Fact-checked by Grok 2 weeks ago

Paraxial mesoderm

The paraxial mesoderm is a longitudinal strip of mesenchymal tissue in vertebrate embryos, positioned bilaterally adjacent to the neural tube and notochord, that undergoes segmentation to form somites, which are transient epithelial structures essential for establishing the segmented body plan along the anterior-posterior axis.^[1]^[2] During gastrulation, the paraxial mesoderm arises from mesodermal cells that ingress through the primitive streak and migrate laterally, forming a continuous unsegmented plate that extends from the head to the tail region.^[1]^[3] As the embryo elongates, this mesoderm organizes into whorls of cells known as somitomeres near the posterior end, which progressively epithelialize and bud off as paired somites in an anterior-to-posterior sequence, with the process regulated by a molecular "segmentation clock" involving oscillatory gene expression (e.g., hairy family genes) and signaling pathways such as Notch and Wnt.^[1]^[2] The number of somites varies by species—typically around 42–44 pairs in humans, forming at a rate of approximately three per day—but all contribute to axial patterning through Hox gene-mediated specification.^[1]^[2] Each somite differentiates into distinct compartments: the ventromedial sclerotome, which undergoes epithelial-to-mesenchymal transition to form the axial skeleton including vertebrae, ribs, and intervertebral discs under the influence of signals like Sonic hedgehog from the notochord and floor plate; the dorsolateral dermomyotome, which gives rise to the dermis of the back as well as skeletal muscles of the body wall, back, and limbs via myogenic regulatory factors; and, in some cases, contributions to tendons and vasculature.^[3]^[1]^[2] This segmentation not only imposes periodicity on the musculoskeletal system but also guides the migration of neural crest cells and motor neurons, ensuring coordinated development of the vertebrate trunk and tail.^[1] Disruptions in paraxial mesoderm formation, such as mutations in genes like Pax1, Pax9, or Paraxis, can lead to congenital defects including vertebral malformations, highlighting its critical role in skeletal integrity.^[3]^[1]

Definition and Embryonic Context

Anatomical Location and Structure

The paraxial mesoderm constitutes the mesodermal tissue that flanks the neural tube bilaterally in neurulating embryos, forming paired longitudinal columns adjacent to the notochord and underlying the neural plate. This tissue extends continuously from the occipital region anteriorly to the tail bud posteriorly, providing structural support along the embryonic axis.^[3] In cross-sections of the embryo, the paraxial mesoderm appears as distinct bands positioned lateral to the notochord and ventral to the emerging neural tube, as illustrated in diagrammatic representations of early vertebrate embryos.^[4] The unsegmented portion of the paraxial mesoderm, known as the presomitic mesoderm (PSM), comprises mesenchymal cells organized into loose, bilateral streaks that maintain cohesiveness through cell-cell interactions. These cells exhibit a mesenchymal morphology, lacking tight junctions typical of epithelia, which allows for dynamic migration and patterning during early development.^[3] As somitogenesis proceeds, the anterior PSM undergoes a mesenchymal-to-epithelial transition, wherein cells reorganize into a pseudostratified columnar epithelium to form the epithelial somites, marked by the expression of boundary markers and apical-basal polarity.^[5] Paraxial mesoderm first emerges distinctly at Carnegie stage 9 (approximately 19-21 days post-fertilization in humans), coinciding with the initial segmentation into 1-3 pairs of somites from the paraxial mesenchyme. At this stage, the tissue transitions from diffuse mesenchyme to the first epithelized somitic structures, setting the foundation for further axial elongation.^[4] This positioning and structural organization of the paraxial mesoderm are critical for its subsequent role in somitogenesis, where periodic segmentation generates somites along the anterior-posterior axis.^[6]

Relation to Other Mesoderm Types

The paraxial mesoderm occupies an axial position along the midline of the vertebrate embryo, immediately lateral to the neural tube and notochord, distinguishing it from the more laterally positioned intermediate mesoderm and the ventrolateral lateral plate mesoderm.^[3] This mediolateral organization arises during gastrulation, where all three mesoderm types emerge from common precursors in the primitive streak, but migrate to distinct positions based on differential cell behaviors influenced by Wnt signaling gradients.^[3] Specifically, higher levels of Wnt and FGF signaling promote paraxial mesoderm specification medially, while increasing BMP gradients laterally favor intermediate and lateral plate mesoderm fates.^[7] Differentiation between these mesoderm types is further refined by distinct Hox gene expression patterns, which establish unique regional identities and boundaries. For instance, several Hox genes exhibit staggered anterior expression borders in paraxial mesoderm compared to lateral plate mesoderm, correlating with axial versus appendicular skeletal patterning and preventing fate mixing.^[8] Intermediate mesoderm shares some Hox expression similarities with paraxial mesoderm, such as Hoxb4 from the sixth somite level posteriorly, but diverges in overall combinatorial codes that direct urogenital versus somitic development.^[9] These Hox-mediated distinctions, modulated by the same Wnt/FGF/RA signaling gradients that pattern the paraxial mesoderm internally, ensure sharp mediolateral boundaries.^[7] The paraxial mesoderm's identity and somitic (segmented) fate are evolutionarily conserved across vertebrates, from lampreys to mammals, contrasting with the non-segmented fates of intermediate and lateral plate mesoderm that form unsegmented structures like kidneys and body cavities.^[10] In basal vertebrates like lampreys, trunk paraxial mesoderm forms somites with myogenic potential similar to gnathostomes, while head mesoderm remains unsegmented, highlighting the axial specificity of somitogenesis as a vertebrate innovation not shared by lateral mesoderm types.^[11] This conservation underscores the paraxial mesoderm's role in establishing the segmented body plan, distinct from the continuous tissues derived from other mesoderm subtypes.^[10]

