Functional coupling between the extracellular matrix and nuclear lamina by Wnt signaling in progeria.

The segmental premature aging disease Hutchinson-Gilford Progeria (HGPS) is caused by a truncated and farnesylated form of Lamin A. In a mouse model for HGPS, a similar Lamin A variant causes the proliferative arrest and death of postnatal, but not embryonic, fibroblasts. Arrest is due to an inability to produce a functional extracellular matrix (ECM), because growth on normal ECM rescues proliferation. The defects are associated with inhibition of canonical Wnt signaling, due to reduced nuclear localization and transcriptional activity of Lef1, but not Tcf4, in both mouse and human progeric cells. Defective Wnt signaling, affecting ECM synthesis, may be critical to the etiology of HGPS because mice exhibit skeletal defects and apoptosis in major blood vessels proximal to the heart. These results establish a functional link between the nuclear envelope/lamina and the cell surface/ECM and may provide insights into the role of Wnt signaling and the ECM in aging.

Expression of an LMNA-N195K variant of A-type lamins results in cardiac conduction defects and death in mice.

The nuclear lamina is an approximately 10 nm thick proteinaceous layer underlying the inner nuclear membrane. The A-type lamins, nuclear intermediate filament proteins encoded by the LMNA gene, are basic components of the nuclear lamina. Mutations in LMNA are associated with the laminopathies, congenital diseases affecting tissue regeneration and homeostasis. One of these laminopathies associated with missense mutations in LMNA is dilated cardiomyopathy with conduction system disease (DCM-CD1). To understand how the laminopathies arise from different mutations in a single gene, we derived a mouse line by homologous recombination expressing the Lmna-N195K variant of the A-type lamins with an asparagine-to-lysine substitution at amino acid 195, which causes DCM in humans. This mouse line shows characteristics consistent with DCM-CD1. Continuous electrocardiographic monitoring of cardiac activity demonstrated that LmnaN195K/N195K mice die at an early age due to arrhythmia. By immunofluorescence and western analysis, the transcription factor Hf1b/Sp4 and the gap junction proteins connexin 40 and connexin 43 were misexpressed and/or mislocalized in LmnaN195K/N195K hearts. Desmin staining revealed a loss of organization at sarcomeres and intercalated disks. Mutations within the LMNA gene may therefore cause cardiomyopathy by disrupting the internal organization of the cardiomyocyte and/or altering the expression of transcription factors essential to normal cardiac development, aging or function.

Mutations in the mouse Lmna gene causing progeria, muscular dystrophy and cardiomyopathy.

At least ten different diseases have been linked to mutations in proteins associated with the nuclear envelope (NE). Eight of these diseases are associated with mutations in the lamin A gene (LMNA). These diseases include the premature ageing or progeric diseases Hutchinson-Gilford progeria and atypical Werner's syndrome, diseases affecting striated and cardiac muscle including muscular dystrophies and dilated cardiomyopathies, lipodystrophies affecting white fat deposition and skeletal development and a peripheral neuropathy resulting in motor neuron demyelination. To understand how these diseases arise from different mutations in the same protein, we established mouse lines carrying some of the same mutations found in the human LMNA gene, as both mouse and human lamin genes show a very high degree of sequence conservation. We have generated mice with different mutations resulting in progeria, muscular dystrophy and dilated cardiomyopathy. Our mouse lines are providing novel insights into how changes to the nuclear lamina affect the mechanical integrity of the nucleus and in turn intracellular signalling, such as the NF-kappaB pathway, as well as cell proliferation and survival, cellular functions that, when disrupted, may be the basis for the origin of such diseases.

A-type lamins regulate retinoblastoma protein function by promoting subnuclear localization and preventing proteasomal degradation.

The retinoblastoma protein (pRB) is a critical regulator of cell proliferation and differentiation and an important tumor suppressor. In the G(1) phase of the cell cycle, pRB localizes to perinucleolar sites associated with lamin A/C intranuclear foci. Here, we examine pRB function in cells lacking lamin A/C, finding that pRB levels are dramatically decreased and that the remaining pRB is mislocalized. We demonstrate that A-type lamins protect pRB from proteasomal degradation. Both pRB levels and localization are restored upon reintroduction of lamin A. Lmna(-/-) cells resemble Rb(-/-) cells, exhibiting altered cell-cycle properties and reduced capacity to undergo cell-cycle arrest in response to DNA damage. These findings establish a functional link between a core nuclear structural component and an important cell-cycle regulator. They further raise the possibility that altered pRB function may be a contributing factor in dystrophic syndromes arising from LMNA mutation.

