Matrix Metalloproteinase-9 Is Involved in the Regulation of Hair Canal Formation.

Sharov, A.A., Schroeder, M., Sharova, T.Y., Mardaryev, Andrei N., Peters, E.M.J., Tobin, Desmond J., Botchkarev, Vladimir A.

January 2011

No / Hair follicle (HF) morphogenesis is governed by a series of signals exchanged between the epidermal keratinocytes committed to HF-specific differentiation and the mesenchymal cells forming the follicular papilla (Schmidt-Ullrich and Paus, 2005). These interactions lead to the construction of the hair bulb, in which keratinocytes rapidly proliferate and differentiate into several cell populations forming the hair shaft and the inner root sheath. During the final steps of development, the HF elongates up to its maximal length and the hair shaft emerges through the epidermis through the hair canal that is formed at the distal portion of the HF epithelium (Schmidt-Ullrich and Paus, 2005). ...To elucidate a role for MMP-9 in the control of HF development and hair canal formation, its expression was studied by immunohistochemistry in cryosections of embryonic and postnatal skin of C57BL/6 mice (Sharov et al., 2003), and was correlated to the micro-anatomy of the developing hair canal depicted by high-resolution light microscopy, as described previously (Magerl et al., 2001). MMP-9 expression was not observed in the epidermis and developing HF placodes.

Matrix Metalloproteinase-9

Hair canal formation

Regulation

Hair follicles

Human Hair Follicle and Epidermal Melanocytes Exhibit Striking Differences in Their Aging Profile which Involves Catalase.

Kauser, Sobia, Westgate, Gillian E., Green, M.R., Tobin, Desmond J.

January 2011

No / Canities or senile hair graying, a universally recognized sign of aging, remains unresolved in terms of physiological causes, although a strong genetic contribution is understood (Gunn et al., 2009). As the hair fiber continues to grow long after melanin production ceases, we suggest that melanocytes in the hair follicle may be more sensitive to the impact of chronological aging than are keratinocytes. Moreover, follicular melanocytes also age more markedly than those in the overlying epidermis. The hair follicle provides a unique opportunity to decouple the impact of age on two hair follicular tissue functions: hair formation and hair pigmentation. ... This study provides analysis of race, age, and anatomically matched cultures of adult human epidermal and hair follicle melanocytes (HFMs).

Human hair follicles

Age

Aging profiles

Catalase

Melanocytes

Keratinocytes

Androgens trigger different growth responses in genetically identical human hair follicles in organ culture that reflect their epigenetic diversity in life

Miranda, Benjamin H., Charlesworth, Matthew R., Tobin, Desmond J., Sharpe, David T., Randall, Valerie A.

2017 October 1918

Yes / Male sex hormones-androgens-regulate male physique development. Without androgen signaling, genetic males appear female. During puberty, increasing androgens harness the hair follicle's unique regenerative ability to replace many tiny vellus hairs with larger, darker terminal hairs (e.g., beard). Follicle response is epigenetically varied: some remain unaffected (e.g., eyelashes) or are inhibited, causing balding. How sex steroid hormones alter such developmental processes is unclear, despite high incidences of hormone-driven cancer, hirsutism, and alopecia. Unfortunately, existing development models are not androgen sensitive. Here, we use hair follicles to establish an androgen-responsive human organ culture model. We show that women's intermediate facial follicles respond to men's higher androgen levels by synthesizing more hair over several days, unlike donor-matched, androgen-insensitive, terminal follicles. We demonstrate that androgen receptors-androgen-activated gene transcription regulators-are required and are present in vivo within these follicles. This is the first human organ that involves multiple cell types that responds appropriately to hormones in prolonged culture, in a way which mirrors its natural behavior. Thus, intermediate hair follicles offer a hormone-switchable human model with exceptional, unique availability of genetically identical, but epigenetically hormone-insensitive, terminal follicles. This should enable advances in understanding sex steroid hormone signaling, gene regulation, and developmental and regenerative systems and facilitate better therapies for hormone-dependent disorders.

Alopecia

Balding

Hirsutism

Intermediate hair follicles

Model system

Re-evaluating cyclosporine A as a hair growth-promoting agent in human scalp hair follicles

Hawkshaw, N.J., Haslam, I.S., Ansell, David, Shamalak, A., Paus, R.

