Functional endogenous LINE-1 retrotransposons are expressed and mobilized in rat chloroleukemia cells.

LINE-1 (L1) is a highly successful autonomous non-LTR retrotransposon and a major force shaping mammalian genomes. Although there are about 600 000 L1 copies covering 23% of the rat genome, full-length rat L1s (L1Rn) with intact open reading frames (ORFs) representing functional master copies for retrotransposition have not been identified yet. In conjunction with studies to elucidate the role of L1 retrotransposons in tumorigenesis, we isolated and characterized 10 different cDNAs from transcribed full-length L1Rn elements in rat chloroleukemia (RCL) cells, each encoding intact ORF1 proteins (ORF1p). We identified the first functional L1Rn retrotransposon from this pool of cDNAs, determined its activity in HeLa cells and in the RCL cell line the cDNAs originated from and demonstrate that it is mobilized in the tumor cell line in which it is expressed. Furthermore, we generated monoclonal antibodies directed against L1Rn ORF1 and ORF2-encoded recombinant proteins, analyzed the expression of L1-encoded proteins and found ORF1p predominantly in the nucleus. Our results support the hypothesis that the reported explosive amplification of genomic L1Rn sequences after their transcriptional activation in RCL cells is based on L1 retrotransposition. Therefore, L1 activity might be one cause for genomic instability observed during the progression of leukemia.

Colocalization of glial fibrillary acidic protein, metallothionein, and MHC II in human, rat, NOD/SCID, and nude mouse skin keratinocytes and fibroblasts.

The expression of glial fibrillary acidic protein (GFAP) by perivascular cells of many mammalian organs suggests an as yet unknown function of this intermediate filament protein in the maintenance of homeostasis and vascular permeability at the blood-tissue interface. Although a similar situation may exist at the air-tissue interface, the cellular distribution of GFAP in skin tissue has never been demonstrated. To approach this issue, we have employed immunofluorescence and Western blotting techniques to detect GFAP in skin sections of young and adult humans, normal rodents, and two types of mutant mice, as well as in rat lung sections, and in cultured human keratinocytes and fibroblasts. Colocalization with antigens known to be associated with GFAP in other tissues was also tested. Epidermal and hair follicle keratinocytes and dermal fibroblasts showed distinct staining for GFAP as well as colocalization with alpha-actin, metallothionein, and antigens of the class-II major histocompatibility complex (MHC II). GFAP was also identified in rat alveolar fibroblasts which, in common with keratinocytes, form part of the air-tissue interface. GFAP was upregulated together with MHC II in nude mice but was barely detectable in the skin of non-obese diabetic severe combined immunodeficiency mice, suggesting a possible involvement in antigen-presenting functions. The intriguing distribution of a common set of antigens both in certain cells of the integumentary system and at the blood-tissue interfaces of internal organs suggests the involvement of these proteins in universal mechanisms controlling tissue homeostasis and protection.

Spontaneously immortalized mouse embryo fibroblasts: growth behavior of wild-type and vimentin-deficient cells in relation to mitochondrial structure and activity.

