6.1. DEVELOPMENT OF MESODERMAL ORGANS Pavel Krejci In vertebrates, the mesoderm becomes partitioned at an early stage into four zones, from medial to lateral: l.NOTOCHORD: occupies the midline. 2. PARAXIAL MESODERM: future somites. 3. INTERMEDIATE MESODERM: forms gonads, kidneys, and adrenals. 4. LATERAL PLATE MESODERM: the lateral plate is subdivided by the coelom into the outer SOMATIC MESODERM (future limb buds) and inner SPLANCHNIC MESODERM that forms mesenteries and heart. The skeleton originates from three regions: Skull is formed from neural crest; the vertebrae are formed from somites; and the bones of the limbs are formed from limb buds and associated lateral plate. SOMITOGENESIS AND MYOGENESIS Somite patterning is a clearest example of segmental arrangement of the vertebrate body. Somites arise in anteroposterior sequence from the paraxial mesoderm by the action of forkhead transcription factors FoxCl and C2. Somites start as loose cell associations called somitomeres, that later condense into the epithelial somites. This structure is transient as it undergoes epithelial-to-mesenchymal transformation to form the sclerotome (future vertebrae/ribs). Dorsal part of sclerotome forms tendons whereas the lateral part forms dermamyotome that later forms skin (dermatome) and muscles (myotome). Epaxial myotome forms segmental muscles of the body axis, hypaxial myotome forms muscles of the ventral body wall, limbs, and diaphragm. Neural tube Motochord o o o o o 0 0o o | Sclerotome Hypaxial myotome SEGMENTATION MECHANISM: Somites generated by molecular oscillator (a clock) operating in conjunction with a spatial gradient. One cycle of the clock forms one somite, the gradient determines that the somites are formed in anterior to posterior sequence. The clock represents a periodic expression of c-hairy 7, that encodes for transcription factor bHLH in chick. Operation of somite oscillator over one cycle of somite formation. The diagrams show the expression pattern of c-hairy at four times of the cycle and the graphs show how the level of transcripts varies at the pointa a, b and c. b c — a m H — 3 — b — c Time (minutes) 90 The actual oscillation is controlled by autoregulation of transcription of the hairy-type of transcription factors (herl in mouse), through a negative-feedback mechanism. h&r7 (delay) Gene mRNA in SUBDIVISION OF THE SOMITE: The subdivision of the somite depends on the interaction wiuth the surrounding tissues. The sclerotome is induced by notochord and ventral part of the neural tube. The epaxial myotome is induced by notochord and dorsal neural tube. The dermatome is induced by neural tube. The signal for sclerotome induction is Sonic hedgehog (Shh). The induction of myotome requires early exposure to Shh followed by Wnt signal from the dorsal neural tube. This results in the induction of the myogenic genes like my f5 and regional repression of the myogenesis inhibitor pax3. The lateral plate-derived BMP4 represses myogenesis to balance the system. The dermatome arises because of the neurotropin 3 signal from the neural tube. Epaxia myotome Signals Dermatom and hypaxi, myotome pdx3 \ Sclerotome MYOGENESIS SKELETAL MUSCLE: derived from myotome of the somites. SMOOTH MUSCLE: formed in lateral plate mesoderm. CARDIAC MUSCLE: formed in the myocardium of the early heart. Skeletal muscle differentiation: cells commited to myoblasts diviode, migrate and fuse to form the multinucleate myofibers. Myogenic proteins - bHLH class of transcription factors (MyoD, Myf5, myogenin) capable of turning cells into the myogenic cells. FGF O Somite cell Wnt Myoblast CeH fusion Metalloproteases Tetraspamns Myotube THE DEVELOPMENT OF THE KIDNEY Kidneys originate from intermediate mesoderm (lateral to paraxial mesoderm). Amniotes has three kidneys - pronephros (non functional), mesonephros (functions transiently in embryonal life) and metanephros (definitive kidney). The nephric duct (Wollfian duct) originates in the anterior of intermediate mesoderm surrounded by the tissue committed to be kidney -nephrogenic mesoderm. The collecting system of metanephros is hovewer not formed from the main nephric duct, but from an outgrowth