Embryonic development

During the third week after fertilization, the human embryo undergoes gastrulation, a complex process of involution and cell redistribution that generates the three primary embryonic germ layers: endoderm, mesoderm, and ectoderm. Shortly after gastrulation, the ectoderm is further subdivided into neuroectoderm, a medial strip parallel to the long axis of the developing embryo, and presumptive epidermis on either side of this strip. Neurulation results in infolding of the embryonic ectoderm to become the neural tube and subsequent brain and spinal cord ( Fig. 1.2 ). The extraembryonic ectoderm (lateral to the epidermis) becomes the amnion lining the amniotic sac. The early presumptive epidermis is a loosely associated single cell layer. By 6 weeks’ EGA (8 weeks’ LMP), the surface ectoderm covering most regions of the body already consists of basal cells and more superficial periderm cells ( Fig. 1.3 ). The periderm layer is a transient embryonic layer that does not participate in the production of definitive epidermal progenitors. The presumptive epidermis at these early stages is not considered a true stratified epithelium.

The process of neurulation and the formation of the neural crest.

During the 3rd to 4th week of gestation, following gastrulation, formation of the neural tube segregates specific populations of ectodermal cells destined to form the brain and spinal cord (neural tube), epidermis (embryonic surface ectoderm), and amnion (extraembryonic ectoderm). The neural crest consists of a migratory cell population, which forms melanocytes, Schwann cells, adrenal medulla, facial cartilage, etc. These complex embryological invaginations and evaginations convert the previous spheroid into a topologically more complex toroidal form.

Epidermal morphogenesis.

(A) At 36 days the epidermis consists only of a basal layer and a superficial periderm layer. (B) By 72 days a well-formed intermediate layer is present between the basal and periderm layers. By the end of the second trimester, there are several intermediate cell layers and the stratified epidermis begins to keratinize. (C) In neonatal skin, a distinct granular layer and stratum corneum are present. Hair follicles first begin to bud down in the dermis between 75 and 80 days. (D) An early bulbous hair peg-stage follicle from a mid-second trimester fetus.

(Photomicrographs courtesy Dr Karen Holbrook.)

The basal cells of the embryonic epidermis display morphologic and biochemical features similar – but not identical – to basal cells of later developmental stages. Embryonic basal cells are slightly more columnar than later fetal basal cells and lack morphologically distinct hemidesmosomes. Matrix adhesion molecules critical for histogenesis and signal transduction, such as E- and P-cadherins and integrins β-1 and β-4, exhibit spatially and temporally coordinated expression in the developing epidermis. The keratin pair K8/K18, typically found in simple epithelial cells, is the first pair expressed in embryogenesis and may represent the oldest phylogenetic keratins. Keratins involved in higher order tonofilament formation such as K5/K14 can also be identified.

Periderm cells of the embryonic epidermis are larger and flatter than the underlying basal cells. As such, periderm cells have been termed a ‘pavement epithelium’. Apical surfaces in contact with the amniotic fluid are studded with microvilli. Their lateral surfaces in contact with adjacent peridermal cells are sealed with tight junctions, possibly precluding passive – but not active – diffusion of fluids across this outer layer of the embryo. Periderm cells, like the embryonic basal cells, express the stratified epithelial keratins K5 and K14, but also express simple epithelial keratins K8, K18, and K19. Towards the end of the second trimester these superficial cells are eventually sloughed.

Early fetal development

By the end of 8 weeks’ gestation (10 weeks’ LMP), the basic components of most organ systems have been laid down and hematopoietic production has shifted to the bone marrow. This marks the classic division between embryonic and fetal development, and it corresponds to initial epidermal stratification and the formation of the third ‘intermediate’ layer between the two pre-existing cell layers ( Fig. 1.3 ). Cells in the intermediate layer of the early fetal epidermis express the K1/10 skin differentiation-type keratin markers, as well as the desmosomal protein desmoglein 3, which is also known as the pemphigus vulgaris antigen. Moreover, intermediate filaments and desmosomal junctions are more abundant in this layer than in the basal or periderm layers. In contrast to the spinous cells of the mature nonwounded epidermis, cells within the intermediate layer remain highly proliferative. Over the next several weeks, more layers are gradually added to this intermediate zone of the developing epidermis, such that by 22–24 weeks’ EGA, the epidermis contains four to five layers in addition to terminal differentiation of the periderm with formation of a cross-linked cornified envelope ( Fig. 1.4 ).

