Altered pre-lamin A processing is a common mechanism leading to lipodystrophy

Capanni, Cristina; Mattioli, Elisabetta; Columbaro, Marta; Lucarelli, Enrico; Parnaik, Veena K.; Novelli, Giuseppe; Wehnert, Manfred; Cenni, Vittoria; Maraldi, Nadir M.; Squarzoni, Stefano; Lattanzi, Giovanna

doi:10.1093/hmg/ddi158

Cited by 201 publications

(227 citation statements)

References 57 publications

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“…4,5,8,11 The increased amount of prelamin A in adipose tissue samples from lipodystrophic patients bearing LMNA mutations or treated with PIs indicates that prelamin A accumulation is occuring in vivo. Moreover, lipodystrophy itself could result from defective prelamin A processing, as sterol-regulatory element-binding protein-1, which contributes to adipogenesis, is sequestrated at the nuclear rim in cells with other LMNA mutations 7 and in preadipocytes chronically treated with PIs, 21 thereby impairing adipocyte differentiation. However, the role of lamin A in adipocyte differentiation is unclear.…”

Section: Discussionmentioning

confidence: 99%

“…LMNA-linked lipodystrophies and progeroid syndromes form a clinical continuum of related phenotypes. [2][3][4][5][6][7][8] Otherwise, HIV-infected patients receiving antiretroviral therapy frequently develop a lipodystrophy syndrome associated with a high risk of metabolic and cardiovascular complications. 9 These patients also face a growing number of other agerelated comorbidities, such as neurodegeneration, osteopenia and malignancies.…”

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confidence: 99%

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Human lipodystrophies linked to mutations in A-type lamins and to HIV protease inhibitor therapy are both associated with prelamin A accumulation, oxidative stress and premature cellular senescence

et al. 2007

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Lipodystrophic syndromes associated with mutations in LMNA, encoding A-type lamins, and with HIV antiretroviral treatments share several clinical characteristics. Nuclear alterations and prelamin A accumulation have been reported in fibroblasts from patients with LMNA mutations and adipocytes exposed to protease inhibitors (PI). As genetically altered lamin A maturation also results in premature ageing syndromes with lipodystrophy, we studied prelamin A expression and senescence markers in cultured human fibroblasts bearing six different LMNA mutations or treated with PIs. As compared to control cells, fibroblasts with LMNA mutations or treated with PIs had nuclear shape abnormalities and reduced proliferative activity that worsened with increasing cellular passages. They exhibited prelamin A accumulation, increased oxidative stress, decreased expression of mitochondrial respiratory chain proteins and premature cellular senescence. Inhibition of prelamin A farnesylation prevented cellular senescence and oxidative stress. Adipose tissue samples from patients with LMNA mutations or treated with PIs also showed retention of prelamin A, overexpression of the cell cycle checkpoint inhibitor p16 and altered mitochondrial markers. Thus, both LMNA mutations and PI treatment result in accumulation of farnesylated prelamin A and oxidative stress that trigger premature cellular senescence. These alterations could participate in the pathophysiology of lipodystrophic syndromes and lead to premature ageing complications. LMNA-linked lipodystrophies and progeroid syndromes form a clinical continuum of related phenotypes. 2-8 Otherwise, HIV-infected patients receiving antiretroviral therapy frequently develop a lipodystrophy syndrome associated with a high risk of metabolic and cardiovascular complications. 9 These patients also face a growing number of other agerelated comorbidities, such as neurodegeneration, osteopenia and malignancies. 10 A-type lamins are nuclear proteins required for the structural and functional integrity of the nucleus. Lamin A is translated as a protein precursor that undergoes several maturation steps, including the addition of a C-terminal farnesyl residue, which is subsequently removed by proteolytic cleavage (reviewed by Mattout et al 1 ). Defective physiological maturation of prelamin A is the main pathophysiological mechanism underlying several premature ageing syndromes, including the Hutchinson-Gilford progeria syndrome (HGPS) (reviewed by Young et al 11 ). Several studies have convincingly demonstrated that the retention of the farnesylated residue confers toxic properties to the partially processed prelamin A. 11-13 Both cellular abnormalities [14][15][16][17] and premature ageing phenotype in mice 18 are significantly improved by using drugs that inhibit prelamin A farnesylation.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Human lipodystrophies linked to mutations in A-type lamins and to HIV protease inhibitor therapy are both associated with prelamin A accumulation, oxidative stress and premature cellular senescence

et al. 2007

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“…It has been proposed that since they are both located on the outside of the carboxyl-terminal globular domain, they might perturb interactions between the A-type lamins and other nuclear proteins [1], such as the adipogenic factor SREBP1, rather than disrupting the structure and/ or assembly of the lamins, as has been suggested for the striated muscle laminopathies [42]. Intriguingly, human cells carrying either an FPLD, MAD, or one of the mutations responsible for atypical Werner's syndrome have been reported to have increased levels of prelamin A [43].…”