Development and Formation

Specification During Gastrulation

During gastrulation in vertebrates, paraxial mesoderm emerges from epiblast cells that ingress through the primitive streak, a transient structure forming at the posterior embryonic axis around embryonic day 6.5 in mice. These cells are initially induced toward a mesodermal fate by high levels of Nodal signaling, which activates Smad2/3 transcription factors to promote primitive streak formation and early mesoderm specification.^[12] As ingress progresses from posterior to anterior along the primitive streak, cells destined for paraxial mesoderm are specified in the anterior region during mid-gastrulation (around E7.5 in mice), distinguishing them from more lateral mesodermal populations.^[3] This posterior-to-anterior timeline ensures sequential allocation of mesodermal subtypes, with paraxial precursors contributing to somitic structures.^[12] The commitment of epiblast cells to a general mesodermal fate involves synergistic actions of fibroblast growth factors (FGFs) and Wnt pathways, which maintain pluripotency in neuromesodermal progenitors while repressing neural identities. FGF signaling, particularly FGF8 expressed in the primitive streak, activates MAPK/ERK cascades to upregulate mesoderm-specific genes like Tbx6 and Msgn1.^[13] Wnt/β-catenin signaling, highest in the posterior primitive streak, further reinforces this by stabilizing β-catenin and promoting Tbx6 expression, essential for paraxial over neural fate.^[3] Paraxial identity is refined through low BMP signaling levels; unlike high BMP gradients in posterior regions that drive lateral plate mesoderm via Id protein induction, reduced BMP in anterior/dorsal areas allows bHLH transcription factors (e.g., Msgn1) to promote medial paraxial fates.^[13] Dorsal paraxial specification is further ensured by BMP antagonists secreted from the organizer (node), such as Noggin and Chordin, which bind and sequester BMP ligands to create a dorsal-low BMP gradient. Noggin, expressed in the node and notochord from late gastrulation, directly inhibits BMP4 to prevent ventralization and maintain Pax3 expression in paraxial precursors.^[3] Similarly, Chordin from the organizer reinforces this antagonism, protecting emerging paraxial mesoderm from lateralizing signals and enabling proper dorsolateral patterning.^[12] This inhibitory mechanism is critical, as ectopic BMP exposure lateralizes paraxial tissues, while Noggin overexpression induces somitic fates in lateral mesoderm.^[3]

Migration and Positioning

During gastrulation, paraxial mesoderm progenitors ingress through the primitive streak in a spatiotemporal manner, with cells emerging from the anterior primitive streak region destined for paraxial fates.^[14] These cells undergo epithelial-to-mesenchymal transition (EMT) at the streak, enabling their dispersal into the embryo proper. Following ingression, the progenitors execute convergent extension movements, narrowing mediolaterally while elongating rostrocaudally to establish the unsegmented presomitic mesoderm (PSM).^[15] This process is primarily driven by non-canonical Wnt signaling via the planar cell polarity (PCP) pathway, involving ligands such as Wnt5a and Wnt11, which polarize cells and promote directed intercalation. Disruption of PCP components, like Vangl2, impairs this extension, leading to shortened body axes in mouse embryos. As gastrulation progresses, the primitive streak regresses caudally from its initial posterior position toward the tail bud, a process that sequentially positions ingressed paraxial mesoderm cells in a rostrocaudal gradient. Cells that ingress earlier, from the anterior streak, occupy more rostral domains of the PSM, while later-ingressing cells from the posterior streak contribute to caudal regions. This regression, coupled with ongoing ingression, ensures the continuous addition of progenitors to the growing PSM column, maintaining axial elongation. Paraxial mesoderm arises from stem-cell-like progenitors marked by Tbx6 expression, which emerge from the primitive streak and migrate laterally and dorsally to form bilateral columns flanking the midline. These Tbx6+ cells, specified in the streak, exhibit self-renewal properties and progressively differentiate as they move away from the source, integrating into the PSM. In Tbx6 mutants, paraxial mesoderm formation is severely compromised, resulting in ectopic neural tissue due to failed repression of neural genes like Sox2. Proper midline alignment of the paraxial mesoderm columns is achieved through interactions with the notochord, which secretes signaling molecules such as Noggin and Sonic hedgehog (Shh) to pattern adjacent tissues. Noggin antagonizes BMP signaling from lateral regions, preventing paraxial cells from adopting intermediate or lateral plate fates and thus preserving their medial position. Shh from the notochord further refines dorsoventral patterning in the PSM, ensuring alignment with the notochord and neural tube. Ablation of the notochord in chick embryos disrupts this alignment, causing medial expansion of lateral mesoderm markers into paraxial domains.

