The skin and its major appendages are prominent target organs and potent sources of key players along the classical hypothalamic-pituitary axis, such as corticotropin releasing hormone (CRH), adrenocorticotropic hormone (ACTH), and alpha melanocyte stimulating hormone (alpha-MSH), and even express key steroidogenic enzymes. Therefore, it may have established local stress response systems that resemble the hypothalamic-pituitary-adrenal (HPA) axis. However, functional evidence that this is indeed the case in normal human skin in situ has still been missing. We show that microdissected, organ-cultured human scalp hair follicles respond to CRH stimulation by up-regulating proopiomelanocortin (POMC) transcription and immunoreactivity (IR) for ACTH and alpha-MSH, which must have been processed from POMC. CRH, alpha-MSH, and ACTH also modulate expression of their cognate receptors (CRH-R1, MC1-R, MC2-R). In addition, the strongest stimulus for adrenal cortisol production, ACTH, also up-regulates cortisol-IR in the hair follicles. Isolated human hair follicles secrete substantial levels of cortisol into the culture medium, and this activity is further up-regulated by CRH. CRH also modulates important functional hair growth parameters in vitro (hair shaft elongation, catagen induction, hair keratinocyte proliferation, melanin production). Finally, human hair follicles display HPA axis-like regulatory feedback systems, since the glucocorticoid receptor agonist hydrocortisone down-regulates follicular CRH expression. Thus, even in the absence of endocrine, neural, or vascular systemic connections, normal human scalp hair follicles directly respond to CRH stimulation in a strikingly similar manner to what is seen in the classical HPA axis, including synthesis and secretion of cortisol and activation of prototypic neuroendocrine feedback loops.
The collapse of major histocompatiblity complex (MHC) class-I-dependent immune privilege can lead to autoimmune disease or fetal rejection. Pragmatic and instructive models are needed to clarify the as yet obscure controls of MHC class I down-regulation in situ, to dissect the principles of immune privilege generation, maintenance, and collapse as well as to develop more effective strategies for immune privilege restoration. Here, we propose that human scalp hair follicles, which are abundantly available and easily studied, are ideally suited for this purpose: interferon-␥ induces ectopic MHC class I expression in the constitutively MHC class-I-negative hair matrix epithelium of organ-cultured anagen hair bulbs, likely via interferon regulatory factor-1, along with up-regulation of the MHC class I pathway molecules  2 microglobulin and transporter associated with antigen processing (TAP-2). In the first report to identify natural immunomodulators capable of down-regulating MHC class I expression in situ in a normal, neuroectoderm-derived human tissue, we show that ectopic MHC class I expression in human anagen hair bulbs can be normalized by treatment with ␣-MSH, IGF-1, or TGF-1, all of which are locally generated, as well as by FK506. These agents are promising candidates for immune privilege restoration and for suppressing MHC class I expression where this is clinically desired (eg, in alopecia areata, multiple sclerosis, autoimmune uveitis, mumps orchitis, and fetal or allograft rejection). A select number of mammalian tissue sites, namely the brain, cornea, anterior chamber of the eye, testis, liver, fetotrophoblast, and the hamster cheek pouch, display a fascinating phenomenon called "immune privilege." [1][2][3][4][5] This name reflects that these tissue environments can award allotransplants relative protection from rejection by the host immune system.
Hair follicles (HFs) enjoy a relative immune privilege (IP) that is characterized by downregulation of major histocompatibility complex (MHC) class I and local expression of potent immunosuppressants. Normally, natural killer (NK) cells attack cells with absent/low MHC class I expression. However, because few perifollicular NK cells are found around healthy human anagen HFs, we asked how HFs escape from NK cell attack. This study suggests that this happens via an active NK cell suppression. Alopecia areata (AA), an organ-specific autoimmune disease thought to result from a collapse of HF-IP, in contrast, shows striking defects in NK cell inhibition/containment. We show that the NK cell inhibitor macrophage migration inhibitory factor is strongly expressed by the HF epithelium, and very few CD56(+)/NKG2D(+) NK cells are observed in and around normal anagen HFs compared to AA with prominent aggregations of CD56(+)/NKG2D(+) NK around AA-HFs. By flow cytometry, many fewer NK function-activating receptors (NKG2D, NKG2C) and significantly more killer cell Ig-like receptors-2D2/2D3 were found to be expressed on peripheral blood CD56(+) NK cells of healthy controls than on those of AA patients. In addition, only weak immunoreactivity for MHC class I chain-related A gene was observed in normal anagen HFs compared to AA. To our knowledge, this defect is previously unreported and must be taken into account in AA pathogenesis and its management.
This essay reviews the available evidence that the proximal hair follicle epithelium generates and maintains an area of relative immune privilege during a defined segment of the hair cycle (i.e., during anagen). This immune privilege is chiefly characterized by a very low level of expression of MHC class Ia antigens and by the local production of potent immunosuppressive agents, such as alpha-MSH and TGF-beta1. We discuss the putative functions of immune privilige of the anagen hair bulb, favoring the view that immune privilege serves mainly to sequester anagen- and/or melanogenesis-associated autoantigens from immune recognition by autoreactive CD8+ T cells. On this basis, we develop how the "immune privilege collapse model" of alopecia areata pathogenesis was conceived. In our discussion of the clinical implications of immune privilege, we outline the currently available evidence in support of this still hypothetical scenario to explain the initiation, progression, and termination of alopecia areata lesions. We review the most recent evidence from our laboratory that alpha-MSH, IGF-1, and TGF-beta1 can downregulate IFN-gamma-induced ectopic MHC class I expression in human anagen hair bulbs in vitro. Finally, we suggest that hair follicle-derived alpha-MSH, IGF-gamma, and TGF-beta1 form part of a constitutively active "IP restoration machinery" of the anagen hair bulb, which we propose to be recruited whenever the hair follicle suffers immune injury. Finally, we sketch some particularly promising avenues for future investigation into the far too long ignored hair follicle immune privilege.
