Role of urocanic acid as an endogenous photoprotectant and as a therapeutic target for treating UV-induced melanoma and non-melanoma malignancies

Wei, Grace

18 June 2019

Overexposure to UV (ultraviolet) radiation has been linked to a number of deleterious effects on human health, particularly epidermal malignancies, which consist of both melanoma and non-melanoma skin cancers, basal cell carcinoma and squamous cell carcinoma. In the 1950’s, an epidermal compound known as Urocanic Acid (UCA) was discovered whose trans isoform was shown to display photoprotective effects against UV radiation. Not long after, the cis-UCA isomer was found to act as a mediator of immune suppression, causing UCA to be removed from all cosmetic products on the commercial market, most notably sunscreen. Numerous studies conducted after this finding further corroborated cis-UCA’s immunosuppressive properties, showing evidence for the ability of cis-UCA to inhibit contact hypersensitivity responses, delayed-type hypersensitivity responses, and allograft rejection. Early evidence for a mechanism of action behind cis-UCA’s immunosuppressive properties were widespread, including modulation of antigen-presenting cells, interaction with histamine receptors, and regulation of cytokine expression. The immunosuppressive nature of cis-UCA quickly became associated with an ability to facilitate cancerous progression, particularly regarding epidermal malignancies. Interesting theories were raised about the evolutionary basis for cis-UCA’s immunosuppressive nature, including speculation that cis-UCA was meant to induce immunosuppression following ultraviolet exposure in order to prevent autoimmune responses against sunburned epidermal cells. After the turn of the 20th century, new research continued to facilitate modern day understanding of the role of UCA. Evidence showed that UCA was ultimately derived from filaggrin within the stratum corneum, interacted with key immune effectors including T-lymphocytes and Langerhans cells, and potentially contributed to acidification of the stratum corneum. Despite the negative reputation cis-UCA has received in regards to facilitating skin cancer evasion of the immune system, research has shown that its immunosuppressive effects may allow it to serve as potent anti-inflammatory therapeutic. In regards to skin cancer, targeting of UCA as a therapeutic varies widely. Some have suggested using UCA as a measure of sunscreen efficacy, as an indirect target that when inhibited can reduce tumor growth, and as a biomarker for skin cancer risk. Others have begun developing UCA-based mimics that retain the benefits of UCA, while avoiding any deleterious effects. The role of UCA in non-melanoma and melanoma malignancies is not well understood, making targeting of UCA as a therapeutic challenging. The aim of this paper is to comprehensively review the scientific literature regarding the pre-21st century history of UCA, followed by an in-depth analysis of post-21st century research. The objective is to determine the overall potential of UCA to serve as a therapeutic target for UV-associated health conditions, most notably dermatologic malignancies.

Pharmaceutical sciences

Dermatology

Immunosuppression

Skin cancer

Urocanic acid

Silver(I) and Gold(I) N-Heterocyclic Carbene Complexes

Durmus, Semih

January 2006

No description available.

Chemistry, Inorganic

NHCs

CARBENES

SILVER(I) NHC

GOLD(I) NHC

ANTIMICROBIALS

ANTICANCER

HISTAMINE

HISTIDINE

UROCANIC ACID

Immunotoxicity of Dermal Permethrin and Cis-Urocanic Acid: Effects of Chemical Mixtures in Environmental Health

Prater, Mary R.

