Immunological localization of a major karyoskeletal protein in nucleoli of oocytes and somatic cells of Xenopus laevis

Oocyte nuclei of Xenopus laevis contain two major karyoskeletal proteins characterized by their resistance to extractions in high salt buffers and the detergent Triton X-100, i.e. a polypeptide of 68,000 mol wt which is located in the core complex-lamina structure and a polypeptide of 145,000 mol wt enriched in nucleolar fractions. Both proteins are also different by tryptic peptide maps and immunological determinants. Mouse antibodies were raised against insoluble karyoskeletal proteins from Xenopus oocytes and analyzed by immunoblotting procedures. Affinity purified antibodies were prepared using antigens bound to nitrocellulose paper. In immunofluorescence microscopy of Xenopus oocytes purified antibodies against the polypeptide of 145,000 mol wt showed strong staining of nucleoli, with higher concentration in the nucleolar cortex, and of smaller nucleoplasmic bodies. In various other cells including hepatocytes, Sertoli cells, spermatogonia, and cultured kidney epithelial cells antibody staining was localized in small subnucleolar granules. The results support the conclusion that this "insoluble" protein is a major nucleus-specific protein which is specifically associated with--and characteristic of--nucleoli and certain nucleolus-related nuclear bodies. It represents the first case of a positive localization of a karyoskeletal protein in the nuclear interior, i.e. away from the pore complex-lamina structure of the nuclear cortex.     

Heat shock-induced changes in the structural stability of proteinaceous karyoskeletal elements in vitro and morphological effects in situ

Karyoskeletal protein fractions prepared from Drosophila melanogaster embryos contain morphologically identifiable remnants of nuclear pore complexes and peripheral lamina as well as what appears to be an internal nuclear "matrix" (Fisher, P. A., M. Berrios, and G. Blobel, 1982, J. Cell Biol., 92: 674-686). Structural stability of these proteinaceous assemblies is dependent on thermal incubation in vitro (37 degrees C, 15 min) before subfractionation of nuclei. In the absence of such incubation, greater than 90% of the total karyoskeletal protein including major polypeptide components of internal "matrix," pore complexes, and the peripheral lamina, is solubilized by 1 M NaCl. In vivo heat shock induces karyoskeletal stabilization resembling that resulting from thermal incubation in vitro. Immunocytochemical studies have been used to establish the effects of heat shock on the organization and distribution of major karyoskeletal marker proteins in situ. Taken together, these results are consistent with the notion that in vivo, regulation of karyoskeletal plasticity (and perhaps form) may be a functionally significant component of the Drosophila heat shock response. They also have broad practical implications for studies pertaining to the structure and function of karyoskeletal protein (nuclear "matrix") fractions isolated from higher eukaryotic cells.     

Monoclonal antibodies to a Mr 68000 pore complex glycoprotein interfere with nuclear protein uptake in Xenopus oocytes

Using a monoclonal antibody (PI1) raised against mouse lymphocyte nuclear matrix fractions we have identified a N-acetylglucosamine (G1cNAc)-containing glycoprotein of M_r 68000 as a component of the nuclear pore complexes of Xenopus laevis oocytes. The antigenic determinant recognized by antibody PI1 comprises both the sugar moiety and protein sequences since, on the one hand, added G1cNAc competed effectively for antibody binding and, on the other hand, the antibody reacted in immunoblots with only one member of the G1cNAc-containing pore complex glycoprotein family. By using immunogold-electron microscopy we could demonstrate that the M_r 68000 glycoprotein was located preferentially to the cytoplasmic side of the pore complex channel. When radiolabeled soluble nuclear proteins were injected into the cytoplasm of Xenopus oocytes, their reentry into the nucleus was almost completely inhibited in the presence of antibody PI1 as shown by two-dimensional gel electrophoresis. The results indicate that the evolutionarily conserved M_r 68000 glycoprotein is involved in transport processes of karyophilic proteins from the cytoplasm into the nucleus.     

