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Somite

A somite is a paired, transient block of paraxial mesoderm that forms bilaterally along the neural tube in the developing vertebrate embryo during the process of somitogenesis, serving as a precursor to key axial structures such as the vertebrae, skeletal muscles, and dermis. These somites emerge sequentially from the unsegmented paraxial mesoderm, starting cranially and progressing caudally, with each new pair added approximately every 4 to 6 hours in humans. In human embryos, somitogenesis begins around day 20 post-fertilization and typically results in about 44 pairs of somites by the end of the fifth week, primarily during Carnegie stages 9 through 14. The formation of somites involves a highly regulated "clock and " mechanism, where oscillating networks—such as those involving the pathway—interact with morphogen gradients like (FGF) to establish periodic segmentation. Once formed, each somite epithelializes into a ball-like structure and differentiates into three main compartments: the sclerotome, which gives rise to the and bone of the vertebrae and ribs; the , which forms the skeletal muscles of the body wall, limbs, and back; and the dermatome, which contributes to the of the dorsal . This segmentation not only establishes the metameric but also guides the of cells and the outgrowth of spinal nerves, ensuring proper coordination between the musculoskeletal and nervous systems. Somites play a critical role in vertebrate evolution and development, with their derivatives influenced by signaling molecules such as Sonic hedgehog (Shh) from the and floor plate, Wnt proteins from the dorsal , and 4 (BMP4) from the , which specify ventral, dorsal, and lateral cell fates, respectively. Disruptions in somitogenesis can lead to congenital anomalies like or segmentation defects, highlighting the precision required in this process.

Overview

Definition and Characteristics

Somites are bilaterally paired, transient blocks of paraxial that form along the anterior-posterior axis in embryos during somitogenesis, serving as precursors to segmented structures in the body. These structures arise on either side of the and play a key role in establishing the segmental organization of the , musculature, and . In s, somites typically number between 30 and 60 pairs, varying by species; for example, embryos form approximately 42–44 pairs, while embryos develop around 65 pairs. Histologically, somites initially consist of mesenchymal cells that undergo epithelialization, transforming into epithelial somites characterized by a enclosing a central mesenchymal cavity known as the somitocoel. This epithelial layer surrounds the somitocoel, which contains proliferating mesenchymal cells that later contribute to somite maturation. Each somite measures roughly 100–200 μm in diameter, with dimensions scaling relative to embryonic size across species. Somites exhibit intrinsic rostral-caudal polarization, dividing each into distinct anterior (rostral) and posterior (caudal) halves with differing properties, including variations in molecules that promote boundary formation between adjacent somites. This polarity is also reflected in gradients of expression, which establish positional identity along the axis and influence cell fate within the halves. Such characteristics integrate with oscillatory mechanisms like the segmentation clock to ensure precise patterning.

Embryonic Formation and Timing

Somites form from the paraxial , transient blocks of tissue that arise bilaterally along the anterior-posterior axis of the vertebrate , positioned lateral to the and flanking the . This paraxial mesoderm originates during and segments sequentially into somites as the elongates caudally. In humans, somitogenesis begins during the third week of embryonic development, around day 20 post-fertilization, with the first pair of somites appearing adjacent to the occipital region, and continues through the fifth week, corresponding to 9 through 14, by which time approximately 30 pairs have formed, though the process ultimately yields about 42-44 pairs total by the end of the fifth week. In mice, somites start forming at embryonic day (E) 8.0 and proceed until approximately E12.5 to E13.0, generating 62-65 pairs that establish the . embryos initiate somitogenesis at about 10 hours post-fertilization (hpf), with pairs forming progressively until around 30 hpf, resulting in 30-32 somites. In chick embryos, the process commences at Hamburger-Hamilton () stage 7-8 and extends through stage 20 and beyond, producing 51-53 pairs in total. Somite formation occurs periodically, with the interval between successive pairs varying by species: approximately 30 minutes in , 90 minutes in , and 120 minutes in mice, while in humans the rate is roughly 90 minutes per pair early on. The total number of somites formed across species correlates with the length of the embryonic axis, ranging from fewer pairs in shorter-bodied vertebrates to hundreds in elongated forms like snakes. As somites develop, they undergo maturation where anterior somites differentiate earlier than posterior ones, progressively losing their initial epithelial integrity through localized epithelial-to-mesenchymal transitions that enable compartmentalization into subregions. This regression of epithelial structure begins in the ventromedial portions of the most rostral somites, facilitating subsequent reorganization without disrupting the overall segmental pattern.