Somitogenesis

Process of Somite Segmentation

The presomitic mesoderm (PSM) elongates posteriorly through the addition of new mesenchymal cells derived from the primitive streak, while somites periodically bud off from its anterior end in a rhythmic, sequential manner. This budding process results in the formation of bilateral pairs of somites that flank the neural tube and notochord, establishing the segmented architecture of the paraxial mesoderm. In mouse embryos, somites form at an interval of approximately 2 hours per pair, reflecting the pace of axial elongation and cellular maturation in the PSM. In human embryos, the process is notably slower, with somites forming every 7 hours, consistent with the extended timeline of early human development compared to rodents.^[16]^[17] The morphological transition begins in the anterior PSM, where loosely organized mesenchymal cells condense and undergo a mesenchymal-to-epithelial transition (MET) to form cohesive epithelial somites. This MET involves cells acquiring apicobasal polarity, adhering tightly via cadherins, and reorganizing into a pseudostratified epithelial sheet that encloses a central mesenchymal core. Somite boundaries emerge through differential cell movements, such as ball-and-socket-like separations in avian embryos or fissure expansion in other vertebrates, propagating from ventral to dorsal or medial to lateral directions to delineate clear segmental borders. Preceding full somite maturation, transient somitomeres serve as precursors in the anterior PSM, manifesting as whorled, segmental arrangements of mesenchymal cells that foreshadow the boundaries without yet forming stable epithelia.^[18]^[19] Upon boundary formation, each somite rapidly establishes anterior-posterior (A-P) polarity, dividing into distinct rostral and caudal halves with differing cellular properties and fates. This polarity arises through patterned gene expression and cell adhesion differences that are initiated in the PSM prior to overt segmentation, ensuring proper alignment with the overlying neural tube and subsequent tissue differentiation. The resulting polarized somites maintain structural integrity while preparing for further compartmentalization into dermomyotome, myotome, and sclerotome.^[20]^[21]

Molecular Clock and Wavefront Model

The molecular clock and wavefront model elucidates the temporal and spatial mechanisms underlying somite segmentation in vertebrate embryos. Proposed as an extension of the original theoretical framework by Cooke and Zeeman, this model posits that somitogenesis arises from the interplay between a molecular oscillator, or "clock," that provides rhythmic timing cues and a dynamic "wavefront" that specifies positional information along the anterior-posterior axis of the presomitic mesoderm (PSM). The clock manifests as synchronized oscillations in the expression of cyclic genes within PSM cells, while the wavefront comprises regressing gradients of signaling molecules that progressively mature cells for segmentation. This coordinated system ensures the precise, periodic budding of somites from the anterior PSM.00394-0) Central to the clock component are oscillations in Hes/Her family transcription factors, particularly Hes7 in mice, which exhibit cyclic expression with a period aligning with the somite formation rate of approximately 2 hours. These oscillations arise from delayed negative feedback loops, where Hes7 represses its own transcription and that of downstream targets like Lunatic fringe, a Notch pathway modulator, leading to rhythmic activation and repression. The clock is initiated posteriorly by FGF signaling and propagated anteriorly through cell-cell communication via the Notch pathway, synchronizing oscillations across the PSM to generate traveling waves of gene activity. Disruptions in Hes7 expression, as demonstrated in knockout studies, abolish these oscillations and halt somitogenesis, underscoring their essential role. The wavefront establishes a maturation gradient through posteriorly high levels of FGF and Wnt signaling, which inhibit differentiation and maintain PSM progenitors; as the embryo elongates, this wavefront sweeps anteriorly, rendering cells competent to respond to the clock only in the anterior PSM. Phase shifts in clock oscillations relative to the wavefront position determine where somite boundaries form, with cells at the appropriate phase activating the bHLH transcription factor Mesp2 in prospective somite domains. Mesp2 expression creates stripes that delineate segmental borders by modulating Notch signaling and promoting epithelialization, thus linking temporal cues to spatial patterning. Conceptually, the oscillatory dynamics resemble a series of wavefronts of gene activation sweeping through the PSM, where each cycle corresponds to one somite's worth of tissue; cells "count" cycles until they encounter the maturation wavefront, triggering segmentation. This mechanism is evolutionarily conserved among vertebrates, with core components like Hes/Her oscillators and FGF/Wnt gradients present in mammals, birds, reptiles, and fish, though cycle periods vary to match species-specific somitogenesis rates—such as 90 minutes in chick embryos and 30 minutes in zebrafish. Variations in cycle length reflect differences in developmental tempo, yet the underlying clock-wavefront architecture remains robust across taxa.00394-0)

