Fact-checked by Grok 2 weeks ago

Myosin

Myosins are a large superfamily of actin-based motor proteins that convert the derived from into mechanical force and directed movement along filaments. These proteins are essential for a wide array of cellular processes, including , intracellular transport, , and . The term "myosin" was coined by Hugo von Kühne in 1859 to describe the extractable component of muscle responsible for contraction. Early biochemical studies in the late 19th and early 20th centuries identified myosin as an , with significant advances in the 1940s by and others isolating myosin and demonstrating its interaction with . The proposed by Hugh Huxley and in 1954 revolutionized understanding of , later confirmed by electron microscopy and diffraction studies. Structurally, myosins typically consist of a conserved motor domain (or head) that binds to and hydrolyzes ATP, a region acting as a lever arm to amplify conformational changes, and a domain that determines binding and dimerization. The motor domain is highly conserved across the superfamily, enabling the power stroke mechanism where ATP binding and drive cycles of attachment, force generation, and detachment. Over 40 classes of myosins have been identified, with humans expressing 13 classes encoded by approximately 40 genes; notable examples include myosin II, which forms bipolar filaments for and , and processive myosins like class V and VI for vesicle and transport. Functionally, myosins power diverse motility events by walking along tracks in a directional manner—most toward the barbed (plus) end, except for myosin VI, which moves toward the pointed (minus) end due to unique structural adaptations in its lever arm. In striated muscle, myosin II interacts with in the to generate sliding filaments and contractile force, while non-muscle myosins support cytoskeletal remodeling and cellular adhesion. Mutations in myosin genes are linked to human diseases such as cardiomyopathies, , and neurological disorders, underscoring their critical physiological roles.

Introduction

Definition and Primary Roles

Myosins constitute a superfamily of ATP-dependent motor proteins that interact with filaments to generate force and movement within eukaryotic cells. These proteins harness the energy from to drive a wide array of motile processes, converting chemical energy into mechanical work along actin tracks. As essential components of the , myosins enable dynamic cellular behaviors critical for life. The primary roles of myosins span multiple cellular functions, with distinct classes specialized for specific tasks. Myosin II is pivotal in , forming bipolar filaments that slide filaments past one another to produce contractile force in striated and smooth muscles. In non-muscle cells, myosin II also contributes to by constricting the actin-myosin ring during . Meanwhile, myosin V facilitates intracellular transport, such as the movement of vesicles and organelles along filaments, ensuring proper distribution of cellular . Myosin I supports cellular by linking to plasma membranes and participates in processes like and ruffling. This superfamily displays extensive , encompassing approximately 45 classes across eukaryotes, each adapted to particular cellular contexts through variations in and . In humans, approximately 40 genes myosin isoforms, allowing for tissue-specific expression and . Such diversity reflects the evolutionary expansion of myosins to meet the demands of complex eukaryotic . Myosins are remarkably conserved evolutionarily, with homologs present from unicellular organisms like to multicellular including humans, highlighting their ancient origins and indispensable roles in fundamental cellular mechanics.

Historical Discovery

The discovery of myosin traces back to 1864, when German physiologist Wilhelm Kühne extracted a viscous, salt-soluble protein from tissue and named it "myosin," attributing to it the role of maintaining muscle tension in the rigor state. Kühne's observation laid the foundational recognition of myosin as a key contractile component, derived from experiments on muscle press-juice where the protein appeared as a single viscous entity responsible for . A pivotal advancement came in 1939, when Vladimir A. Engelhardt and Militza N. Ljubimova demonstrated that purified myosin from rabbit skeletal muscle exhibited adenosine triphosphatase () activity, hydrolyzing ATP to and inorganic . Their experiments, involving precipitation and redissolution of myosin, established a direct enzymatic link between myosin and ATP breakdown, suggesting its central role in energy-dependent . Building on this, Hungarian biochemist advanced myosin research in the 1940s by purifying myosin A as paracrystals and demonstrating that threads formed from actomyosin (a complex of myosin and ) contracted upon ATP addition, mimicking physiological shortening. Szent-Györgyi's work, including the 1943 isolation of pure myosin, confirmed ATP's activating effect on contraction and crystallized the protein, enabling further biochemical studies. In 1971, Andrew F. Huxley and Ralph M. Simmons proposed the cross-bridge theory through tension-transient experiments on frog striated muscle fibers, describing how myosin heads attach to filaments and undergo conformational changes to generate during rapid length alterations. Their model posited that cross-bridges cycle through attached states with varying angles, producing tension via a power stroke tied to , which became a for understanding myosin's mechanochemical mechanism. The 1970s and marked the identification of unconventional myosins beyond muscle-specific forms, beginning with the discovery of myosin I in the amoeba Acanthamoeba castellanii by Thomas D. Pollard and Edward D. Korn in 1973, a single-headed motor with light chains that supported cellular motility without filament assembly. This finding, followed by characterizations in the revealing myosin I's role in membrane interactions and pseudopod extension, expanded the myosin superfamily to include non-muscle isoforms involved in diverse cytoskeletal functions. By the 1990s, genomic sequencing efforts enabled systematic identification of myosin genes across eukaryotes; for instance, the 2001 "A Millennial Myosin Census" by Berg, Powell, and Cheney analyzed cDNA and genomic data from organisms like , Drosophila, and humans, identifying approximately 18 myosin classes and highlighting evolutionary diversification through sequence comparisons. These sequencing milestones, including early Caenorhabditis elegans and Saccharomyces cerevisiae genomes, classified myosins by motor domain homology and underscored their ancient origins in cellular transport.

