In vitro and in vivo studies on biodegradable matrices for autotransplantation /

Gustafson, Carl-Johan,

January 2006

Diss. Stockholm : Karolinska institutet, 2006.

The role of retinoic acid receptors in oral epithelial differentiation /

Kautsky, Mikael B.

January 1997

Thesis (Ph. D.)--University of Washington, 1997. / Vita. Includes bibliographical references (leaves [138]-157).

Topographic and chemical patterning of cell-surface interfaces to influence cellular functions

Charest, Joseph Leo.

January 2007

Thesis (Ph. D.)--Mechanical Engineering, Georgia Institute of Technology, 2007. / Committee Chair: Dr. William P. King; Committee Member: Dr. Andres J. Garcia; Committee Member: Dr. F. Levent Degertekin; Committee Member: Dr. Hang Lu; Committee Member: Dr. Todd C. McDevitt.

The transient receptor potential channel 1 (TRPC1) mediates calcium-regulated differentiation in oral gingival keratinocytes /

Cai, Shiwei.

January 2004

Thesis (Ph. D.)--University of Washington, 2004. / Vita. Includes bibliographical references (leaves 113-124).

Keratinocyte growth factor as a survival factor in human breast cancer

Chang, Hsiang-Lin,

January 2005

Thesis (Ph. D.)--Ohio State University, 2005. / Title from first page of PDF file. Includes bibliographical references (p. 81-90).

Characterization of proteasome assembly in psoriatic skin and during keratinocyte differentiation in vitro - role of the proteasome maturation protein (POMP). / Caractérisation de l'assemblage du protéasome dans la peau psoriasique et au cours de la différenciation kératinocytaire in vitro - rôle de la protéine de maturation du protéasome (POMP).

