Analysis of the nuclear envelope polypeptides by isoelectric focusing and electrophoresis

The more insoluble polypeptides of the avian erythrocyte nuclear envelope have been characterized by a two-dimensional electrophoretic procedure. Most of the polypeptides occur in two classes with isoelectric points of approximately 6.4 and 5.7 respectively. The more acidic class contains two polypeptides, P71 and one which contributes to an electrophoretic band previously identified as P55. The more basic class includes P75, P68, P61 and two or more polypeptides from the P55 band. There are four to six isoelectric point variants of each polypeptide in the more basic class, and the relative stain intensities for the variants are similar for the different polypeptides. These similarities in ionic properties suggest a chemical relationship between the polypeptides. These results are discussed in relation to the in vitro conversion of P75 to polypeptides of the same molecular weight as P68, P61 and P55.     

Integral membrane proteins specific to the inner nuclear membrane and associated with the nuclear lamina

We obtained a monoclonal antibody (RL13) that identifies three integral membrane proteins specific to the nuclear envelope of rat liver, a major 75-kD polypeptide and two more minor components of 68 and 55 kD. Immunogold labeling of isolated nuclear envelopes demonstrates that these antigens are localized specifically to the inner nuclear membrane, and that the RL13 epitope occurs on the inner membrane's nucleoplasmic surface where the nuclear lamina is found. When nuclear envelopes are extracted with solutions containing nonionic detergent and high salt to solubilize nuclear membranes and pore complexes, most of these integral proteins remain associated with the insoluble lamina. Since the polypeptides recognized by RL13 are relatively abundant, they may function as lamina attachment sites in the inner nuclear membrane. Major cross-reacting antigens are found by immunoblotting and immunofluorescence microscopy in all rat cells examined. Therefore, these integral proteins are biochemical markers for the inner nuclear membrane and will be useful models for studying nuclear membrane biogenesis.     

Major oligomeric structural proteins of the HeLa nucleus

The three predominant polypeptides of the insoluble proteinaceous fraction from the HeLa cell nucleus polymerize in vitro upon oxidation of intrinsic sulfhydryl groups. The ease and specificity of this reaction indicate that these polypeptides exist as ordered oligomers in vivo. The comparable insoluble fraction from the rat liver nucleus also contains three predominant polypeptides of the same molecular weights, 65,000 71,000, and 75,000. The insoluble protein of the avian erythrocyte nuclear envelope consists principally of the 71,000- and the 75,000-dalton polypeptides. Indeed, in the avian erythrocyte nucleus these are the predominant polypeptides of the entire nucleus (Shelton, K., Cobbs, C., Povlishock, J. and Burkat, R., 1976, Arch. Biochem. Biophys.174, 177). Further, these avian polypeptides each form homogeneous covalently linked oligomers upon sulfhydryl oxidation (Cochran, D., Cobbs, C. and Shelton, K., 1977, J. Cell Biol.75, 151a). The insolubility, oligomeric disposition, and relative prominence of these polypeptides in a wide variety of cells indicate a fundamental structural role in the nucleus. Morphological features which may reflect this structural or skeletal role could be the nuclear envelope, the fibrous lamina, or perhaps an intrachromatinic matrix. The metabolism of the oligomeric polypeptides has been investigated in HeLa cells. Turnover of the HeLa insoluble nuclear protein is similar to that of the histones which are known to be stable proteins. The insoluble protein, including the oligomeric polypeptides, is synthesized in G1, S, and G2 phases of the cell cycle. This metabolic behavior indicates that the oligomeric polypeptides are reutilized in successive cell cycles and that synthesis accompanies nuclear and cellular expansion rather than deoxyribonucleohistone synthesis. This suggests that neither degradation nor selective synthesis of oligomeric polypeptides at a particular phase of the cell cycle are responsible for the breakdown and reformation of the interphase cell morphological features that occur during mitosis.     

Nuclear and nuclear envelope localization of dystrophin Dp71 and dystrophin-associated proteins (DAPs) in the C2C12 muscle cells: DAPs nuclear localization is modulated during myogenesis