Molecular Structure

Core Domains

The core architecture of myosin molecules is characterized by three principal domains: the head (motor) domain, the neck region, and the domain, which together enable the protein's mechanochemical function across the superfamily. These elements are highly conserved in their fundamental organization, with variations primarily in the tail to accommodate diverse cellular roles. The heavy , the primary structural component, typically spans 1000–2000 and has a molecular weight of approximately 200–250 kDa per chain. The head (motor) domain, the globular core of the head and part of subfragment-1 (S1), forms the N-terminal region and is the most conserved part of the myosin superfamily, with the heavy chain portion measuring about 80-95 kDa. S1 overall, including the neck and light chains, is approximately 130 kDa. It houses the actin-binding site and the ATPase active site, which facilitate nucleotide hydrolysis coupled to actin interaction. This domain is divided into four main subdomains: the N-terminal subdomain, the upper 50 kDa (U50) subdomain, the lower 50 kDa (L50) subdomain, and the converter subdomain (sometimes referred to as the lever arm base). A central seven-stranded β-sheet, known as the transducer, spans the U50 and N-terminal subdomains, serving as a key structural scaffold that transmits conformational changes during the motor cycle. Additional elements include the U30 region within the L50 subdomain, which contributes to nucleotide coordination, and a flexible hook loop involved in actin interface stabilization. The atomic structure of the myosin II head domain was first resolved at 2.8 Å resolution using X-ray crystallography of chicken skeletal muscle S1 (PDB: 2MYS), revealing these subdomains as rigid bodies connected by flexible linkers that allow coordinated movement. The neck region connects the head to the tail and consists of a long α-helical lever arm, typically 6–8 nm in length, that amplifies small conformational shifts in the converter subdomain into larger displacements for force generation. This helix features IQ motifs that serve as binding sites for calmodulin-like light chains, stabilizing the structure and modulating mechanics. In myosin II, the neck binds two light chains per head—one essential and one regulatory—enhancing stability, whereas unconventional myosins like myosin V possess longer necks with up to six IQ motifs for extended leverage. The lever arm's role in motion amplification is evident from structural comparisons across states, where rotation at the converter-neck junction produces swings of 60–100°.(https://www.science.org/doi/10.1126/science.8316857)[](https://pmc.ncbi.nlm.nih.gov/articles/PMC3290112/) The tail domain exhibits the greatest diversity, dictating oligomerization and cargo specificity. In conventional myosins like class , the tail forms a long coiled-coil α-helical rod (~150 or 1500 Å long, consisting of subfragment (~40-50 ) and LMM), enabling assembly into bipolar filaments essential for ; each heavy chain contributes ~1100 residues to this rod structure. Unconventional myosins, such as class I, often feature a monomeric globular tail with domains like pleckstrin homology () motifs for membrane association, while class V has a shorter, intermittent coiled-coil for dimerization followed by a globular cargo-binding domain. Myosin molecules are dimeric overall, with two heavy chains and associated light chains forming a ~520 kDa complex, in contrast to the monomeric forms predominant in classes I, V, and VI. These tail variations underpin the superfamily's functional specialization, from cytoskeletal organization to vesicular .

Regulatory Elements and Light Chains

The essential light chain (ELC) and regulatory light chain (RLC) serve as critical accessory components of myosin, binding to IQ motifs ( IQxxxRGxxxR) within the α-helical lever arm of the myosin heavy chain to provide and enable amplification of conformational changes during the power . The ELC, typically around 22 kDa, primarily acts as a structural scaffold, interacting with filaments via its N-terminal extension to modulate force output and step size, as demonstrated in cardiac and isoforms where ELC mutations alter contractile performance. In contrast, the RLC, approximately 19 kDa, exerts finer control over myosin activity; its N-terminal EF-hand domain can bind calcium ions (Ca²⁺) or magnesium ions (Mg²⁺), influencing cross-bridge kinetics and calcium sensitivity, particularly in myosin where this binding contributes to graded of . Phosphorylation of the RLC represents a primary regulatory for myosin II, particularly in and non-muscle cells, where (MLCK), activated by Ca²⁺-, targets serine-19 (and to a lesser extent threonine-18) on the RLC. This induces a conformational shift in the myosin head, relieving autoinhibition, enhancing actin-activated activity, and promoting the assembly of myosin II into bipolar essential for formation and cellular contractility. In striated muscle, RLC similarly boosts force generation and thick , with diphosphorylation at both sites further accelerating cross-bridge detachment rates. In unconventional myosins, regulatory elements extend beyond muscle-specific light chains to include calmodulin (CaM) binding and intrinsic structural motifs. Myosin V, a processive cargo transporter, binds up to six CaM molecules along its extended lever arm via IQ motifs, where Ca²⁺-induced dissociation of CaM reduces motor duty ratio and processivity, thereby tuning vesicular transport in response to cellular calcium signals. Myosin VI employs a distinct autoinhibitory mechanism, with its C-terminal tail domain folding back onto the motor head to form a compact, inactive monomer; cargo adaptors such as Dab2 or NDP52 bind the tail and disrupt this interaction, unfolding the structure to expose dimerization sites and activate directed motility along actin tracks. Advances in cryo-electron microscopy (cryo-EM) during the 2020s have elucidated how light chain conformations underpin these regulatory transitions. In the relaxed, interacting heads motif (IHM) of human β-cardiac myosin, high-resolution structures reveal the RLC and ELC asymmetrically positioned between the two heads, with the RLC's phosphorylated stabilizing the folded-back state to conserve ATP; activation via RLC phosphorylation or adrenergic signaling repositions the light chains, releasing the blocked head for cross-bridge . Similarly, cryo-EM of myosin in its autoinhibited 10S conformation shows the light chains maintaining an asymmetric arrangement that sequesters the actin-binding site, while dephosphorylation or MLCK activity induces rigid-body rotations in the lever arm and light chains to favor the active 6S filament state. These structural insights highlight light chains as pivotal switches between energy-saving relaxed conformations and force-producing active states across myosin classes.

Functional Mechanism

ATP Hydrolysis and Cross-Bridge Cycle

The cross-bridge cycle of myosin is a fundamental biochemical process that couples to mechanical work, enabling the motor's interaction with filaments. This , originally proposed by Lymn and Taylor, involves sequential nucleotide binding, , and product release that drive conformational changes in the myosin head. Each complete cycle hydrolyzes one ATP molecule and generates a displacement along actin, with the process repeating to produce sustained or force. The cycle progresses through four principal biochemical states defined by the nucleotide occupancy of the myosin active site and its affinity for actin. In the ATP-bound state, myosin is detached from actin, with low affinity due to the open configuration of the actin-binding cleft induced by ATP coordination. Hydrolysis of ATP to ADP and inorganic phosphate (Pi) transitions myosin to the ADP-Pi state, where it remains detached but adopts a primed conformation with the lever arm cocked, poised for weak interaction with actin. Upon encountering actin, Pi release shifts to the ADP state, promoting strong binding and initiating force generation during the power stroke. Finally, ADP release yields the nucleotide-free rigor state, characterized by tight, high-affinity binding to actin, completing the attached phase of the cycle. Key steps in the cycle are tightly regulated by interactions. ATP binding to the rigor complex rapidly dissociates myosin from (rate constant >500 s⁻¹), resetting the detached phase. Subsequent in the detached state "cocks" the lever arm, storing energy for later use, with a rate constant of approximately 100 s⁻¹ in myosin II at 20°C. Weak binding in the ADP-Pi state precedes Pi release, which triggers cleft and strong attachment (rate ~10-100 s⁻¹, isoform-dependent). This is followed by the power stroke and dissociation (rate ~100-1000 s⁻¹ under low load), returning to rigor. Cycle kinetics vary across myosin classes, influencing their function. In non-processive myosins like myosin II, the duty ratio—the fraction of the cycle time spent strongly bound to —is low (~0.05-0.2), allowing rapid detachment for collective force in ensembles such as muscle sarcomeres. In contrast, processive myosins like myosin V exhibit a high duty ratio (>0.7), enabling prolonged attachment for along tracks. These differences arise from tuned rate constants, such as slower ADP release in myosin V (~10 s⁻¹), which extends the attached phase. Recent single-molecule studies have revealed nuances in Pi dynamics, including a multistep release pathway where initial Pi release is followed by reversible rebinding to a secondary site on myosin, delaying the transition from weak to strong binding and tuning energy transduction and sensitivity. Local Pi concentrations can modulate rates, as seen in cardiac myosin where higher Pi promotes in the pre-power , reducing generation.

