Keith R. Porter Lecture, 1996. Of mice and men: genetic disorders of the cytoskeleton.

Fuchs, Elaine

doi:10.1091/mbc.8.2.189

Cited by 92 publications

(52 citation statements)

References 113 publications

(136 reference statements)

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“…7B). The ⌬C⌬coil mutant protein, in agreement with data from previous studies (5,6,8), provokes the collapse of the endogenous keratin cytoskeleton similarly to mutated keratins found in epithelial fragility diseases (3,5,6,15).…”

Section: K10-induced Inhibition Of Cell Proliferation Requires a Funcsupporting

confidence: 90%

Modulation of Cell Proliferation by Cytokeratins K10 and K16

Paramio

Casanova

Segrelles

et al. 1999

Molecular and Cellular Biology

162

160

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The members of the large keratin family of cytoskeletal proteins are expressed in a carefully regulated tissueand differentiation-specific manner. Although these proteins are thought to be involved in imparting mechanical integrity to epithelial cells, the functional significance of their complex differential expression is still unclear. Here we provide new data suggesting that the expression of particular keratins may influence cell proliferation. Specifically, we demonstrate that the ectopic expression of K10 inhibits the proliferation of human keratinocytes in culture, while K16 expression appears to promote the proliferation of these cells. Other keratins, such as K13 or K14, do not significantly alter this parameter. K10-induced inhibition is reversed by the coexpression of K16 but not that of K14. These results are coherent with the observed expression pattern of these proteins in the epidermis: basal, proliferative keratinocytes express K14; when they terminally differentiate, keratinocytes switch off K14 and start K10 expression, whereas in response to hyperproliferative stimuli, K16 replaces K10. The characteristics of this process indicate that K10 and K16 act on the retinoblastoma (Rb) pathway, as (i) K10-induced inhibition is hampered by cotransfection with viral oncoproteins which interfere with pRb but not with p53; (ii) K10-mediated cell growth arrest is rescued by the coexpression of specific cyclins, cyclindependent kinases (CDKs), or cyclin-CDK complexes; (iii) K10-induced inhibition does not take place in Rbdeficient cells but is restored in these cells by cotransfection with pRb or p107 but not p130; (iv) K16 efficiently rescues the cell growth arrest induced by pRb in HaCaT cells but not that induced by p107 or p130; and (v) pRb phosphorylation and cyclin D1 expression are reduced in K10-transfected cells and increased in K16-transfected cells. Finally, using K10 deletion mutants, we map this inhibitory function to the nonhelical terminal domains of K10, hypervariable regions in which keratin-specific functions are thought to reside, and demonstrate that the presence of one of these domains is sufficient to promote cell growth arrest.Keratins are a large family of proteins which form the intermediate filament (IF) cytoskeleton of epithelial cells and their appendages, hairs and nails (reviewed in references 8 and 15). These proteins are subdivided according to biochemical criteria into two subfamilies: type I, or acidic keratins, and type II, or neutral-basic keratins. This division also has important structural and functional implications, since to build up a wellorganized IF cytoskeleton, tetramers containing equimolar amounts of each keratin subtype are required. Like all IF proteins, keratins consist of a central ␣-helical rod domain responsible for dimerization and higher-order polymerization. The rod domain is flanked by globular head (amino) and tail (carboxyl) domains, the functions of which are still unclear. Variations in these nonhelical end domains largely account for the differe...

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Section: K10-induced Inhibition Of Cell Proliferation Requires a Funcsupporting

confidence: 90%

Modulation of Cell Proliferation by Cytokeratins K10 and K16

Paramio

Casanova

Segrelles

et al. 1999

Molecular and Cellular Biology

162

160

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“…This theory is supported by the epidermolysis bullosa simplex skin disease, which harbors a K14 mutation inducing impairment of keratin filament formation, with consequent signs of cytolysis and/or degeneration in the basal layers of the skin. These degenerated ''vacuole''-like structures 4 resemble the vacuoles we observed in mK8Ϫ/Ϫ and F22 MC-LR-treated mice. In transgenic mice that express K14 in the liver with consequent hepatocyte IF disruption, inflammatory infiltration, ballooning degeneration, increased fat-containing vacuoles, and glycogen accumulation were also observed.…”

Section: Keratin 8/18 Filament Assembly Is Regulated By Serine/threoninesupporting

confidence: 73%

“…1,2 There is significant evidence for the structural importance of epidermal keratins, 3 a functional role that is well illustrated by a number of severe skin and corneal diseases associated with keratin mutations. [4][5][6] Keratins participate in attachment to basement membranes as well as in intercellular contacts, by interacting with specific desmosomal and hemidesmosomal proteins. 3 Furthermore, there are indications that they could be linked to microfilaments (MFs) and microtubules (MTs), 3,[7][8][9] and may be of importance for intracellular organization.…”

mentioning

confidence: 99%

Protein phosphatase inhibition in normal and keratin 8/18 assembly-incompetent mouse strains supports a functional role of keratin intermediate filaments in preserving hepatocyte integrity

