Mechanism of muscle-tendon-bone complex development in the head.

The musculoskeletal system comprises muscles, tendons, ligaments, and bones. The connection site between muscle and tendon is termed "myotendinous junction," while the junction between tendon/ligament and bone is termed "enthesis." These two regions are the center of physical function, but how this functional complex is formed during development is unclear. In this review, we discussed recent findings about the development of tissues constituting the musculoskeletal system and the interactions among these tissues during development. The musculoskeletal system of the head develops in the mid-embryonic stage. In addition, head mesoderm-derived cells (muscle anlagen) and cranial neural crest cells (tendon and bone anlagen) interact with each other. Myogenesis initiates in the head without difficulty, even in the absence of cranial neural crest cells; however, muscle tissue does not grow under these conditions and remains small. Tendons, which differentiate from cranial neural crest cells, form myotendinous junctions at the stage at which desmin accumulates in the tendon-side muscle stump, leading to morphological maturation. Therefore, individual tissues (i.e., muscles, tendons, ligaments, and bones) constituting the musculoskeletal system form a functionally important complex, while mutually influencing one another.

Functional domains of the FgfrL1 receptor.

FgfrL1 is a novel growth factor receptor that is primarily expressed in musculoskeletal tissues and the kidney. FgfrL1-deficient mice have a malformed diaphragm and no kidneys. Such animals die immediately after birth because they are not able to inflate their lungs. The FgfrL1 molecule is composed of three extracellular Ig domains, a transmembrane helix and a short intracellular domain. To investigate the contribution of each of these domains to the function of the novel receptor, we generated mice with deletions of the individual domains. Mice lacking the intracellular domain are viable and phenotypically normal. Mice lacking the first (N-terminal) Ig domain are also viable and normal, but have a reduced life span. Mice lacking the Ig2 or the Ig3 domain are born alive, but die within 24 â€‹h after birth. Ig2-deficient animals exhibit substantially smaller kidneys than wild-type littermates and contain a lower number of glomeruli. Ig3-deficient mice completely lack metanephric kidneys. Interestingly, both the Ig2 and the Ig3-deficient animals show only minor alterations in the diaphragm, which still enables them to inflate their lungs after birth. Our results demonstrate that the principal function of the FgfrL1 receptor is to control the growth of the metanephric kidneys by regulating nephrogenesis. It appears that this function is primarily accomplished by the Ig3 domain with some contribution of the Ig2 domain. It is conceivable that the two domains interact with an Fgf ligand and another molecule from the surface of neighboring cells to induce condensation of the metanephric mesenchyme to renal epithelia and glomeruli.

Effects of hyperthyroidism in the development of the appendicular skeleton and muscles of zebrafish, with notes on evolutionary developmental pathology (Evo-Devo-Path).

The hypothalamus-pituitary-thyroid (HPT) axis plays a crucial role in the metabolism, homeostasis, somatic growth and development of teleostean fishes. Thyroid hormones regulate essential biological functions such as growth and development, regulation of stress, energy expenditure, tissue compound, and psychological processes. Teleost thyroid follicles produce the same thyroid hormones as in other vertebrates: thyroxin (T4) and triiodothyronine (T3), making the zebrafish a very useful model to study hypo- and hyperthyroidism in other vertebrate taxa, including humans. Here we investigate morphological changes in T3 hyperthyroid cases in the zebrafish to better understand malformations provoked by alterations of T3 levels. In particular, we describe musculoskeletal abnormalities during the development of the zebrafish appendicular skeleton and muscles, compare our observations with those recently done by us on the normal developmental of the zebrafish, and discuss these comparisons within the context of evolutionary developmental pathology (Evo-Devo-Path), including human pathologies.

HOXA5 protein expression and genetic fate mapping show lineage restriction in the developing musculoskeletal system.

HOX proteins act during development to regulate musculoskeletal morphology. HOXA5 patterns skeletal structures surrounding the cervical-thoracic transition including the vertebrae, ribs, sternum and forelimb girdle. However, the tissue types in which it acts to pattern the skeleton, and the ultimate fates of embryonic cells that activate Hoxa5 expression are unknown. A detailed characterization of HOXA5 expression by immunofluorescence was combined with Cre/LoxP genetic lineage tracing to map the fate of Hoxa5 expressing cells in axial musculoskeletal tissues and in their precursors, the somites and lateral plate mesoderm. HOXA5 protein expression is dynamic and spatially restricted in derivatives of both the lateral plate mesoderm and somites, including a subset of the lateral sclerotome, suggesting a local role in regulating early skeletal patterning. HOXA5 expression persists from somite stages through late development in differentiating skeletal and connective tissues, pointing to a continuous and direct role in skeletal patterning. In contrast, HOXA5 expression is excluded from the skeletal muscle and muscle satellite cell lineages. Furthermore, the descendants of Hoxa5-expressing cells, even after HOXA5 expression has extinguished, never contribute to these lineages. Together, these findings suggest cell autonomous roles for HOXA5 in skeletal development, as well as non-cell autonomous functions in muscle through expression in surrounding connective tissues. They also support the notion that different Hox genes display diverse tissue specificities and locations to achieve their patterning activity.

