Effect of local ultraviolet irradiation on infections of mice with Candida albicans, Mycobacterium bovis BCG, and Schistosoma mansoni

Inflammatory bowel diseases: interrelationships between dietary vitamin D, exposure to UV radiation and the fecal microbiome

Introduction: Environmental factors and an altered fecal microbiome are believed to be central to the pathogenesis of inflammatory bowel diseases (IBD). Vitamin D and ultraviolet radiation (UVR) are environmental factors that are associated by several pathways, including changes to the gastrointestinal microbiome, with the development and course of IBD.Area covered: This review explores the interaction of vitamin D, and UVR, with the intestinal innate and adaptive immune systems, and how they may influence the gut microbiome and the subsequent development, and progression, of IBD.Expert opinion: Vitamin D and UVR both regulate innate and adaptive immunity through a combination of common and independent mechanisms, with the overall effect being the promotion of immune tolerance. Vitamin D, and to a lesser extent UVR, can modify the gastrointestinal microbiome either directly, or through immune-mediated mechanisms and this may explain the effect on intestinal inflammation in animal models of IBD and some clinical studies. Thus, both vitamin D and UVR exposure can be considered potential 'master regulators' of gastrointestinal immunity, fine-tuning the complex interaction between genetics, host immunity and the gut microbiome. Further research and increased understanding of environment-host interactions is essential to achieving the ultimate goal of preventing and curing IBD.

The role of UV radiation and vitamin D in the seasonality and outcomes of infectious disease

The seasonality of infectious disease outbreaks suggests that environmental conditions have a significant effect on disease risk. One of the major environmental factors that can affect this is solar radiation, primarily acting through ultraviolet radiation (UVR), and its subsequent control of vitamin D production. Here we show how UVR and vitamin D, which are modified by latitude and season, can affect host and pathogen fitness and relate them to the outcomes of bacterial, viral and vector-borne infections. We conducted a thorough comparison of the molecular and cellular mechanisms of action of UVR and vitamin D on pathogen fitness and host immunity and related these to the effects observed in animal models and clinical trials to understand their independent and complementary effects on infectious disease outcome. UVR and vitamin D share common pathways of innate immune activation primarily via antimicrobial peptide production, and adaptive immune suppression. Whilst UVR can induce vitamin D-independent effects in the skin, such as the generation of photoproducts activating interferon signaling, vitamin D has a larger systemic effect due to its autocrine and paracrine modulation of cellular responses in a range of tissues. However, the seasonal patterns in infectious disease prevalence are not solely driven by variation in UVR and vitamin D levels across latitudes. Vector-borne pathogens show a strong seasonality of infection correlated to climatic conditions favoring their replication. Conversely, pathogens, such as influenza A virus, Mycobacterium tuberculosis and human immunodeficiency virus type 1, have strong evidence to support their interaction with vitamin D. Thus, UVR has both vitamin D-dependent and independent effects on infectious diseases; these effects vary depending on the pathogen of interest and the effects can be complementary or antagonistic.

A Perspective on the Interplay of Ultraviolet-Radiation, Skin Microbiome and Skin Resident Memory TCRαβ+ Cells

The human skin is known to be inhabited by diverse microbes, including bacteria, fungi, viruses, archaea, and mites. This microbiome exerts a protective role against infections by promoting immune development and inhibiting pathogenic microbes to colonize skin. One of the factors having an intense effect on the skin and its resident microbes is ultraviolet-radiation (UV-R). UV-R can promote or inhibit the growth of microbes on the skin and modulate the immune system which can be either favorable or harmful. Among potential UV-R targets, skin resident memory T cells (T_RM) stand as well positioned immune cells at the forefront within the skin. Both CD4⁺ or CD8⁺ αβ T_RM cells residing permanently in peripheral tissues have been shown to play prominent roles in providing accelerated and long-lived specific immunity, tissue homeostasis, wound repair. Nevertheless, their response upon UV-R exposure or signals from microbiome are poorly understood compared to resident TCRγδ cells. Skin T_RM survive for long periods of time and are exposed to innumerable antigens during lifetime. The interplay of T_RM with skin residing microbes may be crucial in pathophysiology of various diseases including psoriasis, atopic dermatitis and polymorphic light eruption. In this article, we share our perspective about how UV-R may directly shape the persistence, phenotype, specificity, and function of skin T_RM; and moreover, whether UV-R alters barrier function, leading to microbial-specific skin T_RM, disrupting the healthy balance between skin microbiome and skin immune cells, and resulting in chronic inflammation and diseased skin.

