Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
Compound
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
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
