Oxidative T Cell Modifications in Lupus and Sjogren's Syndrome.

OBJECTIVES: Lupus flares are triggered by environmental agents that cause oxidative stress, but the mechanisms involved are unclear. The flares are characterized by oxidative modifications of proteins by 4-hydroxynonenals, malondialdehydes, carbonyls and nitration. These modifications have been proposed to induce and perpetuate lupus flares by "altered self" mechanisms. An epigenetically altered CD4+CD28+ T cell subset, caused at least in part by nitration of T cell signaling molecules, is found in patients with active lupus, and nitrated T cells are sufficient to cause lupus-like autoimmunity in animal models. The relation of protein 4-hydroxynonenals, malondialdehydes, carbonyls and nitration to lupus flares though, is unknown. We tested if the size of the epigenetically altered subset is related to disease activity and one or more of these oxidative modifications in lupus patients. We also tested the relationship between subset size, disease activity and the same oxidative modifications in Sjogren's syndrome, another autoimmune disease also associated with oxidative stress and characterized by anti-nuclear antibodies and the presence of the subset. METHODS: Lupus flare severity was quantitated using the Systemic Lupus Erythematosus Disease Activity Index, and Sjogren's flare severity using the European Sjogren's Syndrome Disease Activity Index. Subset size was determined by flow cytometry. Protein modifications were determined by ELISA. RESULTS: Only protein nitration correlated with the size of the subset in lupus and Sjogren's syndrome. CONCLUSIONS: These results support a role for protein nitration in subset size and lupus flare severity. Protein nitration may also contribute to autoantibody formation in Sjogren's syndrome.

Stronger inflammatory/cytotoxic T-cell response in women identified by microarray analysis.

Women develop chronic inflammatory autoimmune diseases more often than men. The mechanisms causing the increased susceptibility are incompletely understood. Chronic immune stimulation characterizes many autoimmune disorders. We hypothesized that repeated stimulation may cause a different T-cell response in women than in men. Microarrays were used to compare gene expression in T cells from healthy men and women with and without repeated stimulation. Four days after a single stimulation, only 25% of differentially expressed, gender-biased genes were expressed at higher levels in women. In contrast, after restimulation, 72% were more highly expressed in women. Immune response genes were significantly over-represented among the genes upregulated in women and among the immune response genes, the inflammatory/cytotoxic effector genes interferon-gamma (IFN-gamma), lymphotoxin beta (LTbeta), granzyme A (GZMA), interleukin-12 receptor beta2 (IL12Rbeta2), and granulysin (GNLY) were among those overexpressed to the highest degree. In contrast, IL17A was the only effector gene more highly expressed in men. Estrogen response elements were identified in the promoters of half the overexpressed immune genes in women, and in <10% of the male-biased genes. The differential expression of inflammatory/cytotoxic effector molecules in restimulated female T cells may contribute to the differences in autoimmune diseases between women and men.

A clinical trial and molecular study of photoadaptation in vitiligo.

BACKGROUND: Photoadaptation to ultraviolet (UV) B phototherapy is due to both pigmentary and nonpigmentary influences. OBJECTIVES: To measure photoadaptation in vitiliginous skin and to compare it with normal pigmented skin. METHODS: Seventeen patients with Fitzpatrick skin phototypes III-VI with vitiligo received six to nine UVB treatments, two to three times weekly. Minimal erythema dose (MED) testing was done at baseline and after all treatments; the percentage change in MED was analysed as a measure of photoadaptation. The percentage decrease in cyclobutane pyrimidine dimers (CPDs) over 24 h after a single exposure of 1 MED was analysed on vitiliginous and normal skin. RESULTS: The mean +/- SD percentage change in MED from before to after treatments was: treated vitiliginous skin 28.5 +/- 39.9% (P = 0.015), treated normal skin 35.9 +/- 49.9% (P = 0.015), untreated vitiliginous skin 11.9 +/- 22.6% (P =0.070), untreated normal skin 25.1 +/- 41.3% (P = 0.041). Of these patients, two-thirds had a positive percentage change in MED (photoadaptation). The mean amount of CPDs induced per megabase of DNA immediately after exposure was significantly higher in vitiliginous skin. The mean +/- SD percentage decrease in CPDs (rate of repair) in 24 h was 35.7 +/- 26.8% in vitiliginous skin (P = 0.027) and 46.2 +/- 19.5% in normally pigmented skin (P = 0.001); no difference was noted in the repair in vitiliginous skin compared with normal skin (P = 0.4). CONCLUSIONS: Photoadaptation in vitiliginous and normal skin was observed in two-thirds of patients. Vitiliginous skin had significantly more CPDs following UVB exposure; the rate of repair of UVB-induced DNA damage was equivalent to that in normal skin.