07 May 2020

No / Cyclosporine A (CsA) has long been recognized as a potent hair growth stimulator in both humans and rodent. The induction of a dose-dependent hypertrichosis is one of the most frequent adverse effects of long-term CsA therapy (Lutz, 1994). However, it is unclear how this immunosuppressant induces hypertrichosis in patients or stimulates hair growth in human scalp skin transplanted on nude mice (Gilhar et al., 1988; Gilhar et al., 1991).

Cyclosporine A

Hair growth stimulant

Human scalp

Hair follicles

Development of a novel, clinically-relevant model for investigating factors that stimulate human hair growth

Miranda, Benjamin H.

January 2011

Lack of hair due to alopecia or skin grafting procedures causes significant distress due to hair's role in social and sexual communication. Only limited pharmacological agents are currently available to stimulate hair growth; their development is hampered by inappropriate model systems. Most research involves large terminal scalp follicles rather than the clinical targets of tiny vellus or intermediate follicles. The overall aim of this thesis was to develop a novel model system based on intermediate hair follicles. Initially, intermediate follicles from female pre-auricular skin were characterised and compared to matched terminal follicles. Intermediate follicles were smaller, less pigmented, shorter and possessed a more 'tubular' bulb morphology than their more 'bulbous' terminal counterparts. Significant correlations were demonstrated between various hair follicle measurements and corresponding dermal papilla diameters. Isolated terminal follicles grew significantly more than intermediate hair follicles in organ culture for 9 days. Testosterone (10nM), the major regulator of human hair growth, increased only intermediate follicle growth; the anti-androgen, cyproterone acetate (1μM), prevented this stimulation, unlike the 5α-reductase type 2 inhibitor finasteride (40ng/ml). Immunohistochemistry demonstrated androgen receptor and 5α-reductase type 2 proteins in both follicle types, while quantitative real-time PCR and gene microarray analysis detected their increased gene expression in intermediate follicles. Thus, smaller intermediate follicles showed major morphological and gene expression differences to terminal follicles in vivo and retained significant, biologically-relevant differences in vitro in organ culture including androgen-responsiveness. Therefore, intermediate hair follicles offer a novel, exciting, more clinically relevant, albeit technically difficult, model for future investigations into hair growth.

612.7

Disease mechanisms in the C3H/HeJ Mouse Model of Alopecia

Barekatain, Armin

05 1900

Alopecia areata (AA) is a chronic inflammatory disease of hair follicles manifesting as patchy areas of hair loss on the scalp and body. Development of AA is associated with pen- and intra-follicular inflammation of anagen stage hair follicles, primarily by CD4+ and CD8+ cells. We hypothesized that if cell-mediated cytotoxicy against hair follicles is to be a component of the hair loss disease mechanism, increased expression of genes and products typical of cytotoxic cells, as well as increased apoptosis activity within affected hair follicles, would be expected to occur in the lesional skin compared to the normal skin. Furthermore, we studied gene expression levels of multiple cytokines and characteristic chemokines, using the C3FI/HeJ mouse model of AA. mRNA expression levels of granzyme A, granzyme B, perform Fas, Fas ligand, TNF-cL, TNF-aRl and R2, TRAIL, TRAILR, TRAMP, Thi-, Th2-, and Th17-associated cytokines, as well as multiple chemokines were compared between the skin, draining lymph nodes, thymus and spleens of normal and AA-affected mice using quantitative reverse transcriptase PCR. FasL, granzyme A, granzyme B, pro- and anti-inflammatory cytokines were all highly up-regulated in the skin of AA-affected mice. Immunohistochemical studies of the skin revealed that, although greater numbers of granzyme B and FasL expressing cells were present in AA affected skin, the cells were morphologically diffusely distributed and not exclusively located within the focal pen- and intrafollicular infiltrate. The majority of these cells were further characterized as mast cells, which were also found in substantially greater numbers in the skin of mice with AA compared to their normal haired controls. Almost no perform expressing cells were identified in AA affected mouse skin and TUNEL staining suggested relatively limited apoptosis activity in hair follicle keratinocytes. In conclusion, while granzymes and FasL may play important roles in disease development, the profiles and patterns of expression are not consistent with direct cell-mediated cytotoxic action against the follicular epithelium in chronic mouse AA. Potentially, hair growth inhibiting cytokines may play a more dominant role in AA development than previously thought. Furthermore, mast cells, with their increased presence around hair follicles in the AA affected mouse skin and their ability to express granzyme B and FasL, are suggested as potential key players in the pathogenesis of AA.