UV-induced immunosuppression in the balance

Around 1980, experiments with hairless mice showed us that UV-induced actinic keratoses (AK) and ensuing skin carcinomas did not arise independently: the rate of occurrence in one skin area was increased considerably if AKs had already been induced separately in another distant skin area, i.e. a systemic effect. The ground laying work of Margaret Kripke in the 1970s provided a fitting explanation: UV-induced immunosuppression and tolerance toward the UV-induced tumors. From Kripke's work a new discipline arose: "Photoimmunology." Enormous strides were made in exploring and expanding the effects from UV carcinogenesis to infectious diseases, and in elucidating the mechanisms involved. Stemming from concerns about a depletion of the ozone layer and the general impact of ambient UV radiation, the groups I worked in and closely collaborated with explored the anticipated adverse effects of UV-induced immunosuppression on healthy individuals. An important turning point was brought about in 1992 when the group of Kevin Cooper reported that immunosuppression could be induced by UV exposure in virtually all human subjects tested, suggesting that this is a normal and sound physiological reaction to UV exposure. This reaction could actually protect us from illicit immune responses against our UV-exposed skin, such as observed in idiopathic polymorphic light eruption. This premise has fruitfully rekindled the research on this common "sun allergy," affecting to widely varying degrees about one in five Europeans with indoor professions.

SCHISTOSOMA MANSONI: ANTIGEN-PRESENTING CELLS EMIGRATING FROM SKIN EXPOSED TO ATTENUATED CERCARIAE ACTIVATE LYMPHOID CELLS AND TRANSFER PROTECTION IN C57Bl/6 MICE

C57B1/6 mice develop significant levels of protection to a challenge infection after percutaneous exposure to irradiated Schistosoma mansoni cercariae. Although some circumstantial evidence has suggested that antigen-presenting cells (APCs) within the skin play a role in priming anti-schistosomula effector mechanisms, no direct evidence has been presented. In this study, we describe efforts to directly test whether skin-resident APCs exposed to irradiated cercariae are capable of mediating responses consistent with previously proposed mechanisms associated with delayed-type hypersensitivity reactions. We demonstrate that a population of APCs emigrates from the skin after percutaneous vaccination and that these cells are able to induce proliferation of S. mansoni-specific lymphocytes. We describe our experiments conducted to confirm that proliferation is dependent on major histocompatibility complex (MHC) Class-II interactions and cell-to-cell contact between APCs and lymphocytes. Immunohistological staining of emigrating cells revealed a population of large MHC Class-II+ cells with a morphology characteristic of mature dendritic cells. On recovery and adoptive transfer into naive mice, these cells demonstrated the ability to mediate protection to a challenge infection at levels similar to those in percutaneously vaccinated controls. This confirms that cutaneous APCs can initiate anti-schistosomula effector mechanisms in C57B1/6 mice after percutaneous vaccination.

Topical exposure to exogenous ultraviolet-irradiated urocanic acid enhances Mycobacterium ulcerans infection in a Crl:IAF(HA)-hrBR hairless guinea-pig model of Buruli ulcer disease

BACKGROUND

Ultraviolet radiation (UVR) pre-exposure enhances Mycobacterium ulcerans infection in the Crl:IAF(HA)-hrBR hairless guinea-pig, possibly via a photoimmunosuppressive mechanism. The trans-cis photoisomerization of epidermal urocanic acid is an important initiator of the web of events leading to photoimmunosuppression. Thus, the hypothesis tested in this paper was that topical pre-exposure to UVR-irradiated urocanic acid mixture containing cis-urocanic acid (UVR-UCA) enhances the ulcerative form of M. ulcerans infection in the Crl:IAF(HA)-hrBR hairless guinea-pig model of human Buruli ulcer disease.