Aging and nuclear organization: lamins and progeria.

The discoveries of at least eight human diseases arising from mutations in LMNA, which encodes the nuclear A-type lamins, have revealed the nuclear envelope as an organelle associated with a variety of fundamental cellular processes. The most recently discovered diseases associated with LMNA mutations are the premature aging disorders Hutchinson-Gilford progeria syndrome (HGPS) and atypical Werner's syndrome. The phenotypes of both HGPS patients and a mouse model of progeria suggest diverse compromised tissue functions leading to defects reminiscent of aging. Aspects of the diseases associated with disrupted nuclear envelope/lamin functions may be explained by decreased cellular proliferation, loss of tissue repair capability and a decline in the ability to maintain a differentiated state.

Functional identification of distinct sets of antitumor activities mediated by the FKBP gene family.

Assigning biologic function to the many sequenced but still uncharacterized genes remains the greatest obstacle confronting the human genome project. Differential gene expression profiling routinely detects uncharacterized genes aberrantly expressed in conditions such as cancer but cannot determine which genes are functionally involved in such complex phenotypes. Integrating gene expression profiling with specific modulation of gene expression in relevant disease models can identify complex biologic functions controlled by currently uncharacterized genes. Here, we used systemic gene transfer in tumor-bearing mice to identify novel antiinvasive and antimetastatic functions for Fkbp8, and subsequently for Fkbp1a. Fkbp8 is a previously uncharacterized member of the FK-506-binding protein (FKBP) gene family down-regulated in aggressive tumors. Antitumor effects produced by Fkbp1a gene expression are mediated by cellular pathways entirely distinct from those responsible for antitumor effects produced by Fkbp1a binding to its bacterially derived ligand, rapamycin. We then used gene expression profiling to identify syndecan 1 (Sdc1) and matrix metalloproteinase 9 (MMP9) as genes directly regulated by Fkbp1a and Fkbp8. FKBP gene expression coordinately induces the expression of the antiinvasive Sdc1 gene and suppresses the proinvasive MMP9 gene. Conversely, short interfering RNA-mediated suppression of Fkbp1a increases tumor cell invasion and MMP9 levels, while down-regulating Sdc1. Thus, syndecan 1 and MMP9 appear to mediate the antiinvasive and antimetastatic effects produced by FKBP gene expression. These studies show that uncharacterized genes differentially expressed in metastatic cancers can play important functional roles in the metastatic phenotype. Furthermore, identifying gene regulatory networks that function to control tumor progression may permit more accurate modeling of the complex molecular mechanisms of this disease.

The laminopathies: nuclear structure meets disease.

Most inherited diseases are associated with mutations in a specific gene. Sometimes, mutations in two or more different genes result in diseases with a similar phenotype. Rarely do different mutations in the same gene result in a multitude of seemingly different and unrelated diseases. In the past three years, different mutations in LMNA, the gene encoding the A-type lamins, have been shown to be associated with at least six different diseases. These diseases and at least two others caused by mutations in other proteins associated with the nuclear lamina are collectively called the laminopathies. How different tissue-specific diseases arise from unique mutations in the LMNA gene, encoding almost ubiquitously expressed nuclear proteins, are providing tantalizing insights into the structural organization of the nucleus, its relation to nuclear function in different tissues and the involvement of the nuclear envelope in the development of disease.

A progeroid syndrome in mice is caused by defects in A-type lamins.

Numerous studies of the underlying causes of ageing have been attempted by examining diseases associated with premature ageing, such as Werner's syndrome and Hutchinson-Gilford progeria syndrome (HGPS). HGPS is a rare genetic disorder resulting in phenotypes suggestive of accelerated ageing, including shortened stature, craniofacial disproportion, very thin skin, alopecia and osteoporosis, with death in the early teens predominantly due to atherosclerosis. However, recent reports suggest that developmental abnormalities may also be important in HGPS. Here we describe the derivation of mice carrying an autosomal recessive mutation in the lamin A gene (Lmna) encoding A-type lamins, major components of the nuclear lamina. Homozygous mice display defects consistent with HGPS, including a marked reduction in growth rate and death by 4 weeks of age. Pathologies in bone, muscle and skin are also consistent with progeria. The Lmna mutation resulted in nuclear morphology defects and decreased lifespan of homozygous fibroblasts, suggesting premature cell death. Here we present a mouse model for progeria that may elucidate mechanisms of ageing and development in certain tissue types, especially those developing from the mesenchymal cell lineage.