Power Stroke and Force Production

The power stroke in myosin represents the core mechanical event where ATP hydrolysis-driven conformational changes in the motor domain are transduced into directed movement and force along actin filaments. During this phase, which follows the initial weak binding of the myosin head to actin, the lever arm—comprising the light chain binding domain—undergoes a pivotal swing. This rotation, typically spanning 40–70° in myosin II, amplifies a small ~5 nm displacement in the converter domain to generate a 6–10 nm axial step size per ATP hydrolyzed, enabling efficient filament sliding. Force production arises directly from this lever arm amplification, with individual myosin heads capable of exerting 3–7 under conditions, as measured in single-molecule optical assays. In physiological contexts, such as striated muscle, operates in ensembles within thick containing hundreds of heads (e.g., ~300–600 per in ), where coordinated attachment and detachment amplify total output to hundreds of per , supporting macroscopic contraction. Variations in power stroke mechanics distinguish myosin classes; for instance, unconventional myosin V employs a processive hand-over-hand stepping , where alternating head attachments produce 36 nm steps matching the pseudo-repeat, allowing sustained cargo transport without ensemble cooperation. In contrast, myosin II relies on ensemble averaging across many heads for force generation during . Recent structural and biophysical studies (2023–2025) have illuminated regulatory nuances in cardiac myosin, particularly the super-relaxed state (SRX), where interacting-head motifs sequester heads against the thick backbone, minimizing and poised for rapid activation. Disruptions in SRX, as seen in mutations, enhance attachment and force output but increase energy consumption; tensile force applications in bundles further modulate head release, revealing load-dependent transitions between SRX and disordered relaxed states.

Superfamily Classification

Evolutionary Origins and Nomenclature

Myosins represent one of the most ancient families of motor proteins in eukaryotic cells, with evidence indicating their presence in the last eukaryotic common ancestor (LECA), which is estimated to have existed between 1.5 and 2 billion years ago. This primordial myosin likely functioned in basic cytoskeletal dynamics and intracellular transport, reflecting the early evolution of actin-based motility in eukaryotes. Over evolutionary time, the superfamily expanded dramatically through repeated events, resulting in more than 35 distinct classes distributed across diverse eukaryotic lineages. In metazoans, particularly vertebrates, this diversification led to the retention and specialization of approximately 18 classes, enabling adaptations to complex multicellular functions such as and vesicular trafficking. The of the myosin superfamily follows a systematic primarily based on phylogenetic relationships and similarity within the conserved motor , which typically shares greater than 30% identity among members of the same class. Classes are designated using (e.g., class I, class II), with animal-specific myosins numbered as MYO1 through MYO19 under standardized systems like those recommended by the Union of Basic and Clinical Pharmacology (IUPHAR). This numbering reflects the motor 's conservation while accounting for tail variations that confer functional specificity. The system prioritizes the motor for class assignment, as it encodes the core ATP-hydrolyzing and actin-binding activities common to all myosins. Phylogenetically, the myosin superfamily forms a where class II (conventional myosins) occupies a basal position, having diverged early alongside class I to support fundamental cellular processes like and . Subsequent radiations produced unconventional classes (III through XXXV and beyond), which diversified into specialized roles, such as organelle transport (e.g., class V) or sensory functions (e.g., class VII), driven by lineage-specific duplications and losses. Recent phylogenomic analyses in the 2020s, incorporating expanded genomic data from non-metazoan eukaryotes like protists and , have refined this by identifying sequences and reclassifying divergent lineages, revealing greater diversity in unicellular organisms than previously appreciated.

Myosin I

Myosin I family members are single-headed unconventional myosins that play essential roles in linking the to cellular membranes, facilitating short-range movements and tension generation. Unlike dimeric myosins such as myosin II, myosin I motors operate as monomers, enabling them to function as tethers or adaptors rather than forming filaments for large-scale . These motors are characterized by their ability to bind directly, which positions them at membrane-actin interfaces across eukaryotic cells. The core structure of myosin I includes a conserved N-terminal motor domain responsible for binding and , followed by a region that binds 1–6 light chains, which regulate lever arm swinging and force transmission. The C-terminal tail domain is notably short and features a pleckstrin (PH)-like domain within the tail 1 (TH1) region, enabling specific interactions with anionic phospholipids in membranes. This lipid-binding capability, combined with the -bound , allows myosin I to filaments to bilayers while sensing and responding to mechanical tension. myosin I isoforms are divided into short-tailed (e.g., MYO1A, MYO1B) and long-tailed (e.g., MYO1E, MYO1F) variants, with the latter including additional SH3 or TH2 domains for protein interactions. Functionally, myosin I motors generate tension to maintain -cargo associations, powering processes like and by coupling dynamics to deformation. In , they act as tension sensors, enhancing robustness by producing force independently of load in some isoforms, which stabilizes invaginating pits against varying cellular stresses. For instance, myosin IC exhibits a unique tension-sensing mechanism that sustains power output across a range of loads (~0.5–3 pN), distinct from other myosins, by modulating release . Myosin I also supports processivity through load-dependent behaviors, such as in MYO1B, where low-load conditions (~1 pN) promote detachment for , while resistive loads enable prolonged anchoring (~100 s) via side-step-like adjustments along . These properties make myosin I ideal for short-range, adaptive at sites. Key isoforms highlight specialized membrane-actin roles; MYO1A, abundant in intestinal epithelial cells, links actin cores to the plasma membrane in brush border microvilli, maintaining structural integrity and facilitating vesicle shedding for antimicrobial defense. MYO1B, widely expressed, participates in endosomal trafficking and membrane tubulation, with roles at ER-plasma membrane contact sites where it coordinates lipid transfer and tension regulation during cellular stress responses. These isoforms exemplify how myosin I adapts to diverse cargoes, from static tethers in microvilli to dynamic docks in trafficking pathways. Evolutionarily, myosin I represents the oldest class of unconventional myosins, present in the last eukaryotic common ancestor (LECA) and conserved across all eukaryotes, predating other families like myosin V and underscoring its foundational role in early membrane-actin interactions.