METHODS

Groups of six animals were subjected to daily topical treatment with either 0 (vehicle only), 0.1, 0.5 or 1 mg of trans (tUCA) or UVR-UCA (contained a cis : trans urocanic acid isomer ratio of 1 : 9) for three consecutive days. A sham treatment group was also included in the experiment. Three days following their final treatment, the guinea-pigs were intradermally infected in the right dorsal flank with 1.5 x 107 CFU of M. ulcerans in 0.1 ml of phosphate-buffered saline (PBS) and sham infected with 0.1 ml of PBS in the left dorsal flank. The resultant skin lesions were then measured over the next 21 days. At day 21 postinfection, the animals were tested for delayed-type hypersensitivity (DTH) reactivity to M. ulcerans cell fragment antigens (MCF).

RESULTS

Distinct, well-demarcated, dermally situated skin nodules were present at infected, but not sham-infected, skin sites by day 3 postinfection, and the lesions progressed to frank ulcers by day 5. Between days 5 and 21, the mean lesion diameters of the UVR-UCA-treated animals were significantly (P<0.001) greater than those of the sham, vehicle only or tUCA-treated groups. UVR-UCA-treated guinea-pigs also had significantly (P<0.001) suppressed DTH responses to MCF compared with the other treatment groups. There were no significant (P>0.4) differences between the lesion sizes and DTH responses of the tUCA, vehicle only or sham treatment groups. These results demonstrate that topical exposure to UVR-UCA promotes M. ulcerans infection and suppresses DTH responses to M. uclerans antigens in infected animals. These results lend credence to the hypothesis that UVR-mediated enhancement of Buruli ulcer disease in the Crl:IAF(HA)-hrBR hairless guinea-pig model occurs via modulation of cis-urocanic acid-susceptible immune pathways.

Prevention of immunosuppression by sunscreens in humans is unrelated to protection from erythema and dependent on protection from ultraviolet a in the face of constant ultraviolet B protection

Sunscreens have been advocated as an important means of preventing skin cancer. Ultraviolet radiation induced immunosuppression is recognized as an important event in skin cancer development, yet the effectiveness of sunscreens in protecting the human immune system from ultraviolet radiation (i.e. ultraviolet radiation) is still unclear. The only currently accepted method of sunscreen rating is the sun protection factor system based on the prevention of erythema. We determined immune protection factors for six commercially available sunscreens using a nickel contact hypersensitivity model in humans. Both sun protection factor and immune protection factor testing was performed using the same solar simulated ultraviolet radiation source and dose-responses were used to determine endpoints both with and without sunscreens. We found that the immune protection factor did not correlate with the sun protection factor; however, immune protection factor was significantly correlated to the ultraviolet A protective capability of the sunscreens, indicating that sunscreen protection from ultraviolet A is important for the prevention of ultraviolet immunosuppression, when there is constant ultraviolet B protection. We recommend that sunscreens should be rated against their immune protective capability to provide a better indication of their ability to protect against skin cancer.

Ultraviolet radiation enhances both the nodular and ulcerative forms of Mycobacterium ulcerans infection in a Crl:IAF(HA)-hrBR hairless guinea pig model of Buruli ulcer disease

BACKGROUND

Ultraviolet radiation (UV) pre-exposure enhances intracellular mycobacterial infections, however, its effect upon the pathogenesis of the extracellular Mycobacterium ulcerans parasite had not been previously examined. The hypothesis tested was that UV pre-exposure enhances both the nodular and ulcerative forms of M. ulcerans infection in the Crl:IAF(HA)-hrBR hairless guinea pig.

METHODS

Groups of five animals were exposed to total cumulative UV doses of 0 (control), 3 or 30 kJ/m2 followed 3 days later by subcutaneous infection with 3 x 10(4) CFU of M. ulcerans in order to induce the nodular form of the disease. The resultant nodules were then measured for the next 22 days. The experiment was then repeated using intradermal infection with 2 x 10(6) CFU in order to induce the ulcerative form of the disease. The resultant ulcers were measured for the next 30 days. In both experiments, the animals were tested for delayed-type hypersensitivity (DTH) reactivity to Burulin-S as a marker of the onset of the reactive phase of the disease.