Dependent on the presence or absence of vimentin, primary mouse embryo fibroblasts exhibit different growth characteristics in vitro. While most Vim(+/+) fibroblasts stop dividing and die via apoptosis, a substantial fraction of cells immortalize and proliferate almost normally. Vim(-/-) fibroblasts cease to divide earlier, immortalize in vanishingly small numbers and thereafter proliferate extremely slowly. Early after immortalization, Vim(+/+) (imm) fibroblasts appear structurally almost normal, whereas Vim(-/-) (imm) fibroblasts equal postmitotic "crisis" cells, which are characterized by increased cell size, altered cell ultrastructure, nuclear enlargement, genome destabilization, structural degeneration of mitochondria, and diminution of mitochondrial respiratory activity. The differences between immortalized Vim(+/+) (imm) and Vim(-/-) (imm) fibroblasts persist during early cell cloning but disappear during serial subcultivation. At high cell passage, cloned, immortalized vim(-) fibroblasts grow nearly as fast as their cloned vim(+) counterparts, and also resemble them in size, ultrastructure, nuclear volume, and mitochondrial complement; they very likely employ redundancy to cope with the loss of vimentin function when adjusting structure and behavior to that of immortalized vim(+) fibroblasts. Reduction in nuclear size occurs via release of large amounts of filamentous chromatin into extracellular space; because it is complexed with extracellular matrix proteins, it tends to form clusters and to tightly stick to the surface of other cells, thus providing a potential for horizontal gene transfer. On the other hand, cloned vim(+) and vim(-) fibroblasts are equal in showing contact inhibition at young age and becoming anchorage-independent during serial subcultivation, as indicated by the formation of multilayered and -faceted cell sheets and huge spheroids on top of or in soft agar. With this, immortalized vim(-) fibroblasts reduce their adhesiveness to the substratum which, in their precrisis state and early after cloning, is much higher than that of their vim(+) counterparts. In addition, the coupling between the mitochondrial respiratory chain and oxidative phosphorylation is stronger in vim(+) than vim(-) fibroblasts. It appears from these data that after explantation of fibroblasts from the mouse embryo the primary cause of cell and mitochondrial degeneration, including genomic instability, is the mitochondrial production of reactive oxygen species in a vicious circle, and that vimentin provides partial protection from oxidative damage. As a matrix protein with specific in vitro and in vivo affinities for nuclear and mitochondrial, recombinogenic DNA, it may exert this effect preferentially at the genome level via its influence on recombination and repair processes, and in this way also assist the cells in immortalizing. Additional protection of mitochondria by vimentin may occur at the level of mitochondrial fatty acid metabolism.

Stability and association with the cytomatrix of mitochondrial DNA in spontaneously immortalized mouse embryo fibroblasts containing or lacking the intermediate filament protein vimentin.

To extend previous observations demonstrating differences in number, morphology, and activity of mitochondria in spontaneously immortalized vim(+) and vim(-) fibroblasts derived from wild-type and vimentin knockout mice, some structural and functional aspects of mitochondrial genome performance and integrity in both types of cells were investigated. Primary Vim(+/+) and Vim(-/-) fibroblasts, which escaped terminal differentiation by immortalization were characterized by an almost twofold lower mtDNA content in comparison to that of their primary precursor cells, whereby the average mtDNA copy number in two clones of vim(+) cells was lower by a factor of 0.6 than that in four clones of vim(-) cells. However, during serial subcultivation up to high passage numbers, the vim(+) and vim() fibroblasts increased their mtDNA copy number 1.5- and 2.5-fold, respectively. While early-passage cells of the vim(+) and vim(-) fibroblast clones differed only slightly in the ratio between mtDNA content and mitochondrial mass represented by mtHSP70 protein, after ca. 300 population doublings the average mtDNA/mtmass ratio in the vim(+) and vim() cells was increased by a factor of 2 and 4.5, respectively. During subcultivation, both types of cells acquired the fully transformed phenotype. These findings suggest that cytoskeletal vimentin filaments exert a strong influence on the mechanisms controlling mtDNA copy number during serial subcultivation of immortalized mouse embryo fibroblasts, and that vimentin deficiency causes a disproportionately enhanced mtDNA content in high-passage vim(-) fibroblasts. Such a role of vimentin filaments was supported by the stronger retention potential for mtDNA and mtDNA polymerase (gamma) detected in vim(+) fibroblasts by Triton X-100 extraction of mitochondria and agaroseembedded cells. Moreover, although the vim(+) and vim(-) fibroblasts were equally active in generating free radicals, the vim(-) cells exhibited higher levels of immunologically detectable 8-oxoG and mismatch repair proteins MSH2 and MLH1 in their mitochondria. Because in vim(-) fibroblasts only one point mutation was detected in the mtDNA D-loop control region, these cells are apparently able to efficiently remove oxidatively damaged nucleobases. On the other hand, a number of large-scale mtDNA deletions were found in high-passage vim(-) fibroblasts, but not in low-passage vim(-) cells and vim(+) cells of both low and high passage. Large mtDNA deletions were also induced in young vim(-) fibroblasts by treatment with the DNA intercalator ethidium bromide, whereas no such deletions were found after treatment of vim(+) cells. These results indicate that in immortalized vim(-) fibroblasts the mitochondrial genome is prone to large-scale rearrangements, probably due to insufficient control of mtDNA repair and recombination processes in the absence of vimentin.

