Plectin
Intermediate Filament Proteins
Hemidesmosomes
Epidermolysis Bullosa Simplex
Intermediate Filaments
Integrin beta4
Epidermolysis Bullosa
Vimentin
Integrin alpha6beta4
Desmosomes
Plectin is a linker of intermediate filaments to Z-discs in skeletal muscle fibers. (1/133)
Plectin is a versatile linker protein which is associated with various types of cytoskeletal components and/or filaments including intermediate filaments, and its deficiency causes the disruption of myofibrils, or muscular dystrophy. To better understand the functional role of plectin in skeletal muscle fibers, we have examined the topological and structural relationships of plectin to intermediate filaments and Z-discs in rat diaphragm muscles by confocal and immunoelectron microscopy. Immunofluorescence analysis revealed that plectin was colocalized with desmin at the periphery of Z-discs. This plectin localization around Z-discs was constantly maintained irrespective of the contracted or extended state of the muscle fibers, suggesting either direct or indirect association of plectin with Z-discs. Immunogold labeling in skinned muscle fibers clearly demonstrated that plectin-labeled fine threads linked desmin intermediate filaments to Z-discs and connected intermediate filaments to each other. These results indicate that through plectin threads desmin intermediate filaments form lateral linkages among adjacent Z-discs, preventing individual myofibrils from disruptive contraction and ensuring effective force generation. (+info)Plectin is concentrated at intercellular junctions and at the nuclear surface in morphologically differentiated rat Sertoli cells. (2/133)
Intermediate filaments in Sertoli cells have a well-defined pattern of distribution. They form a basally situated perinuclear network from which filaments extend peripherally to adhesion plaques at the plasma membrane and to sites of codistribution with other major elements of the cytoskeleton, particularly with microtubules. Although the general pattern of intermediate filament distribution is known, the molecular components involved with linking the filaments to organelles and attachment plaques in these cells have not been identified. One candidate for such a linking element is plectin. In this study we test for the presence of, and determine the distribution of, plectin in Sertoli cells of the rat testis. Fixed frozen sections and fixed epithelial fragments of rat testis were probed for plectin and vimentin using antibodies. Tissue was evaluated using standard fluorescence microscopy and confocal microscopy. Plectin in Sertoli cells was concentrated in a narrow zone surrounding the nucleus, and at focal sites, presumably desmosome-like plaques, at interfaces with adjacent cells. Plectin was also concentrated at sites where intermediate filament bundles project into specialized actin-filament containing plaques at sites of attachment to elongate spermatids. Plectin in Sertoli cells is concentrated at the nuclear surface and in junction plaques associated with the plasma membrane. The pattern of distribution is consistent with plectin being involved with linking intermediate filaments centrally (basally) to the nucleus and peripherally to intercellular attachment sites. (+info)Structure and function of hemidesmosomes: more than simple adhesion complexes. (3/133)
The attachment of cells to the extracellular matrix is of crucial importance in the maintenance of tissue structure and integrity. In stratified epithelia such as in skin as well as in other complex epithelia multiprotein complexes called hemidesmosomes are involved in promoting the adhesion of epithelial cells to the underlying basement membrane. In the past few years our understanding of the role of hemidesmosomes has improved considerably. Their importance has become apparent in clinical conditions, in which absence or defects of hemidesmosomal proteins result in devastating blistering diseases of the skin. Molecular genetic studies have increased our knowledge of the function of the various components of hemidesmosomes and enabled the characterization of protein-protein interactions involved in their assembly. It has become clear that the alpha6beta4 integrin, a major component of hemidesmosomes, is able to transduce signals from the extracellular matrix to the interior of the cell, that critically modulate the organization of the cytoskeleton, proliferation, apoptosis, and differentiation. Nevertheless, our knowledge of the mechanisms regulating the functional state of hemidesmosomes and, hence, the dynamics of cell adhesion, a process of crucial importance in development, wound healing or tumor invasion, remains limited. The aims of this review are to highlight the recent progresses of our knowledge on the organization and assembly of hemidesmosomes, their involvement in signaling pathways as well as their participation in clinical pathologic conditions. (+info)Binding of integrin alpha6beta4 to plectin prevents plectin association with F-actin but does not interfere with intermediate filament binding. (4/133)