called ureteric bud, that growths into the nephrogenic mesenchyme. The mesenchyme differentiates into nephrons. Developing nephrons Nephrogenic mesenchyme Ureteric bud (a) Ureter Collecting ducts Proximal tubufe Glomerulus Mesenchymal condensation (bj 5-body Fusion Bowman's capsule Nephron . GERM CELL AND GONADAL DEVELOPMENT Gonads have dual origin. The somatic tissue originates from genital ridges of the intermediate mesoderm. The germ cells are derived from primordial germ cells (PGCs) that migrate to the genital ridges from the proximal part of the egg cylinder. PGCs are induced by the extraembryonic ectoderm via BMP4 signal. The migration of PGCs is driven by chemokine SDF1 (stromal cell derived factor 1) produced by lateral plate mesoderm. Genital ridge Mesentery Gut 8.5 day 10,5 day Gonad development depends on sex determination. Gonads develop from the medial part of intermediate mesoderm that forms genital ridge at 9.5E in mouse. Shortly after the appearance of the genital ridge, cord of cells begin to form from the coelomic lining epithelium and grow into the underlying mesenchyme. Two ducts arise in this period, the nephric duct and the Mullerian duct that will eventually became the oviduct, uterus and proximal vagina of a female. There is no difference between two sexes by this stage (E12.5 in mouse). Testis -cords Ovary In male, the cords of coelomic lining cells form a complex systém of seminiferous tubules composed of Sertoli cells into which the germ cells are integrated. Cells responsible for testosteron production (Leydig cells) differentiate from mesenchyme between the tubules. The tubules became connected to nephric duct and the Mullerian duct regresses. The tubules remain solid until after birth, when they start to hollow out and germ cell-derived spermatogonia appear. Type A Type B spermatogonia spermatogonia Mature sperm Blood vessel l Primary Sertoli spermatocyte cell Lumen of seminiferous tubule Leydig cells In the female, the cords of cells derived from coelomic lining stay near the surface as granulosa (follicle) cells, in proximity to the to the oogonia. Thecal cells that produce the estrogen differentiate from the mesenchyme. The gonad becames encapsulated as ovary and the nephric duct degenerates. The two Mullerian ducts fuse at their posterior ends to forma proximal part of vagina and uterus. SEX DETERMINATION: Gonadal develoment does not require the presence of germ cells. WT1 (zinc-finger transcription factor) and SF1 (member of nuclear hormone receptor family) are essential to early, uniform development of gonad. The sex is determined by chomosomal constitution, with Y-linked SRY (sex determining region of Y, encodes for transcription factor of HMG group) being a critical switch controlling the process. If SRY is deleted from Y chromosome, the XY mouse develops as a female and vice versa. SRY regulates sex development through repressing DAX1, a nuclear hormone receptor that inhibits various male functions like AMH (anti-Mullerian hormone) made by Sertoli cells. LIMB DEVELOPMENT The limbs arise from somatic mesoderm (somatopleure = somatic mesoderm + overlying epidermis) that lies lateral to the intermediate mesoderm. The early limb bud is consisted of undifferentiated mesenchyme covered by epidermis, that is thickened to form the apical ectodermal ridge (AER) at the distal edge. The mesenchyme forms cartilage, tendons, ligaments, dermis and the sheats surrounding the muscles, the somites form the muscles themselves. Somatopleure^ Epidermis Somatic mesoderm Der ma myotome Stage is Coelom Epidermis Mesenchyme -AER Stage 23 Srde view Stage 37 Dorsal view Stage 30 Dorsal view PROXIMAL-DISTAL OUTGROWTH AND PATTERNING: The earliest visible event is in limb-bud development is AER formation in the epidermis. The AER expresses transcription factors Msxl and Msx2, which is activated by BMP (Bone Morphogenetic Protein) signaling. BMP signaling is critical for AER formation. The AER releases various factors to regulate the limb bud growth. These include fgfs (fibroblast growth factors), Shh, and BMP. Stage of AER removal 18 19 20 21 25 ANTEROPOSTERIOR PATTERNING: This pattern is controlled by zone of