Interaction in vitro of type III intermediate filament proteins with higher order structures of single-stranded DNA, particularly with G-quadruplex DNA.

Cytoplasmic intermediate filament (cIF) proteins interact strongly with single-stranded (ss) DNAs and RNAs, particularly with G-rich sequences. To test the hypothesis that this interaction depends on special nucleotide sequences and, possibly, higher order structures of ssDNA, a random mixture of mouse genomic ssDNA fragments generated by a novel "whole ssDNA genome PCR" technique via RNA intermediates was subjected to three rounds of affinity binding to in vitro reconstituted vimentin IFs at physiological ionic strength with intermediate PCR amplification of the bound ssDNA segments. Nucleotide sequence and computer folding analysis of the vimentin-selected fragments revealed an enrichment in microsatellites, predominantly of the (GT)n type, telomere DNA, and C/T-rich sequences, most of which, however, were incapable of folding into stable stem-loop structures. Because G-rich sequences were underrepresented in the vimentin-bound fraction, it had to be assumed that such sequences require intramolecular folding or lateral assembly into multistrand structures to be able to stably interact with vimentin, but that this requirement was inadequately fulfilled under the conditions of the selection experiment. For that reason, the few vimentin-selected G-rich ssDNA fragments and a number of telomere models were analyzed for their capacity to form inter- and intramolecular Gquadruplexes (G4 DNAs) under optimized conditions and to interact as such with vimentin and its type III relatives, glial fibrillary acidic protein, and desmin. Band shift assays indeed demonstrated differential binding of the cIF proteins to parallel four-stranded G4 DNAs and, with lower affinity, to bimolecular G'2 and unimolecular G'4 DNA configurations, whereby the transition regions from four- to single-strandedness played an additional role in the binding reaction. In this respect, the binding activity of cIF proteins was comparable with that toward other noncanonical DNA structures, like ds/ss DNA forks, triplex DNA, four-way junction DNA and Z-DNA, which also involve configurational transitions in their interaction with the filament proteins. Association of the cIF proteins with the corresponding nonfolded G-rich ssDNAs was negligible. Considering the almost universal involvement of ssDNA regions and G-quadruplexes in nuclear processes, including DNA transcription and recombination as well as telomere maintenance and dynamics, it is plausible to presume that cIF proteins as complementary constituents of the nuclear matrix participate in the cell- and tissue-specific regulation of these processes.

Type III intermediate filament proteins interact with four-way junction DNA and facilitate its cleavage by the junction-resolving enzyme T7 endonuclease I.

The isolation from proliferating mouse and human embryo fibroblasts of SDS-stable crosslinkage products of vimentin with DNA fragments containing inverted repeats capable of cruciform formation under superhelical stress and the competitive effect of a synthetic Holliday junction on the binding of cytoplasmic intermediate filament (cIF) proteins to supercoiled DNA prompted a detailed investigation of the proteins' capacity to associate with four-way junction DNA and to influence its processing by junction-resolving endonucleases. Electrophoretic mobility shift analysis of reaction products obtained from vimentin and Holliday junctions under varying ionic conditions revealed efficient complex formation of the filament protein not only with the unstacked, square-planar configuration of the junctions but also with their coaxially stacked X-conformation. Glial fibrillary acidic protein (GFAP) was less efficient and desmin virtually inactive in complex formation. Electron microscopy showed binding of vimentin tetramers or octamers almost exclusively to the branchpoint of the Holliday junctions under physiological ionic conditions. Even at several hundredfold molar excess, sequence-related single- and double-stranded DNAs were unable to chase Holliday junctions from their complexes with vimentin. Vimentin also stimulated bacteriophage T7 endonuclease I in introducing single-strand cuts diametrically across the branchpoint and thus in the resolution of the Holliday junctions. This effect is very likely due to vimentin-induced structural distortion of the branchpoint, as suggested by the results of hydroxyl radical footprinting of Holliday junctions in the absence and the presence of vimentin. Moreover, vimentin, and to a lesser extent GFAP and desmin, interacted with the cruciform structures of inverted repeats inserted into a supercoiled vector plasmid, thereby changing their configuration via branch migration and sensibilizing them to processing by T7 endonuclease I. This refers to both plasmid relaxation caused by unilateral scission and, particularly, linearization via bilateral scission at primary and cIF protein-induced secondary cruciform branchpoints that were identified by T7 endonuclease I footprinting. cIF proteins share these activities with a variety of other architectural proteins interacting with and structurally modulating four-way DNA junctions. In view of the known and hypothetical functions of four-way DNA junctions and associated protein factors in DNA metabolism, cIF proteins as complementary nuclear matrix proteins may play important roles in such nuclear matrix-associated processes as DNA replication, recombination, repair, and transcription, with special emphasis on both the preservation and evolution of the genome.