Formation of the cornified cell envelope (CCE) in human periderm.

Following epidermal stratification between 96–160 days EGA, the outermost periderm undergoes terminal differentiation with formation of the CCE. Covalent cross-linking mediated by transglutaminase results in a high molecular weight polymeric structure composed of loricrin, small proline-rich proteins (SPRPs), involucrin, cystatin α, and other proteins. The outermost lipid coating is also covalently cross-linked yielding an insoluble periderm cell which is sloughed to the amniotic fluid. A similar process of CCE formation occurs later in gestation in the formation of vernix corneocytes and the interfollicular stratum corneum.

(Adapted from Akiyama M, Smith LT, Yoneda K, Holbrook KA, Hohl D, Shimizu H. Periderm cells form cornified cell envelope in their regression process during human epidermal development. Journal of Investigative Dermatology 1999; 112(6):903–909.)

After the onset of stratification, the basal layer also displays characteristic morphologic and biochemical changes. Basal cells become more cuboidal and begin to synthesize other keratin peptides, including K6, K8, K19, and the K6/K16 hyperproliferative pair. This latter keratin pair is not normally expressed in mature interfollicular epidermis but is upregulated in response to wounding and hyperproliferative conditions. During early fetal development, the basal cell layer also begins to express the hemidesmosomal proteins BPA1 and BPA2, and to secrete collagen types V and VII, the latter being the major component of the anchoring fibrils of the dermis. DNA-labeling studies indicate that by 80–90 days’ EGA, a distinct subset of slow-cycling cells exists within the basal cell population, suggesting that an epidermal stem cell population has already been set aside at these early stages.

Late fetal development

Maturation of the epidermis during late fetal development is characterized by the generation of granular and stratum corneum (SC) layers, the formation of a water-impermeable barrier, and the sloughing of the periderm. Keratinization, the terminal differentiation seen in the stratum granulosum (SG) and SC, is initiated first in the skin appendages between 11 and 15 weeks’ EGA, and extends to the interfollicular epidermis from about 22–24 weeks’ EGA. During the third trimester, the cornified cell layers increase in number, aiding in the formation of a barrier.

The prenatal epidermal water permeability barrier was previously thought to be derived almost entirely from lipid secreted from cells of the outer SG and processed to highly hydrophobic species in the SC interstices, controlled not only by the intrinsic program of epidermal barrier development but also by prenatal exposure to fetal or maternal hormones, nutrient gradients, or by air exposure at birth. In postnatal humans and rodents, this epidermal permeability barrier is formed by polar lipids secreted from the SG that are then processed into impermeant lamellar bilayers. In contrast, since prior freeze-fracture electron microscopy studies showed only discontinuous tight junction (TJ) strands in adult mouse epidermis, it was widely thought that in contrast to amphibian skin or other ‘tight’ mammalian epithelium (such as kidney), TJ played only a minor role in the epidermal water permeability barrier.

Although congenital human skin diseases caused by mutations in TJ are rare, common diseases such as atopic dermatitis have been linked with acquired TJ dysfunction. Further, studies show that claudin-1 deficient mice suffer barrier defects leading to death soon after birth. Involucrin-Cldn6 (Inv-Cldn6) transgenic mice also display skin barrier defects, the severity of which is dependent upon the level of Cldn6 over-expression. These results suggest that TJ also plays an important role in forming the epidermal permeability barrier during the prenatal period, or in regulating the subsequent development of the lipid barrier.

Clinical relevance

Gross defects in early epidermal specification and organogenesis are rarely observed in the neonate, probably because they are incompatible with fetal survival. Using mice as an animal model system, researchers demonstrated that obliteration of the p63 gene precludes the formation of most multilayered epithelia in the body, leading to perinatal lethality due to loss of skin barrier function. Humans who carry mutations in this gene still retain some functionality and therefore display less severe alterations in their epidermis and appendages (see below).