polarizing activity (ZPA) located at the posterior margin of the bud. ZPA is a source of the diffusible morphogen (Shh), that forms a gradient over the surrounding tissues. Shh regulates this stage of limb development through stabilizing Gli transcription factor. Double posterior duplication LIMB PATTERNING OVERALL: Pattern in all three axes is controled by a separate process. Proximal-distal patterning relies on FGF supply from AER. The anteroposterior pattern is controled by Shh gradient from ZPA. The dorsoventral pattern is controlled by Wnt7 from the dorsal epidermis. The three processes work together to shape the organ, as evidenced by the fact that AER needs both Shh and Wnt7 for its survival and function. Progress zone ^AER ■ > HEART DEVELOPMENT Cardiogenic mesoderm originates from epiblast lateral to the node in chick, later forming two elongated strips on either side of the embryonic axis. The early heart commitment of this region requires transcription factors Nkx2.5, GATA4-6, MEF2 and Tbx5. Heart represents the anteroventral sector of the embryo body that is further specified by inhibition of Wnt and Nodal signaling by the action of factors as Cerberus and Dickkopf, while ventral character is specified by BMP signaling. Primitive streak Prospective heart region Amnion Somites Node Stage 4 Stage S As the heads lifts off the blastoderm surface, the heart rudiments move underneath it towards the midline. This migration depends on FGF8 and fibronectin. A failure of this migration leads to cardia bifida, where two separate hearts form side by side. Normally, both rudiments fuse to form a tube that has 4 layers: endocardium, cardiac jelly, myocardium and pericardium. Shortly after the fusion of two rudiments the heart tube starts pulsation. Ectoderm Somatic mesoderm Splanchnic m e s o de- r m Endoderm Stage S Neural tu be Angioblasts Neural tube Foregut rwl yocardiu rrr Endocardiu rr> (b) Stage 1 O Brain F o reg u t Myocardiu m Endocard íti m O i rrQ Meural tube Outflow tract Right atrium Right ventricle The forming of heart in mammals involves conversion of a simple tube into the four-chambered heart with separate righ- and left-sided circulation. This involves looping, | asymmetrical growth, movement of' blood vessel insertion sites and formation of internal septa to divide the lumen. 1. Looping brings the atria to the anterior and ventricles to the posterior. 2. The venous returns run into the right side of the atrium and new pulmonary vein sprouts from the left side of the atrium. 3. Atrial septa and endocardial cushions form. 4. The cushions meet to form the septum intermedium dividing ventricle into left and right sides. TheT,u,lioconalieptae other cushions later contribute to the atrioventricular valves. 5. Muscular ventricular septum growths from ventricular wall to separate the right and left sides. Future right ventricfe (a) --------Outflow tract *** - Primitive atrium Future left ventricle 26 day« Sinus venosus (h) 33 days Sul biventricular flange Leh air i urn Superior . endocardial cushion AV Canal Inferior " endocardial cuihion Left ventricle Right atrium Superior endocardial cushion Right ventricle Outflow trait Right atrium Right ventricle — Right AVönal 42 days Future pulmonary trunk Left 3i.n1.n1 Lett — AV canal Septum intermedium Left ventricle Muscular ventricular septum Left ventricle Future aorta BLOOD VESSEL DEVELOPMENT Vasculogenesis = de novo formation of blood vessels in embryo. Angiogenesis = formation of new capilaries from the existing ones by cell division and migration. Vasculogenesis is associated with the formation of blood since both vein endothelium and blood have the same precursor - hemangioblast - located in the lateral plate mesoderm. The hemangioblast population is characterized by expression of SCL (stem cell leukemia transcription factor), flkl (receptor for VEGF, vascular endothelial growth factor), FGFRl (receptor for FGF) and GATA-1 and -2 transcription factors. VEGF represents the most potent angiogenic factor, vegf- mice have no blood vessels. Mesoderm Earty vessels Hematopoietic stem cells Angiogenesis Growth of capillaries Hematopoiesis &~ Blood and other cell types