Dystrophin and dystrophin-associated proteins (DAPs) form a complex around the sarcolemma, which gives stability to the sarcolemma and leads signal transduction. Recently, the nuclear presence of dystrophin Dp71 and DAPs has been revealed in different non-muscle cell types, opening the possibility that these proteins could also be present in the nucleus of muscle cells. In this study, we analyzed by Immunofluorescence assays and Immunoblotting analysis of cell fractions the subcellular localization of Dp71 and DAPs in the C(2)C(12) muscle cell line. We demonstrated the presence of Dp71, alpha-sarcoglycan, alpha-dystrobrevin, beta-dystroglycan and alpha-syntrophin not only in plasma membrane but also in the nucleus of muscle cells. In addition, we found by Immunoprecipitation assays that these proteins form a nuclear complex. Interestingly, myogenesis modulates the presence and/or relative abundance of DAPs in the plasma membrane and nucleus as well as the composition of the nuclear complex. Finally, we demonstrated the presence of Dp71, alpha-sarcoglycan, beta-dystroglycan, alpha-dystrobrevin and alpha-syntrophin in the C(2)C(12) nuclear envelope fraction. Interestingly, alpha-sarcoglycan and beta-dystroglycan proteins showed enrichment in the nuclear envelope, compared with the nuclear fraction, suggesting that they could function as inner nuclear membrane proteins underlying the secondary association of Dp71 and the remaining DAPs to the nuclear envelope. Nuclear envelope localization of Dp71 and DAPs might be involved in the nuclear envelope-associated functions, such as nuclear structure and modulation of nuclear processes.     

hnRNP proteins and B23 are the major proteins of the internal nuclear matrix of HeLa S3 cells

The nuclear matrix is the structure that persists after removal of chromatin and loosely bound components from the nucleus. It consists of a peripheral lamina-pore complex and an intricate internal fibrogranular structure. Little is known about the molecular structure of this proteinaceous internal network. Our aim is to identify the major proteins of the internal nuclear matrix of HeLa S3 cells. To this end, a cell fraction containing the internal fibrogranular structure was compared with one from which this structure had been selectively dissociated. Protein compositions were quantitatively analyzed after high-resolution two-dimensional gel electrophoresis. We have identified the 21 most abundant polypeptides that are present exclusively in the internal nuclear matrix. Sixteen of these proteins are heterogeneous nuclear ribonucleoprotein (hnRNP) proteins. B23 (numatrin) is another abundant protein of the internal nuclear matrix. Our results show that most of the quantitatively major polypeptides of the internal nuclear matrix are proteins involved in RNA metabolism, including packaging and transport of RNA. © 1996 Wiley-Liss, Inc.     

Polypeptide chains of the large and small subunits of fraction I protein from tobacco

Crystalline Fraction I protein from tobacco has been dissociated and separated into three large subunit polypeptides and two small subunit polypeptides by isoelectric focusing in polyacrylamide gels containing 8m urea. The three large subunit polypeptides, resolved by isoelectric focusing, could not be differentiated by amino acid analysis or by fingerprinting of trypsin or chymotrypsin hydrolysates of the individual polypeptides. The two small subunit polypeptides, resolved by hydroxylapatite chromatography in 0.1% sodium dodecyl sulfate as well as by isoelectric focusing, were shown to be distinct polypeptides. The two polypeptides were shown to have different tyrosine:tryptophan ratios, shown by ultraviolet spectra in 0.1m NaOH, and different tyrosine contents shown by amino acid analysis, and they gave different peptide fingerprints after trypsin hydrolysis. The two small subunit polypeptides are concluded to be separate gene products but the three large subunit polypeptides are believed to be the result of modification of a single gene product.     

Evidence of the activity of tyrosine kinase(s) and of the presence of phosphotyrosine proteins in pea plantlets

Homogenate fractions from etiolated pea plantlets showed tyrosine kinase activity when incubated with [32P]ATP and substrates like polyamino acid polymer (Glu-Ala-Tyr)n or [Val5]angiotensin II. When these tyrosine kinase substrates were recovered by high voltage electrophoresis, and analyzed by high pressure liquid chromatography after alkaline hydrolysis, yielded radioactive phosphotyrosine. The same product was obtained after acid hydrolysis of either endogenous or exogenous substrates. Phosphorylated polypeptides were extracted after sodium dodecyl sulfate gel electrophoresis of a pellet fraction incubated with [32P]ATP. After acid hydrolysis and high voltage electrophoresis, [32P]phosphotyrosine was found in gel bands with polypeptides of about 92 and 57 kDa. These results suggest that tyrosine kinase(s) and phosphotyrosine proteins are also present in higher plants.     