Somitogenesis

Presomitic Mesoderm and Segmentation

The presomitic (PSM) consists of a longitudinal strip of mesenchymal cells positioned bilaterally posterior to the forming somites during vertebrate embryogenesis. This tissue originates from the during and later from the tailbud mesoderm as the body axis elongates. The PSM cells exhibit a proliferative mesenchymal state, sustained by high levels of (FGF) and Wnt signaling emanating from the posterior embryonic region, which promotes and inhibits . Along the anterior-posterior axis of the PSM, a signaling establishes patterning that drives segmentation. FGF signaling, particularly FGF8, is highest in the posterior PSM and decreases anteriorly, while () signaling is elevated in the anterior region, counteracting FGF activity. This opposing modulates cell proliferation: posterior cells under high FGF continue dividing rapidly, whereas anterior cells, exposed to low FGF and high , slow proliferation and arrest in the of the , forming a somite bud at the anterior PSM tip. Somite boundaries form at a specific anterior known as the determination front, where PSM cells exit the , commit to the somitic fate, and undergo rostro-caudal patterning. At this front, the Mesp2 (in mice) is expressed in nascent somites, conferring anterior-posterior by regulating downstream genes that specify segmental . This process involves brief contributions from signaling to synchronize cellular states, though its detailed role lies beyond the cellular dynamics here. The clock-wavefront model conceptually integrates these dynamics, positing that a posteriorly regressing (the determination front) interacts with traveling waves of across the PSM, timing boundary formation such that somites bud off periodically from the anterior end.

Epithelialization and Maturation

Following boundary formation, nascent somites undergo a mesenchymal-to-epithelial transition (MET), in which mesenchymal cells from the presomitic reorganize into a cohesive epithelial structure. This process is driven by the establishment of apical-basal in somite cells, mediated by regulators such as Cdc42 and Rac1, which play differential roles in promoting and junction formation. Concurrently, N-cadherin expression is upregulated and localized to adherens junctions, facilitating strong cell-cell adhesion essential for epithelial integrity, while extracellular matrix components like are remodeled to support cell rearrangements. The Paraxis further stabilizes this epithelial state by integrating multiple signaling inputs to maintain somite cohesion during early maturation. Somite morphology evolves rapidly post-segmentation, beginning as compact, ball-like epithelial structures that initially elongate along the rostro-caudal due to oriented divisions and cytoskeletal dynamics. In embryos, these nascent somites form spherical epithelial balls enclosing a central fluid-filled known as the somitocoel, which contains loosely arranged mesenchymal cells. Over time, the somites transition to a more elongated, rectangular shape; the ventral portion undergoes epithelial-to-mesenchymal transition to form the mesenchymal sclerotome that surrounds the , while the dorsal portion remains epithelial, forming the dermomyotome, setting the stage for subsequent compartmentalization. In chick embryos, the early epithelial phase of somite maturation lasts approximately 8-10 hours after formation, during which the somite maintains its epithelial organization before beginning to differentiate internally. This is followed by resegmentation, a process in which the anterior and posterior halves of each somite's sclerotome contribute to adjacent vertebrae, resulting in a half-segment shift that aligns skeletal elements with surrounding tissues. Somite maturation is influenced by interactions with adjacent midline structures, including the and , which promote ventralization of the somite through contact-dependent cues that guide the epithelial-to-mesenchymal transition in the ventral domain. These environmental signals ensure proper dorso-ventral patterning without disrupting the initial epithelial architecture.