Immune regulation by polysaccharides: implications for skin cancer.

UV radiation causes sunburn, premature aging of the skin and is the major environmental carcinogen for squamous cell and basal cell skin cancer in humans. Besides causing mutations in DNA, UV radiation contributes to carcinogenesis by suppressing immune responses to highly antigenic, newly arising neoplasms. Strategies aimed at preventing UV-induced immune suppression, the mechanism of action of the agents used, and the significance of immune protection for prevention of skin cancer are reviewed. This review focuses on the use of plant polysaccharides to prevent immune damage triggered by UV radiation, an approach that goes beyond absorption of UV radiation by sunscreens as a means of reducing tissue damage. The efficacy and mechanism of action of these agents in preserving T cell-mediated immunity to model antigens in human beings and in laboratory animals are discussed.

Preservation of the delayed-type hypersensitivity response to alloantigen by xyloglucans or oligogalacturonide does not correlate with the capacity to reject ultraviolet-induced skin tumors in mice.

Chronic exposure to ultraviolet radiation suppresses T cell-mediated immune responses and induces the formation of suppressor T lymphocytes that prevent the rejection of highly antigenic ultraviolet-induced skin cancers in mice. Tamarind seed xyloglucans and pectinic oligogalacturonides prevent suppression of delayed-type hypersensitivity immune responses in mice to Candida albicans and alloantigen caused by a single exposure of ultraviolet radiation. We therefore investigated the ability of these poly/oligosaccharides to prevent suppression of T cell-mediated immune responses and suppressor cell induction during chronic ultraviolet irradiation and to preserve the capacity of ultraviolet-irradiated mice to reject a transplanted, highly antigenic, ultraviolet-induced tumor. C3H/HeN mice were treated 3x per week for 12 wk with 15 kJ per m2 ultraviolet B radiation followed by application of the polysaccharides/ oligosaccharides. The delayed-type hypersensitivity responses to C. albicans and alloantigen were measured after 1, 6, and 12 wk of treatment. Following the 12th wk of treatment the remaining mice were injected with the highly antigenic ultraviolet-induced, syngeneic tumor cell line UV5497-5. The polysaccharides/oligosaccharides protected delayed-type hypersensitivity responses to C. albicans but not contact hypersensitivity responses to dinitrofluorobenzene for up to 6 wk of ultraviolet radiation after which protection declined and suppressor cells were observed. In contrast, the delayed-type hypersensitivity response to alloantigen was preserved for the entire 12 wk of ultraviolet irradiation. Despite protection of immunity to alloantigen, the transplanted tumor cells grew equally well in all ultraviolet-irradiated animals. These results indicate that delayed-type hypersensitivity responses are heterogeneous and that delayed-type hypersensitivity to alloantigen is not a surrogate marker for rejection of ultraviolet-induced skin tumors.

Induction of primary cutaneous melanomas in C3H mice by combined treatment with ultraviolet radiation, ethanol and aloe emodin.