Interaction in vitro of type III intermediate filament proteins with Z-DNA and B-Z-DNA junctions.

The selection of DNA fragments containing simple d(GT)(n) and composite d(GT)(m). d(GA)(n) microsatellites during affinity binding of mouse genomic DNA to type III cytoplasmic intermediate filaments (cIFs) in vitro, and the detection of such repeats, often as parts of nuclear matrix attachment region (MAR)-like DNA, in SDS-stable DNA-vimentin crosslinkage products isolated from intact fibroblasts, prompted a detailed study of the interaction of type III cIF proteins with left-handed Z-DNA formed from d(GT)(17) and d(CG)(17) repeats under the topological tension of negatively supercoiled plasmids. Although d(GT)(n) tracts possess a distinctly lower Z-DNA-forming potential than d(CG)(n) tracts, the filament proteins produced a stronger electrophoretic mobility shift with a plasmid carrying a d(GT)(17) insert than with plasmids containing different d(CG)(n) inserts, consistent with the facts that the B-Z transition of d(GT)(n) repeats requires a higher negative superhelical density than that of d(CG)(n) repeats and the affinity of cIF proteins for plasmid DNA increases with its superhelical tension. That both types of dinucleotide repeat had indeed undergone B-Z transition was confirmed by S1 nuclease and chemical footprinting analysis of the plasmids, which also demonstrated efficient protection by cIF proteins from nucleolytic and chemical attack of the Z-DNA helices as such, as well as of the flanking B-Z junctions. The analysis also revealed sensibilization of nucleotides in the center of one of the two strands of a perfect d(CG)(17) insert toward S1 nuclease, indicating cIF protein-induced bending of the repeat. In all these assays, vimentin and glial fibrillary acidic protein (GFAP) showed comparable activities, versus desmin, which was almost inactive. In addition, vimentin and GFAP exhibited much higher affinities for the Z-DNA conformation of brominated, linear d(CG)(25) repeats than for the B-DNA configuration of the unmodified oligonucleotides. While double-stranded DNA was incapable of chasing the Z-DNA from its protein complexes, and Holliday junction and single-stranded (ss)DNA were distinguished by reasonable competitiveness, phosphatidylinositol (PI) and, particularly, phosphatidylinositol 4,5-diphosphate (PIP(2)) turned out to be extremely potent competitors. Because PIP(2) is an important member of the nuclear PI signal transduction cascade, it might exert a regulatory influence on the binding of cIF proteins to Z- and other DNA conformations. From this interaction of cIF proteins with Z- and bent DNA and their previously detected affinities for MAR-like, ss, triple helical, and four-way junction DNA, it may be concluded that the filament proteins play a general role in such nuclear matrix-associated processes as DNA replication, recombination, repair, and transcription.

Interaction in vitro of type III intermediate filament proteins with supercoiled plasmid DNA and modulation of eukaryotic DNA topoisomerase I and II activities.