Organogenesis of the Musculoskeletal System in Horse Embryos and Early Fetuses.

Musculoskeletal system development involves heterotypical inductive interactions between tendons, muscles, and cartilage and knowledge on organogenesis is required for clarification of its function. The aim of this study was to describe the organogenesis of horse musculoskeletal system between 21 and 105 days of gestation, using detailed macroscopic and histological analyses focusing on essential developmental steps. At day 21 of gestation the skin was translucid, but epithelial condensation and fibrocartilaginous tissues were observed on day 25 of pregnancy. Smooth muscle was seen in lymphatic and blood vessel walls and the beginning of cartilaginous chondrocranium was detected at day 30 of gestation. At day 45, typical chondroblasts and chondrocytes were observed and at day 55, mandibular processes expanded toward the ventral midline of the pharynx. At day 75, muscles became thicker and muscle fibers were seen developing in carpal and metacarpal joints with the beginning of the ossification process. At day 105, major muscle groups, similar to those seen in an adult equine, were observed. The caudal area of the nasal capsule and trabecular cartilages increased in size and became ossified, developing into the ethmoid bone. The presence of nasal, frontal, parietal, and occipital bones was observed. In conclusion, novel features of equine musculoskeletal system development have been described here and each process was linked with an early musculoskeletal event. Data presented herein will facilitate a better understanding of the equine muscular system organogenesis and aid in the detection of congenital deformities. Anat Rec, 299:722-729, 2016. © 2016 Wiley Periodicals, Inc.

Anatomical and histological study of human deep fasciae development.

PURPOSE: To characterize the connective tissue found between the subcutaneous adipose tissue and the underlying muscle tissue in different regions and at different stages of human fetal development. We aim to identify its structural similarities to adult deep fascia, and to establish its role in myofascial development. METHODS: Samples from the arm, forearm, low back and thigh regions (from sites topographically homologous to the adult deep fascia) of five fetus body donors were obtained to perform gross anatomy dissection and histologic sections. Sections were stained with hematoxylin-eosin and Masson trichrome stain to observe their overall structure. Antiserum to protein S100 was used to analyze the presence and distribution of nerve fibers, and immunohistochemistry processing with Tcf4 marker was used to ensure fibroblast activity. RESULTS: Gross anatomy and histological sections of fetal samples showed the presence of connective tissue topographically and morphologically equivalent to adult deep fasciae. Developing blood vessels and nerves were found evenly distributed within the connective tissue during early development and in the portion adjacent to the muscle at later stages. The presence of Tcf4+ fibroblasts was confirmed in all analyzed mesenchymal connective tissue. CONCLUSIONS: Deep fascia is present from week 21 of human development in the lower back and upper and lower limbs. Blood vessels and nerves develop parallel to it and occasionally cross it from the deep to superficial plane. The presence of Tcf4+ fibroblasts in the deep fascia suggests a crucial role for this structure in muscle morphogenesis.

Intestinal cell kinase, a protein associated with endocrine-cerebro-osteodysplasia syndrome, is a key regulator of cilia length and Hedgehog signaling.

Endocrine-cerebro-osteodysplasia (ECO) syndrome is a recessive genetic disorder associated with multiple congenital defects in endocrine, cerebral, and skeletal systems that is caused by a missense mutation in the mitogen-activated protein kinase-like intestinal cell kinase (ICK) gene. In algae and invertebrates, ICK homologs are involved in flagellar formation and ciliogenesis, respectively. However, it is not clear whether this role of ICK is conserved in mammals and how a lack of functional ICK results in the characteristic phenotypes of human ECO syndrome. Here, we generated Ick knockout mice to elucidate the precise role of ICK in mammalian development and to examine the pathological mechanisms of ECO syndrome. Ick null mouse embryos displayed cleft palate, hydrocephalus, polydactyly, and delayed skeletal development, closely resembling ECO syndrome phenotypes. In cultured cells, down-regulation of Ick or overexpression of kinase-dead or ECO syndrome mutant ICK resulted in an elongation of primary cilia and abnormal Sonic hedgehog (Shh) signaling. Wild-type ICK proteins were generally localized in the proximal region of cilia near the basal bodies, whereas kinase-dead ICK mutant proteins accumulated in the distal part of bulged ciliary tips. Consistent with these observations in cultured cells, Ick knockout mouse embryos displayed elongated cilia and reduced Shh signaling during limb digit patterning. Taken together, these results indicate that ICK plays a crucial role in controlling ciliary length and that ciliary defects caused by a lack of functional ICK leads to abnormal Shh signaling, resulting in congenital disorders such as ECO syndrome.

