Oestrogen alters adipocyte biology and protects female mice from adipocyte inflammation and insulin resistance.

AIMS: Obesity is associated with insulin resistance, liver steatosis and low-grade inflammation. The role of oestrogen in sex differences in the above co-morbidities is not fully understood. Our aim was to assess the role oestrogen has in modulating adipocyte size, adipose tissue oxidative stress, inflammation, insulin resistance and liver steatosis. METHODS: To determine the role oestrogen has in the above co-morbidities related to obesity, we randomized C57BL/6J mice into four groups (15 mice per group): (i) male, (ii) non-ovariectomized female (novx), (iii) ovariectomized female (ovx) and (iv) ovariectomized female mice supplemented with 17ß estradiol (ovx-E). Mice received either a low-fat (LF) or a high-fat (HF) diet for 10 weeks. Outcomes measured were bodyweight, body fat, adipocyte diameter, adipose tissue lipolysis markers, adipose tissue oxidative stress, inflammation, insulin resistance and liver steatosis. RESULTS: Male and ovx-female mice consuming the HF diet had a higher propensity of gaining weight, specifically in the form of body fat. Oestrogen protected female mice from adipocyte hypertrophy and from developing adipose tissue oxidative stress and inflammation. Moreover, novx-female and ovx-female+E mice had higher phosphorylated levels of protein kinase A and hormone sensitive lipase, markers associated with lipolysis. Additionally, male and ovx female mice had a higher propensity of developing liver steatosis and insulin resistance. In contrast, oestrogen protected female mice from developing liver steatosis and from becoming insulin resistant. CONCLUSION: We show that oestrogen protects female mice from adipocyte hypertrophy and adipose tissue oxidative stress and inflammation. Furthermore, oestrogen prevented female mice from developing liver steatosis and from becoming insulin resistant.

Ku80 and p53 suppress medulloblastoma that arise independent of Rag-1-induced DSBs.

Ku80 maintains the genome by repairing DNA double-strand breaks (DSBs) through nonhomologous end joining (NHEJ), a pathway that repairs nonspecific DSBs and Rag-1 Rag-2 (Rag)-specific DSBs. As a result, Ku80 deletion results in phenotypes characteristic of defective repair for both nonspecific DSBs (gamma-radiation hypersensitivity and genomic instability) and Rag-specific DSBs (immunodeficiency). ku80(-/-) mice also exhibit neuronal apoptosis, but we do not know the type of DSBs responsible for this response. In spite of genomic instability and immunodeficiency, cancer incidence is not increased in ku80(-/-) mice. However, deletion of the tumor suppressor, p53 greatly increases pro-B-cell lymphoma in ku80(-/-) mice due to IgH/c-Myc translocations suggesting that responses to Rag-specific DNA DSBs suppress cancer. Like suppression of pro-B-cell lymphoma, neuronal apoptosis requires p53 presenting the intriguing possibility that Rag-specific DSBs mediate neuronal development as they do lymphocyte development. Here we delete Rag-1 from ku80(-/-)p53(-/-) mice to differentiate the impact nonspecific vs Rag-specific DSBs have on ku80(-/-) mice. We find that deleting Rag-1 prevents pro-B cell lymphoma confirming Rag-induced DSBs induce this form of cancer. Both the triple mutant mice and the p53(-/-)rag-1(-/-) mice exhibit T-cell lymphoma and medulloblastoma; incidence of T-cell lymphoma is the same for both cohorts whereas incidence of medulloblastoma is higher for the triple-mutant cohort. Thus, p53-mediated neuronal apoptosis likely suppresses medulloblastoma in Ku80-deleted mice and Ku80 likely suppresses medulloblastoma by repairing nonspecific DNA DSBs instead of Rag-specific DSBs. Our observations are the first to show that Ku80 suppresses cancer caused by nonspecific DNA damage and we present a novel mouse model for medulloblastoma.