RESULTS

Following low inoculum subcutaneous infection, distinct, well-demarcated, subcutaneously situated skin nodules were present at infected skin sites between 7 and 22 days post-infection. Between days 14 and 21, the mean nodule diameters of the UV irradiated groups were significantly (P < 0.03) greater than that of the control group. UV pre-exposure resulted in significant (P < 0.035) suppression of DTH responses to Burulin-S challenge. High inoculum intradermal infection resulted in the development of ulcerative lesions. Between 10 and 30 days post-infection, the mean lesion diameters and mean ulcer development times of UV irradiated groups were significantly (P < 0.05) greater than those of the controls. However, UV irradiation did not affect DTH responses to Burulins in the high inoculum experiment. In both experiments, the lesions were histologically consistent with human Buruli ulcer disease. These results demonstrate that UV pre-exposure results in enhanced M. ulcerans infection in the hairless guinea pig model of Buruli ulcer disease and suggest that UV exposure may be a relevant factor in the pathogenesis of human forms of the disease.

Ultraviolet radiation, resistance to infectious diseases, and vaccination responses

Exposure to ultraviolet (UV) radiation, as in sunlight, can modulate immune responses in animals and humans. This immunomodulation can lead to positive health effects especially with respect to certain autoimmune diseases and allergies. However, UV-induced immunomodulation has also been shown to be deleterious. Experimental animal studies have revealed that UV exposure can impair resistance to many infectious agents, such as bacteria, parasites, viruses, and fungi. Importantly, these effects are not restricted to skin-associated infections, but also concern systemic infections. The real consequences of UV-induced immunomodulation on resistance to infectious diseases are not known for humans. Risk estimations have been performed through extrapolation of animal data, obtained from infection models, to the human situation. This estimation indicated that UV doses relevant to outdoor exposure can impair the human immune system sufficiently to have effects on resistance to infections. To further quantify and validate this risk estimation, data, e.g., from human volunteer studies, are necessary. Infection models in humans are not allowed for ethical reasons. However, vaccination against an infectious disease evokes a similar immune response as the pathogen and thereby provides an opportunity to measure the effect of UV radiation on the immune system and an estimate of the possible consequences of altered resistance to infectious agents. Effects of controlled UVB exposure on immune responses after hepatitis B vaccination have been established in mice and human volunteers. In mice, cellular and Th1-associated humoral immune responses to hepatitis B were significantly impaired, whereas in human volunteers no significant effect of UVB on these responses could be found. Preliminary data indicate that cytokine polymorphisms might be, at least in part, responsible for interindividual differences in immune responses and in susceptibility to UVB-induced immunomodulation. In addition, adaptation to UV exposure needs to be considered as a possible explanation for the difference between mice and humans that was observed in the hepatitis B vaccination model.

Green tea polyphenols: DNA photodamage and photoimmunology

Green tea is a popular beverage consumed worldwide. The epicatechin derivatives, which are commonly called 'polyphenols', are the active ingredients in green tea and possess antioxidant, anti-inflammatory and anti-carcinogenic properties. Studies conducted by our group on human skin have demonstrated that green tea polyphenols (GTP) prevent ultraviolet (UV)-B-induced cyclobutane pyrimidine dimers (CPD), which are considered to be mediators of UVB-induced immune suppression and skin cancer induction. GTP treated human skin prevented penetration of UV radiation, which was demonstrated by the absence of immunostaining for CPD in the reticular dermis. The topical application of GTP or its most potent chemopreventive constituent (-)-epigallocatechin-3-gallate (EGCG) prior to exposure to UVB protects against UVB-induced local as well as systemic immune suppression in laboratory animals. Additionally, studies have shown that EGCG treatment of mouse skin inhibits UVB-induced infiltration of CD11b+ cells. CD11b is a cell surface marker for activated macrophages and neutrophils, which are associated with induction of UVB-induced suppression of contact hypersensitivity responses. EGCG treatment also results in reduction of the UVB-induced immunoregulatory cytokine interleukin (IL)-10 in skin as well as in draining lymph nodes, and an elevated amount of IL-12 in draining lymph nodes. These in vivo observations suggest that GTPs are photoprotective, and can be used as pharmacological agents for the prevention of solar UVB light-induced skin disorders associated with immune suppression and DNA damage.

