Striated muscle enables movement in all animals by the contraction of myriads of sarcomeres joined end to end by the Z-bands. The contraction is due to tension generated in each sarcomere between overlapping arrays of actin and myosin filaments. At the Z-band, actin filaments from adjoining sarcomeres overlap and are cross-linked in a regular pattern mainly by the protein α-actinin. The Z-band is dynamic, reflected by the 2 regular patterns seen in transverse section electron micrographs; the so-called small-square and basketweave forms. Although these forms are attributed, respectively, to relaxed and actively contracting muscles, the basketweave form occurs in certain relaxed muscles as in the muscle studied here. We used electron tomogra...
Muscle contraction is brought about by the interaction of the proteins actin and myosin. Xray diffra...
To clarify the distribution of transverse tubule-sarcoplasmic reticulum (T-SR) com-plexes in the swi...
Detailed structural analysis of muscles normally used to study myosin cross-bridge behavior (e.g., f...
Striated muscle enables movement in all animals by the contraction of myriads of sarcomeres joined e...
AbstractThe Z-band in vertebrate striated muscle crosslinks actin filaments of opposite polarity fro...
The sarcomeric M-band in vertebrate striated muscle is thought to maintain the uniform hexagonal lat...
AbstractIn vertebrate muscles, Z-bands connect adjacent sarcomeres, incorporate several cell signali...
Myosin filaments in vertebrate striated muscle have a long roughly cylindrical backbone with cross-b...
Using data from fast time-resolved x-ray diffraction experiments on the synchrotrons at Daresbury an...
Defining the structural changes involved in the myosin cross-bridge cycle on actin in active muscle ...
peer reviewedIn vertebrate skeletal muscles, the architecture of myofibrils is particularly well con...
In electron micrographs of striated muscle, the I-band often shows a distinct cross-striation. The p...
During contraction, the molecular arrangement within muscle undergoes large changes which can be tra...
Invertebrate striated muscle, the Z-line, which defines the sarcomere length, presents diverse struc...
This paper discusses some examples of strong correlations between functions and structures in axial ...
Muscle contraction is brought about by the interaction of the proteins actin and myosin. Xray diffra...
To clarify the distribution of transverse tubule-sarcoplasmic reticulum (T-SR) com-plexes in the swi...
Detailed structural analysis of muscles normally used to study myosin cross-bridge behavior (e.g., f...
Striated muscle enables movement in all animals by the contraction of myriads of sarcomeres joined e...
AbstractThe Z-band in vertebrate striated muscle crosslinks actin filaments of opposite polarity fro...
The sarcomeric M-band in vertebrate striated muscle is thought to maintain the uniform hexagonal lat...
AbstractIn vertebrate muscles, Z-bands connect adjacent sarcomeres, incorporate several cell signali...
Myosin filaments in vertebrate striated muscle have a long roughly cylindrical backbone with cross-b...
Using data from fast time-resolved x-ray diffraction experiments on the synchrotrons at Daresbury an...
Defining the structural changes involved in the myosin cross-bridge cycle on actin in active muscle ...
peer reviewedIn vertebrate skeletal muscles, the architecture of myofibrils is particularly well con...
In electron micrographs of striated muscle, the I-band often shows a distinct cross-striation. The p...
During contraction, the molecular arrangement within muscle undergoes large changes which can be tra...
Invertebrate striated muscle, the Z-line, which defines the sarcomere length, presents diverse struc...
This paper discusses some examples of strong correlations between functions and structures in axial ...
Muscle contraction is brought about by the interaction of the proteins actin and myosin. Xray diffra...
To clarify the distribution of transverse tubule-sarcoplasmic reticulum (T-SR) com-plexes in the swi...
Detailed structural analysis of muscles normally used to study myosin cross-bridge behavior (e.g., f...