Derivatives

Somite-Derived Structures

The somites, transient segmented structures derived from paraxial mesoderm, give rise to multiple tissues that maintain the segmental organization of the trunk in vertebrates, including humans where approximately 33 pairs contribute to the axial skeleton.^[22] This segmentation ensures coordinated development of the musculoskeletal system, with each somite differentiating into distinct compartments that form the vertebrae, skeletal muscles, dermis, and connective tissues.^[1] The sclerotome, originating from the ventral portion of the somite, undergoes epithelial-to-mesenchymal transition to form mesenchymal cells that migrate around the notochord and neural tube, ultimately differentiating into chondrocytes of the vertebrae and ribs.^[3] Key regulators include Pax1, which is essential for sclerotome specification and proliferation, and Sox9, which drives chondrogenesis by activating cartilage-specific genes like Col2a1.^[23] In Pax1-deficient models, vertebral body formation is severely impaired, highlighting its role in maintaining sclerotomal identity.^[24] The myotome arises from the medial and lateral edges of the dermomyotome, the dorsal epithelial layer of the somite, and divides into epaxial and hypaxial domains that innervate distinct muscle groups.^[1] Epaxial myotome cells, located dorsally, form the deep back muscles such as the erector spinae, while hypaxial cells migrate ventrolaterally to generate body wall muscles (e.g., abdominals) and limb muscles (e.g., pectoralis, quadriceps).^[25] Myogenic regulatory factors Myf5 and MyoD are critical for myoblast commitment and differentiation; Myf5 initiates epaxial myogenesis, and MyoD compensates in Myf5 mutants to ensure myotome formation, as evidenced by the absence of skeletal muscle in double knockouts.^[26] The dermatome, comprising the dorsalmost somite region, differentiates into the dermis of the back skin and contributes to some endothelial cells lining dorsal blood vessels.^[27] Dermatomal cells remain epithelial initially before delaminating to form connective tissue layers, with neurotrophin-3 signaling from the neural tube promoting their survival and dermal fate.^[1] Endothelial contributions from somites involve angiogenic progenitors expressing Tie2, which integrate into the dorsal aorta and intersomitic vessels.^[27] The syndetome emerges at the dorsolateral sclerotome-dermomyotome interface, serving as a progenitor domain for tendons and ligaments that connect muscles to the axial skeleton.^[28] Marked by co-expression of scleraxis (Scx), a bHLH transcription factor that specifies tenogenic lineage, and Pax3, which supports progenitor migration and survival, the syndetome forms axial tendons such as those attaching epaxial muscles to vertebrae.00268-X) Scx induction by BMP4 from lateral plate mesoderm and FGF from myotome ensures tendon-muscle connectivity, with Scx-null mice exhibiting disrupted axial tendon formation.^[29]

Head Paraxial Mesoderm Contributions

The head paraxial mesoderm originates from the prechordal mesoderm, which lies anterior to the notochord, and the unsegmented paraxial mesoderm positioned rostral to the first somite during early gastrulation.^[30] This tissue extends posteriorly to contribute to the formation of the first four to five pairs of occipital somites, which represent a transitional zone between the unsegmented cranial domain and the fully segmented trunk paraxial mesoderm.^[31] Unlike the trunk paraxial mesoderm, which undergoes complete somitogenesis to generate somites that differentiate into axial and limb structures, the head paraxial mesoderm largely remains unsegmented, with its cells migrating directly to targeted cranial sites without forming epithelial somite boundaries.^[32] Key contributions of the head paraxial mesoderm include the development of extraocular muscles, which control eye movements and derive primarily from prechordal mesoderm and the mesoderm of the first branchial arch.^[30] It also provides mesenchymal progenitors for facial connective tissues, such as tendons, fascia, and pericytes associated with cranial vasculature, as well as portions of cranial skeletal elements like the rostral sphenoid and post-orbital cartilages in avian models.^[33] These fates are mediated in part by Engrailed-1-positive cells within the head mesoderm, which mark myogenic precursors in branchial arch muscles and contribute to the integration of muscle with surrounding connective and skeletal tissues derived from both mesodermal and neural crest sources.^[33] The cranial identity and patterning of head paraxial mesoderm are regulated by opposing gradients of retinoic acid (RA) and bone morphogenetic protein (BMP) signaling.^[34] RA, synthesized posteriorly and diffusing anteriorly, acts later in development to refine anterior-posterior boundaries, activating transcription factors like Tbx1 to promote branchiomeric myogenesis while restricting posterior fates ventrally through Cyp26a1-mediated degradation.^[30] BMP signaling operates earlier to delineate broad anterior domains in the non-axial mesoderm, establishing territorial sizes along the dorsal-ventral axis that align with anterior-posterior patterning; however, in the head, BMP represses myogenic differentiation until antagonized by neural crest-derived factors such as Noggin and Gremlin, enabling cranial-specific muscle formation.^[34]^[33] This dynamic regulation ensures the head paraxial mesoderm adopts fates distinct from those of the somite-derived trunk structures.^[35]