Seasonal fluctuations of incubation, healing delays, and clinical presentation of cutaneous leishmaniasis in French Guiana

An investigation was conducted to determine whether seasonal variations affected the development of cutaneous leishmaniasis. Data from 499 cases treated between July 1994 and December 1998 were analyzed. The interval between infection and consultation and between treatment and clinical cure varied significantly between cases with an incubation period during the dry season compared with the rainy season (P < 0.001). When the incubation period occurred during the dry season, the standard pentamidine isethionate treatment seemed to be less effective (i.e.. the odds ratio for failure was 1.9 [1.1-3.4], P = 0.01). The presence of lymphangitis was more frequent during the dry season (i.e., the odds ratio was 0.26 [0.15-0.45], P < 0.001). These results suggested that the observed seasonal variations were due to variations in the host/parasite balance. Converging indirect elements that suggest a role for variations in solar ultraviolet radiation are discussed.

The Effect of UV Irradiation on Infection of Mice with Borrelia burgdorferi¶

These studies addressed the hypothesis that UV radiation (UVR) could affect immune responses in mice infected with Borrelia burgdorferi. Immunity against the Lyme spirochete B. burgdorferi was studied in a murine model of UV-induced immune suppression. Borrelia-specific cellular and humoral responses were examined following immunosuppressive doses of UVR. Low-passage Borrelia were injected intradermally at the base of the tail following irradiation. At various time points after infection the blood was cultured for the presence of Borrelia and the serum analyzed for Borrelia-specific antibodies. Two weeks after infection one hind-limb joint was cultured for the presence of spirochetes and the contralateral joint was examined histologically for arthritis formation. The results demonstrated that UV irradiation, administered at the site of infection or at a distant site, suppressed Borrelia-specific cellular and humoral responses in infected mice. Suppression of delayed-type hypersensitivity and antibody responses to UV was abrogated by administration of anti-interleukin (IL)-10 after UV irradiation. In addition, UV irradiation altered the dissemination pattern of the bacteria from the skin into the blood and exacerbated arthritis when compared with unirradiated controls. From these studies we concluded that UV irradiation can modulate the immune response to Borrelia and exacerbate the subsequent arthritic component of Lyme disease in mice. Furthermore, our studies suggest that IL-10 is in part responsible for the suppression of both cellular and humoral responses in addition to playing a role in the development of Lyme arthritis.

Mast cells in UV-B-induced immunosuppression

Degranulating dermal mast cells in UV-B-irradiated skin have been implicated for many years in the mechanisms of irradiation erythema. There is now considerable evidence that dermal mast cells are important to the processes by which both UV-B radiation and cis-urocanic acid (cis-UCA) suppress immune responses to sensitizing antigens applied to non-irradiated/non-cis-UCA-exposed sites. Mast-cell-depleted mice are resistant to the immunosuppressive effects of UV-B radiation and cis-UCA for 'systemic' immunomodulation. However, these mice gain responsiveness if the dorsal skin is reconstituted six weeks prior to irradiation or cis-UCA administration at that site with cultured bone-marrow-derived mast cells from +/+ mice. The molecular triggers for initiating mast-cell degranulation are being actively sought. Evidence suggests that histamine, and not tumour necrosis factor alpha, is the major mast-cell product that signals altered immune responses to sensitizing antigens applied to non-irradiated, non-cis-UCA-exposed sites. Histamine may have multiple roles, but experiments with indomethacin administered to mice have shown that one process involves induction of prostanoid production.

A long-lasting interferon-gamma response is induced to a single inoculation of antigen-pulsed dendritic cells