To further characterize the interaction of cytoplasmic intermediate filament (cIF) proteins with supercoiled (sc)DNA, and to support their potential function as complementary nuclear matrix proteins, the type III IF proteins vimentin, glial fibrillary acidic protein, and desmin were analyzed for their capacities to interact with supercoiled plasmids containing a bent mouse gamma-satellite insert or inserts capable of non-B-DNA transitions into triplex, Z, and cruciform DNA, that is, DNA conformations typically bound by nuclear matrices. While agarose gel electrophoresis revealed a rough correlation between the superhelical density of the plasmids and their affinity for cIF proteins as well as cIF protein-mediated protection of the plasmid inserts from S1 nucleolytic cleavage, electron microscopy disclosed binding of the cIF proteins to DNA strand crossovers in the plasmids, in accordance with their potential to interact with both negatively and positively supercoiled DNA. In addition, the three cIF proteins were analyzed for their effects on eukaryotic DNA topoisomerases I and II. Possibly because cIF proteins interact with the same plectonemic and paranemic scDNA conformations also recognized by topoisomerases, but select the major groove of DNA for binding in contrast to topoisomerases that insert into the minor groove, the cIF proteins were able to stimulate the enzymes in their supercoil-relaxing activity on both negatively and positively supercoiled plasmids. The stimulatory effect was considerably stronger on topoisomerase I than on topoisomerase II. Moreover, cIF proteins assisted topoisomerases I and II in overwinding plasmid DNA with the formation of positive supercoils. Results obtained with the N-terminal head domain of vimentin harboring the DNA binding region and terminally truncated vimentin proteins indicated the involvement of both protein-DNA and protein-protein interactions in these activities. Based on these observations, it seems conceivable that cIF proteins participate in the control of the steady-state level of DNA superhelicity in the interphase nucleus in conjunction with such topoisomerase-controlled processes as DNA replication, transcription, recombination, maintenance of genome stability, and chromosome condensation and segregation.

Deletion mutagenesis of the amino-terminal head domain of vimentin reveals dispensability of large internal regions for intermediate filament assembly and stability.

Previous studies have shown that the non-alpha-helical head domain of vimentin is required for polymerization of intermediate filaments (IFs) and, furthermore, a nonapeptide highly conserved among type III IF subunit proteins at their extreme amino-terminus is essential for this process. Recombinant DNA technology was employed to produce specific vimentin deletion mutant proteins (for in vitro studies) or vimentin protein expression plasmids (for in vivo studies), which were used to identify other regions of the vimentin head domain important for polymerization. Various vimentin proteins lacking either residues 25-38, 44-95, or 40-95 polymerized into wild-type or largely normal IFs, both in vitro and in vivo. Vimentin proteins lacking residues 44-69 or 25-63 failed to form IFs in vitro, but assembled into IFs in vivo. Vimentin proteins lacking residues 25-68, 44-103, or 88-103 failed to form IFs in vitro or in vivo. Taken together with previous results, these data demonstrate that the middle of the vimentin non-alpha-helical head domain, which is known to be the site of nucleic acid binding, is completely dispensable for IF formation, whereas both ends of the vimentin non-alpha-helical head domain are required for IF formation. The simplest explanation for these results is that the middle of the vimentin non-alpha-helical head domain loops out, thereby permitting the juxtaposition of the ends of the head domain and their productive interaction with other protein domains (probably the C-terminus of the rod domain) during IF polymerization. The ability of some of the mutant proteins to form IFs in vivo, but not in vitro, suggests that as-yet-unknown cellular proteins may interact with and, in some cases, enable polymerization of IFs, even though they are not absolutely required for IF formation by wild-type vimentin.

Organization of focal adhesion plaques is disrupted by action of the HIV-1 protease.

Focal adhesion plaques were severely affected in human embryonic fibroblasts permeabilized with digitonin and incubated in buffer containing the human immunodeficiency virus type 1 protease (HIV-1 PR). A mutant HIV-1 PR (3271 HIV-1 PR) had no effect on focal adhesion plaques. Similar effects were seen with cells microinjected with either HIV-1 PR or 3271 HIV-1 PR. Immunoblots of the human embryonic fibroblasts demonstrated that a number of focal adhesion plaque proteins were specifically cleaved by HIV-1 PR. These included fimbrin, focal adhesion plaque kinase (FAK), talin, and, to a lesser extent, filamin, spectrin and fibronectin. Proteins detected by antibodies to beta 4 integrin and alpha 3 integrin were also cleaved by the HIV-1 PR. Control experiments demonstrated that the effect and protein cleavages described are due to action of the HIV-1 PR and not to the action of endogenous host cell proteases.