The role of ultraviolet (UV) radiation in the induction of nonmelanoma skin cancer is widely accepted, although its precise contribution to the development of primary cutaneous melanoma skin cancer requires further definition. We found that painting aloe emodin, a trihydroxyanthraquinone from Aloe barbadensis, in ethyl alcohol vehicle on the skin of mice in conjunction with exposure to UVB (280-320 nm) radiation results in the development of melanin-containing skin tumors. C3H/HeN mice were treated thrice weekly with aloe emodin in a 25% ethanol in water vehicle and exposed to 15 kJ/m2 UV radiation. Neither ethanol vehicle nor aloe emodin alone induced skin tumors in the absence of UV radiation. In two separate experiments, 20-30% of the mice treated with a combination of UV radiation and ethanol vehicle and 50-67% of the UV-irradiated animals given aloe emodin in ethanol vehicle developed primary cutaneous melanin-containing tumors. The diagnosis of melanoma was established using Fontana silver stain for melanin; these tumors were negative for vimentin and keratin. Melanin-containing melanosomes were observed by transmission electron microscopy in tumors diagnosed as melanomas. Although the mechanism of carcinogenesis in these mice is currently unknown, our findings have led to the development of the first facile murine model for the induction of primary melanoma. This model has the potential to clarify the role of UV radiation in the etiology of malignant melanoma.

Plants, polysaccharides, and the treatment and prevention of neoplasia.

Plants and Fungi have traditionally been the single largest source of lead compounds for the development of therapeutics by the pharmaceutical industry. Currently mushroom and plant polysaccharides brought to attention by Complementary and Alternative medicine, are undergoing scientific analysis and development to prevent and treat cancer, Two classes of saccharides are under investigation-beta glucan polysaccharides as biological response modifiers for the adjuvant treatment of cancer and "Oligosaccharin"-related oligosaccharides for the prevention of sun-induced skin cancer. Beta glucans already in human trials in the Far East will require mechanistic pharmacologic studies and definition of stucture function relationships before they are ready for clinical trials in the West. Other beta glucans that prime natural killer cells for antibody dependent cell-mediated cytotoxicity are approaching clinical trials. Oligosaccharides that downregulate production of immunosuppressive cytokines by ultraviolet radiation injured keratinocytes are promising agents for the prevention of environmental skin cancer.

Inhibition of UV-induced immune suppression and interleukin-10 production by plant oligosaccharides and polysaccharides.

Application of Aloe barbadensis poly/oligosaccharides to UV-irradiated skin prevents photosuppression of delayed-type hypersensitivity (DTH) responses in mice. We tested the hypothesis that these carbohydrates belong to a family of biologically active, plant-derived polysaccharides that can regulate responses to injury in animal tissues. C3H mice were exposed to 5 kJ/m2 UVB from unfiltered FS40 sunlamps and treated with between 1 pg and 10 micrograms tamarind xyloglucans or control polysaccharides methylcellulose or dextran in saline. The mice were sensitized 3 days later with Candida albicans. Tamarind xyloglucans and purified Aloe poly/oligosaccharides prevented suppression of DTH responses in vivo and reduced the amount of interleukin (IL)-10 observed in UV-irradiated murine epidermis. Tamarind xyloglucans were immunoprotective at low picogram doses. In contrast, the control polysaccharides methylcellulose and dextran had no effect on immune suppression or cutaneous IL-10 at any dose. Tamarind xyloglucans and Aloe poly/oligosaccharides also prevented suppression of immune responses to alloantigen in mice exposed to 30 kJ/m2 UVB radiation. To assess the effect of the carbohydrates on keratinocytes, murine Pam212 cells were exposed to 300 J/m2 UVB radiation and treated for 1 h with tamarind xyloglucans or Aloe poly/oligosaccharides. Treatment of keratinocytes with immunoprotective carbohydrates reduced IL-10 production by approximately 50% compared with the cells treated with UV radiation alone and completely blocked suppressive activity of the culture supernatants in vivo. The tamarind xyloglucans also blocked UV-activated phosphorylation of SAPK/JNK protein but had no effect on p38 phosphorylation. These results indicate that animals, like plants, may use carbohydrates to regulate responses to environmental stimuli.

Origin and characteristics of ultraviolet-B radiation-induced suppressor T lymphocytes.

