Alterations in chromatin conformation are accompanied by reorganization of nonchromatin domains that contain U-snRNP protein p28 and nuclear protein p107

Hypophosphorylated SR splicing factors transiently localize around active nucleolar organizing regions in telophase daughter nuclei

Upon completion of mitosis, daughter nuclei assemble all of the organelles necessary for the implementation of nuclear functions. We found that upon entry into daughter nuclei, snRNPs and SR proteins do not immediately colocalize in nuclear speckles. SR proteins accumulated in patches around active nucleolar organizing regions (NORs) that we refer to as NOR-associated patches (NAPs), whereas snRNPs were enriched at other nuclear regions. NAPs formed transiently, persisting for 15–20 min before dissipating as nuclear speckles began to form in G1. In the absence of RNA polymerase II transcription, NAPs increased in size and persisted for at least 2 h, with delayed localization of SR proteins to nuclear speckles. In addition, SR proteins in NAPs are hypophosphorylated, and the SR protein kinase Clk/STY colocalizes with SR proteins in NAPs, suggesting that phosphorylation releases SR proteins from NAPs and their initial target is transcription sites. This work demonstrates a previously unrecognized role of NAPs in splicing factor trafficking and nuclear speckle biogenesis.

Nucleic acid compartmentalization within the cell nucleus by in situ transferase-immunogold techniques

In the present review, we report on recent results obtained by in situ transferase-immunogold techniques as to the ultrastructural distribution of DNA and RNA within the cell nucleus. Special emphasis is placed on the various nucleolar components and the various enigmatic structures of the extranucleolar region: interchromatin granules, coiled bodies, and simple nuclear bodies. These data are discussed in the light of our current understanding of the functional organization of the cell nucleus.

Redistribution of nuclear antigens linked to cell proliferation and RNA processing in mouse oocytes and early embryos

We have systematically analyzed by indirect immunofluorescence the subcellular distribution of nuclear antigens in relation to developmental stages of maturing mouse oocytes and developing embryos. Antigens were of two types: (1) a protein whose nuclear localization in interphase somatic cells depends on their proliferative state protein recognized by a monoclonal antibody 43B1N, and (2) snRNP polypeptides recognized by autoimmune sera of anti-Sm and anti-RNP type. The protein recognized by 43B1N was present in the germinal vesicle of oocytes from antral follicles, but absent from the nuclei during the first hours of embryonic life up to the middle to late 2-cell stage. Starting from this stage, it was always found in nuclei of interphase blastomeres, where its "speckles" co-localized with the speckles containing high concentrations of snRNP polypeptides. SnRNP polypeptides recognized by anti-Sm and anti-RNP sera were in turn found in nuclei of all developmental stages. When embryos were treated with aphidicolin or cytochalasin D to arrest cell division, the 43B1N reacting protein was again localized in the pronuclei at 42 hr post-hCG, i.e., slightly later than the onset of transcriptional activity. These results suggest a progressive building up of nuclei during embryonic development, which could influence gene expression.

Activation of heat shock gene transcription by heat shock factor 1 involves oligomerization, acquisition of DNA-binding activity, and nuclear localization and can occur in the absence of stress

The existence of multiple heat shock factor (HSF) genes in higher eukaryotes has promoted questions regarding the functions of these HSF family members, especially with respect to the stress response. To address these questions, we have used polyclonal antisera raised against mouse HSF1 and HSF2 to examine the biochemical, physical, and functional properties of these two factors in unstressed and heat-shocked mouse and human cells. We have identified HSF1 as the mediator of stress-induced heat shock gene transcription. HSF1 displays stress-induced DNA-binding activity, oligomerization, and nuclear localization, while HSF2 does not. Also, HSF1 undergoes phosphorylation in cells exposed to heat or cadmium sulfate but not in cells treated with the amino acid analog L-azetidine-2-carboxylic acid, indicating that phosphorylation of HSF1 is not essential for its activation. Interestingly, HSF1 and HSF2 overexpressed in transfected 3T3 cells both display constitutive DNA-binding activity, oligomerization, and transcriptional activity. These results demonstrate that HSF1 can be activated in the absence of physiological stress and also provide support for a model of regulation of HSF1 and HSF2 activity by a titratable negative regulatory factor.