Molecular Mechanisms

Segmentation Clock and Oscillators

The segmentation clock is a molecular oscillator operating within cells of the presomitic mesoderm (PSM) that regulates the periodic formation of somites during embryogenesis. This clock manifests as cyclic expression of specific genes, particularly members of the Hes/Her family of basic helix-loop-helix transcription factors, which oscillate with periods ranging from 30 minutes in to approximately 5-6 hours in humans, synchronized across the PSM tissue to ensure coordinated somite budding. The initial discovery of this oscillatory mechanism came from observations of dynamic c-hairy1 (cHairy1) expression in the PSM, where transcripts appeared in successive matching the somitogenesis rhythm. At the core of the segmentation clock are loops involving autorepression of Hes/Her genes, which drive their expression. In mice, Hes7 forms a primary oscillator through delayed , where Hes7 protein represses its own transcription, with the oscillation period of about 2-3 hours precisely matching the somite formation rate; disruptions in this loop lead to irregular segmentation. Similarly, in , the related genes her1 and her7 operate via coupled loops, oscillating every 30 minutes to control somite periodicity, with her1 exhibiting rapid decay to sustain the cycle. These loops incorporate transcriptional and translational delays that are essential for generating sustained oscillations rather than stable expression levels. The spatial propagation of clock oscillations occurs as a traveling posteriorly through the PSM, with oscillatory activity decaying anteriorly due to diminishing (FGF) signaling that maintains PSM competence. Mathematical models describe this dynamics through delayed differential equations, such as \frac{dx}{dt} = \frac{P}{1 + (x(t - \tau)/K)^n} - \gamma x(t), where x represents Hes/Her mRNA or protein levels, P is maximal rate, \tau is the delay, \gamma is rate, and repression parameters (K, n) ensure oscillatory solutions that propagate as waves when coupled with the FGF gradient. These models demonstrate how delays in the create the periodic waves observed . Experimental validation includes real-time imaging of fluorescent reporters driven by her1 or her7 promoters in living embryos, revealing synchronized cellular oscillations that desynchronize upon isolation, confirming intercellular coordination. Mutations in deltaC, a Notch essential for , disrupt these oscillations, resulting in aperiodic expression and fused somites that highlight the clock's role in precise boundary formation. The segmentation clock integrates with the to synchronize oscillations across adjacent PSM cells through .

Key Signaling Pathways

The key signaling pathways governing the spatial patterning of the presomitic mesoderm (PSM) and nascent somites include Notch-Delta, FGF/Wnt gradients, , and BMP/Shh interactions, which collectively establish anterior-posterior (A-P) and dorsoventral identities. These pathways operate through steady-state gradients and inhibitory mechanisms to refine somite boundaries and fates, distinct from the temporal dynamics of the segmentation clock. Notch-Delta signaling plays a central role in , promoting boundary refinement and anterior somite identity. Delta-like ligands, expressed in PSM cells, activate receptors in neighboring cells, leading to the upregulation of Mesp2, which confers anterior characteristics and helps delineate somite borders. This intercellular signaling ensures synchronized patterning across the PSM, with disruptions in Delta- components resulting in fused or irregular somites. FGF and Wnt signaling form opposing gradients along the A-P of the PSM, maintaining posterior and fate while permitting anterior . High posterior levels of FGF8 and Wnt3a sustain undifferentiated PSM cells by promoting and inhibiting somite formation, whereas their decline anteriorly allows cells to exit the and mature into somites. Specifically, FGF4 and FGF8 act as signals, with their decay calibrating the position of somite boundaries. Retinoic acid (RA) signaling establishes A-P identity through posterior production in nascent somites, where it patterns expression to specify segmental positions. RA gradients are shaped by Cyp26 enzymes, which degrade RA in the posterior PSM to prevent premature anteriorization, thus creating a precise zone of influence for somite maturation. This pathway antagonizes posterior FGF/Wnt signals, ensuring timely progression from PSM to segmented structures. BMP and Shh signaling from the and influence dorsoventral patterning, with Shh promoting ventral somite fates through sclerotome induction. Shh ventralizes somites by repressing dorsal markers and enhancing ventral , while BMPs from counterbalance this to define dorsal boundaries; their balanced interaction is essential for proper somite compartmentalization. Shh also modulates competence to BMP responses, facilitating ventral mesenchymal transitions without directly inducing skeletal derivatives. Cross-talk between these pathways integrates spatial cues, notably through feedback on FGF targets to amplify patterning signals in the PSM. For instance, activation represses FGF signaling components, refining the posterior and linking to wavefront progression. This interplay ensures robust coordination of somite formation.