Electron microscopic immunolocalization of a karyoskeletal protein of molecular weight 145 000 in nucleoli and perinucleolar bodies of Xenopus laevis

Amplified nucleoli of Xenopus laevis oocytes contain a major karyoskeletal protein of Mr 145 000 insoluble in low- and high-salt buffer as well as in non-denaturing detergents. Electron microscopic localization on native and high-salt extracted nucleoli using specific murine antibodies against this polypeptide and gold-coupled antibodies for visualization reveals that the Mr 145 000 protein is located in coils of filaments of ca 4 nm diameter. In addition, this protein occurs in the medusoid filament bodies (MFBs) present in the nucleolar cortex and free in the nucleoplasm. In somatic cells of tissues and in A6 kidney epithelial cells grown in vitro the Mr 145 000 polypeptide or an immunologically related protein is also organized in coiled aggregates of filaments 4-12 nm in diameter present both in the periphery of nucleoli and free in the nucleoplasm. We discuss a possible role of this protein as a karyoskeletal support involved in the storage and transport of preribosomal particles.     

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.     

The major polypeptides of the nuclear pore complex

Nuclear envelopes of maturing oocytes of various amphibia contain an unusually high number of pore complexes in very close packing. Consequently, nuclear envelopes, which can be manually isolated in great purity, provide a remarkable enrichment of nuclear pore complex material, relative to membranous and other interporous structures. When the polypeptides of nuclear envelopes isolated from oocytes of Xenopus laevis and Triturus alpestris are examined by gel electrophoresis, visualized either by staining with Coomassie blue or by radiofluorography after in vitro reaction with [³H]dansyl chloride, a characteristic pattern is obtained (10 major and 15 minor bands). This polypeptide pattern is radically different from that of the nuclear contents isolated from the same cell. Extraction of the nuclear envelope with high salt concentrations and moderately active detergents such as Triton X-100 results in the removal of membrane material but leaves most of the non-membranous structure of the pore complexes. The dry weight of the pore complex (about 0.2 femtograms) remains essentially unchanged during such extractions as measured by quantitative electron microscopy. The extracted preparations which are highly enriched in nuclear pore complex material contain only two major polypeptide components with apparent molecular weights of 150 000 and 73 000. Components of such an electrophoretic mobility are not present as major bands, if at all, in nuclear contents extracted in the same way. It is concluded that these two polypeptides are the major constituent protein(s) of the oocyte nuclear pore complex and are specific for this structure. When nuclear envelopes are isolated from rat liver and extracted with high salt buffers and Triton X-100 similar bands are predominant, but two additional major components of molecular weights of 78 000 and 66 000 are also recognized. When the rat liver nuclear membranes are further subfractionated material enriched in the 66 000 molecular weight component can be separated from the membrane material, indicating that this is relatively loosely associated material, probably a part of the nuclear matrix. The results suggest that the nuclear pore complex is not only a characteristic ubiquitous structure but also contains similar, if not identical, skeletal proteins that are remarkably resistant to drastic changes of ionic strength as well as to treatments with detergents and thiol reagents.     

Identification of a soluble precursor complex essential for nuclear pore assembly in vitro