Zieba, Barbara Agnieszka

19 December 2016

Les protéasomes jouent un rôle majeur dans la protéolyse intracellulaire non-lysosomale et interviennent de ce fait dans la régulation de toutes les voies biologiques intracellulaires ainsi que dans la production des peptides antigéniques présentés au système immunitaire. La biosynthèse du protéasome 20S (le cœur protéolytique) est un processus complexe qui met en œuvre plusieurs protéines chaperonnes qui facilitent l'assemblage des sous-unités entre elles pour former d’abord des « hémi-protéasomes ». Ces hémi-protéasomes s'unissent ensuite deux à deux pour créer le protéasome 20S. La Protéine de Maturation du Protéasome (POMP) est une chaperonne « clé » de l’assemblage du protéasome: son hyperexpression induit une augmentation des activités protéolytiques du protéasome et une augmentation d’expression de plusieurs de ses sous-unités. Cette surexpression augmente également la longévité de la levure Saccharomyces cerevisiae, et augmente ses capacités de résistance au stress oxydant. L’activité protéolytique et l’expression des sous-unités des protéasomes sont augmentées dans l’épiderme psoriasique. Nos précédents résultats étaient en faveur d’une régulation post-transcriptionnelle de cette expression. Nous avons émis l’hypothèse que POMP était impliquée dans la biosynthèse accrue du protéasome dans la peau psoriasique. L'objectif de cette thèse a donc été d’étudier l’assemblage du protéasome et l’expression de POMP dans la peau psoriasique et au cours de la différenciation kératinocytaire. L'expression des protéasomes et de POMP a été évaluée au niveau protéique et au niveau des ARN messagers par Immuno-Histochimie, Western-blots et RT-PCR. L’assemblage du protéasome a été étudié par électrophorèse en conditions non dénaturantes, à partir de lysats de peaux psoriasiques ou de kératinocytes. L’expression de POMP a été modulée avec des ARN interférents dans des lignées HaCaT. Nous avons observé que les protéasomes 26S et 20S (et leur activité protéolytique) étaient augmentés dans la peau psoriasique lésée, de même que les régulateurs PA28β, PA28γ, PA200 et la sous-unité RPT4 du 19S. Ces résultats suggèrent que toutes les formes majeures des protéasomes sont augmentées dans la peau psoriasique. POMP est surexprimée dans l’épiderme psoriasique et associée à des précurseurs du protéasome. Au cours de la différenciation des cellules HaCaT, l’assemblage des protéasomes 20S et 26S et l’expression de POMP augmentent aux temps précoces (3 premiers jours) alors qu’aux temps plus tardifs les protéasomes 26S se désassemblent. Ce profil de désassemblage (marqué par la diminution du protéasome 26S, l’augmentation du protéasome 20S et l'accumulation du complexe régulateur 19S) est très similaire à celui observé au cours du stress oxydatif. L’inhibition forte de l'expression de POMP a un effet anti-proliferatif et pro-apoptotique via l’inhibition de l’assemblage du protéasome dans les lignées kératinocytaires. Une inhibition plus modérée diminue l’expression des marqueurs de différenciation kératine 10 et involucrine au cours de la différenciation calcium-induite des HaCaT. L’ensemble de ces résultats suggère que l’augmentation de l’assemblage, de l’activité et de la quantité des protéasomes dans l’épiderme psoriasique est liée (au moins en partie) à la surexpression de POMP et que la dérégulation de POMP pourrait altérer la prolifération et la différenciation kératinocytaires. Nos travaux sont donc en faveur de l’implication de POMP et de l’assemblage du protéasome dans la pathogénie du psoriasis. Le ciblage thérapeutique de POMP pourrait potentiellement avoir une action anti-proliférative et anti-inflammatoire (via notamment l’inhibition de NF-κB) et représente donc une perspective thérapeutique intéressante dans le psoriasis. / Proteasomes play a major role in non-lysosomal intracellular proteolysis and thereby are involved in the regulation of all intracellular biological pathways as well as in the production of antigenic peptides presented to the immune system. The biosynthesis of the 20S proteasome (proteolytic core) is a complex process that requires several chaperone proteins that facilitate the assembly of the subunits to form "hemi-proteasomes" that then combine in pairs to create the 20S proteasome. Proteasome Maturation Protein (POMP) is a key chaperone for proteasome assembly: its overexpression induces an increase in proteolytic activities of the proteasome and an increase in expression of several of its subunits. This overexpression also increases the longevity of the yeast Saccharomyces cerevisiae and increases its capabilities of resistance against oxidative stress. The proteolytic activity and expression of the proteasome subunits are increased in psoriatic epidermis. Our previous findings suggested a post-transcriptional regulation of this expression. We hypothesized that POMP was involved in the increased biosynthesis of proteasome in psoriatic skin. The objective of the thesis project was to study proteasome assembly and POMP expression in psoriatic skin and during keratinocyte differentiation. The expression of proteasomes and POMP has been evaluated at the protein and mRNA levels by immunohistochemistry, Western blots and RT-PCR. Proteasome assembly was studied by electrophoresis under non-denaturing conditions, from lysates of psoriatic skin or keratinocytes. POMP expression was modulated by RNA interference in HaCaT cell lines. We observed that proteasomes 26S and 20S (and their proteolytic activity) were increased in the lesional psoriatic skin, as well as the proteasome regulators PA28β, PA28γ, PA200 and the 19S subunit RPT4. These results suggest that all the major proteasomal forms are increased in psoriatic skin. POMP is overexpressed in psoriatic epidermis and associated with precursors of the proteasome. During the differentiation of HaCaT cells, the assembly of 20S and 26S proteasomes and POMP expression increases at early time (first 3 days), while in later times 26S proteasomes disassemble. This disassembly profile (marked by the decrease of the 26S proteasome, the increase of the 20S proteasome complex and the accumulation of its 19S regulator) is very similar to that observed during oxidative stress. The strong inhibition of POMP expression has an anti-proliferative and pro-apoptotic effect via inhibition of proteasome assembly in the HaCaT keratinocyte cell line. However a moderate inhibition decreases the expression of differentiation markers keratin 10 and involucrin during calcium-induced differentiation of these cells. All these results suggest that the increase of the assembly, the activity and amount of proteasomes in psoriatic epidermis are linked (at least partially) to the overexpression of POMP and that deregulation of POMP could alter keratinocyte proliferation and differentiation. Our work is therefore in favor of the involvement of POMP and assembly of the proteasome in the pathogenesis of psoriasis. Therapeutic targeting of POMP could potentially have anti-proliferative and anti-inflammatory effects (particularly through the inhibition of NF-κB) and therefore represents an interesting therapeutic perspective in psoriasis.