Derivatives

Dermatome and Dermal Structures

The dermatome constitutes the dorsal epithelial layer of the somite, forming part of the dermomyotome, and undergoes a mesenchymal transition following the initial mesenchymal-to-epithelial transition (MET) that shapes the somite. This layer generates mesenchymal cells that contribute to the of the dorsal skin, particularly the along the back. In vertebrates, the dermatome remains mesenchymal post-MET, enabling cell migration beneath the overlying to form the dermal layer. Induction of the dermatome involves signaling from the neural tube and surface ectoderm, with bone morphogenetic protein 4 (BMP4) playing a key role in specifying dorsal somitic fates through activation of homeobox genes. BMP4 gradients from these tissues promote and expression in presumptive dermal progenitors within the dermatome, restricting myogenic and favoring formation. Wnt signaling, particularly Wnt1 from the neural tube, maintains the dorsal identity of the dermatome and can substitute for neural tube signals to induce dermal development, as demonstrated in embryo grafts where Wnt1-expressing cells restored patterned formation. Noggin, a BMP antagonist, modulates these signals to refine the timing and extent of dermatome specification, preventing premature ventralization. The primary derivatives of the dermatome include the of the dorsal , which supports structures such as feathers in or follicles in mammals, along with precursors for subcutaneous in the back region. In the , dermatome cells delaminate and migrate to populate the underlying the dorsal . For limb development, cells from the dermomyotome, including dermatome contributions, migrate into the emerging limb buds to form the and of the limbs, as traced in quail-chick studies where somitic cells from specific segments populate distal limb . This migration occurs via the dermomyotome's lateral edges, integrating somite-derived with local limb . Species variations in dermatome organization reflect evolutionary divergences in somite compartmentalization. In amniotes such as mice and chicks, the dermatome forms a distinct dorsolateral compartment within the dermomyotome, enabling clear separation of dermal fates from myotomal and sclerotomal contributions. In contrast, anurans like Xenopus laevis exhibit a thinner, less segregated dermatome integrated more closely with the , where multipotent somitic cells at the lateral somitic frontier interface with lateral plate signals like BMP4 to contribute to both dorsal and abaxial structures, resulting in a more unified mesodermal contribution to and body wall tissues.

Myotome and Musculature

The myotome represents the initial skeletal muscle component derived from the somite, forming as a thin epithelial sheet of post-mitotic myocytes beneath the dermomyotome. It arises from the medial and lateral lips of the dermomyotome through delamination and differentiation of progenitor cells, establishing a dorsoventral compartmentalization into epaxial and hypaxial domains. The epaxial myotome, located dorsally, gives rise to the deep back muscles that extend along the vertebral column, while the hypaxial myotome, positioned ventrolaterally, contributes to the body wall muscles and limb musculature. Induction of the medial myotome occurs primarily through Sonic hedgehog (Shh) signaling from the and floor plate, which activates myogenic determination genes such as Myf5 and in the epaxial domain to promote myoblast differentiation. In contrast, the lateral myotome is induced by bone morphogenetic protein 4 (BMP4) secreted from the , which specifies hypaxial identity and delays early myogenic activation to allow progenitor expansion. Pax3 and Pax7 transcription factors mark the myogenic progenitors in both domains, with initiating specification in the dermomyotome and Pax7 maintaining the progenitor pool for subsequent muscle formation. Myogenic differentiation proceeds with the upregulation of basic helix-loop-helix factors Myf5 and MyoD, which drive myoblast commitment and fusion into multinucleated myofibers in the myotome. Myf5 initiates epaxial myogenesis, while MyoD ensures timely hypaxial differentiation, with both factors compensating for each other to orchestrate sarcomere assembly and muscle contractility. For limb muscles, hypaxial progenitors expressing Pax3 delaminate from the ventrolateral dermomyotome and migrate into the limb buds under hepatocyte growth factor (HGF) signaling, which activates the c-Met receptor tyrosine kinase on these cells to enable epithelial-to-mesenchymal transition and directed motility. In amniotes, myotome formation occurs in iterative waves, with the first wave producing primary fibers for axial muscles, followed by secondary and tertiary waves from the dermomyotome edges that supply additional progenitors for limb and ventral body wall muscles, ensuring progressive muscle mass expansion.