In contrast, congenital defects in epidermal maturation are not uncommon, as they do not usually impinge on in utero survival. Lamellar ichthyosis (see Chapter 19 ) is usually inherited in an autosomal recessive manner and in 30% of patients is caused by mutations in the gene encoding epidermal transglutaminase, the enzyme that cross-links submembranous proteins to form the insoluble cornified envelope of the SC. In its absence, large, dark polygonal scales form over the entire body, and at birth, the infant may be transiently wrapped in a waxy, collodion-like membrane. A similar clinical presentation can be seen in patients homozygous for mutations in the ABCA12 gene, which encodes an ATP-binding cassette thought to be important for lipid trafficking across keratinocyte membranes. Infants with the more severe ‘harlequin ichthyosis’ (see Chapter 19 ) are born encased in armor-like, thickened, adherent SC which cracks upon exposure to air. This extreme variant also appears to be due to mutations in the ABCA12 gene.

In contrast to the permanent manifestations of genetic defects, the inadequate epidermal keratinization and maturation of the premature epidermis are transient. Immaturity of the SC, especially in infants born before 28 weeks’ EGA (30 weeks’ LMP), places these neonates at increased risk for dehydration, excessive penetration of topical drugs or other chemicals, and infection from organisms newly colonizing the skin (see Chapters 4 and 5 ). In general, even full-term newborns display a somewhat reduced barrier function, and continued maturation occurs over the first few weeks of life, such that by 3 weeks of age, the newborn’s SC is structurally and functionally equivalent to that of the adult; maturation is accelerated in the premature infant, although the duration may be longer in extremely premature infants.

Specialized cells within the epidermis

Two major immigrant cells – melanocytes and Langerhans’ cells – populate the epidermis during early embryonic development. Melanocytes are derived from a subset of neuroectoderm cells, the neural crest, which forms along the dorsal neural tube and gives rise to a variety of cell types, including many tissues of the face and peripheral autonomic neurons. Neural crest cells destined to become melanocytes migrate away from the neural tube within the mesenchyme subjacent to the presumptive epidermis. They migrate as semicoherent clones laterally and then ventrally around the trunk to the thoraco-abdominal midline, anteriorly over the scalp and face, and distally along the extremities. Postnatally, the embryonic paths taken by these partially coherent clones can be readily visualized in patients with banded pigmentary dyscrasias following Blaschko’s lines, such as the disorders classified as hypomelanosis of Ito, and linear and whorled hypermelanosis (see Chapters 23 and 24 ).

Melanocytes are first detected within the epidermis of the human embryo at approximately 50 days’ EGA, recognized by their dendritic morphology and their specific immunoreactivity. Even at these early developmental timepoints, the density of melanocytes is quite high (1000 cells/mm ² ). The density increases further around the time of epidermal stratification (80–90 days’ EGA) and initiation of appendageal development. Between 3 and 4 months EGA, depending on body site and the race of the fetus, melanin (visible pigment) production becomes detectable, and by 5 months, melanocytes begin transferring melanosomes to the keratinocytes, a process that will continue after birth. Although all melanocytes are in place at birth and melanogenesis is well under way, the skin of the newborn infant is not fully pigmented and will continue to darken over the first several months. This is most apparent in individuals with darker skin.

Langerhans’ cells, the other major immigrant population, are detectable within the epidermis by 40 days’ EGA. Similar to melanocytes, the early embryonic Langerhans’ cells do not yet possess the specialized organelles characteristic of mature cells, but can be distinguished from other epidermal cells by their dendritic morphology, immunopositive reaction for the HLA-DR surface antigen, and high levels of ATPase activity. After the transition from embryo to fetus, they begin to express the CD1 antigen on their surface and to produce characteristic granules of mature Langerhans’ cells. Although the extent of dendritic processes from individual Langerhans’ cells increases during the second trimester, the total number of cells remains low and only increases to typical adult numbers in the third trimester.