Protéasome 26S

Psoriasis

Kératinocytes

26S proteasome

Psoriasis

Keratinocytes

Assessing the Photoprotective Effects of Fluorescent Sphingomyelin Against UVB Induced DNA Damage in Human Keratinocytes

Kandell, Rebecca Marie

01 June 2018

Non Melanoma Skin Cancer (NMSC) affects 3.3 million Americans each year and results from Ultra Violet Radiation (UVR) damage to DNA in the form of pyrimidine dimers and photoproducts [1]–[5]. Cells directly detect the damage and initiate apoptosis, cell cycle arrest, or DNA repair by modulating p53 and p21 levels [6]–[9]. Current methods of photoprotection include sunscreen, but controversy over safety of some active ingredients necessitates research into more natural alternatives [10]–[12]. In particular, 24 hour incubation with bovine milk sphingomyelin (BSM) has demonstrated photoprotective potential by reducing p21 and p53 levels in keratinocytes (KRTs) after UV radiation [13], [14]. This thesis aims to expand on past BSM research by exploring the mechanism for photoprotection. Normally, sphingomyelin (SM) is metabolically degraded to ceramide which then leads to cell apoptosis [6]. The goals of this thesis were to characterize a fluorescent SM (FSM) to assess changes in intracellular fluorescence distribution after various incubation and post-UV exposure times. FSM was deemed functionally equivalent to BSM by reducing levels of p21 after UV. Furthermore, quantification demonstrated that FSM trafficking and intracellular fluorescence were independent of continuous incubation time, warranting further investigation into shorter timepoints like 1 hour. Across several post-UV timepoints, the 1 hour incubation had a consistently higher average cytoplasmic mean gray value compared to 24 hour incubation. In addition, the no UV control was significantly lower compared to the 24 hour and 12 hour post-UV timepoints. No post-UV differences were observed for the 24 hour incubation, suggesting future work is necessary for the 1 hour incubation, which potentially streamlines future experiments. Two immunofluorescence stains for endogenous SM (lysenin) and ceramide were also optimized for preliminary fluorescence distribution studies and colocalization with FSM. Finally, a 3T3 fibroblast spheroid model was utilized as proof-of-concept for future 3D KRT cultures and depth of dye penetration quantification methods. These findings suggest FSM is an appropriate model for BSM trafficking, a shorter FSM incubation time could potentially be adopted in future studies, dual immunofluorescence staining for SM and ceramide is viable, and spheroids provide a promising model for future 3D KRT studies.

Keratinocytes

UV

NMSC

Fluorescent Sphingomyelin

p21

Immunofluorescence

Molecular Dynamics of p21 and Fluorescent Sphingomyelin in Keratinocytes Exposed to UVB

Fraser, Tyler Malcolm

01 December 2018

Non-melanoma skin cancer (NMSC) is the most common malignant tumor, representing more than a third of all malignant tumors combined and the incidence is increasing every year. Ultraviolet (UV) radiation from the sun is the most dominant factor contributing to tumor initiation and progression. The condition is most prevalent in populations with lighter skin and older age. Current pharmaceutical molecular research targets the inhibition of the Epidermal Growth Factor Receptor (EGFR), a receptor which is commonly over-expressed or dysregulated in skin malignancies. This study evaluates the content and location of the damage marker p21 within keratinocytes that were incubated in sphingomyelin (SM) and later exposed to UV. Confocal microscopy and automated image processing provided the tools to assess large populations of keratinocytes in the effort to accurately identify the photoprotective qualities of sphingomyelin. Classification of individual cells into subpopulations yielded results suggesting SM may be involved in the inhibition of EGFR, and could potentially be a more naturally derived treatment.