Cutaneous exposure to low dose (2 kJ/m2) ultraviolet B radiation impairs the induction of contact hypersensitivity (CHS) responses to haptens applied to UV-irradiated skin and induces hapten-specific suppressor T lymphocytes (Ts). Cells collected from the draining lymph nodes of UV-irradiated, FITC-sensitized mice have impaired Ag-presenting activity and induce Ts cells upon injection into syngeneic recipients. This study investigates whether Ts cells originate in the UV-irradiated donor mice or are induced in lymph node cell recipients and the mechanism of suppression. Using congenic mice, we determined that the Ts cells in recipient animals were derived from T cells in the draining lymph nodes of the UV-irradiated donors. Cell lines and clones established from unirradiated and UV-irradiated, FITC-sensitized mice were CD4+, CD8-, TCR-alpha/beta+, MHC restricted, and hapten specific. The T cells proliferated in response to APC sensitized in vivo, but not to APC coupled in vitro with FITC. Cell lines from unirradiated mice were Th1 like, producing large amounts of IFN-gamma, but little IL-4 or IL-10, whereas cloned Ts cells from UV-irradiated mice produced IL-10, but no IL-4 or IFN-gamma. Ts cells blocked APC functions and IL-12 production in vitro. Injection of 5 x 10(4) cloned Ts cells into untreated recipients suppressed the induction of CHS. These results suggest that UV radiation can induce a distinct T regulatory type 1-like Ts population that may block the activation of Th1 cell-mediated immune responses.

Aloe barbadensis extracts reduce the production of interleukin-10 after exposure to ultraviolet radiation.

Cutaneous exposure to ultraviolet radiation suppresses the induction of T cell mediated responses such as contact and delayed type hypersensitivity (DTH) by altering the function of immune cells in the skin and causing the release of immunoregulatory cytokines. Extracts of crude Aloe barbadensis gel prevent this photosuppression. Because the regulation of contact hypersensitivity and DTH responses differ, we investigated whether protection was afforded by a single or multiple agents in Aloe and the mechanism by which this material prevents suppression of DTH immunity. The ability of Aloe gel to prevent suppression of contact hypersensitivity responses to hapten decayed rapidly after manufacture. In contrast, agents that protected against systemic suppression of DTH responses to Candida albicans were stable over time. Oligosaccharides prepared from purified Aloe polysaccharide prevented suppression of DTH responses in vivo and reduced the amount of IL-10 observed in ultraviolet irradiated murine epidermis. To assess the effect of Aloe extracts on keratinocytes, Pam 212 cells were exposed in vitro to ultraviolet radiation and treated for 1 h with Aloe oligosaccharides. Culture supernatants were collected 24 h later and injected into mice. Supernatants from ultraviolet irradiated keratinocytes suppressed the induction of DTH responses, whereas Aloe oligosaccharide treatment reduced IL-10 and blocked the suppressive activity of the supernatants. These results indicate that Aloe contains multiple immunoprotective factors and that Aloe oligosaccharides may prevent ultraviolet induced suppression of DTH by reducing keratinocyte derived immunosuppressive cytokines.

Immune response associated with nonmelanoma skin cancer.

It is now clear that UV radiation causes nonmelanoma skin cancer in at least two ways: by causing permanent changes in the genetic code and by preventing immunologic recognition of mutant cells. These are interacting rather than separate mechanisms. Damage to DNA results in disregulation of cellular proliferation and initiates immune suppression by stimulating the production of suppressive cytokines. These cytokines contribute to the loss of immunosurveillance. Ultraviolet radiation has both local and systemic immunosuppressive effects. Locally, it depletes and alters antigen-presenting LC at the site of UV irradiation. Systemic suppression results when Ts cells are induced, by altered LC, by inflammatory macrophages that enter the skin following UV irradiation, or by the action of cytokines. Damage to DNA appears to be one of the triggering events in inducing systemic immunosuppression via the release of immunosuppressive cytokines and mediators. Immunologic approaches to treating skin cancers so far have concentrated on nonspecifically stimulating immune cells that infiltrate these tumors, but induction of specific immune responses against these tumors with antitumor vaccines has received little attention as yet. Preventive measures include sun avoidance and the use of sunscreens to prevent DNA damage by UV light. Future strategies may employ means to reverse UV-induced immunosuppression by using anti-inflammatory agents, biologicals that accelerate DNA repair or prevent the generation of immunosuppressive cytokines, and specific immunotherapy with tumor antigens. New approaches for studying the immunology of human skin cancers are needed to accelerate progress in this field.