Another distinct subset of cells within the basal cell layer are Merkel cells, which are highly innervated neuroendocrine cells involved in mechanoreception. Merkel cells can be round or dendritic, and are found at particularly high densities in volar skin. They are frequently associated with epidermal appendageal structures and are occasionally detected within the dermis. Their distinguishing morphologic and immunohistochemical features are cytoplasmic dense-core granules, keratin 18, and neuropeptide expression, which can be detected as early as 8–12 weeks’ EGA in palmoplantar epidermis and at slightly later times in interfollicular skin. Recent keratin expression data, as well as transplant studies, suggest that Merkel cells are derived from pluripotent keratinocytes, rather than neural progenitors such as neural crest, but the results are not conclusive.

Clinical relevance

Many clinical defects are known to affect normal pigmentation. Defects in melanoblast migration, proliferation, and/or survival occur in several clinical syndromes, and many of the genetic mutations responsible for these defects have been identified (see Chapter 23 ). Failure of an adequate number of melanoblasts to completely supply distal points on their embryonic migration path occurs in the different types of Waardenburg syndrome, as well as in piebaldism, resulting in depigmented patches on the central forehead, central abdomen, and extremities. These defects are associated with mutations in several different genes, including genes encoding transcription factors, such as Pax3 and MITF, as well as membrane receptors and their ligands, such as endothelin 3, endothelin-receptor B, and c- kit . In albinism, however, melanocyte development is normal, but production of pigment or melanin is inadequate. The most severe form of oculocutaneous albinism results from null mutations in the gene encoding tyrosinase, the rate-limiting enzyme in the production of melanin. Less severe forms of albinism are caused by mutations in tyrosinase alleles, which lead to partial loss of function, as well as by mutations in other genes encoding proteins important in melanin assembly in melanosomes or transport.

Nerves and vasculature

Development of the cutaneous innervation closely parallels that of the vascular system in terms of its pattern, rate of maturation, and organization. Nerves of the skin consist of somatic sensory and sympathetic autonomic fibers, which are predominantly small and unmyelinated. Localized somatosensory reflexes can first be elicited using von Frey hairs in the perioral area of the 7.5-week fetus, at which time free nerve endings can be visualized beneath the epithelium. The growing sensory nerve endings, therefore, are presumably sensitive to mechanical stimuli transmitted through the fetal skin. Cauna and Mannan have suggested that the developing nerve plexus as a whole functions as a receptor in early development to be superseded by more definitive end organs later in gestation.

Various specialized nerve endings have been well-documented in embryonic and fetal skin ( Fig. 1.5 ). Work by Paus, Slominski, and others has highlighted novel neuroimmunoendocrine functions of postnatal skin. The stress hormone cortisol, for example, can be manufactured de novo by the human hair follicle and is present on preterm SC. These exciting new developments place a premium on better understanding the skin–brain connection during normal development, as well as in conditions such as the neurocristopathies, neurofibromatosis, incontinentia pigmenti, tuberous sclerosis and other diseases highlighted in later chapters. The importance of early fetal somatic (i.e., muscle) innervation to normal skin morphogenesis is the recent demonstration that lack of the fetus-specific component of the acetylcholine receptor produces the extensive dermal webbing seen in multiple pterygium syndrome.

Variety of cutaneous nerve endings in the human fetus.

Free nerve endings are present in oro-facial skin as early as 8–9 weeks’ gestation. Specialized nerve endings such as Pacinian corpuscles, Merkel’s disks, etc., which are known to modulate different cutaneous stimuli in adults are also present in the fetus. Other than touch and reflex withdrawal, however, the functional correlates of fetal cutaneous receptors are obscure and difficult to investigate.

The development of the cutaneous vascular system is dynamic and dependent on gestational age, body site, and function, among other factors. Vessels of the endoderm–mesoderm interface form through the in-situ differentiation of endothelial cells (vasculogenesis). Originally, they form horizontal plexuses within the subpapillary and deep reticular dermis, which are interconnected by groups of vertical vessels. This vascular framework has been elegantly reconstructed by the use of computer graphics to illustrate the complexity that already exists by 45–50 days’ EGA. Such structure does not remain constant even throughout fetal life, but varies depending on the body region and gestational age, as well as on the presence of hair follicles and glands that may require an increased blood supply. Furthermore, vascular emergence and development correlate directly with the particular tissue, determined specifically by the influences of pressure and function.

