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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Age-related hair pigment loss

Tobin, Desmond J. 20 February 2015 (has links)
Yes / Humans are social animals that communicate disproportionately via potent genetic signals imbued in the skin and hair, including racial, ethnic, health, gender, and age status. For the vast majority of us, age-related hair pigment loss becomes the inescapable signal of our disappearing youth. The hair follicle (HF) pigmentary unit is a wonderful tissue for studying mechanisms generally regulating aging, often before this becomes evident elsewhere in the body. Given that follicular melanocytes (unlike those in the epidermis) are regulated by the hair growth cycle, this cycle is likely to impact the process of aging in the HF pigmentary unit. The formal identification of melanocyte stem cells in the mouse skin has spurred a flurry of reports on the potential involvement of melanocyte stem cell depletion in hair graying (i.e., canities). Caution is recommended, however, against simple extrapolation of murine data to humans. Regardless, hair graying in both species is likely to involve an age-related imbalance in the tissue's oxidative stress handling that will impact not only melanogenesis but also melanocyte stem cell and melanocyte homeostasis and survival. There is some emerging evidence that the HF pigmentary unit may have regenerative potential, even after it has begun to produce white hair fibers. It may therefore be feasible to develop strategies to modulate some aging-associated changes to maintain melanin production for longer.
2

Le rôle du complexe de remodelage de la chromatine NURF dans les mélanocytes et les mélanomes / The role of the NURF chromatin remodeling complex in melanocytes and melanoma

Koludrovic, Dana 30 September 2014 (has links)
Le mélanome est un cancer de la peau très agressif. Microphthalmia-associated transcription factor (MITF) est un facteur de transcription clé contrôlant le développement de la lignée mélanocytaire, ainsi que la prolifération et l’invasion des cellules de mélanome. Pour mieux comprendre les fonctions de MITF, nous avons identifié ses cofacteurs impliques dans la régulation de la transcription. Nous avons montré que le complexe de remodelage de la chromatine NURF interagit avec MITF. Ma thèse a consisté à élucider le rôle de NURF dans le mélanome et les mélanocytes. La perte de BPTF, la principale sous-unité de ce complexe, induit un arrêt de la prolifération et une entrée en senescence des cellules de mélanome. Nous avons montré que BPTF et MITF coopèrent pour réguler l’expression de gènes impliqués dans la prolifération and invasion suggérant que BPTF et un cofacteur de MITF. De façon inattendue, l’inactivation de BPTF spécifiquement dans les mélanocytes entraine la perte progressive et totale de la pigmentation du pelage en raison de l’incapacité des cellules souches mélanocytaire à produire une descendance fonctionnelle. C’est la première fois que l’interaction fonctionnelle entre NURF et MITF est démontrée in vitro, complétée par des observations phénotypique uniques in vivo, contribuant à la compréhension de la biologie des mélanocytes et du mélanome. / Melanoma is a highly aggressive form of skin cancer. Microphthalmia-associated transcription factor (MITF) isa key regulator of development of the melanocyte lineage and proliferation and invasion of melanoma cells.To further elucidate the functions of MITF, we identified factors co-regulating transcription with MITF. We identified the NURF chromatin-remodeling complex as MITF interactor. My thesis aims to elucidate the role of NURF in melanoma and melanocytes. Loss of BPTF, the principal subunit of the complex, led to arrest of proliferation and entry into senescence of melanoma lines. We showed BPTF and MITF co-regulate genes involved in proliferation and invasion suggesting that BPTF acts as cofactor for MITF. Remarkably, the mouse model of melanocyte-specific BPTF ablation led to progressive and complete loss of coat pigmentation due to the inability of the melanocyte stem cells to produce functional progeny. This is the first report of NURF-MITF functional interaction in vitro, complemented with a unique in vivo phenotype, both adding to a general understanding of melanocyte and melanoma biology.
3

Dissection of Zebrafish Adult Melanocyte Stem Cell Signaling During Regeneration

Frantz, William Tyler 26 May 2021 (has links)
Tissue-resident stem cells are present in many adult organs, where they are important for organ homeostasis and repair in response to injury. However, the signals that activate these cells and the mechanisms governing how these cells self-renew or differentiate are highly context dependent and incompletely understood, particularly in non-hematopoietic tissues. In the skin, melanocyte stem cells (McSCs) are responsible for replenishing mature pigmented melanocytes. In mammals, these cells reside in the hair follicle bulge and bulb niches where they are activated during homeostatic hair follicle turnover and following melanocyte destruction, as occurs in vitiligo and other skin hypopigmentation disorders. Recently, we identified adult McSCs in the zebrafish. To elucidate mechanisms governing McSC self-renewal and differentiation fates we analyzed individual transcriptomes from thousands of melanocyte lineage cells during the regeneration process. We identified transcriptional signatures for McSCs, deciphered transcriptional changes and intermediate cell states during regeneration, and analyzed cell-cell signaling changes to discover mechanisms governing melanocyte regeneration. We identified KIT signaling via the RAS/MAPK pathway as a regulator of McSC direct differentiation. Analysis of the scRNAseq dataset also revealed a population of mitfa/aox5 co-expressing cells that divides following melanocyte destruction, likely corresponding to cells that undergo self-renewal. Our findings show how different subpopulations of mitfa-positive cells underlie regeneration and differentiation of at least one subpopulation requires reactivation of developmental KIT signaling to properly reconstitute the melanocyte stripe.

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