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.

Localization of DNA damage and its role in altered antigen-presenting cell function in ultraviolet-irradiated mice.

Prior ultraviolet (UV) irradiation of the site of application of hapten on murine skin reduces contact sensitization, impairs the ability of dendritic cells in the draining lymph nodes (DLN) to present antigen, and leads to development of hapten-specific suppressor T lymphocytes. We tested the hypothesis that UV-induced DNA damage plays a role in the impaired antigen-presenting activity of DLN cells. First, we assessed the location and persistence of cells containing DNA damage. A monoclonal antibody specific for cyclobutyl pyrimidine dimers (CPD) was used to identify UV-damaged cells in the skin and DLN of C3H mice exposed to UV radiation. Cells containing CPD were present in the epidermis, dermis, and DLN and persisted, particularly in the dermis, for at least 4 d after UV irradiation. When fluorescein isothiocyanate (FITC) was applied to UV-exposed skin, the DLN contained cells that were Ia+, FITC+, and CPD+; such cells from mice sensitized 3 d after UV irradiation exhibited reduced antigen-presenting function in vivo. We then assessed the role of DNA damage in UV-induced modulation of antigen-presenting cell (APC) function by using a novel method of increasing DNA repair in mouse skin in vivo. Liposomes containing T4 endonuclease V (T4N5) were applied to the site of UV exposure immediately after irradiation. This treatment prevented the impairment in APC function and reduced the number of CPD+ cells in the DLN of UV-irradiated mice. Treatment of unirradiated skin with T4N5 in liposomes or treatment of UV-irradiated skin with liposomes containing heat-inactivated T4N5 did not restore immune function. These studies demonstrate that cutaneous immune cells sustain DNA damage in vivo that persists for several days, and that FITC sensitization causes the migration of these to the DLN, which exhibits impaired APC function. Further, they support the hypothesis that DNA damage is an essential initiator of one or more of the steps involved in impaired APC function after UV irradiation.

Deficient antigen presentation and Ts induction are separate effects of ultraviolet irradiation.

Ultraviolet-B irradiation of murine skin before contact sensitization alters the antigen-presenting activity of cells in the skin and draining lymph nodes (DLN), decreases the contact hypersensitivity (CHS) response, and induces hapten-specific Ts cells. We determined whether hapten-bearing antigen-presenting cells (APC) from the DLN of UV-irradiated mice induce Ts cells. APC from UV-irradiated, FITC-sensitized mice were isolated, and FITC+ cells were FACS-purified and injected into the hind footpads of naive, syngeneic mice. Unseparated and FACS-purified bright FITC+ cells (FITChi) from UV-irradiated mice induced Ts. However, dull (FITClo) FITC+ cells, T-cell-depleted FITChi cells, or DLN cells from C3H SCID mice failed to induce Ts. Injection of FITC-bearing DLN cells from nonirradiated mice into UV-irradiated recipients failed to immunize and induced Ts instead. Treatment of the UV-irradiated recipients with anti-TNF-alpha blocked these effects. Thus, transferable suppression is due to Thy-1+ cells, does not require UV-altered APC for induction, and may depend on TNF-alpha.

Ultraviolet irradiation of murine skin alters cluster formation between lymph node dendritic cells and specific T lymphocytes.

Exposure of murine skin to suberythemal doses of ultraviolet-B (UVB) radiation before contact sensitization alters the activity of antigen-presenting cells (APC) in the draining lymph nodes (DLN), decreases the contact hypersensitivity (CHS) response, and induces hapten-specific Ts cells. We determined whether in vivo UVB irradiation alters the ability of hapten-bearing APC from the DLN to form clusters with hapten-specific T lymphocytes. When APC from UV-irradiated, fluorescein isothiocyanate (FITC)-sensitized mice were mixed with a FITC-specific T-cell line, significantly fewer clusters formed compared with FITC+ APC from unirradiated mice. A higher percentage of clusters formed with APC from UV-irradiated mice were Mac-1+ and bound both CD4+ and CD8+ T cells, whereas FITC+ APC from nonirradiated mice bound CD4+ cells. These results suggest that UVB irradiation interferes with the induction of CHS by altering the functional interaction between APC and T cells, perhaps by altering the population of APC in the skin.

