Intermediate filament binding

Abstract: Plectin, a 500-kDa intermediate filament binding protein, has been proposed to provide mechanical strength to cells and tissues by acting as a cross-linking element of the cytoskeleton. To set the basis for future studies on gene regulation, tissue-specific expression, and pathological conditions involving this protein, we have cloned the human plectin gene, determined its coding sequence, and established its genomic organization. The coding sequence contains 32 exons that extend over 32 kb of the human genome. Most of the introns reside within a region encoding the globular N-terminal domain of the molecule, whereas the entire central rod domain and the entire C-terminal globular domain were found to be encoded by single exons of remarkable length, >3 kb and >6 kb, respectively. Overall, the organization of the human plectin gene was strikingly similar to that of human bullous pemphigoid antigen 1 (BPAG1), confirming that both proteins belong to the same gene family. Comparison of the deduced protein sequences for human and rat plectin revealed that they were 93% identical. By using fluorescence in situ hybridization, we have mapped the plectin gene to the long arm of chromosome 8 within the telomeric region. This gene locus (8q24) has previously been implicated in the human blistering skin disease epidermolysis bullosa simplex Ogna. Detailed knowledge of the structure of the plectin gene and its chromosome localization will aid in the elucidation of whether this or any other pathological conditions are linked to alterations in the plectin gene.

Abstract: Patients with temporal lobe epilepsy (TLE) often have a shrunken hippocampus that is known to be the location in which seizures originate. The role of the sclerotic hippocampus in the causation and maintenance of seizures in temporal lobe epilepsy (TLE) has remained incompletely understood despite extensive neuropathological investigations of this substrate. To gain new insights and develop new testable hypotheses on the role of sclerosis in the pathophysiology of TLE, the differential gene expression profile was studied. To this end, DNA microarray analysis was used to compare gene expression profiles in sclerotic and non-sclerotic hippocampi surgically removed from TLE patients. Sclerotic hippocampi had transcriptional signatures that were different from non-sclerotic hippocampi. The differentially expressed gene set in sclerotic hippocampi revealed changes in several molecular signaling pathways, which included the increased expression of genes associated with astrocyte structure (glial fibrillary acidic protein, ezrin-moesin-radixin, palladin), calcium regulation (S100 calcium binding protein beta, chemokine (C-X-C motif) receptor 4) and blood-brain barrier function (Aquaaporin 4, Chemokine (C-C-motif) ligand 2, Chemokine (C-C-motif) ligand 3, Plectin 1, intermediate filament binding protein 55kDa) and inflammatory responses. Immunohistochemical localization studies show that there is altered distribution of the gene-associated proteins in astrocytes from sclerotic foci compared with non-sclerotic foci. It is hypothesized that the astrocytes in sclerotic tissue have activated molecular pathways that could lead to enhanced release of glutamate by these cells. Such glutamate release may excite surrounding neurons and elicit seizure activity.

Abstract: 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 (a)-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.