Summary of LMNA
The gene codes for a lamin protein. It is involved in nuclear stability, chromatin structure and gene expression. Mutations can cause Emery-Dreifuss muscular dystrophy, familial partial lipodystrophy, limb girdle muscular dystrophy, dilated cardiomyopathy, Charcot-Marie-Tooth disease, and Hutchinson-Gilford progeria syndrome [R].
The Function of LMNA
Prelamin-A/C can accelerate smooth muscle cell senescence. It acts to disrupt mitosis and induce DNA damage in vascular smooth muscle cells (VSMCs), leading to mitotic failure, genomic instability, and premature senescence.
Recommended name:Prelamin-A/C [Cleaved into: Lamin-A/C
Alternative name(s):70 kDa lamin
Renal carcinoma antigen NY-REN-32
Top Gene-Substance Interactions
LMNA Interacts with These Diseases
Substances That Increase LMNA
Substances That Decrease LMNA
Charcot-Marie-Tooth disease At least one LMNA gene mutation has been identified in people with a form of Charcot-Marie-Tooth disease known as type 2B1. Charcot-Marie-Tooth disease is characterized by nerve damage, which can result in loss of sensation and wasting (atrophy) of muscles in the feet, legs, and hands. The mutation changes a single amino acid in the lamin A and lamin C proteins. Specifically, the amino acid arginine is replaced by the amino acid cysteine at protein position 298 (written as Arg298Cys or R298C). Although its effect is not fully understood, the Arg298Cys mutation alters a protein region important for interactions with other molecules. It is unclear how the altered proteins contribute to the signs and symptoms of type 2B1 Charcot-Marie-Tooth disease. Emery-Dreifuss muscular dystrophy More than 100 mutations in the LMNA gene have been identified in people with Emery-Dreifuss muscular dystrophy, a condition characterized by weakness of the muscles used for movement (skeletal muscles) and the heart (cardiac) muscle. Most of these mutations change single amino acids in lamins A and C, which alters the structure of these proteins. The effect of LMNA mutations within cells remains unclear. Abnormal versions of lamins A and C may alter the activity of certain genes or weaken the structure of the nucleus, making cells more fragile. Researchers continue to investigate how LMNA mutations affect skeletal muscles and cardiac muscle, leading to the characteristic features of Emery-Dreifuss muscular dystrophy. familial dilated cardiomyopathy Genetics Home Reference provides information about familial dilated cardiomyopathy. Hutchinson-Gilford progeria syndrome A specific mutation in the LMNA gene has been found in most patients with Hutchinson-Gilford progeria syndrome, which is a condition that causes the dramatic, rapid appearance of aging beginning in childhood. This mutation changes a single DNA building block (nucleotide) in the gene. Specifically, the mutation replaces the nucleotide cytosine with the nucleotide thymine at position 1824 (written as C1824T). This mutation is also sometimes noted as Gly608Gly or G608G, which refers to the position in the lamin A protein affected by the mutation. The C1824T mutation leads to an abnormal version of the lamin A protein called progerin, which is missing 50 amino acids near one end. The location of this mutation does not affect the production of lamin C. Other mutations in the LMNA gene have been identified in a small number of people with the features of Hutchinson-Gilford progeria syndrome. The mutations responsible for this disorder result in an abnormal version of lamin A that cannot be processed correctly within the cell. When the altered protein is incorporated into the lamina, it can disrupt the shape of the nuclear envelope. Over time, a buildup of this altered protein appears to damage the structure and function of the nucleus, making cells more likely to die prematurely. Researchers are working to determine how these changes lead to the signs and symptoms of Hutchinson-Gilford progeria syndrome. limb-girdle muscular dystrophy At least six mutations in the LMNA gene have been identified in people with limb-girdle muscular dystrophy type 1B. Limb-girdle muscular dystrophy is a group of related disorders characterized by muscle weakness and wasting, particularly in the shoulders, hips, and limbs. LMNA gene mutations that cause limb-girdle muscular dystrophy may impair the function of lamin proteins. Impaired lamin protein function may lead to a fragile, easily-damaged cell nucleus or improperly regulated genes that affect a variety of cell activities. It is not known how the effects of LMNA gene mutations relate to the specific signs and symptoms of limb-girdle muscular dystrophy. mandibuloacral dysplasia At least four mutations in the LMNA gene cause a form of mandibuloacral dysplasia called mandibuloacral dysplasia with type A lipodystrophy (MADA). This condition is characterized by a variety of signs and symptoms, which can include bone abnormalities; mottled or patchy skin coloring; and loss of fatty tissue under the skin, particularly affecting the limbs (type A lipodystrophy). The LMNA gene mutations that cause this condition change single protein building blocks (amino acids) in the lamin A and lamin C proteins. The most common mutation replaces the amino acid arginine at position 527 with the amino acid histidine (written as Arg527His or R527H). The effects of LMNA gene mutations are not