Abstract

We investigated the role of LMNA in adipose tissue by developing a novel mouse model of lipodystrophy. Transgenic mice were generated that express the LMNA mutation that causes familial partial lipodystrophy of the Dunnigan type (FPLD2). The phenotype observed in FPLD-transgenic mice resembles many of the features of human FPLD2, including lack of fat accumulation, insulin resistance, and enlarged, fatty liver. Similar to the human disease, FPLD-transgenic mice appear to develop normally, but after several weeks they are unable to accumulate fat to the same extent as their wild-type littermates. One poorly understood aspect of lipodystrophies is the mechanism of fat loss. To this end, we have examined the effects of the FPLD2 mutation on fat cell function. Contrary to the current literature, which suggests FPLD2 results in a loss of fat, we found that the key mechanism contributing to the lack of fat accumulation involves not a loss, but an apparent inability of the adipose tissue to renew itself. Specifically, preadipocytes are unable to differentiate into mature and fully functional adipocytes. These findings provide insights not only for the treatment of lipodystrophies, but also for the study of adipogenesis, obesity, and insulin resistance.

Highlights

  • We investigated the role of LMNA in adipose tissue by developing a novel mouse model of lipodystrophy

  • We have studied the effects of the FPLD2 mutation on fat cell function and found that while there appear to be no defects in lipolysis, there are significant defects in adipocyte differentiation

  • The results reported here implicate impaired adipocyte differentiation as the basis for lipodystrophy in FPLD2

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Summary

Introduction

We investigated the role of LMNA in adipose tissue by developing a novel mouse model of lipodystrophy. Transgenic mice were generated that express the LMNA mutation that causes familial partial lipodystrophy of the Dunnigan type (FPLD2). One poorly understood aspect of lipodystrophies is the mechanism of fat loss To this end, we have examined the effects of the FPLD2 mutation on fat cell function. The role of LMNA in adipose: a novel mouse model of lipodystrophy based on the Dunnigan-type familial partial lipodystrophy mutation. Years of research have revealed many new genes and proteins that have been defined as having a key role in regulating adipose tissue metabolism. Mutations in the LMNA gene have been shown to cause Dunnigan-type familial partial lipodystrophy (FPLD2) [3]. The disease is characterized by a host of metabolic complications, including insulin resistance, type 2 diabetes, dyslipidemia, and hepatic steatosis [6, 7]

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