Myosin II

Myosin II, also known as conventional myosin, is the primary isoform responsible for forming filaments that drive cytoskeletal organization and across eukaryotic cells. It consists of two heavy chains, each approximately 200 , that dimerize through their C-terminal coiled-coil , with each heavy chain featuring an N-terminal globular motor domain, a region bound to two light chains ( and regulatory), and a long α-helical rod-like . These dimers self-assemble via electrostatic interactions in the tail domain to form filaments, with muscle variants typically measuring about 1.6 μm in length and comprising roughly 300 myosin molecules, enabling collective force generation on filaments. In non-muscle cells, these filaments are shorter, around 300 nm, and contain fewer molecules (approximately 30), but retain the architecture with a central bare zone flanked by motor heads arranged in crowns. Myosin II exists in multiple isoforms encoded by distinct genes, tailored to specific tissues and functions. Skeletal muscle isoforms are primarily MYH1 (fast oxidative), MYH2 (fast oxidative-glycolytic), MYH3 (embryonic), and MYH4 (fast glycolytic), which support rapid in different types. Cardiac isoforms include MYH6 (α-myosin heavy chain, predominant in atrial and small ventricular myocytes) and MYH7 (β-myosin heavy chain, main in ventricular myocytes), contributing to the heart's rhythmic pumping. and non-muscle isoforms encompass MYH9 (non-muscle IIA), MYH10 (non-muscle IIB), MYH11 (), and MYH14 (non-muscle IIC), which facilitate in vascular and visceral smooth muscles as well as dynamic cytoskeletal remodeling in non-muscle cells. In non-muscle cells, Myosin II powers by assembling into contractile rings that constrict to divide the , a process essential for . In striated muscle, it drives sliding during contraction, where bipolar filaments interact with thin filaments to generate shortening forces. Activity is tightly regulated by of the regulatory light chain (RLC) at serine 19, which relieves an autoinhibited conformation, promotes filament assembly, and enhances actin-activated activity, thereby modulating force output in both contexts. Recent studies have elucidated how filament structure influences force production, demonstrating that the tensile force generated by Myosin II bundles is directly proportional to the number of motor heads per , with implications for ensemble mechanics in muscle and cytoskeletal dynamics. This proportionality highlights the cooperative role of multiple heads in amplifying output, consistent with the power stroke mechanism operating within assembled .

Myosin V

Myosin V is a class of unconventional myosin motors characterized by their ability to undergo processive movement along filaments, enabling the of various cellular cargoes such as vesicles and organelles. Unlike muscle myosins, myosin V operates as a dimeric protein, with each consisting of a globular head domain for binding and , a region, and a tail domain. This dimeric architecture allows for coordinated stepping, making it highly efficient for long-distance intracellular without frequent dissociation from actin tracks. The structure of myosin V features a long neck domain containing six IQ motifs, which bind calmodulin light chains and contribute to a high duty ratio— the proportion of time the motor spends attached to during its cycle— facilitating sustained processivity. The C-terminal globular domain is specialized for , interacting with specific adaptors or receptors on organelles like melanosomes, enabling targeted . For instance, in melanocytes, the of MYO5A binds to melanosomes via intermediaries such as melanophilin and Rab27a, ensuring precise transport. This structural design supports a characteristic hand-over-hand stepping mechanism, where the trailing head advances to become the leading head, covering 36 nm per step, matching the pseudo-repeat distance. Functionally, myosin V drives unidirectional, plus-end-directed transport along filaments, playing critical roles in cellular and positioning. In neurons, MYO5A facilitates the movement of and secretory vesicles within growth cones, supporting axonal extension and formation. Similarly, in melanocytes, it transports melanosomes to the periphery for distribution. Although myosin V itself is plus-end directed, cargoes it binds can exhibit bidirectional movement when coupled with microtubule-based motors like , allowing dynamic routing in polarized cells such as neurons. This processivity, with run lengths exceeding 1 μm, underscores its role in maintaining cellular architecture and function. Regulation of myosin V activity involves an autoinhibited state where the globular folds back onto the head, suppressing activity and preventing unproductive movement. Cargo binding to the releases this inhibition by promoting dimerization and relieving the intramolecular , thereby activating processive . Calcium levels and binding to IQ motifs further modulate this, with elevated calcium potentially slowing velocity. Isoforms such as MYO5B, expressed in epithelial cells including the gut, mediate apical-basal trafficking of endosomes and are essential for nutrient absorption; defects here lead to microvillus inclusion disease. Pathologically, mutations in the MYO5A gene disrupt transport, causing type 1 (), an autosomal recessive disorder marked by silvery-gray hair, , and severe neurological deficits due to impaired neuronal delivery. Specific mutations, such as deletions in the F-exon, abolish motor function and cargo interaction, leading to perikaryal accumulation of organelles. Unlike GS2 caused by RAB27A defects, GS1 lacks but features progressive neurodegeneration.

Myosin VI

Myosin VI is the only known class of myosin that moves toward the minus ends of filaments, enabling it to perform unique roles in intracellular transport that other myosins cannot.00482-4) Structurally, it features a monomeric configuration in its autoinhibited state, adopting a compact "head-to-tail" where the tail domain folds back onto the motor domain to block binding and activity. Dimerization occurs upon binding to adaptors, facilitated by a short coiled-coil region and proximal cargo-binding domain, allowing processive movement.00633-3) A distinctive feature is the reverse orientation of its lever arm, achieved through Insert 2 (a large insertion in the motor domain's upper 50 kDa subdomain), which rotates the lever arm approximately 180° relative to conventional myosins, directing motion toward minus ends. This insert also contributes to a large working , supporting variable step sizes of 30-36 nm and high processivity as a dimer. In cellular functions, myosin VI plays critical roles in endocytosis by concentrating at clathrin-coated pits, where it facilitates the inward movement of early vesicles along filaments. It also contributes to Golgi complex trafficking, maintaining integrity and supporting exocytic pathways through interactions that position it at the trans-Golgi network. These activities rely on its minus-end-directed processivity, allowing it to tether and transport cargo toward the cell interior, distinct from plus-end motors like myosin V.00482-4) Regulation of myosin VI involves cargo-induced activation via adaptor proteins, such as Disabled-2 (DAB2), which binds the cargo-binding domain to induce dimerization and relieve autoinhibition, thereby linking the motor to endocytic vesicles.00633-3) Other adaptors, like optineurin, similarly promote Golgi targeting by stabilizing the dimeric form and specifying cargo interactions. This adaptor-mediated mechanism ensures context-specific activation, modulating its monomeric tethering versus dimeric transport modes.00633-3) Evolutionarily, myosin VI's minus-end directionality arose from adaptations in its motor domain, particularly the lever arm insert, setting it apart as the sole unconventional myosin class with this polarity in vertebrates and invertebrates.