well understood. The amino acid changes may affect the structure of the lamin A or lamin C protein or both and alter how they interact with other proteins in the nuclear lamina. Some researchers speculate that these changes disrupt the nuclear envelope, making cells more fragile; however, it is unclear how the altered lamin proteins contribute to the signs and symptoms of MADA. other disorders Mutations in the LMNA gene have been found to cause several other inherited conditions. Because the conditions result from mutations that affect lamin proteins, they are known as laminopathies. Familial dilated cardiomyopathy with conduction defects has severe effects on cardiac muscle that result in life-threatening heart problems. The features of this disorder, and also those of limb-girdle muscular dystrophy type 1B, overlap with those of the autosomal dominant form of Emery-Dreifuss muscular dystrophy. Because certain LMNA mutations may be responsible for any of these conditions, researchers suspect that limb-girdle muscular dystrophy type 1B and familial dilated cardiomyopathy with conduction defects may be variants of Emery-Dreifuss muscular dystrophy instead of separate disorders. As in mandibuloacral dysplasia (described above), laminopathies can affect the amount and distribution of fat in the body. Dunnigan-type partial lipodystrophy is characterized by a loss of fatty tissue from the torso and limbs and a buildup of fat around the neck and shoulders. Mutations in the LMNA gene also cause atypical progeroid syndrome (APS); the features of this condition are similar to those of Hutchinson-Gilford progeria syndrome and mandibuloacral dysplasia (described above). As in Hutchinson-Gilford progeria syndrome, children with APS look as though they are aging prematurely, although the signs and symptoms of APS usually begin slightly later in life. APS can also cause similar abnormalities in bone development and fat distribution as mandibuloacral dysplasia, although they are typically milder in APS. Mutations in the LMNA gene have been identified in newborns with a disorder called lethal restrictive dermopathy. Infants with this disorder have tight, rigid skin; underdeveloped lungs; and other abnormalities. They do not usually survive past the first week of life. Researchers have not determined how mutations in the LMNA gene result in this diverse group of disorders, but the multiple roles of the nuclear lamina in cells may help explain the wide variety of signs and symptoms.
The LMNA gene provides instructions for making several slightly different proteins called lamins. The two major proteins produced from this gene, lamin A and lamin C, are made in most of the body's cells. These proteins have a nearly identical sequence of protein building blocks (amino acids). The small difference in the sequence makes lamin A longer than lamin C. Lamins A and C are structural proteins called intermediate filament proteins. Intermediate filaments provide stability and strength to cells. Lamins A and C are scaffolding (supporting) components of the nuclear envelope, which is a structure that surrounds the nucleus in cells. Specifically, these proteins are located in the nuclear lamina, a mesh-like layer of intermediate filaments and other proteins that is attached to the inner membrane of the nuclear envelope. The nuclear envelope regulates the movement of molecules into and out of the nucleus, and researchers believe it may play a role in regulating the activity (expression) of certain genes. The lamin A protein must be processed within the cell before becoming part of the lamina. Its initial form, called prelamin A, undergoes a complex series of steps that are necessary for the protein to be inserted into the lamina. Lamin C does not have to undergo this processing before becoming part of the lamina.
Conditions with Increased Gene Activity
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Conditions with Decreased Gene Activity
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The following transcription factors affect gene expression:
In the arteries, prelamin-A/C accumulation is not observed in young healthy vessels but is prevalent in medial vascular smooth muscle cells (VSMCs) from aged individuals and in atherosclerotic lesions, where it often colocalizes with senescent and degenerate VSMCs. Prelamin-A/C expression increases with age and disease. In normal aging, the accumulation of prelamin-A/C is caused in part by the down-regulation of ZMPSTE24/FACE1 in response to oxidative stress.
- Mitotic Nuclear Envelope Disassembly
- Mitotic Nuclear Envelope Reassembly
- Muscle Organ Development
- Response To Mechanical Stimulus
- Regulation Of Cell Migration
- Establishment Or Maintenance Of Microtubule Cytoskeleton Polarity
- Protein Localization To Nucleus
- Sterol Regulatory Element Binding Protein Import Into Nucleus
- Ire1-Mediated Unfolded Protein Response
- Positive Regulation Of Osteoblast Differentiation
- Ventricular Cardiac Muscle Cell Development
- Cellular Response To Hypoxia
- Negative Regulation Of Mesenchymal Cell Proliferation
- Negative Regulation Of Release Of Cytochrome C From Mitochondria
- Positive Regulation Of Cell Aging
- Regulation Of Protein Localization To Nucleus
- Negative Regulation Of Adipose Tissue Development
- Negative Regulation Of Extrinsic Apoptotic Signaling Pathway