Phenotypic and ultrastructural properties of antigen-presenting cells involved in contact sensitization of normal and UV-irradiated mice.

We investigated the surface phenotype and localization of hapten in antigen-presenting cells involved in the induction of contact hypersensitivity or tolerance. Dendritic cells collected 18 h earlier from the draining lymph nodes of mice sensitized with fluorescein isothiocyanate (FITC), which induce contact hypersensitivity upon injection into the foot-pads of naive mice, stimulated proliferation of lymphocytes from FITC-specific T-cell lines. By immunoelectron microscopy, these cells expressed high amounts of surface Ia molecules but had a negligible amount of FITC on the cell membrane. The majority of the FITC was localized in discrete structures in the cytoplasm, including mitochondria, endocytic vesicles, lysosomes, and cored tubules. In contrast, lymph node cells conjugated with FITC in vitro did not stimulate proliferation of FITC-specific T cells and showed a heavy, uniform distribution of FITC throughout the cytoplasm. Draining lymph node cells from mice exposed to ultraviolet (UV) radiation and then sensitized by applying FITC to the UV-irradiated skin, which induce tolerance upon injection into naive mice, induced significantly less proliferation of FITC-specific T cells than draining lymph node cells from unirradiated mice. The differences in activity of these cells, relative to draining lymph node cells from unirradiated, FITC-sensitized mice could not be attributed to a decreased number of Ia+ dendritic cells in the DLN, decreased surface expression of Ia molecules on these cells, or an alteration in the intracellular localization of hapten. However, a significantly higher percentage of the FITC+ dendritic cells from UV-irradiated mice expressed mac-1, -2, and -3 and F4/80 macrophage markers than did those from unirradiated animals, and fewer cells contained Birbeck granules, suggesting that a different population of Ia+ antigen-presenting cells may reach the draining lymph nodes of UV-irradiated mice.

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.

Evidence for direct interaction of Gs alpha with the Ca2+ channel of skeletal muscle.

The alpha subunits of heterotrimeric GTP-binding (G) proteins act upon ion channels through both cytoplasmic and membrane-delimited pathways (Brown, A. M., and Birnbaumer, L. (1990) Annu. Rev. Physiol. 52, 197-213). The membrane pathway may involve either a direct interaction between G protein and ion channel or an indirect interaction involving a membrane-delimited second messenger. To distinguish between the two possibilities, we tested whether a purified G protein could interact with a purified channel protein in a defined system to produce changes in channel currents. We selected the alpha subunit of Gs and the dihydropyridine (DHP)-sensitive Ca2+ channel of skeletal muscle T-tubules, the DHP binding protein (DHPBP), because: 1) a membrane-delimited interaction between the two has been shown (Brown, A. M., and Birnbaumer, L. (1990) Annu. Rev. Physiol. 52, 197-213; Yatani, A., Imoto, Y., Codina, J., Hamilton, S. L., Brown, A. M., and Birnbaumer, L. (1988) J. Biol. Chem. 263, 9887-9895); and 2) at the present time, these Ca2+ channels are the only putative G protein channel effectors which, following purification, still retain channel function. We used a defined system in which purified components were studied by direct reconstitution in planar lipid bilayers. Just as we had found in crude skeletal muscle T-tubule membranes (Yatani, A., Imoto, Y., Codina, J., Hamilton, S. L., Brown, A. M., and Birnbaumer, L. (1988) J. Biol. Chem. 263, 9887-9895), alpha*s but not alpha*i-3 stimulated Ca2+ currents. However, in the reconstituted system, this probably represents a direct interaction between Gs alpha and Ca2+ channels. To establish whether the two proteins were physically associated in the native T-tubule membrane, we examined the ability of either endogenous G proteins or exogenous alpha*s to purify with detergent-solubilized DHPBP through a wheat germ agglutinin affinity column and a sucrose gradient. Small amounts of a labeled G protein were found to co-purify with DHPBP. In addition, partially purified DHPBP increased the sedimentation rate of purified alpha*s but not alpha*i-3. G proteins were immunoprecipitated with an antibody to the alpha 1 subunit of the DHPBP, and, in addition, both alpha s and the beta subunit of Gs were detected in Western blots of the partially purified DHPBP. The results suggest that Gs and Ca2+ channels are closely associated in the T-tubule plasma membrane, and we conclude that skeletal muscle Ca2+ channels are direct effectors for Gs.

