Molecular dynamics simulations and single molecule experiments are used to suggest that charged helices in the medial tail domain participate in myosin VI dimerization (Kim et al., 2010), which reinforces the mechanism that unfolding of the three helix bundle in the proximal tail serves as a lever arm extension
The human genome contains 39 myosin genes, divided up into 12 different classes. The structure, cell...
The myosin superfamily is comprised of nearly twenty classes of actin-based motors. Prior to 1999, i...
AbstractThe recent observation that class VI myosins move in a direction opposite to all other known...
Molecular dynamics simulations and single molecule experiments are used to suggest that charged heli...
SummaryThe unconventional motor protein, myosin VI, is known to dimerize upon cargo binding to its C...
AbstractThe molecular motor protein myosin VI moves toward the minus-end of actin filaments with a s...
Myosin VI is one of the myosin superfamily members that are actin-based molecular motors. It has rec...
It is unclear whether the reverse-direction myosin (myosin VI) functions as a monomer or dimer in ce...
Myosin VI is the only known molecular motor that moves towards the minus end of actin filaments, and...
AbstractMyosin V is a single-molecule motor that moves organelles along actin. When myosin V pulls l...
SummaryMyosin VI is the only known molecular motor that moves toward the minus ends of actin filamen...
Myosin motor function depends on the interaction between different domains that transmit information...
Background:Myosin VI plays diverse cellular roles ranging from intracellular transport to mechanical...
The myosin superfamily is a versatile group of molecular motors involved in the transport of specifi...
Although the α-helix has long been recognized as an all-important element of secondary structure, it...
The human genome contains 39 myosin genes, divided up into 12 different classes. The structure, cell...
The myosin superfamily is comprised of nearly twenty classes of actin-based motors. Prior to 1999, i...
AbstractThe recent observation that class VI myosins move in a direction opposite to all other known...
Molecular dynamics simulations and single molecule experiments are used to suggest that charged heli...
SummaryThe unconventional motor protein, myosin VI, is known to dimerize upon cargo binding to its C...
AbstractThe molecular motor protein myosin VI moves toward the minus-end of actin filaments with a s...
Myosin VI is one of the myosin superfamily members that are actin-based molecular motors. It has rec...
It is unclear whether the reverse-direction myosin (myosin VI) functions as a monomer or dimer in ce...
Myosin VI is the only known molecular motor that moves towards the minus end of actin filaments, and...
AbstractMyosin V is a single-molecule motor that moves organelles along actin. When myosin V pulls l...
SummaryMyosin VI is the only known molecular motor that moves toward the minus ends of actin filamen...
Myosin motor function depends on the interaction between different domains that transmit information...
Background:Myosin VI plays diverse cellular roles ranging from intracellular transport to mechanical...
The myosin superfamily is a versatile group of molecular motors involved in the transport of specifi...
Although the α-helix has long been recognized as an all-important element of secondary structure, it...
The human genome contains 39 myosin genes, divided up into 12 different classes. The structure, cell...
The myosin superfamily is comprised of nearly twenty classes of actin-based motors. Prior to 1999, i...
AbstractThe recent observation that class VI myosins move in a direction opposite to all other known...
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