Molecular Regulation

Key Signaling Pathways

The development of paraxial mesoderm begins with the initial induction of mesoderm during gastrulation, primarily driven by Nodal and Activin signaling from the TGF-β superfamily. Nodal ligands, expressed in a graded manner across the primitive streak, promote mesoderm formation with low concentrations favoring paraxial mesoderm fate while higher levels direct lateral plate mesoderm, thereby defining the paraxial borders through differential signaling thresholds.^[36] Activin, acting similarly to Nodal, reinforces this induction by activating downstream Smad complexes that specify early mesodermal progenitors, ensuring the allocation of cells to the paraxial domain adjacent to the midline.^[3] Following induction, key extracellular signals pattern and maintain paraxial mesoderm identity. Inhibition of BMP signaling by secreted antagonists such as Noggin and Chordin is essential for dorsal specification of the paraxial mesoderm, preventing ventralization and promoting myogenic potential in somitic precursors.^[37] Canonical Wnt signaling contributes to the initial specification of paraxial mesoderm from neuromesodermal progenitors, while non-canonical Wnt pathways regulate the convergent extension movements required for proper migration and positioning of paraxial cells during gastrulation.^[38] In the presomitic mesoderm (PSM), FGF8 signaling sustains proliferation and maintains an undifferentiated state, with posterior-high gradients preventing premature differentiation.^[39] Retinoic acid (RA), produced by Raldh2 in the somites, establishes anterior-posterior patterning along the axis, promoting anterior PSM maturation.^[40] These pathways interact dynamically to coordinate paraxial mesoderm development, notably through RA-FGF antagonism that defines the somitogenesis wavefront. RA signaling opposes posterior FGF8 activity, restricting the proliferative zone and enabling oscillatory gene expression in the anterior PSM to drive segmentation.^[7] This balance ensures timely progression from PSM maintenance to somite formation.

Gene Expression and Transcription Factors

The paraxial mesoderm exhibits dynamic gene expression patterns that drive its differentiation into somites and subsequent lineages, orchestrated by key transcription factors. In the presomitic mesoderm (PSM), Tbx6 plays a central role in establishing paraxial mesoderm identity by promoting the expression of mesodermal genes while suppressing neural fate, as evidenced by Tbx6-null mice that fail to form proper PSM and instead generate ectopic neural tubes. Tbx6 expression is initiated in the primitive streak and maintained in the PSM, where it interacts with signaling pathways to refine mesodermal specification.^[41] During somitogenesis, Mesp2 emerges as a critical transcription factor for somite boundary determination, expressed in the anterior PSM where it activates boundary-specific genes like Epha4 and represses posterior markers such as Tbx6 in nascent somites. In Mesp2 mutants, somite boundaries are disrupted, leading to fused somites and loss of rostro-caudal polarity, underscoring its role in segmental patterning. Following somite formation, Pax3 and Pax7 drive myogenic commitment in the dermomyotome, marking progenitor cells that migrate to limb and trunk muscles; Pax3 initiates myoblast specification in early somites, while Pax7 sustains satellite cell populations for postnatal muscle growth.^[42] Hox genes, expressed in nested domains along the rostro-caudal axis, confer positional identity to paraxial mesoderm derivatives, with posterior Hox clusters (e.g., Hox9-13) patterning trunk somites and anterior clusters (e.g., Hox4-6) influencing head mesoderm contributions. Feedback loops involving these factors ensure precise temporal and spatial control. Hes7 forms an auto-repressive negative feedback loop in the PSM, where its oscillatory expression—peaking every 2 hours in mice—regulates the segmentation clock by repressing its own transcription and that of downstream targets like Lfng, essential for synchronized somite formation.^[43] In the sclerotome, Sox9 establishes a positive autoregulatory loop with Nkx3.2 to promote chondrogenesis, driving expression of cartilage matrix genes such as Col2a1 in ventral somite regions. Spatial Hox expression domains further delineate paraxial mesoderm subdivisions, with low or absent Hox levels in the anterior head paraxial mesoderm supporting unsegmented structures like craniofacial muscles, contrasting with high posterior Hox expression that patterns segmented trunk somites.^[44]

Clinical and Research Significance

Associated Developmental Disorders

Defects in the segmentation and differentiation of the paraxial mesoderm during early embryogenesis can lead to Klippel-Feil syndrome (KFS), a congenital disorder characterized by the fusion of two or more cervical vertebrae, resulting in a short neck, limited neck mobility, and potential neurological complications. This condition arises from improper segmentation of the somites derived from paraxial mesoderm, particularly affecting the sclerotome, which normally resegment to form distinct vertebral bodies and intervertebral discs. Failure in this process, often occurring between weeks 3 and 8 of gestation, leads to sclerotome fusion and absence of intervening discs, as seen in the congenital fusion of C1 and C2 vertebrae.^[45]^[46] Disrupted somitogenesis in the paraxial mesoderm is also implicated in congenital scoliosis, where vertebral malformations such as hemivertebrae or block vertebrae cause lateral spinal curvature and progressive deformity. This stems from interruptions in the formation or patterning of somites, regulated by genes like TBX6, which controls paraxial mesoderm differentiation into segmented structures; compound heterozygous variants in TBX6 (a null mutation and a hypomorphic allele) account for approximately 10% of cases, leading to segmentation defects that manifest as asymmetric vertebral development. Clinical features include spinal asymmetry detectable at birth, with risks of respiratory compromise and neurological deficits if untreated.^[47]^[48] Mutations in Pax3, a key transcription factor expressed in the paraxial mesoderm, underlie myogenesis disorders such as those observed in Waardenburg syndrome type 3 (WS3), where defective migration and differentiation of myogenic progenitors from the dermomyotome result in limb muscle hypoplasia or aplasia. Pax3 normally promotes the delamination and migration of muscle precursor cells to form trunk and limb muscles; loss-of-function mutations disrupt this, leading to congenital absence of certain muscle groups and associated skeletal anomalies. These defects highlight Pax3's role in regulating myogenic determination via downstream targets like Myf5 and MyoD.^[49]^[50] In the head paraxial mesoderm, dysregulation of signaling pathways such as retinoic acid (RA) and bone morphogenetic protein (BMP) contributes to disorders like craniosynostosis, the premature fusion of cranial sutures. BMP signaling, essential for osteoprogenitor differentiation in cranial mesoderm-derived bones, when augmented, accelerates suture closure, as evidenced in mouse models where increased Smad-dependent BMP activity in mesodermal cells causes skull vault deformities.^[51]^[52]