Pax genes: regulators of lineage specification and progenitor cell maintenance.

Pax genes encode a family of transcription factors that orchestrate complex processes of lineage determination in the developing embryo. Their key role is to specify and maintain progenitor cells through use of complex molecular mechanisms such as alternate RNA splice forms and gene activation or inhibition in conjunction with protein co-factors. The significance of Pax genes in development is highlighted by abnormalities that arise from the expression of mutant Pax genes. Here, we review the molecular functions of Pax genes during development and detail the regulatory mechanisms by which they specify and maintain progenitor cells across various tissue lineages. We also discuss mechanistic insights into the roles of Pax genes in regeneration and in adult diseases, including cancer.

Effects of maternal administration of aluminum chloride on the development of the skeletal system of albino rat fetuses - protective role of saffron

Aluminum is widely used in food packaging and additives. Aluminum chloride (AlCl3) was known to cause maternal toxicity and embryolethality. Previous studies have demonstrated the antioxidant effects of saffron. The purpose of the present study was to assess the effect of maternal administration of aluminum chloride during the period of embryogenesis on the development of the skeletal system of albino rat fetuses and the protective role of saffron. Twenty four virgin female albino rats were used throughout this study. One male rat was introduced into a cage with two females for mating. Once the pregnancy was confirmed, pregnant rats were divided into the following groups: Control, AlCl3 treated (200 mg/kg) and AlCl3+S treated (AlCl3 200 mg/kg and saffron 200 mg/kg in water extract). Rats received treatments daily from the 6th to 15th day of gestation intragastrically and sacrificed on the 20th day. The fetuses were obtained through Caesarian section, stained with Alizarin red and examined for skeletal development. AlCl3 treated rats showed toxic manifestations and decreased weight gain and their fetuses revealed increased embryolethality and a higher number of bones showed delayed ossification. AlCl3 +S treated animals revealed improvement in maternal weight gain, embryolethality and bone ossification. We conclud that AlCl3 induces delay in bone development, and saffron ameliorates its effects (AU)

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MR imaging of the fetal musculoskeletal system.

Magnetic resonance imaging (MRI) appears to be increasingly used, in addition to standard ultrasonography for the diagnosis of abnormalities in utero. Previous studies have recently drawn attention to the technical refinement of MRI to visualize the fetal bones and muscles. Beyond commonly used T2-weighted MRI, echoplanar, thick-slab T2-weighted and dynamic sequences, and three-dimensional MRI techniques, are about to provide new imaging insights into the normal and the pathological musculoskeletal system of the fetus. This review emphasizes the potential significance of MRI in the visualization of the fetal musculoskeletal system.

Irxl1 mutant mice show reduced tendon differentiation and no patterning defects in musculoskeletal system development.

Irxl1 (Iroquois-related homeobox like-1) is a newly identified three amino-acid loop extension (TALE) homeobox gene, which is expressed in various mesoderm-derived tissues, particularly in the progenitors of the musculoskeletal system. To analyze the roles of Irxl1 during embryonic development, we generated mice carrying a null allele of Irxl1. Mice homozygous for the targeted allele were viable, fertile, and showed reduced tendon differentiation. Skeletal morphology and skeletal muscle weight in Irxl1-knockout mice appeared normal. Expression patterns of several marker genes for cartilage, tendon, and muscle progenitors in homozygous mutant embryos were unchanged. These results suggest that Irxl1 is required for the tendon differentiation but dispensable for the patterning of the musculoskeletal system in development.

Skeletal development on fetal magnetic resonance imaging.