Sclerotome and Skeletal Elements

The sclerotome forms from the ventral region of the somite, where epithelial somitic cells undergo mesenchymal transition and delaminate to generate a loose of progenitor cells. This process is primarily induced by Sonic hedgehog (Shh) signaling emanating from the and the floor plate of the , which establishes a ventral-to-dorsal gradient that specifies sclerotomal fate while repressing myotomal and dermatomal identities. Shh activates the expression of key transcription factors, including Pax1 and , which are critical regulators of sclerotome specification and maintenance; for instance, Pax1 is directly induced by and floor plate signals in avian embryos. Sox9, in turn, supports integrity and perinotochordal sclerotome development, ensuring proper mesenchymal . The primary derivatives of the sclerotome constitute the axial and appendicular skeletal elements, including the , , and contributions to the . Sclerotomal cells migrate around the and to form mesenchymal condensations that undergo chondrogenesis, eventually ossifying into ; the proximal arise from the lateral sclerotome, while occipital somites contribute to the . A key morphogenetic event is resegmentation, whereby the rostral (anterior) portion of one sclerotome fuses with the caudal (posterior) portion of the adjacent sclerotome to generate each vertebral body and , ensuring proper alignment of skeletal elements with segmental structures like nerves and muscles. This resegmentation is region-specific, with sclerotomal cells shifting differentially to pattern the . Patterning of sclerotomal derivatives along the anterior-posterior (A-P) axis is orchestrated by clusters, which confer regional identity to vertebrae through collinear expression domains. For example, the anterior limits of Hox6 paralogs mark the cervicothoracic transition, where lacking ribs give way to bearing them, while posterior shifts in Hox expression dictate and sacral identities. (BMP) signaling, mediated by receptors such as Bmpr1a and Bmpr1b, is essential for promoting chondrogenesis within these condensations, enabling cartilage formation that precedes ; BMPs act downstream of Shh to redirect cellular responses toward skeletal differentiation. Mutations in sclerotome-associated genes, such as Pax1, disrupt vertebral segmentation and chondrogenesis, leading to congenital scoliosis characterized by malformed or fused vertebrae. For instance, Pax1 variants in mouse models recapitulate spinal deformities observed in human patients, underscoring the gene's role in maintaining sclerotomal integrity during development.

Syndetome and Connective Tissues

The syndetome represents a specialized compartment within the somite dedicated to the formation of tendon progenitors, emerging as a distinct lineage at the dorsolateral edges of the sclerotome, positioned at the rostro-caudal borders adjacent to the myotome. This compartment is molecularly defined by the expression of the basic helix-loop-helix transcription factor scleraxis (Scx), which marks cells committed to the tendon fate. Unlike the primary somitic derivatives such as the myotome for muscle or sclerotome for skeletal elements, the syndetome arises through a process of specification within the maturing somite, where progenitor cells integrate signals to establish connectivity between musculoskeletal components.00268-X) Induction of the syndetome occurs primarily through signaling from the adjacent , with (FGF) ligands, particularly FGF8, acting directly on sclerotome cells to activate Scx expression via transcription factors such as Pea3 and Erm. (BMP) signaling from the somite edges further modulates this process, cooperating with FGF to promote tenogenic differentiation from sclerotomal precursors and ensure proper positioning at the myotome-sclerotome interface. This inductive interaction facilitates the syndetome's role in establishing teno-muscle attachments, where tendon progenitors extend processes that link developing myotomal muscle fibers to the emerging , laying the foundation for coordinated axial movement. The derivatives of the syndetome include axial tendons, ligaments, and aponeuroses that epaxial and hypaxial muscles to the vertebral , providing tensile strength and flexibility to the . In the developing limbs, syndetomal progenitors migrate along with limb bud to contribute to distal tendons and ligaments, connecting limb musculature to skeletal elements such as long bones and joints. These structures are essential for force transmission and joint stability, with Scx-positive cells differentiating into tenocytes that produce components like type I. The syndetome's adjacency to the sclerotome ensures spatial coordination with skeletal development, as detailed in the sclerotome section.00268-X) Evolutionarily, the syndetome is a , appearing in conjunction with the elaboration of the sclerotome and to support the complex axial and appendicular musculoskeletal system of vertebrates; it is absent in chordates like amphioxus, where somites lack specialized tendon-forming compartments.