Other Unconventional Myosins

Myosin III represents a unique of unconventional myosins characterized as a single-headed motor with an N-terminal domain that enables autophosphorylation and regulation of its motor activity. This kinase-motor hybrid structure allows Myosin III to transport actin-binding proteins, such as espin, to the tips of in sensory hair cells, where it promotes bundling and cross-linking essential for stereocilia maintenance and length regulation. In the , MYO3A and MYO3B isoforms play critical roles in phototransduction by modulating dynamics in photoreceptor cells, ensuring proper organization of the for visual signaling. Myosin VII is a dimeric, unconventional myosin with a dual-headed structure and a tail domain that folds back toward the motor-neck region, forming a compact monomer in solution. It functions primarily in maintaining stereocilia integrity in inner ear hair cells by linking cadherins to the actin cytoskeleton, which supports mechanotransduction and bundle cohesion. Mutations in MYO7A, the gene encoding Myosin VIIa, underlie Usher syndrome type 1, highlighting its significance in auditory and vestibular function, though its core role involves actin-based anchoring and transport in sensory epithelia. Myosin X, or MYO10, is an unconventional myosin featuring MyTH4-FERM domains in its tail for cargo recognition and a pleckstrin (PH) domain that targets it to lipids on membranes. This structure enables Myosin X to localize to tips, where it drives filopodia formation, extension, and stabilization by transporting regulatory proteins and facilitating during migration. Its motor activity supports polarized epithelial functions and fusion by promoting actin-based protrusions that mediate intercellular contacts. Myosin XV, encoded by MYO15A, possesses a motor domain and an extended tail with two FERM domains that interact with whirlin to regulate elongation in cochlear and vestibular s. It drives the graded staircase architecture of bundles by transporting elongation factors to tips, ensuring precise height gradation and diameter control across rows, which is vital for auditory mechanosensation. in MYO15A cause hereditary by disrupting this actin-based assembly, underscoring its role in . Class IX myosins are single-headed motors with a C-terminal domain that negatively regulates Rho signaling, influencing dynamics at focal adhesions. In , they contribute to by modulating adhesion turnover and cytoskeletal remodeling at integrin-based sites. Class XI myosins are -specific, multimeric motors responsible for rapid and organelle transport, including movement along filaments. They exhibit high velocity, up to 60 μm/s in some isoforms, facilitating long-distance trafficking in elongated plant cells. Higher-numbered myosin classes (XII–XIX) are less characterized but fulfill specialized roles in diverse organisms, often in -associated or . The following table summarizes key examples:
ClassPrimary Organism/SystemKey FunctionExample Significance
XIIMammals (e.g., MYO12A/B)Potential role in cargo and dynamicsSupports vesicular trafficking in epithelial cells
XIIIMammals (e.g., MYO13A)Intracellular of vesiclesInvolved in endocytic recycling pathways
XIVParasites (e.g., like ) and host cell invasionPowers actin-dependent propulsion in parasites
XVIMammals (e.g., MYO16)Association with cytoskeletal anchorsRegulates microtubule-actin crosstalk in neurons
XVIIMammals (e.g., MYO17A)Limited data; possible linkageExpressed in epithelial tissues for adhesion support
XVIIIMammals (e.g., MYO18A/B)Endocytic and phagocytic processesAids in during engulfment
XIXMammals (e.g., MYO19)Mitochondrial and positioningDrives actin-based movement of mitochondria in energy-demanding cells

Physiological Functions

Role in Muscle Contraction

In striated muscle, the serves as the fundamental contractile unit, where thick filaments composed primarily of interdigitate with thin filaments made of , anchored at the Z-lines that define the boundaries of each . This arrangement allows for the sliding filament mechanism, in which the thick filaments, with their projecting myosin heads, overlap the actin thin filaments extending from opposite Z-lines, enabling force generation through cross-bridge interactions without altering filament lengths. The precise interdigitation ensures that shortening occurs via relative filament sliding, with the degree of overlap influencing the maximum force output. Muscle contraction is initiated by the release of calcium ions (Ca²⁺) from the , which bind to on the thin filaments, inducing a conformational change that shifts away from the myosin-binding sites on . This exposes the sites, allowing energized myosin heads to form cross-bridges with , initiating the power stroke that pulls the thin filaments toward the center. The cycle repeats as detaches and re-energizes the myosin heads, sustaining filament sliding until Ca²⁺ levels drop and re-blocks the sites. The velocity of shortening versus force production follows the Hill equation, approximately (F + a)(v + b) = (F₀ + a)b, where F is load, v is velocity, F₀ is maximum force, and a and b are muscle-specific constants reflecting the hyperbolic relationship that balances speed and power. Different myosin II isoforms tailor contraction properties across muscle types; for instance, fast skeletal muscles predominantly express MYH1 (myosin heavy chain IIx), enabling rapid shortening for explosive movements, while slow skeletal muscles rely on MYH7 (myosin heavy chain I), supporting sustained, fatigue-resistant contractions. In , MYH7 predominates, and regulation involves a super-relaxed state where myosin heads are sequestered along the thick filament backbone, minimizing activity to conserve energy during and enhancing efficiency during . This state allows precise modulation of force and velocity in response to physiological demands. The energetic cost of contraction is substantial, as each cross-bridge cycle consumes one ATP to drive the collective sliding of filaments and generate force. This high turnover underscores the efficiency of myosin II in coupling chemical energy to mechanical work, with variations in isoform influencing the rate of ATP utilization.