Nuclear envelope fraction proteins: Isolation and comparison with the nuclear protein of the avian erythrocyte

A nuclear envelope fraction is obtained from circulating erythrocytes of mature chickens. This fraction was characterized by chemical analysis, ultramicroscopic examination and electrophoretic analysis of the polypeptides. It is free of plasma membrane polypeptides, of hemoglobin and of deoxyribonucleohistone. Comparisons of the sodium dodecyl sulfate-polyacrylamide-gel electropherograms of the nuclear envelope fraction polypeptides with either chromosomal fraction or the total nonhistone fraction polypeptides from Triton X-100-washed nuclei indicate that certain major polypeptides are common to all fractions. This indicates that many chicken erythrocyte nonhistone “chromosomal” polypeptides may be primarily associated with nuclear structural elements which are not, in fact, deoxyribonucleohistone. Although this finding cannot be extended per se to other cells, it does suggest that caution should be exercised in describing nuclear components as “chromosomal” when this designation is intended to imply primary association with the deoxyribonucleohistone. This analysis of the polypeptides in the nuclear envelope fraction of the erythrocyte indicates that further study of the envelope fraction will provide new insights into nuclear structure and function.     

The localization of the nuclear protein pool in Xenopus oocytes

It has been demonstrated previously that nuclear proteins in Xenopus oocytes are synthesized in the cytoplasm and maintained in a cellular pool. The present study was performed to determine if any portion of this pool is associated specifically with the nuclear envelope. This was accomplished by first micro-injecting oocytes with [³H]leucine; at various times after injection, nuclear envelope and nucleoplasmic fractions were run on SDS-polyacrylamide gels. In this way labeled polypeptides available in the envelope fraction could be compared to polypeptides which were subsequently incorporated into the nucleoplasm. No evidence was obtained that the nuclear protein pool is associated with the envelope.     

A Toc75-like protein import channel is abundant in chloroplasts

Chloroplasts import post-translationally most of their constituent polypeptides via two distinct translocon units located in the outer and inner envelope. The protein import channel of the translocon of the outer envelope of chloroplasts, Toc75, is the most abundant protein in that membrane. We identify a novel Toc75 homologous protein, atToc75-V, a prominent protein that is clearly localized in the chloroplastic outer envelope. Phylogenetic analysis indicates that Toc75-V is more closely related to its prokaryotic ancestors than to Toc75 from plants. The presence of a second translocation channel suggests that alternative, previously unrecognized import routes into chloroplasts might exist.     

Nucleocytoplasmic transport of macromolecules.

Nucleocytoplasmic transport is a complex process that consists of the movement of numerous macromolecules back and forth across the nuclear envelope. All macromolecules that move in and out of the nucleus do so via nuclear pore complexes that form large proteinaceous channels in the nuclear envelope. In addition to nuclear pores, nuclear transport of macromolecules requires a number of soluble factors that are found both in the cytoplasm and in the nucleus. A combination of biochemical, genetic, and cell biological approaches have been used to identify and characterize the various components of the nuclear transport machinery. Recent studies have shown that both import to and export from the nucleus are mediated by signals found within the transport substrates. Several studies have demonstrated that these signals are recognized by soluble factors that target these substrates to the nuclear pore. Once substrates have been directed to the pore, most transport events depend on a cycle of GTP hydrolysis mediated by the small Ras-like GTPase, Ran, as well as other proteins that regulate the guanine nucleotide-bound state of Ran. Many of the essential factors have been identified, and the challenge that remains is to determine the exact mechanism by which transport occurs. This review attempts to present an integrated view of our current understanding of nuclear transport while highlighting the contributions that have been made through studies with genetic organisms such as the budding yeast, Saccharomyces cerevisiae.     

Nuclear matrix: isolation and characterization of a framework structure from rat liver nuclei

A nuclear framework structure termed the nuclear matrix has been isolated and characterized. This matrix forms the major residual structure of isolated nuclei and consists largely of protein with smaller amounts of RNA, DNA, carbohydrate, and phospholipid. The nuclear matrix can be further resolved by combined treatment with DNase and RNase. The remaining nuclear protein structure, after extraction of 90 percent of the nuclear protein, 99.9 percent of the DNA, and 98 percent of the RNA and phospholipid, is termed the nuclear protein matrix. Electron microscopy of this final nuclear protein matrix reveals an interior framework structure composed of residual nucleolar structures associated with a granular and fibrous internal matrix structure. The internal matrix framework is derived from the interchromatinic structures of the nucleus, and is connected to a surrounding residual nuclear envelope layer containing residual nuclear pore complex structures. Sodium dodecyl sulfate-acrylamide gel electrophoresis of the nuclear matrix proteins demonstrates three major polypeptide fractions, P-1, P-2, and P-3, with average molecular weights of approximately 69,000, 66,000 and 62,000, as well as several minor polypeptides which migrate at approximately 50,000 and at higher molecular weights (>100,000). Polypeptides with molecular weights identical to those of P-1, P-2 and P-3 are also components of isolated nuclear envelopes and nucleoli, whereas isolated chromatin contains no detectable matrix polypeptides. This suggests that the major matrix polypeptides are localized in specific structural regions of the nucleus, i.e., nuclear envelope, nucleoli, and interchromatinic structures. The presence of cytochrome oxidase activity in the isolated nuclear matrix indicates that at least some integral proteins of the nuclear membrane are associated with the matrix.     