Vaccines against infectious organisms must produce not only long-lasting immunity but also the appropriate immune response to clear the infection. Obligate intracellular parasites, such as mycobacteria, require a predominantly cell-mediated immune response rather than antibody. Presentation of antigen by dendritic cells (DC) has been associated with the development of strong cell-mediated responses generating the production of interferon-gamma (IFN-gamma). This cytokine has an essential role in the elimination of mycobacteria. Therefore, we investigated both the duration and the nature of the immune response after priming with DC pulsed with mycobacterial antigen and compared this with priming using a conventional adjuvant. We used two strains of mice: C57BL/6, which inherently produces a T-helper 1 (Th1)-type response to mycobacterial antigen, and BALB/c, which does not. DC-enriched cell suspensions, purified DC or cultured bone marrow cells resembling DC (BMAPC) were prepared, pulsed overnight with PPD and injected intravenously (i.v.) into naive mice. Six and 12 weeks later, splenic T lymphocytes from these mice were challenged in vitro with antigen and their proliferative response and cytokine production was determined. Significant antigen-specific proliferation was observed in all assays on rechallenge with antigen in vitro 6 and 12 weeks after the initial priming with DC. IFN-gamma was detected in both strains but was only antigen specific in the C57BL/6 strain. Purified protein derivative (PPD)-pulsed BMAPC generated similar responses 6 weeks after priming. Thus, long-term T-lymphocyte responses and the production of IFN-gamma can be generated using a single inoculation of PPD-pulsed DC.

The effect of UVB irradiation on antibody responses during herpes simplex virus type 1 (HSV-1) infections of mice

Ultraviolet B (UVB) exposure suppresses cell-mediated immunity and may alter the cytokine profile, reducing T helper 1 (Th1) cytokines and promoting Th2 cytokines. Th1 cytokines enhance the production of immunoglobulin (Ig) G2a, IgG2b and IgG3 antibodies, while Th2 cytokines enhance the production of IgG1 and IgE antibodies. The effect of suberythemal UVB irradiation on antibody isotypes following infection of C3H/HeN mice with herpes simplex virus (HSV) was investigated using two protocols. First, mice were irradiated prior to two subcutaneous infections with HSV. Second, mice were immunised with inactivated HSV before being irradiated and challenged epidermally with HSV, which led to an increase in the size of the clinical lesions compared with unirradiated animals. In both models, the HSV-specific IgG titre was not affected by the UVB exposure but, generally, the irradiated animals showed a small reduction in both Th1- and Th2-associated HSV antibody isotypes. IL-4 knockout (IL-4-/-) mice were used to investigate the role of IL-4 in UVB-induced isotype switching. Here IL-4-/- and IL-4+/+ strains were irradiated prior to primary and secondary epidermal infections with HSV, followed by measurement of antibody titres and lesion size. In both the mutant and parent mice, UV irradiation led to an increase in lesion severity. In IL-4+/+ mice, UV exposure did not affect the HSV titre of any of the individual isotypes tested but did suppress the total IgG to HSV This suppression may be due to UV-induced IL-4 release because, in the IL-4-/- mice, HSV IgG was elevated by the UVB irradiation. If UV modulates the immune response solely via the action of cytokines, then the downregulation of Th1 cytokines and upregulation of Th2 cytokines should be accompanied by antibody isotype switching from IgG2a and IgG3 towards IgG1 and IgE. This result was not obtained in the models tested, perhaps because HSV infection promotes such a complex array of innate and acquired immune responses that a clear effect on virus-specific isotype production may not be apparent.

UVB irradiation decreases the magnitude of the Th1 response to hapten but does not increase the Th2 response

Exposure of murine skin to low doses of ultraviolet-B (UVB) radiation before sensitization with hapten reduces the ability of antigen presenting cells (APC) in the draining lymph nodes to initiate contact hypersensitivity responses in vivo and results in the induction of hapten-specific suppressor T cells. In the present study, we tested the hypothesis that exposure of skin to UVB radiation suppresses T cell responses to hapten in vivo by altering the functions of APC, resulting in decreased stimulation of Th1 lymphocytes, which mediate contact hypersensitivity responses, and preferential activation of Th2 cells. C3H/HeN mice were exposed to either a single 2 kJ/m2 dose of UVB or to 400 J/m2 of UVB daily from FS40 sunlamps for four consecutive days and sensitized with fluorescein isothiocyanate on UV-irradiated skin. Draining lymph node cells were collected 18 h after sensitization and co-cultured with nylon wool-purified T cells from naive or fluorescein-immunized mice. Unseparated lymph node cells or sorter-purified fluorescein-bearing APC from UV-irradiated mice induced less T cell proliferation than APC from non-UV-exposed mice. Lymph node cells produced less Th1 and Th2-associated cytokines, interferon-gamma and interleukin-4, respectively, in response to APC from UV-irradiated animals compared with APC from unirradiated, fluorescein-sensitized mice. Thus, low doses of UV radiation do not result in preferential stimulation of Th2 response in lymph nodes, and results from cloned cell lines may incompletely reflect T cell responses in vivo.