Roles in Cellular Motility and Transport

Myosins play essential roles in non-muscle cellular processes, particularly through unconventional isoforms that drive motility and intracellular transport along actin filaments. In cytokinesis, non-muscle myosin II assembles into a contractile ring at the cell equator during mitosis, where its motor activity generates the force required to constrict the plasma membrane and divide the cytoplasm into two daughter cells. Phosphorylation of the myosin II regulatory light chain activates filament assembly and bipolar minifilament formation, enabling the ring to purse-string the cell membrane with a constriction rate of approximately 1-2 μm/min in mammalian cells. This process relies on myosin II's ATPase-dependent sliding of actin filaments, and inhibition of its activity leads to cytokinesis failure and binucleate cells. Unconventional myosins V and VI mediate short-range organelle transport in the actin-rich cortical regions of cells, complementing microtubule-based motility. Myosin V transports melanosomes in melanocytes toward the cell periphery along actin tracks, interacting with Rab27a and melanophilin adaptors to deliver pigment granules for skin coloration; mutations in this pathway cause Griscelli syndrome with defective pigmentation. Similarly, myosin V facilitates mitochondrial positioning in neurons and fibroblasts by handing off cargos from microtubules to actin networks near synapses or growth cones. Myosin VI, moving toward the pointed end of actin filaments, drives endocytic vesicle trafficking from the plasma membrane inward, including uncoated endosomes at speeds up to 35 nm/s, and supports melanosome maturation by tethering them to the cytoskeleton. In , class I myosins contribute to leading-edge dynamics by linking to plasma in lamellipodia. Myosin I isoforms, such as myosin Ib and Ic, regulate and recruit molecules like to lamellipodial tips, promoting stable contacts that propel forward movement at rates of 0.1-1 μm/min in migrating epithelial cells. Myosin IX acts as a RhoGAP to locally inactivate RhoA signaling, facilitating remodeling and reducing contractility at the to enable persistent in immune and epithelial cells. Myosin X drives extension and stabilization during exploratory , transporting and to filopodial tips to sense and initiate adhesions, which is critical for endothelial and cancer . Sensory functions of myosins are prominent in specialized cells, where they maintain structural integrity and transduction in actin-based bundles. Myosin VIIa localizes to the of s, anchoring tip links and transducing mechanical stimuli into electrical signals for hearing; its mutations cause with combined deafness and retinal degeneration. Myosin XVa positions actin-protruding at hair cell tips via whirlin interactions, ensuring proper bundle morphology essential for vestibular and auditory function. In vision, myosin IIIa in photoreceptor cells transports visual into rhabdomeric microvilli upon light exposure, adapting phototransduction and preventing saturation; its kinase-motor dual function regulates cargo binding dynamically. Myosins integrate with microtubule motors like and for efficient hybrid transport, particularly in neurons and polarized epithelia. Myosin V tethers to -1 via adaptor proteins on organelles such as mitochondria, enhancing bidirectional movement by buffering pauses and preventing premature unloading during switches between and tracks. This coordination ensures long-range delivery followed by local actin-based positioning, with myosin V's processivity (step size ~36 nm) complementing kinesin's longer runs.

Genetics and Expression

Human Myosin Genes

The contains 40 genes encoding myosin heavy chains, spanning 12 distinct classes, along with one , MYH16 on 7q22.1. These genes are dispersed across multiple s and are broadly divided into conventional class II myosins (encoded by the MYH family) and unconventional myosins (encoded by various MYO families). Conventional myosins predominate in striated and tissues, facilitating contraction through actin-myosin interactions, while unconventional myosins support diverse non-muscle functions such as vesicular transport, positioning, and membrane dynamics. Conventional myosins encompass skeletal muscle isoforms like MYH1 (fast type 2X), MYH2 (fast type 2A), MYH3 (embryonic), and MYH4 (fast type 2B), all clustered on chromosome 17p13.1 and expressed primarily in fast-twitch skeletal fibers for rapid contraction. Cardiac isoforms MYH6 (α-myosin) and MYH7 (β-myosin) are located on chromosome 14q11.2, with MYH6 predominant in atrial and fast ventricular myocardium and MYH7 in ventricular and slow skeletal muscle for sustained force generation. Non-muscle and smooth muscle variants include MYH9 (non-muscle IIA) on 22q12.3, involved in platelet contraction and cytokinesis; MYH10 (non-muscle IIB) on 17p13.1, supporting cell migration and adhesion; MYH11 (smooth muscle) on 16p13.11, essential for vascular and visceral smooth muscle tone; and MYH14 (non-muscle IIC) on 19q13.33, contributing to epithelial integrity and hearing. Unconventional myosins include class I (MYO1A–H), distributed across chromosomes such as 12q13.3 (MYO1A, microvilli in ), 2q32.3 (MYO1B, plasma membrane tension), and 17p13.3 (MYO1C, anchoring), generally linking to membranes for tension sensing and trafficking. Class V myosins MYO5A and MYO5C on 15q21.2 and MYO5B on 18q21.1 mediate melanosome and vesicle transport along actin filaments in melanocytes, neurons, and epithelia. MYO6 on 6q14.1 drives endocytic and Golgi positioning, while MYO7A on 11q13.5 supports stereocilia maintenance in sensory hair cells of the . Other classes, such as MYO3 (10p12.1 for MYO3A, phototransduction in ) and MYO10 (5p15.1, extension), further diversify -based motility in specialized cells.
GeneClassPrimary Tissue/ExpressionAssociated FunctionsChromosome
MYH1IISkeletal muscle (fast-twitch)Rapid contraction in type 2X fibers17p13.1
MYH2IISkeletal muscle (fast-twitch)Force generation in type 2A fibers17p13.1
MYH3IIEmbryonic skeletal muscleDevelopmental fiber assembly17p13.1
MYH4IISkeletal muscle (fast-twitch)High-speed contraction in type 2B fibers17p13.1
MYH6IICardiac muscle (atrial)Atrial contraction and heart rate14q11.2
MYH7IICardiac and slow skeletal muscleVentricular force and endurance14q11.2
MYH9IINon-muscle cells (platelets)Cytokinesis and cell adhesion22q12.3
MYH10IINon-muscle cellsCell migration and shape maintenance17p13.1
MYH11IISmooth muscle (vascular)Vascular tone and peristalsis16p13.11
MYH14IINon-muscle (epithelium)Tissue integrity and audition19q13.33
MYO1AIIntestinal brush borderMicrovilli stabilization12q13.3
MYO1BIUbiquitous (membrane)Actin-membrane tethering2q32.3
MYO1CINuclear and cytoplasmicGene expression regulation17p13.3
MYO5AVMelanocytes and neuronsMelanosome transport15q21.2
MYO5BVEpithelial cellsApical recycling and polarity18q21.1
MYO5CVSensory epitheliaVesicle trafficking15q21.2
MYO6VIEndocytic compartmentsIntracellular sorting6q14.1
MYO7AVIISensory hair cellsStereocilia bundle integrity11q13.5
MYO10XFibroblasts and neuronsFilopodia formation and guidance5p15.1
This table highlights representative genes; the full set includes additional isoforms like MYH8 (perinatal skeletal, 17p13.1), MYH13 (extraocular, 17p13.1), MYO3A (, 10p12.1), and MYO15A (, 17p11.2), among others.