Evolutionary and Comparative Biology

Origins in Vertebrates

Somites represent a fundamental feature of the , first appearing in the fossil record during the Early period around 520 million years ago. Fossil evidence from the Chengjiang biota in , such as the primitive Haikouichthys ercaicunensis, reveals segmented myomeres indicative of early somite patterning, with a and supporting these structures in a streamlined, fish-like body. Similarly, the contemporaneous Pikaia gracilens from the exhibits a series of vertical bands interpreted as somite , linking these structures to the emergence of axial segmentation. These findings establish somites as an ancient , conserved across all extant lineages from agnathans like lampreys to gnathostomes and mammals. In non-vertebrate chordates, somite-like blocks are evident but show variations in complexity. Cephalochordates, such as amphioxus (), possess segmented paraxial forming somitomeres that remain largely epithelial without the full mesenchymal-to-epithelial seen in vertebrates, contributing to myotomal muscles along the trunk. Urochordates, by contrast, exhibit reduced or absent segmentation, with larval stages showing only rudimentary muscle bands derived from presumptive somitic tissue, reflecting a secondary loss in this lineage. This pattern underscores somites' conservation within chordates, with vertebrate innovations enhancing their role in axial elongation and patterning. The molecular segmentation clock, involving oscillatory , appears conserved across these groups, though detailed mechanisms are elaborated elsewhere. Adaptations in somite number and identity have accompanied diversification, particularly in elongated forms. In , such as certain colubrids, somite pairs exceed 400, correlating with extended vertebral columns and enabled by prolonged somitogenesis wavefront activity. Regional somite identity is governed by an evolutionary conserved code, where combinatorial expression of Hox clusters specifies axial domains, from to caudal regions, as seen in the transition from basal lampreys to derived amniotes. This Hox-mediated patterning has facilitated morphological innovations, maintaining somites' core function in vertebrate evolution despite varying body plans.

Homology in Arthropods and Invertebrates

In embryos, segmentation of the gives rise to somite-like structures that form the foundational units for body organization, contributing to the development of the ventral nerve cord, segmental muscles, and elements of the . These somites emerge as fused segmental blocks during embryogenesis, particularly evident in model organisms like the Drosophila melanogaster, where the paraxial subdivides into repeating units aligned with ectodermal segments. Unlike somites, which are epithelialized blocks of paraxial , somites are more integrated with the overall segmental architecture from the outset, reflecting the developmental mode. The formation of these somite-like structures in arthropods is regulated by a hierarchical cascade of segmentation genes, prominently featuring pair-rule genes such as even-skipped (eve), which establish a periodic pattern of expression in the early embryo. In Drosophila, eve is expressed in seven stripes, each spanning the anterior half of every other parasegment, thereby initiating the double-segmental periodicity that refines into individual segments. This patterning is further delineated by segment-polarity genes like engrailed (en), which is activated at the posterior boundary of each segment by pair-rule inputs, including eve, to define compartment boundaries and maintain segmental integrity. In other arthropods, such as beetles (Tribolium castaneum) and spiders (Cupiennius salei), orthologs of eve and en exhibit conserved roles in sequential segmentation, particularly in short-germ-band species where somites form progressively from a posterior growth zone. Notably, oscillations in pair-rule gene expression have been observed in some arthropods, suggesting a segmentation "clock" analogous to mechanisms in other bilaterians, though driven by different regulatory dynamics. Debates on homology between arthropod somite-like segmentation and vertebrate somites center on rather than shared ancestry, as the morphological and genetic underpinnings differ despite superficial similarities in metameric organization. Both groups express engrailed in posterior segmental compartments, hinting at deep conservation of boundary-defining roles, but the upstream regulators diverge: vertebrate somitogenesis relies on a -based oscillator coupled with FGF/Wnt gradients, whereas arthropod segmentation primarily involves gap and pair-rule gene hierarchies without equivalent reliance on for periodicity in most . signaling, while present in both, functions in ventral patterning in arthropods rather than clock oscillation as in some vertebrate contexts. In annelids, segmentation produces somites more closely aligned with arthropod patterns through teloblastic growth and shared ectodermal-mesodermal coordination, supporting within lineages but reinforcing the independent evolution of vertebrate somitogenesis.00286-2) A key distinction lies in developmental persistence: somites evolve into enduring adult segments that define the tagmosis of the , such as the fusion into head, , and , whereas somites are transient, rapidly differentiating into specialized tissues without maintaining overt segmentation in the adult. This contrast underscores the adaptive divergence of segmentation as a modular system for diverse body architectures across bilaterians.