We analysed the soluble form in which the nuclear pore complex protein p68 is stored in Xenopus laevis eggs and its involvement in pore complex assembly processes. We have shown previously that p68, which is the major wheat germ agglutinin (WGA)-binding glycoprotein of nuclear pore complexes from Xenopus oocytes, is located in the pore channel and participates in mediated transport of karyophilic proteins. Using a monoclonal antibody directed against p68 (PI1) we removed this protein from Xenopus egg extract by immunoadsorption. On addition of lambda DNA the immunodepleted extract supported reconstitution of nuclei which were surrounded by a continuous double-membrane envelope but lacked pore complexes and were unable to import karyophilic proteins such as nucleoplasmin or lamin L_III. Essentially identical results were obtained with extract depleted of WGA-binding proteins. Our finding that both the anti-p68 antibody and WGA efficiently removed components from the extract necessary for pore complex assembly but did not interfere with nuclear membrane formation demonstrates that these processes are independent of each other. Analysis of the immunoprecipitate on silver-stained SDS-polyacrylamide gels indicated that the antibody adsorbed other proteins besides p68, notably two high molecular weight components. By sucrose gradient centrifugation and gel filtration we showed that p68 together with associated protein(s) forms a stable, approximately globular complex plex with an M_r of 254,000, a Stokes radius of 5.2 nm and a sedimentation coefficient of 11.3 S. Our finding that p68 occurs in the form of larger macromolecular assemblies offers an explanation for the distinctly punctate immunofluorescence pattern observed in the cytoplasm of mitotic cells after staining with antibodies to p68.W. Hennig     

Argyrophilic nuclear and nucleolar proteins of Xenopus laevis oocytes identified by gel electrophoresis

In order to identify argyrophilic proteins of nuclei and nucleoli, in particular those responsible for the ‘nucleolar Ag staining’ widely used in cytology, we have utilized oocytes of Xenopus laevis because of the abundance of ‘pure’ extrachromosomal nucleoli. Examination of oocytes by light and electron microscopy shows that the large extrachromosomal nucleoli are heavily stained with the Ag technique and that the Ag deposits are largely enriched in, if not exclusive to, the internal, fibrillar region. The same pattern of Ag staining in internal regions of nucleoli is observed in isolated nucleoli from which soluble nuclear proteins were removed by extensive washing. Argyrophilic proteins of isolated oocyte nuclei and purified nucleoli have been identified by reaction with AgNO₃ and formaldehyde on gel-electrophoretically separated polypeptides. Among nuclear proteins, the most prominent argyrophilia is associated with nucleoplasmin, a soluble MW 30000 phosphoprotein of the nuclear sap. In addition, four minor Ag-staining nuclear proteins have been observed. By contrast, the only strongly argyrophilic protein observed on gel electrophoresis of proteins of purified nucleoli is a high molecular weight component (apparent MW 195000) which is often resolved in a characteristic ‘pair’ of closely spaced polypeptide bands. The enrichment of this high molecular weight argyrophilic protein in isolated nucleoli and the corresponding absence of argyrophilic proteins of the nuclear sap, including nucleoplasmin, indicates that this protein contributes to the nucleolus-specific Ag staining observed in histological sections. The possible nature of this polypeptide of MW 195000 is discussed.     

Cell type-specific differences in protein composition of nuclear pore complex-lamina structures in oocytes and erythrocytes of Xenopus laevis

Nuclear envelopes from oocytes of Xenopus laevis are rich in pore complexes and contain a major polypeptide of apparent molecular weight (M_r) 68,000. A rapid extraction procedure using buffer containing 1% ($\text{v}\text{v}$) Triton X-100 and 1.0 m-KCl allows the preparation of insoluble nuclear envelope skeletons showing only residual pore complex structures, with some interconnecting filament material, and one major polypeptide; i.e. that of M_r 68,000. This skeletal protein, which is not found in nuclear contents, reveals, on two-dimensional gel electrophoresis, a series of distinct isoelectric variants focusing in the pH range from 6.4 to 6.6. In living oocytes, this protein is continuously synthesized, as demonstrated by incorporation of labelled amino acids, and phosphorylated, A similar prominent skeletal protein has been found in nuclear envelopes of oocytes of other amphibia; however, slight but significant differences in electrophoretic mobility can be noted between different amphibian species.For comparison, nucleocortical lamina structures containing few pore complexes have been isolated, using similar extraction procedures, from various somatic cells of X. laevis, including erythrocytes. Laminae from these cells contain two major polypeptides, one (L_I) of M_r 72,000 focusing at approximately pH 5.35 and another (L_II) of M_r 69,000 focusing in several variants between pH 6.20 and 6.35. Similarly extracted “pore complex-lamina” fractions from rat liver contain a polypeptide of similar size and electrical charge as protein L_I from Xenopus and, in addition, two other polypeptides (M_r values: 74,000 and 62,000) both focusing between pH 6.6 and 6.9.It is concluded that the pore complex-lamina structure of the oocyte nucleus is assembled by only one major protein of M_r 68,000. The results also show that the protein composition of this insoluble nucleocortical structure can be different in different cells of the same organism. The compositional differences of these nuclear envelope skeletons are discussed in relation to the relative proportions of pore complex and interporous (lamina) material in the nuclear envelopes of the specific cells. It is suggested that the M_r 68,000 protein predominant in oocyte nuclear envelopes contributes, as an architectural component, to the formation of the highly organized nuclear pore complex.     

