motor protein

Motor proteins travel in a specific direction along a microtubule.

He has contributed significantly to the understanding of how motor proteins walk along their filaments.

This classification group also includes numerous other structural, regulatory, and motor proteins.

His specialty is biophysics, particularly the mechanism of muscles and motor proteins.

In early mitosis, several motor proteins drive the separation of centrosomes.

The importance of motor proteins in cells becomes evident when they fail to fulfill their function.

Kinesins are a group of related motor proteins that use a microtubule track along which to "walk."

The Kinesin-13 Family are a subfamily of motor proteins known as kinesins.

In neurons, P-bodies move by motor proteins in response to stimulation.

Identification and purification of the first cytoskeleton based motor protein such as dynein.

Both the actin- and the microtubule-base are implicated in these processes, along with several motor proteins.

In contrast, dyneins are motor proteins that move toward the microtubules' minus end.

Motor proteins fulfill the role of transporting large cargo about the cell to their required destinations.

Jonathan Howard (2001), Mechanics of motor proteins and the cytoskeleton.

A kinesin is a protein belonging to a class of motor proteins found in eukaryotic cells.

A number of theoretical models of the molecular motor protein Kinesin have been proposed.

This gene encodes a motor protein that is part of the kinesin superfamily.

DYNLT3 is a member of the dynein motor protein family.

The building of cell plate and ultimately the new cell wall requires kinesin-like motor proteins.

Second, the centrosomes are separated via microtubules motor proteins.

Molecular motor proteins then push the centrosomes along these microtubules to opposite sides of the cell.

A different type of motor protein known as dyneins, move towards the minus end of the microtubule.

These data indicate that the fractions of the major motor proteins, actin and myosin, are similar in both blood vessels.

The motor proteins actin and myosin generate the forces exerted by contracting muscles.

Myosin X is an actin-based motor protein known to associate at the tips of filopodia.