Activation of heat shock gene transcription by heat shock factor 1 involves oligomerization, acquisition of DNA-binding activity, and nuclear localization and can occur in the absence of stress

The existence of multiple heat shock factor (HSF) genes in higher eukaryotes has promoted questions regarding the functions of these HSF family members, especially with respect to the stress response. To address these questions, we have used polyclonal antisera raised against mouse HSF1 and HSF2 to examine the biochemical, physical, and functional properties of these two factors in unstressed and heat-shocked mouse and human cells. We have identified HSF1 as the mediator of stress-induced heat shock gene transcription. HSF1 displays stress-induced DNA-binding activity, oligomerization, and nuclear localization, while HSF2 does not. Also, HSF1 undergoes phosphorylation in cells exposed to heat or cadmium sulfate but not in cells treated with the amino acid analog L-azetidine-2-carboxylic acid, indicating that phosphorylation of HSF1 is not essential for its activation. Interestingly, HSF1 and HSF2 overexpressed in transfected 3T3 cells both display constitutive DNA-binding activity, oligomerization, and transcriptional activity. These results demonstrate that HSF1 can be activated in the absence of physiological stress and also provide support for a model of regulation of HSF1 and HSF2 activity by a titratable negative regulatory factor.

Cytostellin: a novel, highly conserved protein that undergoes continuous redistribution during the cell cycle

Cytostellin, a 240 kDa protein, has been purified from mammalian cells by immunoaffinity chromatography using monoclonal antibody H5. Immunofluorescence microscopy shows diffuse and punctate cytostellin immunoreactivity in interphase nuclei. Nuclease digestion and salt extraction are not required to expose the epitope. The onset of prophase is marked by the appearance of multiple intensely immunofluorescent cytostellin-containing ‘bodies’ within the nucleus. Nuclear disassembly is heralded by the movement of cytostellin bodies from the nucleus to multiple positions throughout the cell. Cytostellin bodies in metaphase, anaphase and telophase cells are widely dispersed, including some in cell processes far removed from the mitotic spindle apparatus. However, a distinct subset of larger, more intensely staining bodies surrounds the mitotic spindle apparatus. Cytostellin bodies remain in the cytoplasm of the daughter cells and disappear after the appearance of nascent nuclei. Cytostellin is immunologically distinct from other nuclear and cytoplasmic proteins, and it has been detected by immunoblot analysis in all species tested from yeast to humans. Based upon these findings, we postulate that cytostellin has a cell cycle-dependent function which is conserved in higher and lower eukaryotic cells.

Transcription-dependent colocalization of the U1, U2, U4/U6, and U5 snRNPs in coiled bodies

We have recently shown that discrete foci are present in the nuclei of mammalian cells in which each of the U1, U2, U4/U6, and U5 snRNPs involved in pre-mRNA splicing, and the non-snRNP-splicing factor U2AF, are concentrated (Carmo-Fonseca, M., D. Tollervey, R. Pepperkok, S. Barabino, A. Merdes, C. Brunner, P. D. Zamore, M. R. Green, E. Hurt, and A. I. Lamond. 1991. EMBO (Eur. Mol. Biol. Organ.) J. 10:195-206; Carmo-Fonseca, M., R. Pepperkok, B. S. Sproat, W. Ansorge, M. S. Swanson, and A. I. Lamond. 1991 EMBO (Eur. Mol. Biol. Organ.) J. 10:1863-1873). Here, we identify these snRNP-rich organelles as coiled bodies. snRNPs no longer concentrate in coiled bodies after cells are treated with the transcription inhibitors alpha-amanitin or actinomycin D. snRNP association with coiled bodies is also disrupted by heat shock. This indicates that the association of snRNPs with coiled bodies may be connected with the metabolism of nascent transcripts. A novel labeling method is described which shows both the RNA and protein components of individual snRNPs colocalizing in situ. Using this procedure all spliceosomal snRNPs are seen distributed in a nonhomogeneous pattern throughout the nucleoplasm, excluding nucleoli. They are most concentrated in coiled bodies, but in addition are present in "speckled" structures which are distinct from coiled bodies and which contain the non-snRNP splicing factor SC-35. U1 snRNP shows a more widespread nucleoplasmic staining, outside of coiled bodies and "speckled" structures, relative to the other snRNPs. The association of snRNPs with "speckles" is disrupted by heat shock but enhanced when cells are treated with alpha-amanitin.