Toivola

Omary

et al. 1998

Hepatology

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The function and regulation of keratin 8 (K8) and 18 (K18), intermediate filament (IF) proteins of the liver, are not fully understood. We employed the liver damage induced by microcystin-LR (MC-LR), a liver-specific inhibitor of type-1 and type-2A protein phosphatases, in normal and in keratin assembly-incompetent mouse strains as a model to elucidate the roles of IF phosphorylation in situ. The mouse strains used were wild-type (wt) mice and mice with abnormal filament assembly, caused by a targeted null mutation of the K8 gene or caused by expression of a point-mutated dominant negative human K18. In vivo 32 P-labeled wt mice, subsequently injected with a lethal dose of MC-LR, showed hyperphosphorylation, disassembly, and reorganization of K8/K18, in particular K18, indicating high phosphate turnover on liver keratins in situ. At lethal doses, the keratin assembly-incompetent mice displayed liver lesions faster than wt mice, as indicated histopathologically and by liver-specific plasma enzyme elevations. The histological changes included centrilobular hemorrhage in all mouse strains. The assembly-incompetent mice showed a marked vacuolization of periportal hepatocytes. Indistinguishable MC-LR-induced reorganization of microfilaments was observed in all mice, indicating that this effect on microfilaments is not dependent on the presence of functional K8/K18 networks. At sublethal doses of MC-LR, all animals had the same potential to recover from the liver damage. Our study shows that K8/K18 filament assembly is regulated in vivo by serine phosphorylation. The absence or occurrence of defective K8/K18 filaments render animals more prone to liver damage, which supports the previously suggested roles of keratin IFs in maintenance of structural integrity. (HEPATOLOGY 1998;28: 116-128.)The intermediate filament (IF) proteins of hepatocytes consist of the simple epithelial IFs, keratin 8 (K8; type II) and keratin 18 (K18; type I). K8 and K18 form obligate heteropolymers assembling into complex filamentous networks spanning the hepatocyte cytoplasm.

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“…12 K18 arg89 is a highly conserved site among keratins and a frequently mutated amino acid in several severe human skin diseases. 4 K18C mice with this dominant-negative mutation develop mild chronic hepatitis and markedly fragile hepatocytes in association with K8/18 filament disruption. 12 K18C mouse hepatocytes have disrupted keratin IFs and increased K8/18 phosphorylation and glycosylation.…”

mentioning

confidence: 99%

“…1,2 Characteristic for keratins is that they are obligate heteropolymers, so that at least one type I and one type II keratin are needed for filament formation. [2][3][4][5][6] In hepatocytes, the IFs are composed of K8/18 filaments that form a pericanalicular sheet supporting the bile canaliculus 7,8 and a cytoplasmic network of filaments maintaining the integrity of hepatocytes. 5,7,9 In mouse pancreas, there are two distinct pools of keratin IFs: a cytoplasmic network consisting of K8/18 and an apicolateral band-like network consisting of K8/18/19.…”

mentioning

confidence: 99%

Disturbances in hepatic cell-cycle regulation in mice with assembly-deficient keratins 8/18

et al. 2001

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Simple epithelial tissues such as liver and pancreas express keratins 8 (K8) and 18 (K18) as their major intermediate filament proteins. K8 and K18 null mice and transgenic mice that express mutant K18 (K18C) manifest several hepatocyte abnormalities and demonstrate that K8/18 are important in maintaining liver tissue and cell integrity, although other potential functions remain uncharacterized. Here, we report an additional abnormal liver phenotype, which is similar in K8 null, K18 null, and K18C mouse models. Liver histologic examination showed large polynuclear areas that lacked cell membranes, desmosomal structures, and filamentous actin. Similar, but less prominent, areas were observed in the pancreas. The parenchyma outside the polynuclear areas displayed irregular sinusoidal structures and markedly enlarged nuclei. Most K8 null hepatocytes were positive for the proliferating cell nuclear antigen (PCNA) with a doubled DNA content in comparison with the predominantly PCNA-negative wild-type hepatocytes. The distribution of the 14-3-3 protein was also altered in K8 null mice. Taken together, our results indicate that absence of keratin filaments causes disturbances in cellcycle regulation, driving cells into the S-G2 phase and causing aberrant cytokinesis. These effects could stem from disturbed functions of K8/18-dependent cell-cycle regulators, such as the signaling integrator, 14-3-3. (HEPATOLOGY 2001; 34:1174-1183

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Keith R. Porter Lecture, 1996. Of mice and men: genetic disorders of the cytoskeleton.

Cited by 92 publications

References 113 publications

Modulation of Cell Proliferation by Cytokeratins K10 and K16

Modulation of Cell Proliferation by Cytokeratins K10 and K16

Protein phosphatase inhibition in normal and keratin 8/18 assembly-incompetent mouse strains supports a functional role of keratin intermediate filaments in preserving hepatocyte integrity

Disturbances in hepatic cell-cycle regulation in mice with assembly-deficient keratins 8/18

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