26 April 2002

The present study examined adverse effects of sunlight exposure (mimicked by intradermal cis-urocanic acid, cUCA) on local and systemic immune responses, with or without co-exposure to the immunotoxic insecticide permethrin. A single exposure to cUCA caused diminished splenic macrophage phagocytosis that was persistent up to 30 days post-exposure. Five-day exposure to cUCA subtly increased splenocyte proliferation in response to the T cell mitogen Concanavalin A. Four-week exposure to cUCA caused increased splenic lymphocyte cellularity, thymic hypocellularity, and enhanced hydrogen peroxide production by splenic leukocytes. Single exposure to topical permethrin resulted in decreased thymic and splenic weight and cellularity, and inhibited antibody production by splenic B cells. cUCA worsened the negative effect of permethrin on both thymic weight and cellularity, and depressed splenocyte blastogenesis, hydrogen peroxide production, and antibody production. Five-day exposure to either cUCA or permethrin also caused persistent decreased contact hypersensitivity responses, an effect that became more than additive when the chemicals were administered concurrently. Defects in antigen processing and presentation by cutaneous Langerhans cells were evaluated as possible contributing mechanisms to the cutaneous immunosuppression, using mice with deleted genes. Vehicle-exposed IFNg knockout mice displayed approximately a 22.1% depression in the ear swelling response as compared to control C57BL/6N mice, suggesting that this cytokine may be required for mounting a control-level hypersensitivity response. Ear swelling in cUCA-exposed IFNg knockout mice displayed a 21.4% depressed response as compared to cUCA-exposed wild-type C57BL/6N mice, again suggesting that IFNg is an important cytokine in the contact hypersensitivity (CH) response. TNFaR knockout mice exposed to cUCA displayed 33.9% greater ear swelling than cUCA-exposed wild-type C57BL/6N mice, suggesting that increased TNFa may be involved in inhibited CH by cUCA. TNFaR knockout mice exposed to permethrin displayed 33.9% greater ear swelling than permethrin-exposed C57BL/6N mice, suggesting that increased TNFa may also be involved in inhibited CH by permethrin. C57BL/6N mice exposed to cUCA + permethrin displayed severe reduction of the CH response to 8.7% of the control level. IFNg knockout mice exposed to permethrin + cUCA showed essentially identical depression of the CH response as IFNg knockout mice exposed to either permethrin or cUCA alone. These results suggest that IFNg is required for the greater than additive immunotoxic effect that occurred when these two agents were co-administered. TNFaR knockout mice exposed to cUCA + permethrin displayed 8.7 fold greater ear swelling than similarly exposed C57BL/6N mice, again suggesting that increased TNFa is involved in inhibited CH by both cUCA and permethrin. / Ph. D.