Regulation of Expression

The expression of myosin genes is regulated at the transcriptional level by specific transcription factors that dictate tissue-specific patterns. In , the myocyte enhancer factor 2 (MEF2) transcription factors are essential for activating the promoters of fast myosin heavy chain genes, including MYH1 and MYH2, thereby promoting their expression during and fiber type specification. In cells, serum response factor (SRF), in association with coactivators like myocardin, binds to CArG boxes in the MYH11 promoter to drive the expression of smooth muscle myosin heavy chain, which is critical for contractile function. Isoform switching of myosin heavy chains occurs during development to match physiological needs, involving coordinated changes in . In , the embryonic isoform encoded by MYH3 predominates early in development and is progressively downregulated, giving way to adult fast isoforms such as MYH1 to support increased contractile speed and power. In the heart, thyroid hormone modulates the MYH7 (β-myosin heavy chain, slow) to MYH6 (α-myosin heavy chain, fast) ratio; represses MYH7 while enhancing MYH6 expression, optimizing cardiac performance under varying metabolic demands. Post-transcriptional mechanisms further refine myosin expression, particularly in response to developmental cues and pathological states like . MicroRNAs such as miR-133a target the 3' of MYH7 mRNA, downregulating its expression during cardiac to influence the shift toward faster contractile isoforms. in the tail domains of unconventional myosins, including myosin Va and myosin VI, produces isoforms with altered cargo-binding capabilities; for example, inclusion or exclusion of specific exons in the medial tail of myosin Va modulates its interactions with melanophilin and other adapters in a cell-type-specific manner. Tissue-specific regulation ensures appropriate myosin localization, as seen with MYO5A, which exhibits enrichment in neurons due to repression by the RE1-silencing (REST) in non-neuronal cells; REST binds to RE1 elements in the MYO5A promoter, silencing its expression outside neural tissues to prevent ectopic activity.

Clinical and Pathophysiological Aspects

Mutations and Associated Diseases

Mutations in the MYH7 gene, encoding β-cardiac myosin heavy chain, are a leading cause of (HCM), an autosomal dominant disorder characterized by and increased risk of arrhythmias and . Over 1,000 mutations have been identified across sarcomeric genes in HCM, with MYH7 accounting for approximately 30-50% of familial cases, including the seminal R403Q in the globular head domain that enhances myosin activity and contractility by altering the lever arm swing and actin-myosin interactions. This mutation, first reported in 1993, exemplifies how HCM-associated MYH7 variants disrupt the super-relaxed state of myosin, leading to hypercontractility and energy inefficiency in cardiac sarcomeres. In contrast, truncating variants in MYH7 are implicated in (), an autosomal dominant condition featuring ventricular dilation and systolic dysfunction, where they reduce force-generating capacity by producing non-functional myosin tails that impair assembly and cross-bridge cycling. These mutations, often leading to , result in decreased myocardial force output and progression to heart failure, distinct from the gain-of-function effects seen in HCM. Mutations in unconventional myosins also underlie sensory and epithelial disorders. Biallelic variants in MYO7A cause type 1B (USH1B), an autosomal recessive condition combining congenital profound deafness, vestibular dysfunction, and progressive due to defective maintenance in hair cells and photoreceptor transport in the . Similarly, recessive mutations in MYO15A are responsible for DFNB3 nonsyndromic deafness, where loss of myosin XVa function disrupts bundling and elongation in auditory hair cells, leading to prelingual profound . Other myosin-related diseases include microvillus inclusion disease (MVID), a severe autosomal recessive enteropathy caused by biallelic MYO5B mutations that impair apical trafficking and microvilli formation in intestinal epithelial cells, resulting in intractable and from infancy. Additionally, dominant MYH9 mutations lead to MYH9-related disorders, encompassing macrothrombocytopenia with giant platelets and inclusions, often accompanied by progressive , cataracts, and nephropathy due to disrupted non-muscle myosin IIA function in platelet formation and leukocyte . Recent studies (2020-2025) highlight the in MYH7's as a severe variant that prolongs attachment by slowing release, thereby boosting contractility while destabilizing the super-relaxed state and increasing myosin duty ratio, contributing to hypertrophic remodeling.

Therapeutic Targeting and Inhibitors

Therapeutic targeting of myosin has emerged as a promising strategy in cardiovascular medicine, particularly for conditions involving excessive such as obstructive (HCM). Cardiac myosin inhibitors represent a class of small molecules designed to modulate β-cardiac myosin activity, thereby reducing hypercontractility without broadly impairing cardiac function. Mavacamten, the first approved cardiac myosin inhibitor, received U.S. (FDA) approval in for the treatment of symptomatic obstructive HCM in adults. This oral agent allosterically stabilizes the super-relaxed state of cardiac myosin, which decreases the number of myosin-actin cross-bridges and reduces activity, leading to diminished contractility. Clinical trials, including the phase 3 EXPLORER-HCM study, demonstrated that improves exercise capacity, alleviates symptoms, and lowers left gradients in patients with obstructive HCM. The phase 3 VALOR-HCM trial further showed that significantly reduced the need for septal reduction therapy by 82% compared to after 16 weeks of treatment, highlighting its role in delaying invasive procedures. Aficamten, another next-generation cardiac myosin inhibitor, has completed phase 3 clinical development, with positive topline results from the reported in late 2024, additional data from the presented in 2025, and ongoing evaluations in non-obstructive HCM via the . As of November 2025, the (NDA) for aficamten is under FDA review, with a (PDUFA) target action date of December 26, 2025. Like , aficamten binds to the motor domain of cardiac myosin to inhibit activation, but it achieves this without fully blocking activity, allowing for dose-dependent modulation of contractility. In the , aficamten outperformed metoprolol in improving peak oxygen uptake and symptom relief in symptomatic obstructive HCM, positioning it as a potential first-line with a favorable safety profile comparable to beta-blockers. Beyond cardiac applications, myosin inhibitors have been explored for non-muscle myosin II (NMII) in cellular processes like . Blebbistatin, a prototypical small-molecule of class II myosins, binds to the motor domain of NMII to prevent actin-activated activity, effectively halting in research models without disrupting early furrow ingression. Analogs of blebbistatin, such as para-nitroblebbistatin, have been developed to address limitations like and poor , enabling more precise studies of NMII in and migration. Recent structure-activity relationship efforts have yielded NMII-selective inhibitors with reduced activity against cardiac myosin, minimizing off-target cardiac effects while maintaining potency for non-muscle applications. In 2025, emerging brain-penetrant analogs with cardiac-sparing profiles are under investigation for potential neurological uses, though they remain primarily in preclinical stages. Developing myosin inhibitors faces key challenges, including achieving isoform specificity to avoid unintended effects on non-target myosins, such as skeletal or variants, and overcoming physicochemical issues like low aqueous solubility that complicate formulation and . For instance, early inhibitors like blebbistatin exhibit broad class II myosin inhibition, prompting ongoing efforts to engineer selectivity through targeted chemical modifications. In clinical settings, cardiac myosin inhibitors like require careful monitoring for left ventricular reductions, as seen in trials where dose adjustments were needed in up to 25% of patients, underscoring the need for personalized dosing strategies. These hurdles are being addressed in ongoing trials, such as VALOR-HCM extensions, to refine therapeutic windows and expand applications.