Alopecia areata

Hair follicles

Autoimmunity

Cell-mediated cytotoxicity

Cytokines

Mast cells

Disease mechanisms in the C3H/HeJ Mouse Model of Alopecia

Barekatain, Armin

05 1900

Alopecia areata (AA) is a chronic inflammatory disease of hair follicles manifesting as patchy areas of hair loss on the scalp and body. Development of AA is associated with pen- and intra-follicular inflammation of anagen stage hair follicles, primarily by CD4+ and CD8+ cells. We hypothesized that if cell-mediated cytotoxicy against hair follicles is to be a component of the hair loss disease mechanism, increased expression of genes and products typical of cytotoxic cells, as well as increased apoptosis activity within affected hair follicles, would be expected to occur in the lesional skin compared to the normal skin. Furthermore, we studied gene expression levels of multiple cytokines and characteristic chemokines, using the C3FI/HeJ mouse model of AA. mRNA expression levels of granzyme A, granzyme B, perform Fas, Fas ligand, TNF-cL, TNF-aRl and R2, TRAIL, TRAILR, TRAMP, Thi-, Th2-, and Th17-associated cytokines, as well as multiple chemokines were compared between the skin, draining lymph nodes, thymus and spleens of normal and AA-affected mice using quantitative reverse transcriptase PCR. FasL, granzyme A, granzyme B, pro- and anti-inflammatory cytokines were all highly up-regulated in the skin of AA-affected mice. Immunohistochemical studies of the skin revealed that, although greater numbers of granzyme B and FasL expressing cells were present in AA affected skin, the cells were morphologically diffusely distributed and not exclusively located within the focal pen- and intrafollicular infiltrate. The majority of these cells were further characterized as mast cells, which were also found in substantially greater numbers in the skin of mice with AA compared to their normal haired controls. Almost no perform expressing cells were identified in AA affected mouse skin and TUNEL staining suggested relatively limited apoptosis activity in hair follicle keratinocytes. In conclusion, while granzymes and FasL may play important roles in disease development, the profiles and patterns of expression are not consistent with direct cell-mediated cytotoxic action against the follicular epithelium in chronic mouse AA. Potentially, hair growth inhibiting cytokines may play a more dominant role in AA development than previously thought. Furthermore, mast cells, with their increased presence around hair follicles in the AA affected mouse skin and their ability to express granzyme B and FasL, are suggested as potential key players in the pathogenesis of AA.

Alopecia areata

Hair follicles

Autoimmunity

Cell-mediated cytotoxicity

Cytokines

Mast cells

The roles of hepatocyte growth factor family members in androgen-regulation of human hair growth : a comparison of the expression of hepatocyte growth factor family members, HGF and MSP, and their receptors, c-Met and RON, in isolated hair follicles from normal and androgenetic alopecia (balding) scalp

Al-Waleedi, Saeed A.

January 2010

Androgens are the main regulators of human hair growth stimulating larger, terminal hair development e.g. beard and causing scalp balding, androgenetic alopecia. Hair disorders cause psychological distress but are poorly controlled. Androgens probably act by altering regulatory paracrine factors produced by the mesenchyme-derived dermal papilla. This study aimed to investigate paracrine factors involved in androgen-regulated alopecia, particularly hepatocyte growth factor (HGF) family members, by investigating their in vivo status. Balding and non-balding scalp hair follicles and their component tissues were isolated and analysed by molecular biological methods (reverse transcriptase-polymerase chain reaction (RT-PCR), quantitative PCR and DNA microarray analysis), cell culture and immunohistochemistry. Scalp follicles expressed a range of paracrine messenger genes. The dermal papilla, cultured dermal papilla cells and dermal sheath expressed several HGF family genes, while matrix cells only produced the receptor RON suggesting autocrine roles for HGF and MSP, but a paracrine route only for MSP. Comparing balding and non-balding follicles from the same individuals revealed the expected reduction in several keratin and keratin-related protein genes supporting this approach's validity. There were also significant differences in paracrine factors previously implicated in androgen action by in vitro studies. Several factors believed to increase during androgen stimulation of larger, darker follicles, e.g. IGF-I and SCF, were lowered in balding follicles, while putative inhibitory factors, e.g. TGFß-1, were increased. HGF and MSP and their receptors, c-Met and RON, were significantly reduced. These results increase our understanding of androgen action in human hair follicles; this could lead to better treatments for hair disorders.