Section: The A-type Laminopathiesmentioning

confidence: 99%

Mouse models of the laminopathies

Stewart

Kozlov

Fong

et al. 2007

Experimental Cell Research

107

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The A and B type lamins are nuclear intermediate filament proteins that comprise the bulk of the nuclear lamina, a thin proteinaceous structure underlying the inner nuclear membrane. The A-type lamins are encoded by the lamin A gene (LMNA). Mutations in this gene have been linked to at least nine diseases, including the progeroid diseases Hutchinson-Gilford progeria and atypical Werner's syndromes, striated muscle diseases including muscular dystrophies and dilated cardiomyopathies, lipodystrophies affecting adipose tissue deposition, diseases affecting skeletal development, and a peripheral neuropathy. To understand how different diseases arise from different mutations in the same gene, mouse lines carrying some of the same mutations found in the human diseases have been established. We, and others have generated mice with different mutations that result in progeria, muscular dystrophy, and dilated cardiomyopathy. To further our understanding of the functions of the lamins, we also created mice lacking lamin B1, as well as mice expressing only one of the Atype lamins. These mouse lines are providing insights into the functions of the lamina and how changes to the lamina affect the mechanical integrity of the nucleus as well as signaling pathways that, when disrupted, may contribute to the disease.

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“…Mutation in this gene leading to accumulation of LMNA precursor is one cause of partial lipodystrophy, indicating a role in human adipogenesis. 37 The LMNA precursor interacts with SREBP1, thereby decreasing the pool of active SREBP-1c that normally promotes pre-adipocyte differentiation. 37 A silent allele, 1908T, in LMNA is associated with obesity in two populations.…”

Section: Adipogenesismentioning

confidence: 99%

“…37 The LMNA precursor interacts with SREBP1, thereby decreasing the pool of active SREBP-1c that normally promotes pre-adipocyte differentiation. 37 A silent allele, 1908T, in LMNA is associated with obesity in two populations. 38,39 Recently, other genes that infer with adipocyte differentiation have emerged as candidates for obesity.…”

Section: Adipogenesismentioning

confidence: 99%

Obesity and polymorphisms in genes regulating human adipose tissue

Dahlman

Arner

2007

Int J Obes

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Obesity is the result of an imbalance between food intake and energy expenditure resulting in the storing of energy as fat. Adipose tissue contains the largest store of energy in the body and plays important roles in regulating energy partitioning. Developments in genomics, in particular microarray-based expression profiling, have provided scientists with a number of new candidate genes whose expression in adipose tissue is regulated by obesity. Integrating expression profiles with genome-wide linkage and/or association analyses is a promising strategy to identify new genes underlying susceptibility to obesity. This article provides a comprehensive review of adipose-tissue-expressed genes implicated in predisposition to human obesity. The authors consider the following genes of particular interest: peroxisome proliferator-activated receptor gamma and, potentially, INSIG2 acting in adipogenesis; the adrenoreceptors beta 2 and 3, as well as hormone-sensitive lipase acting on lipolysis; uncoupling protein 2 acting in mitochondria energy expenditure; and among secreted molecules the cytokine tumor necrosis factor alpha and the hormone leptin. With the rapid development in genome research, we predict that additional alleles in genes regulating adipose tissue function will be established as risk factors for common obesity in the coming years. This has important implications for the prevention of obesity and may also offer new therapeutic targets.

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Altered pre-lamin A processing is a common mechanism leading to lipodystrophy

Cited by 201 publications

References 57 publications

Human lipodystrophies linked to mutations in A-type lamins and to HIV protease inhibitor therapy are both associated with prelamin A accumulation, oxidative stress and premature cellular senescence

Human lipodystrophies linked to mutations in A-type lamins and to HIV protease inhibitor therapy are both associated with prelamin A accumulation, oxidative stress and premature cellular senescence

Mouse models of the laminopathies

Obesity and polymorphisms in genes regulating human adipose tissue

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