Stem Cell Differentiation and Applications

Directed differentiation of paraxial mesoderm from pluripotent stem cells, such as induced pluripotent stem cells (iPSCs) and embryonic stem cells (ESCs), has been achieved through protocols that mimic embryonic signaling gradients. A seminal method involves initial activation of the Wnt pathway using agonists like CHIR99021, combined with fibroblast growth factor 2 (FGF2) to induce neuromesodermal progenitors, followed by BMP inhibition with LDN193189 to specify paraxial mesoderm and presomitic mesoderm (PSM)-like cells. This transgene-free approach, detailed by Chal et al. (2015), enables efficient generation of PSM cells expressing markers like Tbx6 and Msgn1 within 4-5 days, progressing to somite-like structures without cell sorting. These differentiated paraxial mesoderm cells hold significant applications in research and medicine. In vitro models of somitogenesis derived from these cells facilitate drug screening by recapitulating segmentation processes, allowing testing of compounds that modulate developmental pathways like Notch or FGF signaling.^[53] For regenerative medicine, paraxial mesoderm derivatives, such as myogenic progenitors, have been transplanted into mouse models of Duchenne muscular dystrophy, contributing to muscle repair through differentiation into Pax7-positive satellite cells and formation of functional dystrophin-expressing fibers. Similarly, sclerotome-like cells from these protocols show promise for vertebral repair in spinal cord injury contexts, potentially supporting structural regeneration alongside neural therapies. Recent advances include the development of 3D organoids, termed "Somitoids," generated from human PSCs by aggregating cells in low-attachment conditions with FGF and Wnt modulation, followed by withdrawal to promote somite boundary formation. These organoids recapitulate oscillatory gene expression and morphological segmentation, matching in vivo somite sizes and enabling study of human-specific somitogenesis.^[53] As of 2024, protocols have been developed to generate expandable, self-renewing neuromesodermal progenitors from human PSCs, facilitating long-term culture and enhanced differentiation into paraxial mesoderm derivatives for improved disease modeling and therapy development.^[54] Such models open avenues for personalized therapies using patient-derived iPSCs to tailor treatments for musculoskeletal disorders.^[53] Despite these progresses, challenges persist in replicating in vivo dynamics, particularly achieving synchronized oscillations of the segmentation clock in vitro. Dissociated PSM cells often lose oscillatory synchrony due to disrupted cell-cell interactions, resulting in prolonged cycle periods (e.g., ~75 minutes in zebrafish models versus ~30 minutes in vivo) and reduced precision. High cell density and inhibition of pathways like Hippo/Yap are required to restore coordinated pulsatile expression of genes such as Hes7, highlighting the need for advanced culture systems to fully mimic embryonic timing.

