via lateral and end-on interactions with microtubules, and
NOD
chimeras with either plus end-directed motility or tip-tracking activity produced PEFs. Thus, kt-MT attachment stability is modulated by PEFs, which can be generated by distinct force-producing interactions between chromosomes and dynamic spindle microtubules.
...
PMID:Elevated polar ejection forces stabilize kinetochore-microtubule attachments. 2333 18
Chromosome congression, the process of positioning chromosomes in the midspindle, promotes the stable transmission of the genome to daughter cells during cell division. Congression is typically facilitated by DNA-associated, microtubule (MT) plus end-directed motors called chromokinesins. The
Drosophila melanogaster
chromokinesin
NOD
contributes to congression, but the means by which it does so are unknown in large part because
NOD
has been classified as a nonmotile, orphan
kinesin
. It has been postulated that
NOD
promotes congression, not by conventional plus end-directed motility, but by harnessing polymerization forces by end-tracking on growing MT plus ends via a mechanism that is also uncertain. Here, for the first time, it is demonstrated that
NOD
possesses MT plus end-directed motility. Furthermore,
NOD
directly binds EB1 through unconventional EB1-interaction motifs that are similar to a newly characterized MT tip localization sequence. We propose
NOD
produces congression forces by MT plus end-directed motility and tip-tracking on polymerizing MT plus ends via association with EB1.
...
PMID:NOD is a plus end-directed motor that binds EB1 via a new microtubule tip localization sequence. 2989 40
Chromokinesins
NOD
and KID have similar DNA binding domains and functions during cell division, while their motor domain sequences show significant variations. It has been unclear whether these motors have the similar structure, chemistry, and microtubule interactions necessary to follow a similar mechanism of force generation. We used biochemical rate measurements, cosedimentation, and structural analysis to investigate the ATPase mechanisms of the
NOD
and KID core domains. These studies revealed that
NOD
and KID have different ATPase mechanisms, microtubule interactions, and catalytic domain structures. The ATPase cycles of
NOD
and KID have different rate-limiting steps. The ATPase rate of
NOD
was robustly stimulated by microtubules, and its microtubule affinity was weakened in all nucleotide-bound states. KID bound microtubules tightly in all nucleotide states and remained associated with the microtubule for more than 100 cycles of ATP hydrolysis before dissociating. The structure of KID was most like that of conventional
kinesin
(KIF5). Key differences in the microtubule binding region and allosteric communication pathway between KID and
NOD
are consistent with our biochemical data. Our results support the model in which
NOD
and KID utilize distinct mechanistic pathways to achieve the same function during cell division.
...
PMID:Chromokinesins NOD and KID Use Distinct ATPase Mechanisms and Microtubule Interactions To Perform a Similar Function. 3097 12