Prenatal magnetic resonance imaging (MRI) is being increasingly used, in addition to standard ultrasound, for the diagnosis of congenital diseases beyond the central nervous system. Previous studies have demonstrated that MRI may be useful for the in utero visualization of spinal dysraphism and for differentiating between isolated and complex skeletal disorders with associated abnormalities. More recently, attention has focused on the visualization of the human fetal skeleton for the delineation of normal and pathological development of skeletal structures. On 1.5 T, in particular, echoplanar imaging enables the delineation of various epimetaphyseal structures and morphometric measurements of the fetal long bones from 18 gestational weeks until term. This information gathered from prenatal MRI might be helpful in the diagnosis of focal bone abnormalities and generalized skeletal disorders, such as bone dysplasias. Further clinical research, along with the refinement of the newest techniques, will enable expansion of the preliminary findings and help in determining the impact of fetal magnetic resonance bone imaging in the routine clinical setting. This review summarizes the current data in the literature and the authors' clinical experience with the magnetic resonance visualization of the developing fetal skeleton and also comments on the potential future applications of this technique.

Development of the pharyngeal arch skeleton in Catostomus commersonii (Teleostei: Cypriniformes).

Skeletal elements of the gill arches of adult cypriniform fishes vary widely in number, size, and shape and are important characters in morphologically based phylogenetic studies. Understanding the developmental basis for this variation is thus phylogenetically significant but also important in relation to the many developmental genetic and molecularly based studies of the early developing and hence experimentally tractable gill arches in the zebrafish, a cyprinid cypriniform. We describe the sequence of the chondrification and ossification of the pharyngeal arches and associated dermal bones from Catostomus commersonii (Catostomidae, Cypriniformes) and make selected comparisons to other similarly described pharyngeal arches. We noted shared spatial trends in arch development including the formation of ventral cartilages before dorsal and anterior cartilages before posterior. Qualitatively variable gill arch elements in Cypriniformes including pharyngobranchial 1, pharyngobranchial 4, and the sublingual are the last such elements to chondrify in C. commersonii. We show that the sublingual bone in C. commersonii has two cartilaginous precursors that fuse and ossify to form the single bone in adults. This indicates homology of the sublingual in catostomids to the two sublingual bones in the adults of cobitids and balitorids. Intriguing patterns of fusion and segmentation of the cartilages in the pharyngeal arches were discovered. These include the individuation of the basihyal and anterior copula through segmentation of a single cartilage rod, fusion of cartilaginous basibranchials 4 and 5, and fusion of hypobranchial 4 with ceratobranchial 4. Such "fluidity" in cartilage patterning may be widespread in fishes and requires further comparative developmental studies.

Chondromodulin-I and tenomodulin are differentially expressed in the avascular mesenchyme during mouse and chick development.

Chondromodulin-I (ChM-I) and tenomodulin (TeM) are homologous angiogenesis inhibitors. We have analyzed the spatial relationships between capillary networks and the localization of these molecules during mouse and chick development. ChM-I and TeM proteins have been localized to the PECAM-1-negative avascular region: ChM-I is expressed in the avascular cartilage, whereas TeM is detectable in dense connective tissues, including tendons and ligaments. We have also examined the vasculature of chick embryos by injection with India ink and have performed in situ hybridization of the ChM-I and TeM genes. The onset of ChM-I expression is associated with chondrogenesis during mouse embryonic development. ChM-I expression is also detectable in precartilaginous or noncartilaginous avascular mesenchyme in chick embryos, including the somite, sclerotome, and heart. Hence, the expression domains of ChM-I and TeM during vertebrate development incorporate the typical avascular regions of the mesenchymal tissues.

YKL-40 protein expression in the early developing human musculoskeletal system.

YKL-40 is a growth factor for chondrocytes and fibroblasts. The aim was to evaluate YKL-40 expression in the musculoskeletal system during early human development. We studied sections from 15 human embryos [weeks 5.5-8; 7- to 31-mm crown-rump length (CRL)] and 68 fetuses (weeks 9-14; 33- to 105-mm CRL) for YKL-40 protein expression by immunohistochemistry. YKL-40 mRNA expression was evaluated in two human embryos (days 41 and 51). Initially YKL-40 is expressed in all germ layers: ecto-, meso-, and endoderm. YKL-40 mRNA and protein expression are found in tissues of the ecto-, meso-, and endoderm, and YKL-40 protein expression is present during development of cartilage, bone, joints, and muscles. At the cellular level, YKL-40 protein expression is high in tissues characterized by rapid proliferation, marked differentiation, and undergoing morphogenetic changes. Examples of rapid cell proliferation include the chondrogenic inner layer of perichondrium and the osteogenic inner layer of periosteum. Differences in YKL-40 expression during differentiation are found in the chondrogenic and osteogenic cell lineages. The initial shaping of cartilage and bone models and joints is concomitant with a strong outline of YKL-40-positive cells. This indicates that YKL-40 is associated with cell proliferation, differentiation, and tissue morphogenesis during development of the human musculoskeletal system.