Hemidesmosomes are stable adhesion complexes in basal epithelial cells that provide a link between the intermediate filament network and the extracellular matrix. We have investigated the recruitment of plectin into hemidesmosomes by the alpha6beta4 integrin and have shown that the cytoplasmic domain of the beta4 subunit associates with an NH(2)-terminal fragment of plectin that contains the actin-binding domain (ABD). When expressed in immortalized plectin-deficient keratinocytes from human patients with epidermol- ysis bullosa (EB) simplex with muscular dystrophy (MD-EBS), this fragment is colocalized with alpha6beta4 in basal hemidesmosome-like clusters or associated with F-actin in stress fibers or focal contacts. We used a yeast two-hybrid binding assay in combination with an in vitro dot blot overlay assay to demonstrate that beta4 interacts directly with plectin, and identified a major plectin-binding site on the second fibronectin type III repeat of the beta4 cytoplasmic domain. Mapping of the beta4 and actin-binding sites on plectin showed that the binding sites overlap and are both located in the plectin ABD. Using an in vitro competition assay, we could show that beta4 can compete out the plectin ABD fragment from its association with F-actin. The ability of beta4 to prevent binding of F-actin to plectin explains why F-actin has never been found in association with hemidesmosomes, and provides a molecular mechanism for a switch in plectin localization from actin filaments to basal intermediate filament-anchoring hemidesmosomes when beta4 is expressed. Finally, by mapping of the COOH-terminally located binding site for several different intermediate filament proteins on plectin using yeast two-hybrid assays and cell transfection experiments with MD-EBS keratinocytes, we confirm that plectin interacts with different cytoskeletal networks. (+info)Unusual 5' transcript complexity of plectin isoforms: novel tissue-specific exons modulate actin binding activity. (5/133)
Plectin, the most versatile cytolinker identified to date, has essential functions in maintaining the mechanical integrity of skin, skeletal muscle and heart, as indicated by analyses of plectin-deficient mice and humans. Expression of plectin in a vast variety of tissues and cell types, combined with a large number of different binding partners identified at the molecular level, calls for complex mechanisms regulating gene transcription and expression of the protein. To investigate these mechanisms, we analyzed the transcript diversity and genomic organization of the murine plectin gene and found a remarkable complexity of its 5'-end structure. An unusually high number of 14 alternatively spliced exons, 11 of them directly splicing into plectin exon 2, were identified. Analysis of their tissue distribution revealed that expression of a few of them is restricted to tissues such as brain, or skeletal muscle and heart. In addition, we found two short exons tissue-specifically spliced into a highly conserved set of exons encoding the N-terminal actin binding domain (ABD), common to plectin and the superfamily of spectrin/dystrophin-type actin binding proteins. Using recombinant proteins we show that a novel ABD version contained in the muscle-specific isoform of plectin exhibits significantly higher actin binding activity than other splice forms. This fine tuning mechanism based on alternative splicing is likely to optimize the proposed biological role of plectin as a cytolinker opposing intense mechanical forces in tissues like striated muscle. (+info)Cytoskeletal linkers: new MAPs for old destinations. (6/133)
A new isoform of the actin-neurofilament linker protein BPAG has been found that binds to and stabilizes axonal microtubules. This and other newly identified microtubule-associated proteins are likely to be just the tip of an iceberg of multifunctional proteins that stabilize and crosslink cytoskeletal filament networks. (+info)Identification of the hemidesmosomal 500 kDa protein (HD1) as plectin. (7/133)