A monoclonal antibody against nuclear lamina proteins reveals cell type-specificity in Xenopus laevis

Immunofluorescence microscopy shows that the monoclonal murine antibody PKB8 stains the nuclear lamina of various somatic cells from vertebrates as diverse as mammals, birds and amphibia. It also decorates the nuclear periphery of oocytes from rat and chicken but does not react with spermatocytes, spermatids and spermatozoa. Immunoblotting experiments demonstrate reaction with lamina polypeptides A, B and C of rat, with lamina polypeptide A of chicken, and with lamina polypeptides LI and LII of erythrocytes of the frog, Xenopus laevis. Antibody PKB8 does, however, not bind, on blotted polypeptides and on sections through ovaries, to the pore complex-lamina polypeptide of Mr 68000 present in Xenopus oocytes. These results reveal the existence of a common antigenic determinant in all three lamina polypeptides of mammals, in one lamina polypeptide of chicken and in two amphibian lamina polypeptides. The immunological data also indicate that, in Xenopus laevis, pore complex-lamina polypeptides of somatic cells and oocytes are distinct. The Mr 68000 protein of Xenopus oocytes is also different from polypeptides LI and LII of somatic Xenopus cells by tryptic peptide mapping. The results suggest that nuclear pore complex-lamina polypeptides represent a family of related polypeptides containing regions highly conserved during evolution and that these polypeptides can be differentially expressed in cells of at least one species, Xenopus laevis.     

A Novel Karyoskeletal Protein: Characterization of Protein NO145, the Major Component of Nucleolar Cortical Skeleton in Xenopus Oocytes

The nucleolus is a ubiquitous, mostly spheroidal nuclear structure of all protein-synthesizing cells, with a well-defined functional compartmentalization. Although a number of nonribosomal proteins involved in ribosome formation have been identified, the elements responsible for the shape and internal architecture of nucleoli are still largely unknown. Here, we report the molecular characterization of a novel protein, NO145, which is a major and specific component of a nucleolar cortical skeleton resistant to high salt buffers. The amino acid sequence of this polypeptide with a SDS-PAGE mobility corresponding to M(r) 145,000 has been deduced from a cDNA clone isolated from a Xenopus laevis ovary expression library and defines a polypeptide of 977 amino acids with a calculated mass of 111 kDa, with partial sequence homology to a synaptonemal complex protein, SCP2. Antibodies specific for this protein have allowed its recognition in immunoblots of karyoskeleton-containing fractions of oocytes from different Xenopus species and have revealed its presence in all stages of oogenesis, followed by a specific and rapid degradation during egg formation. Immunolocalization studies at the light and electron microscopic level have shown that protein NO145 is exclusively located in a cage-like cortical structure around the entire nucleolus, consisting of a meshwork of patches and filaments that dissociates upon reduction of divalent cations. We propose that protein NO145 contributes to the assembly of a karyoskeletal structure specific for the nucleolar cortex of the extrachromosomal nucleoli of Xenopus oocytes, and we discuss the possibility that a similar structure is present in other cells and species.     