Discrete nuclear domains of poly(A) RNA and their relationship to the functional organization of the nucleus

The functional organization of the nucleus was studied using a fluorescence microscopy approach which allowed integration of positional information for RNA, DNA, and proteins. In cells from sea urchin to human, nuclear poly(A) RNA was found concentrated primarily within several discrete "transcript domains" which often surrounded nucleoli. Concentrations of poly(A) RNA were coincident with snRNP antigen clusters, providing evidence for the localization of pre-mRNA splicing at these sites. The spatial relationship of transcript domains with respect to various classes of DNA was established, in that the poly(A) RNA-rich regions coincided with discrete regions of low DNA density and were non-randomly distributed with respect to specific DNA sequences. Centromeric DNA and late-replicating DNA did not overlap transcript domains, whereas a subset of early-replicating DNA may. Results indicate that transcript domains do not result directly from a simple clustering of chromatin corresponding to metaphase chromosomes bands. Finally, observations on the reassembly of these domains after mitosis suggest that the clustering of snRNP antigens may be dependent on the reappearance of pol II transcription. Implications of these findings for overall nuclear structure and function are considered, including a discussion of whether transcript domains may be sites of polymerase II transcription reflecting a clustering of active genes.

Nuclear matrins: identification of the major nuclear matrix proteins

A preparative two-dimensional polyacrylamide gel system was used to separate and purify the major Coomassie blue-stained proteins from the isolated rat liver nuclear matrix. Approximately 12 major proteins were consistently found. Of these, 5 proteins represented identified proteins, including nuclear lamins A, B, and C, the nucleolar protein B-23, and residual components of core heterogeneous nuclear ribonucleoproteins. The remaining eight major proteins termed the nuclear matrins consisted of matrin 3 (125 kDa, slightly acidic), matrin 4 (105 kDa, basic), matrins D-G (60-75 kDa, basic), and matrins 12 and 13 (42-48 kDa, acidic). Peptide mapping and two-dimensional immunoblot studies indicate that matrins D-G compose two pairs of related proteins (matrins D/E and F/G) and that none of the matrins resemble the nuclear lamins or any of the other major proteins detected on our two-dimensional gels. Subfractionation immunoblot experiments demonstrated the nearly exclusive localization of matrins F/G and other matrins to the nuclear matrix fraction of the cell. These results were further supported by indirect immunofluorescence microscopy that showed a strictly interior nuclear localization of the matrins in intact cells in contrast to the peripherally located nuclear lamins. We conclude that the nuclear matrins are a major class of proteins of the nuclear matrix interior and are distinct from the nuclear lamins.

Associations between distinct pre-mRNA splicing components and the cell nucleus

SC-35 is a non-snRNP spliceosome component that is specifically recognized by the anti-spliceosome monoclonal antibody alpha SC-35. In this paper we provide direct evidence that SC-35 is an essential splicing factor and we examine the immunolocalization of SC-35 by confocal laser scanning microscopy and by electron microscopy. We have found that the speckled staining pattern observed by fluorescence microscopy corresponds to structures previously designated as interchromatin granules and perichromatin fibrils. Although snRNP antigens are also concentrated in these nuclear regions, we show that the two types of spliceosome components are localized through different molecular interactions: The distribution of SC-35 was not affected by treatment with DNase I or RNase A, or when the cells were heat shocked. In contrast, snRNP antigens become diffusely distributed after RNase A digestion or heat shock. Examination of cells at different stages of mitosis revealed that the SC-35 speckled staining pattern is lost during prophase and speckles containing SC-35 begin to reform in the cytoplasm of anaphase cells. In contrast, snRNP antigens do not associate with speckled regions until late in telophase. These studies reveal a dynamic pattern of assembly and disassembly of the splicing factor SC-35 into discrete nuclear structures that colocalize with interchromatin granules and perichromatin fibrils. These subnuclear regions may therefore be nuclear organelles involved in the assembly of spliceosomes, or splicing itself.