Restricted idiotypic profile of anti-phosphorylcholine antibodies induced by carrier-specific helper T cell clones.

The primary antibody response of C57BL/6 mice to phosphorylcholine (PC) is dominated by immunoglobulins of the T15 idiotype family. Using monoclonal antibodies that define individual idiotopes (Id) of T15, it has been shown that the antibody plaque-forming cells (PFC) arise from heterogeneous population of B cells that may express some but not all T15 Id. In the present study, we tested the ability of antigen (keyhole limpet hemocyanin, KLH)-specific CD4+ T cell clones (Th) to provide help for various T15 B cell subsets in response to PC-KLH in vitro. Four independently derived, KLH-specific Th clones were found to provide quantitative help (80-120 PFC/culture of 10(6) B cells) which was comparable to KLH-primed, unselected T cells. However, the response in the presence of the cloned T cells was idiotopically restricted: T15 idiotopes B24-44 and B36-75 were expressed on 60% to 90% PFC, whereas Id AB1-2 and B36-82 were not present (0%-20% PFC). All of these Id were highly expressed in cultures with KLH-primed, unselected splenic T cells. Evidently, the cloned Th cells provided help to only a subset of idiotypically distinct B cells. Bulk spleen T cells from unprimed donors by themselves did not provide any help for the primary response to PC-KLH. However, when these cells were added to the cultures containing B cells and KLH-specific Th clones, the repertoire of the response was fully restored, including the AB1-2/B36-82 Id (50%-80% PFC). These results suggest the existence of an auxiliary helper mechanism that may be required for activation of some B cells in addition to the antigen-specific Th cells.

Regulation of idiotype expression. II. The phenotypic diversity of T15 idiotype-bearing antibody to phosphorylcholine in response to T-dependent and T-independent antigens.

The idiotypic (Id) diversity of the immune response to phosphorylcholine (PC) was studied by immunization of mice with thymus-dependent (PC-keyhole limpet haemocyanin; PC-KLH) and thymus-independent (S. pneumoniae R36a; Pn) forms of the antigen. Mice with the BALB/c genetic background (BALB/c, C.B20, and BALB.B) were used because their response to PC is dominated by immunoglobulins encoded in VH-1 and V kappa 22 genes, which uniformly express the T15 idiotype. The actual repertoire of the antibody was determined by idiotypic markers (Id) defined with monoclonal antibodies designated AB1-2, B36-82, MaId5-4, and B24-44. Previous studies from our laboratory have shown that these Id are present on T15 (VS107-1/V kappa 22) immunoglobulins only, but that they differentiate between somatic variants of the antibody molecules. We have measured the serum concentrations of these four Id after primary (1 degree), secondary (2 degree), and tertiary (3 degree) immunization; all of the Id activity was associated with the PC-binding antibody, as shown by specific immunoadsorbents. However, the levels of the Id-bearing (Id+) antibody did not correlate with each other. After immunization with PC-KLH, the AB1-2+ antibody declined precipitously, whereas the levels of B24-44 and B36-82 remained steady. A similar pattern of Id heterogeneity was seen at the level of direct antibody-plaque-forming cells from the spleen, suggesting that the idiotopic (clonal) diversification occurred already during the early IgM response. A significant portion of anti-PC antibody after the 3 degrees PC-KLH immunization was negative for all four Id, implying that the late response to the antigen involved distinct, T15-negative clones.