Protection against ultraviolet-B radiation-induced local and systemic suppression of contact hypersensitivity and edema responses in C3H/HeN mice by green tea polyphenols

Exposure of skin to UV radiation can cause diverse biological effects, including induction of inflammation, alteration in cutaneous immune cells and impairment of contact hypersensitivity (CHS) responses. Our laboratory has demonstrated that oral feeding as well as topical application of a polyphenolic fraction isolated from green tea (GTP) affords protection against the carcinogenic effects of UVB (280-320 nm) radiation. In this study, we investigated whether GTP could protect against UVB-induced immunosuppression and cutaneous inflammatory responses in C3H mice. Immunosuppression was assessed by contact sensitization with 2,4-dinitrofluorobenzene applied to UVB-irradiated skin (local suppression) or to a distant site (systemic suppression), while double skin-fold swelling was used as the measure of UVB-induced inflammation. Topical application of GTP (1-6 mg/animal), 30 min prior to or 30 min after exposure to a single dose of UVB (2 kJ/m2) resulted in significant protection against local (25-90%) and systemic suppression (23-95%) of CHS and inflammation in mouse dorsal skin (70-80%). These protective effects were dependent on the dose of GTP employed; increasing the dose (1-6 mg/animal) resulted in an increased protective effect (25-93%). The protective effects were also dependent on the dose of UVB (2-32 kJ/m2). Among the four major epicatechin derivatives present in GTP, (-)-epigallocatechin-3-gallate, the major constituent in GTP, was found to be the most effective in affording protection against UVB-caused CHS and inflammatory responses. Our study suggests that green tea, specifically polyphenols present therein, may be useful against inflammatory dermatoses and immunosuppression caused by solar radiation.

UVB-induced immune suppression and infection with Schistosoma mansoni

Irradiation with ultraviolet B (UVB, 290-320 nm) causes a systemic immunosuppression of cell-mediated immunity. The question of whether UV immunosuppression modulates the course of infectious diseases is important because UVB levels in sunlight are sufficient to predict significant UV-induced immunosuppression at most latitudes. We have investigated the effect of immunosuppressive doses of UVB on the disease caused by the helminth parasite Schistosoma mansoni. C57BL/6 mice were irradiated once or three times weekly over 60-80 days with UV from a bank of FS40 sunlamps. Each UV treatment consisted of an immunosuppressive UV dose, as determined by suppression of contact hypersensitivity to trinitrochlorobenzene, corresponding to about 15-30 min of noonday tropical sunlight exposure under ideal clear sky conditions. Cumulative UV doses were between 80 and 170 kJ/m2. Worm and egg burdens, liver granuloma diameters and liver fibrosis showed minimal changes (< 20%) compared with parameters in unirradiated animals. Ultraviolet irradiation (a total of 55 kJ/m2 administered in six treatments) did not impair the resistance to rechallenge conferred by vaccination with 60Co-irradiated cercariae. We have thus observed a dichotomy between UV immunosuppression and both disease and vaccination in this helminth infection, in contrast to the effects of UVB shown in other infectious diseases.

Prevention of ultraviolet radiation-induced suppression of contact and delayed hypersensitivity by Aloe barbadensis gel extract