The plant nuclear envelope

This review summarizes our present knowledge about the composition and function of the plant nuclear envelope. Compared with animals or yeast, our molecular understanding of the nuclear envelope in higher plants is in its infancy. However, fundamental differences in the structure and function of the plant and animal nuclear envelope have already been found. Here, we compare and contrast these differences with respect to nuclear pore complexes, targeting of Ran signaling to the nuclear envelope, inner nuclear envelope proteins, and the role and fate of the nuclear envelope during mitosis. Further investigation of the emerging fundamental differences as well as the similarities between kingdoms might illuminate why there appears to be more than one blueprint for building a nucleus.Abbreviations GFP Green fluorescent protein - INE Inner nuclear envelope - LAP Lamina-associated polypeptide - LBR Lamin B receptor - MTOC Microtubule-organizing center - NE Nuclear envelope - NPC Nuclear pore complex - ONE Outer nuclear envelope - RanBP Ran-binding protein - RanGAP Ran GTPase-activating protein - WPP domain Tryptophan–proline–proline domain     

Identification and localisation of a nucleoporin-like protein component of the plant nuclear matrix

Salt-detergent extraction of purified plant nuclei yields a fraction enriched in putative structural proteins known as the nuclear matrix. Compared with mammalian nuclear matrices, which contain three major proteins, plant nuclear matrices are complex, containing at least 100 polypeptides. In order to characterise more fully the plant nuclear matrix we have used antibodies raised against both yeast (Saccharomyces cerevisiae) and mammalian (rat) nuclear pore proteins. We have shown that the nuclear matrix of carrot (Daucus carota L.) contains at least one nucleoporin-like protein of about 100 kDa which is immunologically related to both the yeast nuclear pore protein NSP1 and mammalian nucleoporins (p62). Antibody labelling of a variety of plant cells at the light-microscope and electron-microscope levels confirms that this antigen is located at the nuclear pores. This, to our knowledge, is the first identification of a nuclear pore protein in plants.Abbreviations IgG immunoglobulin G - kDa kilodaltons - DAPI 4,6-diamidino-2-phenylindole - FITC fluorescein isothioganate The authors would like to thank Dr. E. Hurt (European Molecular Biology Laboratory, Heidelberg, FRG) for antibodies against yeast nucleoporins, and Dr. L. Davis (Whitehead Institute for Biomedical Research, Cambridge, Mass., USA) for the monoclonal antibodies MAb 414 & 350. We thank Brian Wells for useful advice on electron microscopy. We also thank Peter Scott, Andrew Davis, and Nigel Hannant for photography, and Sue Bunnewell for development and printing of electronmicrographs.     

Mediators of Nuclear Protein Import Target Karyophilic Proteins to Pore Complexes of Cytoplasmic Annulate Lamellae

Nuclear pore complexes are constitutive structures of the nuclear envelope in eukaryotic cells and represent the sites where transport of molecules between nucleus and cytoplasm takes place. However, pore complexes of similar structure, but with largely unknown functional properties, are long known to occur also in certain cytoplasmic cisternae that have been termed annulate lamellae (AL). To analyze the capability of the AL pore complex to interact with the soluble mediators of nuclear protein import and their karyophilic protein substrates, we have performed a microinjection study in stage VI oocytes ofXenopus laevis.In these cells AL are especially abundant and can easily be identified by light and electron microscopy. Following injection into the cytoplasm, fluorochrome-labeled mediators of two different nuclear import pathways, importin β and transportin, not only associate with the nuclear envelope but also with AL. Likewise, nuclear localization signals (NLS) of the basic and M9 type, but not nuclear export signals, confer targeting and transient binding of fluorochrome-labeled proteins to cytoplasmic AL. Mutation or deletion of the NLS signals prevents these interactions. Furthermore, binding to AL is abolished by dominant negative inhibitors of nuclear protein import. Microinjections of gold-coupled NLS-bearing proteins reveal specific gold decoration at distinct sites within the AL pore complex. These include such at the peripheral pore complex-attached fibrils and at the central “transporter” and closely resemble those of “transport intermediates” found in electron microscopic studies of the nuclear pore complex (NPC). These data demonstrate that AL can represent distinct sites within the cytoplasm of transient accumulation of nuclear proteins and that the AL pore complex shares functional binding properties with the NPC.     

