Cutting edge: cardiac myosin activates innate immune responses through TLRs.

Autoimmune attack on the heart is linked to host immune responses against cardiac myosin, the most abundant protein in the heart. Although adaptive immunity is required for disease, little is known about innate immune mechanisms. In this study we report that human cardiac myosin (HCM) acted as an endogenous ligand to directly stimulate human TLRs 2 and 8 and to activate human monocytes to release proinflammatory cytokines. In addition, pathogenic epitopes of human cardiac myosin, the S2 fragment peptides S2-16 and S2-28, stimulated TLRs directly and activated human monocytes. Our data suggest that cardiac myosin and its pathogenic T cell epitopes may link innate and adaptive immunity in a novel mechanism that could promote chronic inflammation in the myocardium.

Functional interaction between mouse erbB3 and wild-type rat c-neu in transgenic mouse mammary tumor cells.

INTRODUCTION: Co-expression of several receptor tyrosine kinases (RTKs), including erbB2 and erbB3, is frequently identified in breast cancers. A member of the RTK family, the kinase-deficient erbB3 can activate downstream signaling via heterodimer formation with erbB2. We studied the expression of RTK receptors in mammary tumors from the wild-type (wt) rat c-neu transgenic model. We hypothesized that physical and functional interactions between the wt rat neu/ErbB2 transgene and mouse ErbB3-encoded proteins could occur, activating downstream signaling and promoting mammary oncogenesis. METHODS: Immunohistochemical and Western blot analyses were performed to study the expression of rat c-neu/ErbB2 and mouse erbB3 in mammary tumors and tumor-derived cell lines from the wt rat c-neu transgenic mice. Co-immunoprecipitation methods were employed to quantitate heterodimerization between the transgene-encoded protein erbB2 and the endogenous mouse erbB3. Tumor cell growth in response to growth factors, such as Heregulin (HRG), epidermal growth factor (EGF), or insulin-like growth factor-1 (IGF-1), was also studied. Post-HRG stimulation, activation of the RTK downstream signaling was determined by Western blot analyses using antibodies against phosphorylated Akt and mitogen-activated protein kinase (MAPK), respectively. Specific inhibitors were then used with cell proliferation assays to study the phosphoinositide-3 kinase (PI-3K)/Akt and MAPK kinase (MEK)/MAPK pathways as possible mechanisms of HRG-induced tumor cell proliferation. RESULTS: Mammary tumors and tumor-derived cell lines frequently exhibited elevated co-expression of erbB2 and erbB3. The transgene-encoded protein erbB2 formed a stable heterodimer complex with endogenous mouse erbB3. HRG stimulation promoted physical and functional erbB2/erbB3 interactions and tumor cell growth, whereas no response to EGF or IGF-1 was observed. HRG treatment activated both the Akt and MAPK pathways in a dose- and time-dependent manner. Both the PI-3K inhibitor LY 294002 and MEK inhibitor PD 98059 significantly decreased the stimulatory effect of HRG on tumor cell proliferation. CONCLUSION: The co-expression of wt rat neu/ErbB2 transgene and mouse ErbB3, with physical and functional interactions between these two species of RTK receptors, was demonstrated. These data strongly suggest a role for erbB3 in c-neu (ErbB2)-associated mammary tumorigenesis, as has been reported in human breast cancers.

Hormonal and dietary modulation of mammary carcinogenesis in mouse mammary tumor virus-c-erbB-2 transgenic mice.

Exogenous and dietary estrogens have been associated with modification of breast cancer risk. Mammary cancer model systems can be used to explore interactions between specific transgenes, and hormonal and dietary factors. Transgenic mice bearing the rat wild-type erbB-2 gene were used to study the effects of short-term hormonal exposure [17beta-estradiol (E2) or tamoxifen] or a soy meal diet on mammary carcinogenesis. In mice fed a casein diet, mammary tumors developed at an earlier age after short-term E2 exposure during the early reproductive period. The median mammary tumor latency was shortest (29 weeks) for the high-dose estrogen as compared with the lowest dose of E2 treated or placebo control mice (33 and 37 weeks, respectively). The timing of short-term E2 exposure was also important, with the most significant changes observed in mice exposed to E2 between 8 and 18 weeks of age. E2 exposure was associated with the subsequent development of more aggressive tumors as determined by histologic grade, multifocal tumor development, stromal invasion, and pulmonary metastasis. In contrast, short-term tamoxifen-exposed mice generally failed to develop mammary tumors by 60 weeks of age. Mice fed a soy meal diet developed mammary tumors at a later age than casein-fed animals treated with E2 or placebo, whereas no differences were observed by diet for the tamoxifen-treated mice. Mammary tumor prevention was >80% in tamoxifen-treated mice on either diet. Novel histologic tumor types were identified, suggesting greater phenotypic diversity than described previously. Benign mammary gland morphogenesis was also significantly altered by short-term hormonal exposure or dietary factors, consistent with the modification of mammary tumor risk in specific treatment groups. Estrogenic modulation of the mammary tumor phenotype in wild-type erbB-2 transgenic mice was observed. Histologic tumor types and clinical aggressivity not reported previously in this transgenic model were noted, suggesting greater biologic heterogeneity than reported previously. In addition, dietary phytoestrogens modified mammary development and tumor latency, suggesting a need for greater stringency in dietary assignment for transgenic mouse models of mammary neoplasia.