Cryo-electron tomography of cardiac myofibrils reveals a 3D lattice spring within the Z-discs

Oda, Toshiyuki; Yanagisawa, Haruaki

doi:10.1038/s42003-020-01321-5

Cited by 18 publications

(24 citation statements)

References 51 publications

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“…In addition, a rare ''split-head'' conformation also occurs when the two heads from one myosin binds to two different adjacent thin filaments (10 pairs observed; 0.6% of all heads) (Figures 3D and S4). This conformation has been previously suggested (Offer and Elliott, 1978) and vaguely indicated by 2D projection images (Hirose and Wakabayashi, 1993). Our observation provides direct proof of this conformation in three-dimensions in the rigor state vertebrate sarcomere.…”

Section: Cross-bridges In the A-band Depict A Pseudo-regular Distribution Of Myosin Heads And Reveal A Split-head Conformationsupporting

confidence: 82%

“…Our analysis shows that this arrangement was not an in vitro artifact but a feature of native sarcomeres. Interestingly, these doublets were not apparent in the recent reconstruction of the F-actin-α-actinin complex from branched cardiac myofibrils obtained through sub-volume averaging, in which the angles between α-actinin and actin resemble the thick-form Z-disc ( Oda and Yanagisawa, 2020 ). Importantly, as single α-actinins were not distinguishable in these tomograms, this study relied strongly on subtomogram averaging at certain positions, assuming a highly symmetric Z-disc.…”

Section: Resultsmentioning

confidence: 99%

“…The recently presented structure from resin-embedded sections of the highly atypical Z-disc of the midshipman sonic muscle, structures that are at least 10 times thicker than the Z-discs of representative vertebrate skeletal muscles, revealed a fundamental arrangement of transverse crosslinks with an axial displacement of 19.2 nm, in line with previous work at lower resolution ( Burgoyne et al., 2015 , 2019 ; Perz-Edwards and Reedy, 2011 ). A further study of the Z-disc from isolated branches of cardiac myofibrils using electron cryo-tomography (cryo-ET) determined averaged structures of actin-α-actinin complexes in two states (putatively, the relaxed and activated states) at ~23 Å resolution ( Oda and Yanagisawa, 2020 ). These two structures highlight changes within the Z-disc in response to torque applied by the myosin heads on thin filaments, whereby α-actinin can pivot via linker domains between the central “rod” domain and the N-terminal actin binding domain.…”

Section: Introductionmentioning

confidence: 99%

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The molecular basis for sarcomere organization in vertebrate skeletal muscle

Wang

Grange

Wagner

et al. 2021

Cell

115

101

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Summary Sarcomeres are force-generating and load-bearing devices of muscles. A precise molecular picture of how sarcomeres are built underpins understanding their role in health and disease. Here, we determine the molecular architecture of native vertebrate skeletal sarcomeres by electron cryo-tomography. Our reconstruction reveals molecular details of the three-dimensional organization and interaction of actin and myosin in the A-band, I-band, and Z-disc and demonstrates that α-actinin cross-links antiparallel actin filaments by forming doublets with 6-nm spacing. Structures of myosin, tropomyosin, and actin at ~10 Å further reveal two conformations of the “double-head” myosin, where the flexible orientation of the lever arm and light chains enable myosin not only to interact with the same actin filament, but also to split between two actin filaments. Our results provide unexpected insights into the fundamental organization of vertebrate skeletal muscle and serve as a strong foundation for future investigations of muscle diseases.

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Section: Cross-bridges In the A-band Depict A Pseudo-regular Distribution Of Myosin Heads And Reveal A Split-head Conformationsupporting

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The molecular basis for sarcomere organization in vertebrate skeletal muscle

Wang

Grange

Wagner

et al. 2021

Cell

115

101

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show abstract

“…( F ) Surface of the rod-α-actinin-2/FATZ-1 structure showing the sequence conservation of α-actinin interacting residues for FATZ-1 (alignment done using 1505 α-actinins from vertebrates). ( G ) Model of F-actin/α-actinin-2/FATZ-1 (F-actin in light and dark gray) based on a cryo–electron tomography structure of the Z-disk ( 47 ) and our integrative model. See also figs.…”

Section: Resultsmentioning

confidence: 99%

“…Electron tomography reconstructions of paracrystalline vertebrate Z-disks show a defined orientation for α-actinin-2 rod in cross-linked actin filaments ( 47 , 69 ). This cannot be explained in the context of the built-in flexibility in the neck region of α-actinin, which allows rotation of the rod along its longitudinal axis ( 12 ).…”

Section: Discussionmentioning

confidence: 99%

Order from disorder in the sarcomere: FATZ forms a fuzzy but tight complex and phase-separated condensates with α-actinin

et al. 2021

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In sarcomeres, α-actinin cross-links actin filaments and anchors them to the Z-disk. FATZ (filamin-, α-actinin-, and telethonin-binding protein of the Z-disk) proteins interact with α-actinin and other core Z-disk proteins, contributing to myofibril assembly and maintenance. Here, we report the first structure and its cellular validation of α-actinin-2 in complex with a Z-disk partner, FATZ-1, which is best described as a conformational ensemble. We show that FATZ-1 forms a tight fuzzy complex with α-actinin-2 and propose an interaction mechanism via main molecular recognition elements and secondary binding sites. The obtained integrative model reveals a polar architecture of the complex which, in combination with FATZ-1 multivalent scaffold function, might organize interaction partners and stabilize α-actinin-2 preferential orientation in Z-disk. Last, we uncover FATZ-1 ability to phase-separate and form biomolecular condensates with α-actinin-2, raising the question whether FATZ proteins can create an interaction hub for Z-disk proteins through membraneless compartmentalization during myofibrillogenesis.

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Arrested in Glass: Actin within Sophisticated Architectures of Biosilica in Sponges

et al. 2022

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Actin is a fundamental member of an ancient superfamily of structural intracellular proteins and plays a crucial role in cytoskeleton dynamics, ciliogenesis, phagocytosis, and force generation in both prokaryotes and eukaryotes. It is shown that actin has another function in metazoans: patterning biosilica deposition, a role that has spanned over 500 million years. Species of glass sponges (Hexactinellida) and demosponges (Demospongiae), representatives of the first metazoans, with a broad diversity of skeletal structures with hierarchical architecture unchanged since the late Precambrian, are studied. By etching their skeletons, organic templates dominated by individual F‐actin filaments, including branched fibers and the longest, thickest actin fiber bundles ever reported, are isolated. It is proposed that these actin‐rich filaments are not the primary site of biosilicification, but this highly sophisticated and multi‐scale form of biomineralization in metazoans is ptterned.

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Cryo-electron tomography of cardiac myofibrils reveals a 3D lattice spring within the Z-discs

Cited by 18 publications

References 51 publications

The molecular basis for sarcomere organization in vertebrate skeletal muscle

The molecular basis for sarcomere organization in vertebrate skeletal muscle

Order from disorder in the sarcomere: FATZ forms a fuzzy but tight complex and phase-separated condensates with α-actinin

Arrested in Glass: Actin within Sophisticated Architectures of Biosilica in Sponges

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