A comprehensive study of the spatial and temporal expression of the col5a1 gene in mouse embryos: a clue for understanding collagen V function in developing connective tissues.

Collagen V is a quantitatively minor component of collagen I fibrils and the defective product of classic Ehlers-Danlos syndrome (EDS). To provide new insights into its embryonic function, a continuous evaluation of the expression pattern of proalpha1(V), a chain common to all collagen V molecular forms, was performed by in situ hybridization of developing mouse from 7.5 days after conception (dpc) to birth. Proalpha1(V) transcripts were first detected at 8.5 dpc, signals being considerably augmented at 16.5 dpc and declining at birth. Hybridization signals were, at first, exclusively detected in the dorsal aorta wall, heart, and adnexa. At 10.5 dpc, col5a1 expression was found in the heart, dorsal aorta wall, branchial arches, mesonephrotic tubules, and intestinal mesenchyme and coincided with proalpha1(I) developmental expression. Later stages exhibited an intense signal in more restricted regions, notably the skin, the bones and vertebral column, the cornea, the tendons and ligaments, the peritoneal membranes, the umbilical cord, and the salivary gland. The data revealed the important contribution of collagen V to the development of functional connective tissues. Proalpha1(V) signals were exclusively detected in the flattened cells of the surface ectoderm at 10.5 dpc. By 12.5 dpc, when cells had become cuboidal, the signal switched to the dermal fibroblasts. Thus, type V collagen appears to contribute to epidermis differentiation. Our data also suggest that collagen V participates in bone formation and/or mineralization and in the renewal of stromal cells in the cornea. The results underscore the role of collagen V in developing embryos and provide important clues for analyzing the phenotype of mouse models for EDS.

Differential regulation of imprinting in the murine embryo and placenta by the Dlk1-Dio3 imprinting control region.

Genomic imprinting is an epigenetic mechanism controlling parental-origin-specific gene expression. Perturbing the parental origin of the distal portion of mouse chromosome 12 causes alterations in the dosage of imprinted genes resulting in embryonic lethality and developmental abnormalities of both embryo and placenta. A 1 Mb imprinted domain identified on distal chromosome 12 contains three paternally expressed protein-coding genes and multiple non-coding RNA genes, including snoRNAs and microRNAs, expressed from the maternally inherited chromosome. An intergenic, parental-origin-specific differentially methylated region, the IG-DMR, which is unmethylated on the maternally inherited chromosome, is necessary for the repression of the paternally expressed protein-coding genes and for activation of the maternally expressed non-coding RNAs: its absence causes the maternal chromosome to behave like the paternally inherited one. Here, we characterise the developmental consequences of this epigenotype switch and compare these with phenotypes associated with paternal uniparental disomy of mouse chromosome 12. The results show that the embryonic defects described for uniparental disomy embryos can be attributed to this one cluster of imprinted genes on distal chromosome 12 and that these defects alone, and not the mutant placenta, can cause prenatal lethality. In the placenta, the absence of the IG-DMR has no phenotypic consequence. Loss of repression of the protein-coding genes occurs but the non-coding RNAs are not repressed on the maternally inherited chromosome. This indicates that the mechanism of action of the IG-DMR is different in the embryo and the placenta and suggests that the epigenetic control of imprinting differs in these two lineages.

Dynamic expression of sparc precedes formation of skeletal elements in the Medaka (Oryzias latipes).

Sparc is a secreted calcium-binding glycoprotein that regulates mineralization of bone tissues in mammals. In other vertebrates, its function remains largely unclear. Here, we describe the isolation, genomic organization and expression of the sparc gene in the teleost Medaka (Oryzias latipes), an established vertebrate model for developmental studies. During earliest stages of Medaka embryogenesis, sparc is expressed in the sclerotome compartment of the somites that gives rise to precursor cells of the axial skeleton. Importantly, in this area its expression precedes that of twist-1, which is a crucial regulator of osteoblast formation. Dynamic expression is also found in the floor plate of the neural tube and the notochord. Both structures are passed by migrating skeletal precursors shortly before they differentiate and form the vertebrae. In general, sparc is expressed before the formation and mineralization of bone elements and expression of bone markers like collagen type 1a in the fins and axial skeleton of Medaka embryos. It is also expressed in several non-skeletal tissues of embryos and adult fish, suggesting possible other functions not related to bone mineralization. Taken together, the Medaka sparc gene represents an excellent marker for early sclerotome development. Its restricted and highly dynamic expression suggests a novel function during migration of sclerotome cells and their differentiation into early vertebrae. This marker thus allows the analysis of early skeletal development and formation of extracellular bone matrix in this vertebrate model.