Regional variation also depends on gestational age. Blood vessels have been identified in fetal skin as early as 9 weeks’ EGA. At this stage, they help delineate the dermal–hypodermal junction. By 3 months, the distinct horizontal and vertical networks have formed. And by 5 months, vasculogenesis has largely ceased and the formation of the complex vascular plexus is initiated by angiogenesis, the budding and migration of endothelium from pre-existing vessels. With increasing gestational age, the superficial architecture becomes more organized, culminating at birth in an extensive capillary network responsible for the skin redness often observed in the newborn. Within the first few postnatal months the complexity decreases as skin surface area increases, lanugo hairs are lost, and sebaceous gland activity decreases. It is during this time that the rate of skin growth is greatest. By approximately 3 months of age, the vascular patterns more closely resemble those of the adult.

Not only do the number and caliber of the blood vessels change over time, so too does the direction of blood flow. Considering the dynamic nature of this circulatory system, it is not surprising that, of the malformations and tumors seen in newborns, vascular anomalies are the most common.

Errors in neurovascular morphogenesis likely lead to several relatively common syndromes such as Klippel–Trenaunay, Sturge–Weber and PHACE syndromes. See Chapters 21 and 22 for further discussion of these topics.

Overview

The fully developed dermis is characterized by complex interwoven collagen and elastic fibers enmeshed in a proteoglycan matrix. Fibroblasts, mast cells, and macrophages are scattered throughout the dermis, and nerve fibers and vascular networks course through it, dividing it into distinct domains. In contrast, the embryonic dermis is quite cellular and amorphous, lacking organized extracellular fibers. Embryonic mesenchymal cells capable of differentiating into a wide variety of cell types are embedded in a highly hydrated gel, rich in hyaluronic acid. Moreover, only a few nerve fibers have reached this peripheral location, and vessels have not evolved into their mature patterns. During the course of fetal development, this so-called cellular dermis, which is conducive to cell migration and tissue remodeling, is transformed into the fibrillar dermis of the adult, which provides increased strength, resilience, and structural support.

Embryonic dermal development

The specification and allocation of dermal mesenchymal cells are rather complex and not well understood. The cell of origin for the presumptive dermis depends on its anatomic location. The dermis of the face is derived from neural crest cells; that of the dorsal trunk is derived from the dermatomyotome portion of the differentiated somite; and the dermis of the limbs is derived from the lateral plate (somatic) mesoderm. Regional patterning of the skin and differences in the type and quality of the epidermal appendages produced in the older fetus might in part reflect these early differences in dermal cell precursors. In addition, signaling from adjacent tissues plays a critical role.

By 6–8 weeks’ EGA, the presumptive dermal cells already underlie the epidermis. However, there is, as yet, no sharp demarcation between cells giving rise to skin dermis and those giving rise to musculoskeletal elements. Electron microscopic (EM) studies of the presumptive dermis at these stages demonstrate fine filaments, but rarely fibers. Although most protein components of collagen fibers and some microfibrillar components of elastin fibers (fibrillin) are synthesized by the embryonic dermal cells, the proteins are not yet assembled into large, rigid fibers. Moreover, the ratio of collagen III to collagen I is 3 : 1, the reverse of that in the adult.