Change in the expression of a nuclear matrix-associated protein is correlated with cellular transformation

We have identified a monoclonal antibody that recognizes a nuclear matrix-associated protein in NIH 3T3 cells. The immunofluorescence pattern consists predominantly of bright nuclear granule clusters distributed throughout the nucleoplasm, with the exclusion of nucleoli. It recognizes a protein of 190 kDa that is down-regulated to various degrees in a panel of single-oncogene-transformed NIH 3T3 cells. Its localization is similar, but not identical, to the spliceosomal speckles. p190 shows a coordinate expression during the growth cycle of nontransformed NIH 3T3 cells; it is synthesized at the highest level under growth arrest conditions. It is expressed in adult mouse brain and is also present in human IMR-90 fibroblasts.

In vivo detection of snRNP-rich organelles in the nuclei of mammalian cells

The in vivo distribution of snRNPs has been analysed by microinjecting fluorochrome-labelled antisense probes into the nuclei of live HeLa and 3T3 cells. Probes for U2 and U5 snRNAs specifically label the same discrete nuclear foci while a probe for U1 snRNA shows widespread nucleoplasmic labelling, excluding nucleoli, in addition to labelling foci. A probe for U3 snRNA specifically labels nucleoli. These in vivo data confirm that mammalian cells have nuclear foci which contain spliceosomal snRNPs. Co-localization studies, both in vivo and in situ, demonstrate that the spliceosomal snRNAs are present in the same nuclear foci. These foci are also stained by antibodies which recognize snRNP proteins, m3G-cap structures and the splicing factor U2AF but are not stained by anti-SC-35 or anti-La antibodies. U1 snRNP and the splicing factor U2AF closely co-localize in the nucleus, both before and after actinomycin D treatment, suggesting that they may both be part of the same complex in vivo.

Immunologically-related nucleic acid-binding proteins associated with the nuclear matrix of Physarum polycephalum

The nuclear matrix of Physarum polycephalum is composed of two abundant polypeptides of 27 and 38 kDa as well as numerous minor polypeptides of various molecular weight. By contrast, the nuclear matrix of vertebrates consists of three major (the lamins) and many minor polypeptides mainly in the 60-70 kDa molecular weight range. In order to better characterize the major nuclear matrix proteins of P. polycephalum and, perhaps, define their relationship with the major nuclear matrix proteins of vertebrates, we have purified the abundant nuclear matrix proteins of P. polycephalum. In Western blot analyses, polyclonal antibodies raised against the purified 27 kDa polypeptide recognised polypeptides of 50 kDa, 45 kDa and several low molecular weight species (14-21 kDa) in the P. polycephalum nuclear matrix. The polyclonal antibodies did not react with the other abundant nuclear matrix protein of 38 kDa from P. polycephalum nor with polypeptides of the mouse nuclear matrix. Two-dimensional gel electrophoresis showed that the major nuclear matrix proteins of P. polycephalum were more basic than the major nuclear matrix proteins of vertebrates, the lamins. Moreover, both the 27 and 38 kDa polypeptides are post-translationally modified by either D-mannosyl or D-glycosyl moieties, and not by phosphorylation as has been demonstrated for the vertebrate lamins. DNA-binding assays further revealed that the immunologically related polypeptides of 50 kDa, 45 kDa, 27 kDa and low molecular weight species of 14-21 kDa preferentially bound single-stranded DNA, but the 38 kDa polypeptide of Physarum matrix did not. Based on these findings, we conclude that the abundant nuclear matrix protein of 27 kDa belongs to a group of immunologically-related nucleic acid-binding proteins, and is immunologically and functionally distinct from the other major nuclear matrix protein of 38 kDa from P. polycephalum and the vertebrate lamins.