HD1 is a 500 kDa hemidesmosomal plaque protein recognized by monoclonal antibody mAb-121. Recent research on inherited skin disease has suggested that it might be identical to plectin or an isoform. To cast light on this question, we have prepared several monoclonal antibodies that recognize a 500 kDa protein in the hemidesmosome fraction. Unexpectedly, some staining pattern heterogeneity was observed on immunofluorescence microscopy. Attention was focused on two monoclonal antibodies which gave different localization in bovine skin and retinal pigment epithelial cells. Determination of the amino-terminal sequence of an antigenic 100 kDa polypeptide fragment derived from the 500 kDa component of an insoluble fraction of bovine hepatocytes revealed it was identical to that of plectin. Using the two antibodies, we screened a cDNA library derived from BMGE+H, a bovine mammary gland epithelial cell line. The isolated cDNA clones corresponded to the rod domain of bovine plectin, with two separate epitope regions for each of the antibodies. From these results we conclude that the hemidesmosomal 500 kDa component HD1 is identical to plectin. As judged on rough estimation of molar ratios on this basis, hemidesmosomes are composed of plectin, BP230, the integrin beta4 subunit, and alpha6 in a 1:1:1:1 ratio. (+info)Dose-dependent linkage, assembly inhibition and disassembly of vimentin and cytokeratin 5/14 filaments through plectin's intermediate filament-binding domain. (8/133)
Plectin, the largest and most versatile member of the cytolinker/plakin family of proteins characterized to date, has a tripartite structure comprising a central 200 nm-long (&agr;)-helical rod domain flanked by large globular domains. The C-terminal domain comprises a short tail region preceded by six highly conserved repeats (each 28-39 kDa), one of which (repeat 5) contains plectin's intermediate filament (IF)-binding site. We used recombinant and native proteins to assess the effects of plectin repeat 5-binding to IF proteins of different types. Quantitative Eu(3+)-based overlay assays showed that plectin's repeat 5 domain bound to type III IF proteins (vimentin) with preference over type I and II cytokeratins 5 and 14. The ability of both types of IF proteins to self-assemble into filaments in vitro was impaired by plectin's repeat 5 domain in a concentration-dependent manner, as revealed by negative staining and rotary shadowing electron microscopy. This effect was much more pronounced in the case of vimentin compared to cytokeratins 5/14. Preassembled filaments of both types became more and more crosslinked upon incubation with increasing concentrations of plectin repeat 5. However, at high proportions of plectin to IF proteins, disassembly of filaments occurred. Again, vimentin filaments proved considerably more sensitive towards disassembly than those composed of cytokeratins 5 and 14. In general, IFs formed from recombinant proteins were found to be slightly more responsive towards plectin influences than their native counterparts. A dose-dependent plectin-inflicted collapse and putative disruption of IFs was also observed in vivo after ectopic expression of vimentin and plectin's repeat 5 domain in cotransfected vimentin-deficient SW13 (vim(-)) cells. Our results suggest an involvement of plectin not only in crosslinking and stabilization of cytoskeletal IF networks, but also in regulation of their dynamics. (+info)Plectin is a large cytolinker protein that plays a crucial role in the structural organization and stability of the cell. It has the ability to interact with various components of the cytoskeleton, including intermediate filaments, microtubules, and actin filaments, thereby providing a critical link between these structures. Plectin is widely expressed in many tissues and is involved in maintaining the integrity and functionality of cells under both physiological and pathological conditions. Mutations in the gene encoding plectin have been associated with several human diseases, including epidermolysis bullosa, muscular dystrophy, and neuropathies.
Intermediate filament proteins (IFPs) are a type of cytoskeletal protein that form the intermediate filaments (IFs), which are one of the three major components of the cytoskeleton in eukaryotic cells, along with microtubules and microfilaments. These proteins have a unique structure, characterized by an alpha-helical rod domain flanked by non-helical head and tail domains.
Intermediate filament proteins are classified into six major types based on their amino acid sequence: Type I (acidic) and Type II (basic) keratins, Type III (desmin, vimentin, glial fibrillary acidic protein, and peripherin), Type IV (neurofilaments), Type V (lamins), and Type VI (nestin). Each type of IFP has a distinct pattern of expression in different tissues and cell types.
Intermediate filament proteins play important roles in maintaining the structural integrity and mechanical strength of cells, providing resilience to mechanical stress, and regulating various cellular processes such as cell division, migration, and signal transduction. Mutations in IFP genes have been associated with several human diseases, including cancer, neurodegenerative disorders, and genetic skin fragility disorders.