Fetal dermal development

After embryonic–fetal transition at 60 days, the presumptive dermis is distinguishable from the underlying skeletal condensations. Moreover, within the dermis, there is a progressive change in matrix organization and cell morphology, such that by 12–15 weeks, the fine interwoven mesh of the papillary dermis adjacent to the epidermis can be distinguished from the deeper, more fibrillar reticular dermis. Large collagen fibers accumulate in the reticular dermis during the second and third trimesters. Definitive elastin fibers first become detectable by EM studies around 22–24 weeks’ EGA, although both the microfibrillar protein fibrillin and the microfibrillar structures, which are morphologically similar to elastin-associated microfibrils of the adult, can be detected at earlier stages. By the end of gestation, the dermis is thick and well organized, but is still much thinner than in the adult and has a higher water content, reminiscent of the fetal dermis. Dermal maturation is marked by increasing tensile strength and the transition from a nonscarring to a scarring response after wounding. Thus, fetal skin biopsies tend to heal with little evidence of the surgical event. This has obvious clinical implications, and the molecular controls critical for nonscarring fetal wound healing are an area of active research ( Table 1.3 ).

Clinical relevance

Congenital defects in the specification and development of the dermis are probably incompatible with survival to term, although there are a few exceptions. Infants with restrictive dermopathy disorder, which is characterized by a thin, flat dermis, lack of elastic tissue fibers, and shortened appendageal structures, do survive to birth but then die in the neonatal period, partly because of insufficient elaboration of the dermis. This disorder is caused by mutations in either the LaminA gene or the gene encoding the LaminA processing enzyme. Another syndrome characterized by inadequate dermal development is Goltz syndrome (focal dermal hypoplasia). This is an X-linked dominant condition caused by mutations in the PORCN gene, in which most males who inherit the mutation on their single X chromosome die in utero. In contrast, females are functional mosaics as a result of random X-inactivation early in embryogenesis, and those with Goltz syndrome display areas of dermal hypoplasia where the mutant X is active. These bands of dermal hypoplasia follow Blaschko’s lines and alternate with bands of normal dermal development where the normal X is active.

Development of the hypodermis and adipose tissue

The hypodermis can be delineated by 50–60 days’ EGA. It is a distinct region that is separated from the overlying cellular dermis by a plane of thin-walled vessels. Toward the end of the first trimester, the sparse matrix of the hypodermis can be distinguished morphologically from the slightly denser, more fibrous matrix of the dermis. In the second trimester, mesenchymally derived preadipocytes begin to differentiate and accumulate lipids and by the third trimester, the more mature adipocytes are aggregated into large lobules of fat divided by fibrous septa. In addition to a passive fuel reserve for the body, recent evidence supports an active endocrine role for adipose tissue with effects on vascular and immune function. An example is the gene that encodes leptin, whose abnormal regulation has been implicated in the pathogenesis of obesity.

Dermoepidermal junction

The dermoepidermal junction (DEJ) is the region where the epidermis and dermis abut. In the broadest definition, it includes the specialized extracellular matrix on which the basal keratinocytes sit, known as the basement membrane, as well as the basal-most portion of the basal cells and the superficial-most portion of the dermis. Importantly, both dermal and epidermal compartments contribute to the molecular synthesis, assembly, and integration of this region.

A simple basement membrane, separating the dermis and epidermis, can be discerned as early as 8 weeks’ EGA. The basic protein constituents common to all basement membranes can already be detected immunohistochemically at this stage. These include collagen IV, laminin, and heparin sulfate and proteoglycans.

Specialized components of the DEJ do not appear until after the embryonic–fetal transition, around the time of initial epidermal stratification. With a few exceptions, all basement membrane antigens are in place by the end of the first trimester. As discussed, the α6 and β4 integrin subunits are expressed quite early by embryonic basal cells. However, they do not become localized to the basal surface until after 9.5 weeks, which is coincident with the time when bullous pemphigoid antigens are first detected immunohistochemically and hemidesmosomes are recognized ultrastructurally. Similarly, anchoring filaments and anchoring fibrils, the basement membrane components that mediate basal cell attachment to extracellular matrix, are recognizable by 9 weeks’ EGA. Collagen VII, the anchoring fibril protein, is detected slightly earlier, at 8 weeks. Recent experimental data have delineated many of the molecular interactions crucial for connecting the cytoskeletal networks of the basal cells with the extracellular filamentous networks important in matrix adhesion ( Fig. 1.6 ) (see Chapters 10 and 11 ).

Schematic of the dermoepidermal junction indicating the proteins that are defective in the relevant hereditary bullous diseases (X).

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