Sphingomyelin

keratinocytes

skin cancer

nmsc

immunofluorescence

Cancer Biology

Extracellular vesicles from UVB irradiated keratinocytes contain cyclobutane pyrimidine dimers

Ginugu, Meghana Reddy

07 June 2021

No description available.

Pharmacology

Pharmacy Sciences

Pharmaceuticals

UVB

irradiated keratinocytes

extracellular vesicles

The role of photoreceptors in human skin physiology; potential targets for light-based wound healing treatments. Identification of opsins and cryptochromes and the effect of photobiomodulation on human skin and in cultured primary epidermal keratinocytes and dermal fibroblasts

Castellano-Pellicena, Irene

January 2017

The positive effect of photobiomodulation in wound healing has previously been reported, however there is a considerable lack of knowledge regarding the molecular mechanisms involved, and no consensus on light parameters. Cytochrome c oxidase (CCO) is established as the main photoreceptor in cells, but light also induces nitric oxide (NO), production of reactive oxygen species (ROS) and activation of ion channels. Emerging new molecular targets include the GPCRs opsins (OPNs) and the circadian clock transcription factors, cryptochromes (CRYs). Localisation of OPN1-SW, OPN3, OPN5, CRY1 and CRY2 was seen in female facial and abdominal human skin. Furthermore, expression of these photoreceptors was retained in primary epidermal keratinocytes and dermal fibroblasts in culture; both cell types expressed OPN1-SW, OPN3, CRY1 and CRY2, at the mRNA and protein level. OPN2 was only expressed in cultured dermal fibroblasts, while in line with in situ expression, OPN5 was only expressed in cultured keratinocytes. The photoreceptor-expressing cultured epidermal keratinocytes demonstrated a dose- and wavelength- dependent response in both metabolic activity and cell migration in a scratch-wound assay. Specifically, low dose (2 J/cm2) blue light (447 nm) increased metabolic activity, but it did not impact keratinocyte migration. In contrast, high dose (30 J/cm2) blue light had no effect on metabolism, but inhibited migration of epidermal keratinocytes. Red light (655 nm) at 30 J/cm2 stimulated metabolic activity but did not modulate migration, while a higher dose of 60 J/cm2 had no effect on keratinocyte metabolic activity. In order to study OPN3 and CRY1 function, they were silenced in keratinocytes using siRNA; additionally 8 μM KL001 was used to stabilize CRY1. KL001 inhibited migration, and induced KRT1 and KRT10, an effect which was abrogated by knockdown of OPN3. Interestingly, knockdown of OPN3 upregulated CRY1 expression, while KL001 upregulated OPN3 expression, indicating a regulation by OPN3 of the molecular epidermal clock. Low levels of blue light increased early differentiation of epidermal keratinocytes, which was mediated by OPN3 and circadian clock mechanisms. However, low levels of blue light decreased keratinocyte DNA synthesis, which was mediated by circadian clock independently of OPN3. Translation of parameters ex vivo showed increasing re-epithelialisation and induction of OPN3 and CRY1 expression following exposure to 2 J/cm2 of blue light; however high doses of blue light inhibited re-epithelialisation. Red light, also increased re-epithelialisation, but had no effect on OPN3 or CRY1 expression. In conclusion, photoreceptors are expressed in human skin and they mediate DNA synthesis, migration and differentiation of epidermal keratinocytes. Furthermore, low dose of blue light interacts with OPN3 to induce epidermal differentiation, through the regulation of the circadian clock. A better understanding of the molecular mechanisms behind the photobiomodulation response in vitro will help to develop light based therapies for human wound healing. Interestingly, selected light parameters translated to human ex vivo skin showed a beneficial effect of low doses of blue (2 J/cm2) and red (30 J/cm2) light in re-epithelialisation. / Marie Curie ... the CLaSSiC project

Human skin

Keratinocytes

Fibroblasts

Opsins

Cryptochromes

Photobiomodulation

Light

Wound healing