Hemidesmosomes are specialized structures found in the cell membranes of epithelial cells that help to anchor them to the underlying basement membrane. They are composed of several proteins, including integrins and collagen type XVII, which interact with both intracellular keratin filaments and extracellular matrix components such as laminin-332. Hemidesmosomes play a crucial role in maintaining the integrity and stability of epithelial tissues by providing strong adhesive bonds between the epithelial cells and the underlying basement membrane, which is essential for normal tissue function and homeostasis. Mutations in genes encoding hemidesmosomal proteins can lead to various inherited skin blistering disorders, such as epidermolysis bullosa.
Epidermolysis Bullosa Simplex (EBS) is a group of genetic skin disorders characterized by the development of blisters and erosions on the skin following minor trauma or friction. It is caused by mutations in genes that encode proteins responsible for anchoring the epidermis (outer layer of the skin) to the dermis (inner layer of the skin).
There are several subtypes of EBS, which vary in severity and clinical presentation. The most common form is called "Dowling-Meara" EBS, which is characterized by blistering at or near birth, widespread blistering, and scarring. Other forms of EBS include "Weber-Cockayne" EBS, which is characterized by localized blistering and healing with minimal scarring, and "Kobner" EBS, which is characterized by blistering in response to heat or physical trauma.
Treatment for EBS typically involves wound care, prevention of infection, and pain management. In some cases, protein therapy or bone marrow transplantation may be considered as a treatment option. It's important to note that the prognosis for individuals with EBS varies depending on the severity and subtype of the disorder.
Intermediate filaments (IFs) are a type of cytoskeletal filament found in the cytoplasm of eukaryotic cells, including animal cells. They are called "intermediate" because they are smaller in diameter than microfilaments and larger than microtubules, two other types of cytoskeletal structures.
Intermediate filaments are composed of fibrous proteins that form long, unbranched, and flexible filaments. These filaments provide structural support to the cell and help maintain its shape. They also play a role in cell-to-cell adhesion, intracellular transport, and protection against mechanical stress.
Intermediate filaments are classified into six types based on their protein composition: Type I (acidic keratins), Type II (neutral/basic keratins), Type III (vimentin, desmin, peripherin), Type IV (neurofilaments), Type V (lamins), and Type VI (nestin). Each type of intermediate filament has a specific function and is expressed in different cell types. For example, Type I and II keratins are found in epithelial cells, while vimentin is expressed in mesenchymal cells.
Overall, intermediate filaments play an essential role in maintaining the structural integrity of cells and tissues, and their dysfunction has been implicated in various human diseases, including cancer, neurodegenerative disorders, and genetic disorders.
Integrin beta4, also known as ITGB4 or CD104, is a type of integrin subunit that forms part of the integrin receptor along with an alpha subunit. Integrins are transmembrane proteins involved in cell-cell and cell-extracellular matrix (ECM) adhesion, signal transduction, and regulation of various cellular processes such as proliferation, differentiation, and migration.
Integrin beta4 is unique among the integrin subunits because it has a large cytoplasmic domain that can interact with several intracellular signaling molecules, making it an important regulator of cell behavior. Integrin beta4 is widely expressed in various tissues, including epithelial cells, endothelial cells, and hematopoietic cells.
Integrin beta4 forms heterodimers with integrin alpha6 to form the receptor for laminins, which are major components of the basement membrane. This receptor is involved in maintaining the integrity of epithelial tissues and regulating cell migration during development, tissue repair, and cancer progression. Mutations in ITGB4 have been associated with several human diseases, including epidermolysis bullosa, a group of inherited skin disorders characterized by fragile skin and blistering.
Epidermolysis Bullosa (EB) is a group of rare inherited skin disorders that are characterized by the development of blisters, erosions, and scarring following minor trauma or friction. The condition results from a genetic defect that affects the structural proteins responsible for anchoring the epidermis (outer layer of the skin) to the dermis (inner layer of the skin).
There are several types of EB, which vary in severity and clinical presentation. These include:
1. Epidermolysis Bullosa Simplex (EBS): This is the most common form of EB, and it typically affects the skin's superficial layers. Blistering tends to occur after minor trauma or friction, and healing usually occurs without scarring. There are several subtypes of EBS, which vary in severity.
2. Junctional Epidermolysis Bullosa (JEB): This form of EB affects the deeper layers of the skin, and blistering can occur spontaneously or following minor trauma. Healing often results in scarring, and affected individuals may also experience nail loss, dental abnormalities, and fragile mucous membranes.