Egg envelope conversion following fertilization in Bufo japonicus

The envelope of the Bufo japonicus egg becomes impenetrable to sperm following fertilization. Electrophoretic analysis of envelopes showed that two glycoprotein components with apparent molecular weights of 65,000 and 61,000 were hydrolyzed during fertilization to 62,000 and 58,000, respectively. These two envelope components were structurally related as shown by peptide mapping and deglycosylation studies. Hardening of the envelope following egg activation was also observed, as detected by an increase in the envelope melting temperature. The involvement of proteolytic activities in the envelope hydrolysis and hardening reactions was demonstrated using protease inhibitors, and was verified for the hydrolysis reaction by observing a loss of mass in deglycosylated envelope components obtained before and after fertilization. A low ionic strength medium (less than 50 mM) was required for both the hardening and hydrolysis reactions. Envelopes from eggs activated in a high ionic strength medium were resistant to lysin from sperm, indicating that neither hydrolysis nor hardening was necessary to block lysin activity on the envelope. Both envelope hydrolysis and hardening could be effected in the absence of sperm (i.e., when eggs were activated by electric shock) and after egg jelly had been removed, indicating that neither sperm nor jelly factors were required for the envelope modifications. In addition, when eggs were activated in the presence of NH4Cl to suppress cortical granule exocytosis, envelope hardening and hydrolysis were still observed, indicating that a cortical granule-derived factor may not be involved.     

Identification of specific polypeptides of the nuclear envelope by iodination of mouse liver nuclei.

A sensitive technique is described for the rapid identification of nuclear-envelope proteins. Mouse liver nuclei (purified on sucrose gradients) were iodinated with Na125I by the immobilized water-insoluble reagent Iodogen. Iodinated nuclei were digested with RNAase A and DNAase I and then salt-extracted to obtain labelled nuclear envelopes. Nuclear envelopes were characterized by morphological and biochemical criteria and by SDS/polyacrylamide-gel electrophoresis. In all, 13 polypeptides of molecular masses 145, 115, 98, 85, 75, 70, 65, 54, 50, 45, 40, 38 and 36 kDa were identified in the labelled nuclear envelopes. The labelled polypeptides were localized to the nuclear envelope by extraction of the envelope with Triton X-100 and different concentrations of salt. Iodination of intact nuclei was shown to be specific for the nuclear envelope by the absence of labelling of histones and cytoplasmic contaminants.     

A FIBER APPARATUS IN THE NUCLEUS OF THE YEAST CELL

The structure and mode of division of the nucleus of budding yeast cells have been studied by phase-contrast microscopy during life and by ordinary microscopy after Helly fixation. The components of the nucleus were differentially stained by the Feulgen procedure, with Giemsa solution after hydrolysis, and with iron alum haematoxylin. New information was obtained in cells fixed in Helly's by directly staining them with 0.005% acid fuchsin in 1% acetic acid in water. Electron micrographs have been made of sections of cells that were first fixed with 3% glutaraldehyde, then divested of their walls with snail juice, and postfixed with osmium tetroxide. Light and electron microscopy have given concordant information about the organization of the yeast nucleus. A peripheral segment of the nucleus is occupied by relatively dense matter (the "peripheral cluster" of Mundkur) which is Feulgen negative. The greater part of the nucleus is filled with fine-grained Feulgen-positive matter of low density in which chromosomes could not be identified. Chromosomes become visible in this region under the light microscope at meiosis. In the chromatin lies a short fiber with strong affinity for acid fuchsin. The nucleus divides by elongation and constriction, and during this process the fiber becomes long and thin. Electron microscopy has resolved it into a bundle of dark-edged 150 to 180 A filaments which extends between "centriolar plaques" that are attached to the nuclear envelope.     