Glial fibrillary acidic protein-positive cells of the kidney are capable of raising a protective biochemical barrier similar to astrocytes: expression of metallothionein in podocytes.

Blood-tissue exchange and homeostasis within the organs depend on various interactions between endothelial and perivascular cells (Buniatian, 2001). Podocytes possess anatomical and cellular features intermediate between those of astrocytes and hepatic stellate cells (HSCs). Podocytes, like HSCs, are associated with fenestrated capillaries and, similar to astrocytes, interact with the capillaries via the basement membrane and participate in permeability-limiting ultrafiltration. The fact that podocytes come in direct contact with xenobiotics prompted us to investigate whether they express metallothionein (MT), an anticytotoxic system characteristic of astrocytes. In comparative studies, cryosections of 1- and 3-month-old rat kidney and adult rat brain, as well as podocytes and astrocytes from early and prolonged primary cultures of glomerular explants and newborn rat brain, respectively, were investigated. The cells were double-labeled with antiserum against glial fibrillary acidic protein (GFAP) and monoclonal antibody (MAb) against the lysine-containing epitope of Cd/Zn-MT-I (MAb MT) or MAb against alpha-actin. In kidney sections, MT immunoreactivity was detected in GFAP-positive glomerular cells and in interstitial fibroblasts. The pattern of staining for MT and GFAP in glomerular cells was similar to that of astrocytes in vivo. In glomerular cell cultures, MT was expressed in cobblestone-like podocytes which contained Wilms' tumor protein and lacked desmin. MT was upregulated at later culture periods, during which podocytes acquired features typical of undifferentiated astrocytes. This study hints at the existence of common regulatory mechanisms of blood-tissue interactions by neural and non-neural perivascular cells. These mechanisms appear to be used in an organ-specific manner.

Interaction in vitro of type III intermediate filament proteins with triplex DNA.

As previously shown, type III intermediate filaments (IFs) select from a mixture of linear mouse genomic DNA fragments mobile and repetitive, recombinogenic sequences that have also been identified in SDS-stable crosslinkage products of vimentin and DNA isolated from intact fibroblasts. Because these sequences also included homopurine.homopyrimidine (Pu.Py) tracts known to adopt triple-helical conformation under superhelical tension, and because IF proteins are single-stranded (ss) and supercoiled DNA-binding proteins, it was of interest whether they have a particular affinity for triplex DNA. To substantiate this, IF-selected DNA fragments harboring a (Pu.Py) segment and synthetic d(GA)(n) microsatellites were inserted into a vector plasmid and the constructs analyzed for their capacity to interact with IF proteins. Band shift assays revealed a substantially higher affinity of the IF proteins for the insert-containing plasmids than for the empty vector, with an activity decreasing in the order of vimentin > glial fibrillary acidic protein > desmin. In addition, footprint analyses performed with S1 nuclease, KMnO(4), and OsO(4)/bipyridine showed that the (Pu.Py) inserts had adopted triplex conformation under the superhelical strain of the plasmids, and that the IF proteins protected the triple-helical insert sequences from nucleolytic cleavage and chemical modification. All these activities were largely reduced in extent when analyzed on linearized plasmid DNAs. Because intramolecular triplexes (H-DNA) expose single-stranded loops, and the prokaryotic ssDNA-binding proteins g5p and g32p also protected at least the Pu-strand of the (Pu.Py) inserts from nucleolytic degradation, it seemed likely that the IF proteins take advantage of their ssDNA-binding activity in interacting with H-DNA. However, in contrast to g5p and E. coli SSB, they produced no clear band shifts with single-stranded d(GA)(20) and d(TC)(20), so that the interactions rather appear to occur via the duplex-triplex and triplex-loop junctions of H-DNA. On the other hand, the IF proteins, and also g32p, promoted the formation of intermolecular triplexes from the duplex d[A(GA)(20).(TC)(20)T] and d(GA)(20) and d(TC)(20) single strands, with preference of the Py (Pu.Py) triplex motif, substantiating an affinity of the proteins for the triplex structure as such. This triplex-stabilizing effect of IF proteins also applies to the H-DNA of (Pu.Py) insert-containing plasmids, as demonstrated by the preservation of intramolecular triplex-vimentin complexes upon linearization of their constituent supercoiled DNAs, in contrast to poor complex formation from free, linearized plasmid DNA and vimentin. Considering that (Pu.Py) sequences are found near MAR/replication origins, in upstream enhancer and promoter regions of genes, and in recombination hot spots, these results might point to roles of IF proteins in DNA replication, transcription, recombination, and repair.