3. Dystrophic Epidermolysis Bullosa (DEB): DEB affects the deeper layers of the skin, and blistering can lead to significant scarring, contractures, and fusion of fingers and toes. There are two main subtypes of DEB: recessive DEB (RDEB), which is more severe and associated with a higher risk of skin cancer, and dominant DEB (DDEB), which tends to be milder.
4. Kindler Syndrome: This is a rare form of EB that affects both the epidermis and dermis. Blistering can occur spontaneously or following minor trauma, and affected individuals may experience photosensitivity, poikiloderma (a mottled skin appearance), and oral and gastrointestinal abnormalities.
Treatment for EB typically focuses on managing symptoms, preventing blister formation and infection, and promoting wound healing. There is currently no cure for EB, but research is ongoing to develop new therapies and treatments.
Vimentin is a type III intermediate filament protein that is expressed in various cell types, including mesenchymal cells, endothelial cells, and hematopoietic cells. It plays a crucial role in maintaining cell structure and integrity by forming part of the cytoskeleton. Vimentin is also involved in various cellular processes such as cell division, motility, and intracellular transport.
In addition to its structural functions, vimentin has been identified as a marker for epithelial-mesenchymal transition (EMT), a process that occurs during embryonic development and cancer metastasis. During EMT, epithelial cells lose their polarity and cell-cell adhesion properties and acquire mesenchymal characteristics, including increased migratory capacity and invasiveness. Vimentin expression is upregulated during EMT, making it a potential target for therapeutic intervention in cancer.
In diagnostic pathology, vimentin immunostaining is used to identify mesenchymal cells and to distinguish them from epithelial cells. It can also be used to diagnose certain types of sarcomas and carcinomas that express vimentin.
Integrin α6β4 is a type of cell surface receptor that is composed of two subunits, α6 and β4. It is also known as CD49f/CD104. This integrin is primarily expressed in epithelial cells and plays important roles in cell adhesion, migration, and signal transduction.
Integrin α6β4 specifically binds to laminin-332 (also known as laminin-5), a component of the basement membrane, and forms a stable anchorage complex that links the cytoskeleton to the extracellular matrix. This interaction is critical for maintaining the integrity of epithelial tissues and regulating cell behavior during processes such as wound healing and tissue regeneration.
Mutations in the genes encoding integrin α6β4 have been associated with various human diseases, including epidermolysis bullosa, a group of inherited skin disorders characterized by fragile skin and blistering. Additionally, integrin α6β4 has been implicated in cancer progression and metastasis, as its expression is often upregulated in tumor cells and contributes to their invasive behavior.
Desmosomes are specialized intercellular junctions that provide strong adhesion between adjacent epithelial cells and help maintain the structural integrity and stability of tissues. They are composed of several proteins, including desmoplakin, plakoglobin, and cadherins, which form complex structures that anchor intermediate filaments (such as keratin) to the cell membrane. This creates a network of interconnected cells that can withstand mechanical stresses. Desmosomes are particularly abundant in tissues subjected to high levels of tension, such as the skin and heart.
A blister is a small fluid-filled bubble that forms on the skin due to friction, burns, or contact with certain chemicals or irritants. Blisters are typically filled with a clear fluid called serum, which is a component of blood. They can also be filled with blood (known as blood blisters) if the blister is caused by a more severe injury.
Blisters act as a natural protective barrier for the underlying skin and tissues, preventing infection and promoting healing. It's generally recommended to leave blisters intact and avoid breaking them, as doing so can increase the risk of infection and delay healing. If a blister is particularly large or painful, medical attention may be necessary to prevent complications.
Desmin is a type of intermediate filament protein that is primarily found in the cardiac and skeletal muscle cells, as well as in some types of smooth muscle cells. It is an important component of the cytoskeleton, which provides structural support to the cell and helps maintain its shape. Desmin plays a crucial role in maintaining the integrity of the sarcomere, which is the basic contractile unit of the muscle fiber. Mutations in the desmin gene can lead to various forms of muscular dystrophy and other inherited muscle disorders.