We investigated the ability of Aloe barbadensis gel extract to prevent suppression of contact hypersensitivity (CHS) and delayed-type hypersensitivity (DTH) responses in mice by ultraviolet (UV) irradiation. Local immune suppression was induced in C3H mice by exposure to four daily doses of 400 J/m2 UV-B (280-320 nm) radiation from FS40 sunlamps, followed by sensitization with 0.5% fluorescein isothiocyanate (FITC) through the irradiated skin. Topical application of 0.167-1.67% Aloe gel after each irradiation significantly reduced this suppression. Aloe treatment partially preserved the number and morphology of Langerhans and Thy-1+ dendritic epidermal cells in skin, compared to those in the skin of mice given only UVR or UVR plus the vehicle. Experiments using a single (2 kJ/m2) dose of UVR followed by Aloe treatment showed that the effect of Aloe was not due to screening of the UVR. Systemic suppression of DTH to Candida albicans or CHS to FITC was induced in C3H mice exposed to 5 or 10 kJ/m2 UV-B radiation, respectively, on shaved dorsal skin and sensitized 3 d later with a subcutaneous injection of formalin-fixed Candida or FITC painted on unirradiated, ventral skin. Treatment of the UV-irradiated skin with Aloe immediately after irradiation prevented suppression of both DTH to Candida and CHS to FITC. Aloe treatment did not prevent the formation of cyclobutyl pyrimidine dimers in the DNA of UV-irradiated skin or accelerate the repair of these lesions. These studies demonstrate that topical application of Aloe barbadensis gel extract to the skin of UV-irradiated mice ameliorates UV-induced immune suppression by a mechanism that does not involve DNA damage or repair.

Epidermal Langerhans cells are critical for immunoregulation of cutaneous leishmaniasis

In leishmaniasis, macrophages are known to play a central role as modulators of the specific immune activity. In this article, Heidrun Moll presents evidence for the critical involvement of another component of the skin immune system, the epidermal Langerhans cell. She proposes that Langerhans cells take up parasites in the skin and transport them to the draining lymph node for presentation to T cells and initiation of the specific immune response.

Effects of ultraviolet radiation on the pathogenesis of Mycobacterium lepraemurium infection in mice

The purpose of this study was to determine whether exposing mice to ultraviolet radiation (UVR) would alter the pathogenesis of infection with Mycobacterium lepraemurium (MLM), which causes a chronic, progressive, lethal disease in susceptible mouse strains. BALB/c mice were irradiated on dorsal skin with various doses of UVR from FS40 sunlamps 3 days before infection with MLM in the hind footpad. The course of disease was followed by assessing the number of acid-fast bacteria in the footpad, regional lymph node and spleen, and measuring the size of the lesion at the site of MLM infection at various times after infection. Mice were also tested periodically for a delayed-type hypersensitivity (DTH) response by injecting MLM antigen into the uninfected footpad and measuring footpad swelling 24 hours later. Mice treated with a single high dose of UVR (45 kJ/m2) had significantly more bacteria in the infected footpad, lymph node and spleen than unirradiated control animals. They also had larger lesions at the site of MLM infection and exhibited significant suppression of the DTH response at 3 and 6 months after infection. Injection of mice s.c. in the footpad with MLM 3d after 45 kJ/m2 UVR reduced the median survival time from 391 to 305 d and after i.v. infection from 171 to 139 d. Dose-response studies indicated that exposing mice to 2.3 kJ/m2 of UVR, which is approximately 1 minimal erythemal dose for this strain, suppressed the DTH response by 50% at 3 months after infection.(ABSTRACT TRUNCATED AT 250 WORDS)

Lack of correlation between UV-induced enhancement of melanoma development and local suppression of contact hypersensitivity

Injection of melanoma cells into the UV-irradiated ear skin of syngeneic mice results in an increased incidence of melanomas compared with that in nonirradiated ear skin. This effect of UV is localized to the site of irradiation and appears to be immunologically mediated. In these studies we test the hypothesis that the effect of UV irradiation on melanoma development is related to its ability to alter epidermal Langerhans cells and impair the induction of contact hypersensitivity. A regimen of UV irradiation that altered epidermal immune cells and interfered with the generation of contact hypersensitivity was tested for its ability to increase the incidence of melanoma. Conversely, the ear skin of C3H mice treated with a regimen of UV radiation that enhanced melanoma development was examined for the number of appearance of ATPase+ and Thy-1+ dendritic epidermal cells and tested for the ability to initiate a contact hypersensitivity response. No correlation between these effects of UV irradiation could be detected. Furthermore, implantation of melanoma cells into UV-irradiated ear skin resulted in the generation of systemic immunity against subsequent tumor challenge. Therefore, we conclude that the ability of UV irradiation to modify melanoma development is unrelated to its effects on the afferent arm of the contact hypersensitivity response and that enhanced melanoma development is not due to an impairment in the induction of tumor immunity.