SDS-PAGE comparative studies on the polyhedral and viral polypeptides of the nuclear polyhedrosis viruses of Mamestra brassicae, Autographa californica, and Lymantria dispar

After solubilization of polyhedra of Autographa californica, Lymantria dispar, and Mamestra brassicae nuclear polyhedrosis viruses, PAGE showed at least eight distinct polyhedral polypeptide bands. Whereas the molecular weights of the major polypeptide were similar for the three NPVs (28.0–30.0 kdalton), characteristic differences between the species were found for the minor polypeptides having molecular weights in the range from 12.4 to 62.0 kdalton. It is assumed that these polypeptides are not generated by polyhedral alkaline protease since they are detected after protease inactivation. The data demonstrate that different baculoviruses can be distinguished from each other by SDS-PAGE of their polyhedral polypeptides.     

Nucleocytoplasmic trafficking of proteins: With or without Ran?

Proteins and RNAs move between the nucleus and cytoplasm by translocation through nuclear pore complexes in the nuclear envelope. To do this, they require specific targeting signals, energy, and a cellular apparatus that catalyzes their transport. Several of the factors involved in nucleocytoplasmic trafficking of proteins have been identified and characterized in some detail. The emerging picture for nuclear transport proposes a central role for the small GTPase Ran and proteins with which it interacts. In particular, asymmetric distribution of these proteins between nucleus and cytoplasm appears to be responsible for the vectorial nature of nucleocytoplasmic transport. Here, we summarize the role of Ran and Ran-binding proteins in nuclear trafficking of proteins with classical nuclear localisation signals. We also discuss examples of the growing number of alternative pathways that are involved in transport of proteins across the nuclear envelope. BioEssays 21:579–589, 1999. © 1999 John Wiley & Sons, Inc.     

The germinal vesicle nucleus of Xenopus laevis oocytes as a selective storage receptacle for proteins

The amorphous nucleoplasm of the germinal vesicle nucleus of Xenopus laevis oocytes has been selectively extracted under conditions which leave the nuclear formed elements morphologically intact. The nucleoplasm contains about 97% of the total nuclear proteins and on SDS- polyacrylamide gels some 68 polypeptides can be distinguished. On the basis of solubility differences, the nucleoplasmic proteins can be classified into two categories. The first consists of soluble or easily solubilized proteins which comprise about 34 polypeptides making up 87% of the nucleoplasm. A few of these proteins show electrophoretic mobilities similar to those of soluble proteins of the cytoplasm, but most are unique to the nucleus. The residual 13% of the nucleoplasmic proteins are tightly bound to a nucleoplasmic gel and can be extracted only by solubilizing the gel. The solubility characteristics of the proteinaceous gel suggest a complex held together by salt, nonpolar, hydrogen, and possibly disulfide bonding. Some 34 polypeptides can be distinguished in this gel fraction, including prominent and highly enriched polypeptides of about 115,000 and 46,000 daltons. The relatively soluble fraction of the nucleoplasm does not contain informofers and contains little or no nucleic acid. Evidence is presented that if histones are present in the germinal vesicle, they can comprise no more than about 8% of the total protein. The possibility is discussed that the unique polypeptides of the nucleoplasm may be sequestered there by selective adsorption to or in the nuclear gel.     

Identification of a major polypeptide of the nuclear pore complex

The nuclear pore complex is a prominent structural component of the nuclear envelope that appears to regulate nucleoplasmic molecular movement. Up to now, none of its polypeptides have been defined. To identify possible pore complex proteins, we fractionated rat liver nuclear envelopes and microsomal membranes with strong protein perturbants into peripheral and intrinsic membrane proteins, and compared these fractions on SDS gels. From this analysis, we identified a prominent 190-kilodalton intrinsic membrane polypeptide that occurs specifically in nuclear envelopes. Lectin binding studies indicate that this polypeptide (gp 190) is the major nuclear envelope glycoprotein. Upon treatment of nuclear envelopes with Triton X-100, gp 190 remains associated with a protein substructure of the nuclear envelope consisting of pore complexes and nuclear lamina. We prepared monospecific antibodies to gp 190 for immunocytochemical localization. Immunofluorescence staining of tissue culture cells suggests that gp 190 occurs exclusively in the nucleus during interphase. This polypeptide becomes dispersed throughout the cell in mitotic prophase when the nuclear envelope is disassembled, and subsequently returns to the nuclear surfaces during telophase when the nuclear envelope is reconstructed. Immunoferritin labeling of Triton-treated rat liver nuclei demonstrates that gp 190 occurs exclusively in the nuclear pore complex, in the regions of the cytoplasmic (and possibly nucleoplasmic) pore complex annuli. A polypeptide that cross-reacts with gp 190 is present in diverse vertebrate species, as shown by antibody labeling of nitrocellulose SDS gel transfers. On the basis of its biochemical characteristics, we suggest that gp 190 may be involved in anchoring the pore complex to nuclear envelope membranes.