Cytoplasmic intermediate filaments are stably associated with nuclear matrices and potentially modulate their DNA-binding function.

The tight association of cytoplasmic intermediate filaments (cIFs) with the nucleus and the isolation of crosslinkage products of vimentin with genomic DNA fragments, including nuclear matrix attachment regions (MARs) from proliferating fibroblasts, point to a participation of cIFs in nuclear activities. To test the possibility that cIFs are complementary nuclear matrix elements, the nuclei of a series of cultured cells were subjected to the Li-diiodosalicylate (LIS) extraction protocol developed for the preparation of nuclear matrices and analyzed by immunofluorescence microscopy and immunoblotting with antibodies directed against lamin B and cIF proteins. When nuclei released from hypotonically swollen L929 suspension cells in the presence of digitonin or Triton X-100 were exposed to such strong shearing forces that a considerable number were totally disrupted, a thin, discontinuous layer of vimentin IFs remained tenaciously adhering to still intact nuclei, in apparent coalignment with the nuclear lamina. Even in broken nuclei, the distribution of vimentin followed that of lamin B in areas where the lamina still appeared intact. The same retention of vimentin together with desmin and glial IFs was observed on the nuclei isolated from differentiating C2C12 myoblast and U333 glioma cells, respectively. Nuclei from epithelial cells shed their residual perinuclear IF layers as coherent cytoskeletal ghosts, except for small fractions of vimentin and cytokeratin IFs, which remained in a dot-to cap-like arrangement on the nuclear surface, in apparent codistribution with lamin B. LIS extraction did not bring about a reduction in the cIF protein contents of such nuclei upon their transformation into nuclear matrices. Moreover, in whole mount preparations of mouse embryo fibroblasts, DNA/chromatin emerging from nuclei during LIS extraction mechanically and chemically cleaned the nuclear surface and perinuclear area from loosely anchored cytoplasmic material with the production of broad, IF-free annular spaces, but left substantial fractions of the vimentin IFs in tight association with the nuclear surface. Accordingly, double-immunogold electron microscopy of fixed and permeabilized fibroblasts disclosed a close neighborhood of vimentin IFs and lamin B, with a minimal distance between the nanogold particles of ca. 30 nm. These data indicate an extremely solid interconnection of cIFs with structural elements of the nuclear matrix, and make them, together with their susceptibility to crosslinkage to MARs and other genomic DNA sequences under native conditions, complementary or even integral constituents of the karyoskeleton.

Inhibition of protein synthesis in a polyribosome-dependent cell-free system by a specific ribonuclease prepared from the follicles of two different stages of development of the silkmothAntherea pernyi.

Crude, cell-free protein-synthesizing systems were prepared from follicles of two different stages of development in the ovariole of the silkmothAntherea pernyi. The efficiency of the translation of natural and synthetic mRNAs in these systems was compared with that in a cell-free wheat germ system. A postmitochondrial extract (S-30) from the follicles almost completely inhibited protein synthesis in a polyribosome-dependent, cell-free systems. A specific ribonuclease, obtained from the post mitochondrial extract by ammonium sulphate precipitation, heat denaturation and DEAE-cellulose chromatography, inhibited polyribosome-dependent protein synthesis. The effect of this specific ribonuclease on the structural integrity of radioactive RNAs and ribosomal subunits, which were isolated from Ehrlich ascites tumor cells, was also studied.