Related Proteins

Paramyosin

Paramyosin is an invertebrate-specific protein that serves as a key structural component associated with myosin in muscle thick filaments, particularly in molluscan and other non-vertebrate smooth and obliquely striated muscles. It forms a rigid, paracrystalline core within these filaments, providing mechanical stability and enabling specialized contractile properties not found in muscles. Unlike vertebrate systems, where thick filaments consist primarily of myosin, paramyosin's presence allows for the assembly of longer, more stable filaments that support sustained tension with minimal energy expenditure. This protein is encoded by a single in many invertebrates, such as nematodes and molluscs, and its expression is tightly linked to muscle development. Structurally, paramyosin is a homodimeric α-helical coiled-coil protein, with each subunit comprising approximately 850–950 and a molecular weight of around 100–120 kDa, depending on the . About 95% of its adopts an α-helical conformation, characterized by heptad repeats of hydrophobic residues that stabilize the coiled-coil dimer. This extended rod-like structure, roughly twice the length of vertebrate (approximately 40–50 nm long), assembles end-to-end and side-by-side to create the central core of thick filaments in molluscan muscles, such as those in bivalves and cephalopods. Myosin molecules surround this core, binding via their tail domains to integrate paramyosin into the filament lattice. Functionally, paramyosin stabilizes myosin filaments by promoting their ordered assembly and preventing disassembly under , which is essential for generation in muscles. It interacts directly with the coiled-coil tails of myosin heavy chains, facilitating co-polymerization and indirectly modulating myosin's actin-activated activity by enhancing filament-actin interactions and reducing the off-rate of cross-bridges. In molluscan catch muscles, paramyosin enables the "catch" state—a latch-like for prolonged at low ATP consumption—by providing a rigid scaffold that maintains cross-bridge attachments. This state is regulated by calcium ions (Ca²⁺) through interactions with and of associated proteins like twitchin, allowing reversible transitions between relaxed and contracted forms without continuous cycling. Evolutionarily, paramyosin is absent in vertebrates, reflecting a divergence in muscle early in metazoan ; it is a homolog of the rod domain in myosin heavy chains rather than a direct relative of , though it shares functional analogies as a coiled-coil of contraction. While in vertebrates wraps around thin filaments to sterically block myosin binding in a Ca²⁺-dependent manner, paramyosin operates intrafilamentously within thick filaments, promoting and enabling unique regulatory states like the catch mechanism. This longer, internal positioning distinguishes it from the shorter, surface-oriented , highlighting adaptations in muscle for diverse physiological demands, such as burrowing or shell closure in molluscs.

Interactions with Actin and Other Motors

Myosins interact with filaments primarily through their motor domains, which bind to actin in a polarity-dependent manner that determines the direction of movement. For most myosin classes, such as myosins I, II, V, and X, the motor domain propels the myosin toward the plus (barbed) end of the actin filament, facilitating directed along polarized cytoskeletal tracks. In contrast, myosin VI uniquely moves toward the minus (pointed) end, enabling retrograde in processes like . This polarity-driven interaction is essential for generating force and displacement in cellular contexts, where the core actin-binding domain within the motor head establishes the initial contact. Coordination between myosins and microtubule-based motors like kinesins often occurs at junctions where filaments intersect , allowing for seamless handoff of vesicular cargos during intracellular . Myosin V, a plus-end-directed motor, collaborates with kinesin-1, a plus-end-directed motor, to tether and transfer organelles such as melanosomes or secretory vesicles from tracks to , ensuring efficient long-range delivery in cells like melanocytes and neurons. This heteromotor complex forms dynamic links that enhance processivity, with myosin V halting microtubule-based to initiate actin-dependent movement at crossroads. In neuronal endosomal positioning, myosin VI engages in competitive and cooperative dynamics with , a minus-end-directed motor, to regulate localization along axons and dendrites. Myosin VI drives endosomes toward actin-rich peripheral regions, counteracting dynein's centralizing pull toward the microtubule-organizing center, which fine-tunes endosomal distribution for synaptic function. Muskelin facilitates these dynein-myosin VI interactions, promoting endosomal delivery to nuclear-adjacent sites while balancing forces to prevent aberrant clustering. Recent structural insights from cryo-electron microscopy (cryo-EM) have elucidated the rigor state of - complexes, revealing atomic-level details of binding interfaces. In 2024, high-resolution cryo-EM structures of -IC bound to F- in rigor demonstrated adaptations in the motor domain that enhance affinity, with an altered interface supporting its roles in cellular adhesion. Similarly, cryo-EM analysis of myosin V's lever arm in rigor highlighted its flexibility, swinging through a 93° angle along the axis to transition post-powerstroke states, informing models of force generation. Beyond specific motors, myosins contribute to the actomyosin cortex, a dynamic meshwork underlying the plasma membrane, where non-muscle integrates with Arp2/3-branched actin networks to generate contractile forces. Non-muscle assembles into minifilaments that pull on Arp2/3-nucleated branches, constraining cortical tension and driving processes like and migration. This cross-talk between contractility and Arp2/3-mediated branching maintains cortical integrity, with disruptions leading to altered hydraulic pressure and blebbing. In composite networks, linear and branched F-actin architectures optimize myosin-induced contractility, preventing excessive deformation while enabling force transmission.