References

[1]
Paraxial Mesoderm: The Somites and Their Derivatives - NCBI - NIH
The paraxial mesoderm separates into blocks of cells called somites. Although somites are transient structures, they are extremely important in organizing the ...
[2]
Paraxial Mesoderm - an overview | ScienceDirect Topics
The paraxial mesoderm refers to a strip of closely packed mesenchymal cells that appear lateral to the neural plate during embryonic development.
[3]
Understanding paraxial mesoderm development and sclerotome ...
Aug 13, 2020 · The paraxial mesoderm gives rise to the axial skeleton. The lateral plate mesoderm gives rise to the appendicular skeleton. The neural crest ...
[4]
Segmentation in staged human embryos: the occipitocervical region ...
The first epithelized cellular group within the paraxial mesenchyme at stage 9 is somite 1 (Fig. 1A) because it is not preceded even in later stages by another ...
[5]
Mesenchymal-Epithelial Transition during Somitic Segmentation Is ...
Presomitic mesenchymal cells, which normally contribute to both the epithelial and mesenchymal populations of the somite, were hyperepithelialized when Cdc42 ...
[6]
Periodic formation of epithelial somites from human pluripotent stem ...
Apr 28, 2022 · In this study, we report human embryonic organoids that periodically form pairs of somite-like structures with the mature epithelial organization along the ...
[7]
Signaling Gradients during Paraxial Mesoderm Development - PMC
These pathways show graded distribution of signaling activity within the paraxial mesoderm of vertebrate embryos.
[8]
Hox genes and morphological identity: axial versus lateral ...
Oct 1, 2000 · Several studies have demonstrated that specific Hox genes have different anterior expression borders in paraxial mesoderm and lateral plate ...
[9]
Comparative spatiotemporal analysis of Hox gene expression in ...
Aug 28, 2012 · We found that the expression pattern of Hox genes in both intermediate and paraxial mesodermal tissues is similar at least regarding the genes ...
[10]
Evolution of Somite Compartmentalization: A View From Xenopus
During evolution, somites appear in the chordate phylum and compartmentalize mainly into the dermomyotome, the myotome, and the sclerotome in vertebrates.
[11]
Evolutionary perspectives from development of mesodermal ...
May 3, 2007 · Thus, the vertebrate cephalic mesoderm may be entirely different from the somites, or at most it may correspond to two mesodermal segments, one ...Missing: non- | Show results with:non-
[12]
Mouse gastrulation: Coordination of tissue patterning, specification ...
Gastrulation is initiated at the posteriorly positioned primitive streak, from which nascent mesoderm and endoderm progenitors ingress and begin to diversify.
[13]
BMP and FGF signaling interact to pattern mesoderm by controlling ...
High Wnt signaling promotes the formation of paraxial mesoderm, which later gives rise to somites, while low Wnt signaling is required for adoption of lateral ...
[14]
Wnt5a and Wnt11 regulate mammalian anterior-posterior axis ...
Gastrulation is initiated with primitive streak (PS) formation at the posterior of the embryo (Tam and Behringer, 1997). The PS elongates anteriorly during ...
[15]
Spinal neural tube formation and tail development in human embryos
Nov 21, 2024 · Hence, somite formation in humans occurs at a rate that is 3.5-times slower than in rodent embryos, and ceases after CS16.
[16]
The period of the somite segmentation clock is sensitive to Notch ...
Using this result, we estimated that the period of somite formation was ∼106 min and 111 min in the wild-type embryos and the Nrarp−/– embryos, respectively ( ...
[17]
From Segment to Somite: Segmentation to Epithelialization ... - NIH
In this short review, we present two quantitative frameworks that address the morphogenesis from segment to somite and discuss recent data of segmentation and ...
[18]
Somitomeres: mesodermal segments of vertebrate embryos
Oct 1, 1988 · Somitomeres are formed along the length of the embryo during gastrulation, and in the segmental plate and tail bud at later stages. They form in ...
[19]
Cellular and molecular control of vertebrate somitogenesis - PMC
Jan 2, 2025 · The antero-posterior polarity of the future somite is also established before formation of the boundary which separates the epithelial somite ...
[20]
The Anterior/Posterior Polarity of Somites Is Disrupted in Paraxis ...
Jan 1, 2001 · Establishing the anterior/posterior (A/P) boundary of individual somites is important for setting up the segmental body plan of all vertebrates.
[21]
Developmental mechanisms of intervertebral disc and vertebral ...
Jul 18, 2017 · 35 In humans, the 33 vertebrae along the vertebral column form from 33 pairs of somites established during embryogenesis.36 In mice, 65 ...
[22]
Pax1 and Pax9 synergistically regulate vertebral column development
The gradual loss of Sox9 and Collagen II expression in this mesenchyme indicates that the sclerotomes are prevented from undergoing chondrogenesis. The first ...
[23]
Pax1 and Pax9 synergistically regulate vertebral column development
Furthermore, the development of neural arches indicates that sclerotome formation can not be completely abolished in the absence of Pax1 and Pax9. Fig. 2 ...Results · Pax1 And Pax9 Are Required... · Cell Proliferation And...
[24]
Skeletal myogenesis and Myf5 activation - PMC - PubMed Central
Skeletal myogenesis is regulated by four MRFs: Myf5, MyoD, myogenin and MRF4. In the mouse embryo, Myf5 is the earliest MRF to be expressed. It is first ...
[25]
Myf5 and MyoD activation define independent myogenic ...
Gene targeting has indicated that Myf5 and MyoD are required for myogenic determination because skeletal myoblasts and myofibers are missing in mouse ...