"Nagashima-type" palmoplantar keratosis (NPPK) is an autosomal recessive nonsyndromic diffuse palmoplantar keratosis characterized by well-demarcated diffuse hyperkeratosis with redness, expanding on to the dorsal surfaces of the palms and feet and the Achilles tendon area. Hyperkeratosis in NPPK is mild and nonprogressive, differentiating NPPK clinically from Mal de Meleda. We performed whole-exome and/or Sanger sequencing analyses of 13 unrelated NPPK individuals and identified biallelic putative loss-of-function mutations in SERPINB7, which encodes a cytoplasmic member of the serine protease inhibitor superfamily. We identified a major causative mutation of c.796C>T (p.Arg266(∗)) as a founder mutation in Japanese and Chinese populations. SERPINB7 was specifically present in the cytoplasm of the stratum granulosum and the stratum corneum (SC) of the epidermis. All of the identified mutants are predicted to cause premature termination upstream of the reactive site, which inhibits the proteases, suggesting a complete loss of the protease inhibitory activity of SERPINB7 in NPPK skin. On exposure of NPPK lesional skin to water, we observed a whitish spongy change in the SC, suggesting enhanced water permeation into the SC due to overactivation of proteases and a resultant loss of integrity of the SC structure. These findings provide an important framework for developing pathogenesis-based therapies for NPPK.
The peripheral nervous system comprises the autonomic and sensory (afferent) nervous systems. Major advances in our understanding of the autonomic and sensory transmission and function include the recognition of the phenotypic expression of a variety of transmitters and modulators that often coexist in individual neurons, the concept of co-transmission and chemical coding, the evidence for local effector functions of primary afferent nerves, and the discovery of plasticity of both the autonomic and the sensory nervous system during development, aging, diseases states, and inflammation. Co-transmission or plurichemical transmission, which indicates the release of more than one chemical messenger from the same neuron, enables autonomic and sensory neurons to exert a fine and highly regulated control of various functions such as circulation and immune response. The concept of chemical coding, in which the combination of transmitters/modulators is established, allows the identification of functional classes of neurons with their projections and targets. In addition to transmitters and modulators, autonomic and sensory neurons express multiple receptors, including G-proteincoupled and ion-gated receptors, further supporting the complexity of autonomic and sensory transmission and function. Autonomic neurons regulate the internal environment and maintain multiple homeostatic functions, and sensory neurons act as receptive structures that activate their targets in response to stimulation but also exert effector functions including the control of blood flow and vascular permeability, maintenance of mineralized tissue, and regulation of gene expression. Neurophysiology of painThe nociceptive system supports two sensory functions, pain and itch. Itch has often been regarded as a minor form of pain. Recently, it has been shown, however, that the pruritic system is supported by its own peripheral and central neuronal pathways which are closely associated, although antagonistic in some POMC processing in human melanocytes has been widely documented, and the a-MSH/MC1R/cAMP cascade has been implicated in the control of pigmentation. Only very recently, a role of b-endorphin, one cleavage product of b-LPH, has been demonstrated to influence melanocyte growth, dendricity and melanin biosynthesis via the m-opiate receptor. However, much earlier, it was shown that b-MSH, the other cleavage product of b-LPH, controls melanogenesis and melanin transfer in amphibians. To date, a specific receptor for b-MSH has not been identified. Earlier POMC processing has been found in melanosomes. Therefore, an MC1R-independent role of a-MSH was postulated and demonstrated in control of 6-tetrahydrobiopterin (6BH 4 )inhibited tyrosinase. Utilizing the depigmentation disorder vitiligo, we were now able to follow the fate of epidermal POMC processing in the presence of mM levels of hydrogen peroxide (H 2 O 2 ). In vitiligo epidermal PC2 and 7B2 protein expression is increased, whereas a-MSH, b-MSH and b-endorphin are significantly decreased. Analys...
The nail apparatus is constantly exposed to environmental damage. It requires effective immune responses to combat infection, while avoiding the loss of nail production and regeneration by autoaggressive immunity. By immunohistology, we define here previously unknown characteristics of the normal human nail immune system (NIS). Compared with other regions of nail epithelium, human leukocyte antigen (HLA)-A/B/C expression is prominently down regulated on both keratinocytes and melanocytes of the proximal nail matrix (PNM), whereas HLA-G(+) is upregulated here. Together with the expression of macrophage migration inhibitory factor in PNM, this may serve to inhibit an natural killer (NK) cell attack on major histocompatibility complex (MHC) class Ia-negative PNM. PNM also displays strong immunoreactivity for potent, locally generated immunosuppressants such as transforming growth factor-beta1, alpha-melanocyte stimulating hormone, insulin-like growth factor-1, and adrenocorticotropic hormone, exhibits unusually few CD1a(+), CD4(+), or CD8(+), NK, and mast cells. Finally, MHC class II and CD 209 expression on CD1a(+) cells in and around the PNM is reduced, indicating diminished antigen-presenting capacity. Thus, the NIS strikingly differs from the skin immune system, but shows intriguing similarities to the hair follicle immune system, including the establishment of an area of relative immune privilege in the PNM. This nail immune privilege may offer a relative safeguard against autoimmunity. But, the localized intraepithelial defect of innate and adaptive immunity in the PNM revealed here also may impede effective anti-infection defense.
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