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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)
A chemomechanical-network model for
myosin V
is presented on the basis of both the nucleotide-dependent binding affinity of the head to an actin filament (AF) and asymmetries and similarity relations among the chemical transitions due to an intramolecular strain of the leading and trailing heads. The model allows for branched chemomechanical cycles and takes into account not only two different force-generating mechanical transitions between states wherein the leading head is strongly bound and the trailing head is weakly bound to the AF but also load-induced mechanical-slip transitions between states in which both heads are strongly bound. The latter is supported by the fact that ATP-independent high-speed backward stepping has been observed for
myosin V
, although such motility has never been for
kinesin
. The network model appears as follows: (1) the high chemomechanical-coupling ratio between forward step and ATP hydrolysis is achieved even at low ATP concentrations by the dual mechanical transitions; (2) the forward stepping at high ATP concentrations is explained by the front head-gating mechanism wherein the power stroke is triggered by the inorganic-phosphate (Pi) release from the leading head; (3) the ATP-binding or hydrolyzed ADP.Pi-binding leading head produces a stable binding to the AF, especially against backward loading.
...
PMID:Myosin V: Chemomechanical-coupling ratchet with load-induced mechanical slip. 2904 45
Many motor proteins achieve high efficiency for chemomechanical conversion, and single-molecule force-resisting experiments are a major tool to detect the chemomechanical coupling of efficient motors. Here, we introduce several quantitative relations that involve only parameters extracted from force-resisting experiments and offer new benchmarks beyond mere efficiency to judge the chemomechanical optimality or deficit of evolutionary remote motors on the same footing. The relations are verified by the experimental data from F
1
-ATPase,
kinesin
-1,
myosin V
and cytoplasmic dynein, which are representative members of four motor protein families. A double-fitting procedure yields the chemomechanical parameters that can be cross-checked for consistency. Using the extracted parameters, two generic maps of chemomechanical optimality are constructed on which motors across families can be quantitatively compared. The maps reveal two chemomechanical coupling regimes, one conducive to high efficiency and high directionality, and the other advantageous to force generation. Surprisingly, an F
1
rotor and a
kinesin
-1 walker belong to the first regime despite their obvious evolutionary gap, while
myosin V
and cytoplasmic dynein follow the second regime. This analysis also predicts the symmetries of directional biases and heat productions for the motors, which impose constraints on their chemomechanical coupling and are open to future experimental tests. The verified relations, six in total, present a unified fitting framework to analyze force-resisting experiments. The generic maps of optimality, to which many more motors can be added in future, provide a rigorous method for a systematic cross-family comparison of motors to expose their evolutionary connections and mechanistic similarities.
...
PMID:Generic maps of optimality reveal two chemomechanical coupling regimes for motor proteins: from F
1
-ATPase and kinesin to myosin and cytoplasmic dynein. 2929 87
The posterior determination of the
Drosophila melanogaster
embryo is defined by the posterior localization of
oskar (osk
) mRNA in the oocyte. Defects of its localization result in a lack of germ cells and failure of abdomen specification. A microtubule motor
kinesin
-1 is essential for
osk
mRNA posterior localization. Because
kinesin
-1 is required for two essential functions in the oocyte-transport along microtubules and cytoplasmic streaming-it is unclear how individual
kinesin
-1 activities contribute to the posterior determination. We examined Staufen, an RNA-binding protein that is colocalized with
osk
mRNA, as a proxy of posterior determination, and we used mutants that either inhibit
kinesin
-driven transport along microtubules or cytoplasmic streaming. We demonstrated that late-stage streaming is partially redundant with early-stage transport along microtubules for Staufen posterior localization. Additionally, an actin motor,
myosin V
, is required for the Staufen anchoring to the actin cortex. We propose a model whereby initial
kinesin
-driven transport, subsequent
kinesin
-driven streaming, and
myosin V
-based cortical retention cooperate in posterior determination.
...
PMID:Ooplasmic flow cooperates with transport and anchorage in
Drosophila
oocyte posterior determination. 3003 24
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