Isolation and ultrastructural characterization of the residual nuclear matrix in a plant cell system

We isolated the nuclear matrix of proliferative meristematic root cells of Allium cepa bulbs and characterized it ultrastructurally and by one-dimensional SDS-polyacrylamide gel electrophoresis. The general organization of the nuclear matrix in onion root cells is similar to that found in other eukaryotes extracted under the same conditions. There are three main morphological components: the residual pore-lamina complex, the internal matrix and the residual nucleolus. The matrix has a fibrillo-granular structure composed of 5–10 nm fibrils and 20–25 nm granules. The residual protein matrix has a complex pattern, with several polypeptide bands of 12000 to 70000 Mr. The major bands have Mrs of 62000, 56000, 35000 and 27000.by M. Trendelenburg     

Primary biliary cirrhosis sera recognize not only gp210 but also proteins of the p62 complex bearing N-acetylglucosamine residues from rat liver nuclear envelope

We have recently observed reactivity of primary biliary cirrhosis (PBC) sera with several proteins bearing N-acetylglucosamine residues from rat liver nuclear envelopes. The aim of this study was to characterize the reactive antigens. Sera from 31 patients with PBC, 30 with rheumatoid arthritis (RA) and 30 with Sjögren's syndrome (SS) were examined. Rim-like immunofluorescence staining was observed in 15 of 31 (48%) sera from patients with PBC, in 1 of 30 with RA and in 1 of 30 with SS. Upon immunoblotting using preparations of whole rat liver nuclear envelopes and their Triton X 100-KCl extract as antigen souces, a 200 kDa protein band was observed in 9 of sera with PBC. Furthermore, upon immunoblotting using the wheat germ aggulutinin-bound fraction of rat liver envelope as antigen, 62, 60 and 54 kDa protein bands corresponding to components of the p62 complex in the nuclear pore complex (Kita et al. Biochem. 113, 377–382) were observed in 7, 5 and 6 samples respectively, of the 31 PBC sera. Our data suggest that PBC sera recognize not only the 210 kDa protein but also the p62 complex proteins.Abbreviations ANA antinuclear antibody - AMA anti-mitochondrial antibodies - IF immunofluorescence - LAP2 lamina-associated polypeptide 2 - LBR lamin B receptor - anti-NBP 60 anti-nuclear localization signal binding protein 60 - NE nuclear envelope - NPC nuclear pore complex - PBC primary biliary cirrhosis - RA rheumatoid arthritis - SLE systemic lupus erythematosus - SS Sjögren's syndrome - WGA wheat germ agglutinin     

Identification and Cloning of an mRNA Coding for a Germ Cell-Specific A-Type Lamin in Mice

The nuclear lamins are karyoskeletal proteins which have important functions, such as maintaining nuclear envelope integrity and organizing high order nuclear structure during mitosis in higher eukaryotes. In somatic mammalian cells, the A-type and B-type lamins, composed of lamins A and C and lamins B1 and B2, are major components of the nuclear lamina. However, A-type lamins have as yet not been identified in germ cells and undifferentiated embryonic cells. Here we report the cloning of a new 52-kDa A-type lamin from mouse pachytene spermatocytes, termed lamin C2 because of its similarities with lamin C. It has a sequence identical to that of lamin C except that the N -terminal segment, containing the head and the α-helical coil 1A domains, is replaced with a short non-α-helical stretch of amino acids. In mice, lamin C2 was found to be specifically expressed in germ cells. This specific expression and unique structure suggests a role for lamin C2 in determining the organization of nuclear and chromosomal structures during spermatogenesis.     

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.