[26]
Amniote somite derivatives - Christ - 2007 - Developmental Dynamics
Jun 7, 2007 · In this review, we focus on the crucial role of the somites in building the body wall and limbs of amniote embryos.
[27]
A Somitic Compartment of Tendon Progenitors - ScienceDirect.com
Scx, the Syndetome, and Tendon Development. This study describes a somitic compartment of tendon progenitors, termed the syndetome, and traces its emergence ...
[28]
Molecular targets for tendon neoformation - JCI
Feb 1, 2008 · This Review discusses the several factors that might serve as molecular targets that upon activation can enhance or lead to tendon neoformation.
[29]
Muscle Development: Forming the Head and Trunk Muscles - NIH
Head muscles derive from the pre-chordal and paraxial head mesoderm (referred as cranial mesoderm) and control mastication, breathing, eye movement and facial ...
[30]
2: Development of the Head, Face, and Mouth | Pocket Dentistry
Jan 4, 2015 · The paraxial mesoderm cranial to the first occipital somite does not undergo segmentation or form somites. Unsegmented paraxial mesoderm ...
[31]
The molecular setup of the avian head mesoderm and its implication ...
Sep 12, 2006 · It consists of the paraxial mesoderm and the remnant of the originally axial, pre-chordal mesoderm that is pushed posteriorly through the ...
[32]
The differentiation and morphogenesis of craniofacial muscles
Feb 24, 2006 · Osteogenic precursors of intramembranous bone originate deep and medially within head paraxial mesoderm. These cells move dorsally around the ...
[33]
BMP and retinoic acid regulate anterior–posterior patterning of ... - NIH
Jul 13, 2016 · We find that BMP signalling acts early to establish broad anterior and posterior territories in the non-axial mesoderm while retinoic acid (RA) functions later.Missing: Engrailed- | Show results with:Engrailed-
[34]
Distinct regulatory cascades for head and trunk myogenesis
Feb 1, 2002 · Most head muscles arise from the pre-otic axial and paraxial head mesoderm. This tissue does not form somites, yet expresses the somitic ...
[35]
https://journals.biologists.com/dev/article/129/3/573/18302/Distinct-regulatory-cascades-for-head-and-trunk
[36]
Regulation of dorsal somitic cell fates: BMPs and Noggin control the ...
Conversely, administration of the BMP antagonist, Noggin, to paraxial mesoderm cocultured with ectoderm dramatically up-regulates the expression of MyoD and ...
[37]
In Vitro Generation of Neuromesodermal Progenitors Reveals ...
In Vitro Generation of Neuromesodermal Progenitors Reveals Distinct Roles for Wnt Signalling in the Specification of Spinal Cord and Paraxial Mesoderm Identity.
[38]
FGF Signaling Controls Somite Boundary Position and Regulates ...
Overexpressing FGF8 in the paraxial mesoderm by in ovo electroporation blocks segment formation by maintaining the caudal PSM identity of cells in regions which ...Missing: maintenance | Show results with:maintenance
[39]
Regulation of Segmental Patterning by Retinoic Acid Signaling ...
These results indicate that RA signaling contributes to segmental patterning by antagonizing the effects of FGF signaling on cells in the TBD, thus functioning ...
[40]
WNT signaling, in synergy with T/TBX6, controls Notch signaling by ...
Embryos lacking Tbx6 produce presumptive paraxial mesoderm, but the differentiation of these cells is impaired and supernumerary neural tubes form instead of ...Missing: Chapple | Show results with:Chapple
[41]
Pax3/Pax7 mark a novel population of primitive myogenic cells ...
Pax3+/Pax7+ cells are a novel, muscle marker-negative population that give rise to muscle progenitors and mark satellite cells during development.
[42]
Dynamic expression and essential functions of Hes7 in somite ...
These results indicate that Hes7 controls the cyclic expression oflunatic fringe and is essential for coordinated somite segmentation.
[43]
Establishment of Hox vertebral identities in the embryonic spine ...
The paraxial tissue anterior to the otic vesicle is called the cephalic or head mesoderm. It does not segment into somites and gives rise to bones and muscles ...
[44]
Klippel-Feil Syndrome - Spine - Orthobullets
Jan 16, 2024 · Klippel-Feil Syndrome (KFS) is a rare congenital condition caused by failure of normal segmentation or formation of cervical somites during ...
[45]
Klippel-Feil Syndrome Essentials, Part 1 - Applied Radiology
Dec 1, 2024 · The paraxial mesoderm forms around the notochord and, as neurulation progresses, matures and segments into somites on both sides of the neural ...
[46]
Progress and perspective of TBX6 gene in congenital vertebral ...
Disruption of the genesis of paraxial mesoderm, somites or axial bones can result in spinal deformity. In the course of somitogenesis, the segmentation clock ...
[47]
PAX3 gene: MedlinePlus Genetics
Aug 16, 2022 · Homozygous and heterozygous inheritance of PAX3 mutations causes different types of Waardenburg syndrome. Am J Med Genet A. 2003 Sep 15;122A ...
[48]
The expression and function of PAX3 in development and disease
This protein is expressed during development of skeletal muscle, central nervous system and neural crest derivatives, and regulates expression of target genes ...Missing: syndetome | Show results with:syndetome
[49]
BMP Signaling in the Development and Regeneration of Cranium ...
Mar 10, 2020 · A disrupted BMP signaling pathway results in severe skeletal defects. Murine calvaria has been identified to have dual-tissue lineages, namely, ...
[50]
Common mechanisms in development and disease: BMP signaling ...
BMP signaling is one of the key pathways regulating craniofacial development. It is involved in the early pattering of the head, the development of cranial ...
[51]
https://pmc.ncbi.nlm.nih.gov/articles/PMC7075941/