616.5

Disease mechanisms in the C3H/HeJ Mouse Model of Alopecia

Barekatain, Armin

05 1900

Alopecia areata (AA) is a chronic inflammatory disease of hair follicles manifesting as patchy areas of hair loss on the scalp and body. Development of AA is associated with pen- and intra-follicular inflammation of anagen stage hair follicles, primarily by CD4+ and CD8+ cells. We hypothesized that if cell-mediated cytotoxicy against hair follicles is to be a component of the hair loss disease mechanism, increased expression of genes and products typical of cytotoxic cells, as well as increased apoptosis activity within affected hair follicles, would be expected to occur in the lesional skin compared to the normal skin. Furthermore, we studied gene expression levels of multiple cytokines and characteristic chemokines, using the C3FI/HeJ mouse model of AA. mRNA expression levels of granzyme A, granzyme B, perform Fas, Fas ligand, TNF-cL, TNF-aRl and R2, TRAIL, TRAILR, TRAMP, Thi-, Th2-, and Th17-associated cytokines, as well as multiple chemokines were compared between the skin, draining lymph nodes, thymus and spleens of normal and AA-affected mice using quantitative reverse transcriptase PCR. FasL, granzyme A, granzyme B, pro- and anti-inflammatory cytokines were all highly up-regulated in the skin of AA-affected mice. Immunohistochemical studies of the skin revealed that, although greater numbers of granzyme B and FasL expressing cells were present in AA affected skin, the cells were morphologically diffusely distributed and not exclusively located within the focal pen- and intrafollicular infiltrate. The majority of these cells were further characterized as mast cells, which were also found in substantially greater numbers in the skin of mice with AA compared to their normal haired controls. Almost no perform expressing cells were identified in AA affected mouse skin and TUNEL staining suggested relatively limited apoptosis activity in hair follicle keratinocytes. In conclusion, while granzymes and FasL may play important roles in disease development, the profiles and patterns of expression are not consistent with direct cell-mediated cytotoxic action against the follicular epithelium in chronic mouse AA. Potentially, hair growth inhibiting cytokines may play a more dominant role in AA development than previously thought. Furthermore, mast cells, with their increased presence around hair follicles in the AA affected mouse skin and their ability to express granzyme B and FasL, are suggested as potential key players in the pathogenesis of AA. / Medicine, Faculty of / Medicine, Department of / Experimental Medicine, Division of / Graduate

Alopecia areata

Hair follicles

Autoimmunity

Cell-mediated cytotoxicity

Cytokines

Mast cells

Investigations into the roles of potassium channels in hair growth. Studies confirming the presence of several ATP-­sensitive potassium (K+ATP) channels in hair follicles and exploring their mechanism of action using molecular biological, cell culture, organ culture and proteomic approaches.

Zemaryalai, Khatera

January 2010

Hair disorders cause significant distress. The main, but limited, treatment for hair loss is minoxidil, an ATP-­sensitive potassium (KATP) channel opener whose mechanism of stimulation is unclear. The regulatory component of KATP channels has three forms: SUR1, SUR2A and SUR2B which all respond to different molecules. Minoxidil only opens SUR2B channels, though SUR1 and SUR2B are present in human hair follicles. To expand our understanding, the red deer hair follicle model was used initially. Deer follicles expressed the same KATP channel genes as human follicles when growing (anagen), but no channels were detected in resting follicles. This reinforces the importance of KATP channels in active hair growth and the usefulness of the deer model. To assess whether SUR1 KATP channels are actually involved in human hair growth, the effects of a selective SUR1 channel opener, NNC55-­9216, on scalp follicle growth in organ culture was examined. NNC55-­9216 stimulated anagen; its effect was augmented by minoxidil. This creates the potential for more effective pharmaceuticals to treat hair loss via SUR1 channels, either alone or in combination with minoxidil. The dermal papilla plays a crucial regulatory role in hair follicle activity determining the type of hair produced. Minoxidil had no effect on dermal papilla cell proliferation, but altered the profile of proteins produced when assessed by proteomics. Further research into the roles of KATP channels and greater understanding of the significance of these protein changes should enhance our knowledge of hair biology and help the development of new, improved therapies for hair pathologies.

Hair follicles

; Human

; KATP channel

; Minoxidil

; Animal model

; Red deer

; SUR1

; SUR2B

; Dermal papilla

; Hair loss