Thymus

Skin

Ultraviolet irradiation

CD1a

Contact hypersensitivity

IFNg

Mouse

TNFa

Spleen

Cis-urocanic acid

Permethrin

Immunotoxicity

Modulation of immune responses by UV irradiation

Yu, Cunjing

January 2016

Atopic dermatitis (AD) is a common, chronic relapsing inflammatory skin disease associated with cutaneous hyper-reactivity to environmental triggers that are innocuous to normal nonatopic individuals. AD affects 10% to 15% of children and 2% to 10% of adults in industrialized countries. There has been increasing interest in this disease triggered by its increasing prevalence in western societies and its contribution to the increasing health care costs. Yet, the underlying pathophysiologic and genetic mechanisms leading to the manifestation of AD are not clear. AD results from a complex interplay between environmental triggers, susceptibility genes including mutations in the keratinocyte protein filaggrin and altered immune responses resulting in allergic CD4+ T cell (Th2) immunity to epidermally encountered antigens. Regulatory T cells (Tregs) play an important role in controlling responsiveness to self-antigens and preventing autoimmune diseases, as well as in limiting inflammatory responses during inflammation and infection. Currently, studies investigating the number and function of Tregs in patients with AD have shown controversial results. It has been long established that symptoms of AD improve on exposure to sunlight. Narrowband UVB (NB-UVB) phototherapy is a common treatment modality for a variety of skin diseases. Considering the adverse effects for systemic treatment for severe adult AD, phototherapy, especially NB-UVB phototherapy may be a more practical long-term treatment. However, approximately 50% of patients over an 8-week treatment course do not improve after NB-UVB phototherapy. Therefore, it is important to identify characteristics of AD patients to determine whether they will respond to phototherapy and to avoid adverse effects for unresponsive patients. UVB exposure has also been associated with induction of Tregs in mice and increasing their numbers and/or functional capacity may offer benefit to patients with chronic AD. Active vitamin D (1,25(OH)2D3), one of the factors induced by UV-B radiation induces Tregs and is suggested to contribute to the suppressive effect of NB-UVB phototherapy. However, UV radiation could also have beneficial effects through other pathways known to affect immunoregulation. UVB exposure upregulates production of nitric oxide (NO) in the skin which also affects immune cell function. The protein filaggrin is broken down in differentiating keratinocytes to form the natural moisturizer of the skin. The gene encoding filaggrin (FLG) has been shown to be a major predisposing factor for AD. A key breakdown product is urocanic acid (UCA) which also acts as a natural sunscreen and undergoes trans-cis isomerisation on exposure to UV-B. Cis-UCA is known to modulate immune responses, however, the mechanisms of its action remain elusive. The production of all three compounds, vitamin D, cis-UCA and NO might all increase in the circulation of patients undergoing UVB phototherapy. While the immunomodulatory effect of Vitamin D is well described, cis-UCA and NO may also affect the behaviour of T lymphocytes systemically. Therefore, I investigated the effect of NO and cis-UCA on the phenotype and function of CD4+T cells and monocyte-derived dendritic cells (Mo-DCs) derived from peripheral blood mononuclear cells (PBMCs) from healthy volunteers. I also investigated the correlation between plasma concentration of 25(OH) vitamin D and nitrate, FLG genotype, circulating Tregs and clinical efficacy of NB-UVB phototherapy. My results showed that NO did not affect the phenotype of human mo-DCs and directly affected peripheral CD4+ T cells by inducing functional CD25+Foxp3+CD127-Tregs from CD4+CD25lo/- effector T cells. Moreover, NO increased expression of the of skin homing marker CLA on these Tregs, suggesting an increased ability of NO-induced Tregs to migrate to the skin. These NO-induced CD25+Foxp3+CD127-Tregs had immunosuppressive functions and inhibited autologous CD4+ T cell proliferation. Cytokines, at least IL-10, secreted by NO-treated CD4+ T cells were not sufficient for the suppressive function of NOinduced Foxp3+Tregs. The immune regulatory function of NO-induced Fopx3+Tregs required cell-cell contact and was mediated by membrane bound TGFβ and PD-1/PD-L1 but not CTLA-4. Results also showed that cis-UCA might have both pro- and anti-inflammatory effects. Cis- UCA significantly decreased the proportion of CD25hi Foxp3+ cells from activated CD4+ T cells. It also decreased the expression of vitamin D receptor in CD4+ T cells which may interfere with the immune regulatory function of vitamin D. These results suggested that there might be a fine balance between UV-induced anti-inflammatory molecules’ effect on CD4+ T cells. However, Cis-UCA also modulated CD4+ T cell directly by decreasing CD4+ T cell proliferation, decreasing phosphorylation of ERK after TCR activation, enhancing immune suppressive cytokines secretion, and inhibiting the percentage of CLA+CD4+T cells suggesting a decreased ability to migrate to the skin, . Cis-UCA also affected the phenotype and function of antigen presenting cells by decreasing the expression of HLA-DR, CD86 and CD40 on immature mo-DCs, which led to increased proportion of CD25+Foxp3+CD127- T cells when co-cultured with allogenic CD4+ T cells. Results generated from the clinical study in which all 29 patients got better after phototherapy suggested although circulating 25 (OH) vitamin D concentration was significantly increased after NB-UVB phototherapy, the change of circulating 25 (OH) vitamin D concentration did not correlate with disease improvement. This suggests that vitamin D is not the only pathway involved and that other molecules contribute to UVB-induced immune-regulation. The data also show that of the levels of circulating nitrate and the FLG genotype did not correlate with improvement / change with phototherapy. However, the expression of CD69 and CLA on circulating CD4+ T cells was decreased after treatment suggesting that UVB affected T cell activation and migration to the skin, and their importance in determining clinical responses requires further investigation. Taken together, the results from my study provide evidence that vitamin D is not the only molecule responsible for the beneficial effect of NB-UVB phototherapy. NO and cis-UCA may down-regulate immune responses by affecting human peripheral CD4+ T cells and mo- DCs phenotype and function. A further understanding of the effect of NO and cis-UCA on skin resident immune cells will provide more insights for narrowing NB-UVB phototherapy which will help to select patients that most likely to benefit from a mechanism-based treatment.

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