Mammalian nuclei contain foci which are highly enriched in components of the pre-mRNA splicing machinery

The organization of the major snRNP particles in mammalian cell nuclei has been analysed by in situ labelling using snRNA-specific antisense probes made of 2'-OMe RNA. U3 snRNA is exclusively detected in the nucleolus while all the spliceosomal snRNAs are found in the nucleoplasm outside of nucleoli. Surprisingly, U2, U4, U5 and U6 snRNAs are predominantly observed in discrete nucleoplasmic foci. U1 snRNA is also present in foci but in addition is detected widely distributed throughout the nucleoplasm. An anti-peptide antibody specific for the non-snRNP splicing factor U2AF reveals it to have a similar distribution to U1 snRNA. Co-localization studies using confocal fluorescence microscopy prove that U2AF is present in the snRNA-containing foci. Antibody staining also shows the foci to contain snRNP-specific proteins and m3G-cap structures. The presence of major components of the nuclear splicing apparatus in foci suggests that these structures may play a role in pre-mRNA processing.

Biochemical characterization of U2 snRNP auxiliary factor: an essential pre-mRNA splicing factor with a novel intranuclear distribution

U2 auxiliary factor (U2AF) is a non-snRNP protein required for the binding of U2 snRNP to the pre-mRNA branch site. Purified U2AF comprises two polypeptides of 65 and 35 kd. We have performed biochemical complementation and immunological assays to characterize U2AF in greater detail. First, we use an extract lacking only U2AF activity to show that U2AF is an essential splicing factor. Second, we show that all U2AF activity in vitro resides in the 65 kd U2AF polypeptide. Third, based upon both immunological and functional criteria, we show that U2AF is evolutionarily conserved. Most significantly, a Drosophila melanogaster nuclear extract contains proteins that are antigenically related to both human U2AF polypeptides and can substitute for human U2AF in vitro. Finally, we show that U2AF has an unexpected intranuclear distribution. Although diffusely present throughout the nucleoplasm, U2AF is also concentrated in a small number (between one and five) of nuclear 'centers.' This localization differs strikingly from that reported for snRNP antigens and splicing factors. Our data, in conjunction with those in the accompanying paper [Carmo-Fonseca et al. (1991) EMBO J., 10, 195-206.], suggest that these centers represent novel aspects of nuclear organization.

Differential distribution of factors involved in pre-mRNA processing in the yeast cell nucleus

The yeast cell nucleus has previously been shown to be divided into two regions by a variety of microscopic approaches. We used antibodies specific for the 2,2,7-trimethylguanosine cap structure of small nuclear ribonucleic acids (snRNAs) and for a protein component of small nuclear ribonucleoprotein particles to identify the distribution of small nuclear ribonucleoprotein particles within the yeast cell nucleus. These studies were performed with the fission yeast Schizosaccharomyces pombe and the budding yeast Saccharomyces cerevisiae. By using immunofluorescence microscopy and immunoelectron microscopy, most of the abundant snRNAs were localized to the portion of the nucleus which has heretofore been referred to as the nucleolus. This distribution of snRNAs is different from that found in mammalian cells and suggests that the nucleolar portion of the yeast nucleus contains functional domains in addition to those associated with RNA polymerase I activity.

Differential distribution of factors involved in pre-mRNA processing in the yeast cell nucleus

The yeast cell nucleus has previously been shown to be divided into two regions by a variety of microscopic approaches. We used antibodies specific for the 2,2,7-trimethylguanosine cap structure of small nuclear ribonucleic acids (snRNAs) and for a protein component of small nuclear ribonucleoprotein particles to identify the distribution of small nuclear ribonucleoprotein particles within the yeast cell nucleus. These studies were performed with the fission yeast Schizosaccharomyces pombe and the budding yeast Saccharomyces cerevisiae. By using immunofluorescence microscopy and immunoelectron microscopy, most of the abundant snRNAs were localized to the portion of the nucleus which has heretofore been referred to as the nucleolus. This distribution of snRNAs is different from that found in mammalian cells and suggests that the nucleolar portion of the yeast nucleus contains functional domains in addition to those associated with RNA polymerase I activity.

Immunocytochemistry of the cell nucleus

This electron microscopic review addresses in situ immunocytochemistry of the mammalian cell nucleus with special reference to the use of autoantibodies, which are the major source of antinuclear antibodies. The localization of many key nuclear antigens is documented and immunocytochemical data are related to the major functional processes of transcription and processing of RNA and to replication of DNA.

Identification of La ribonucleoproteins as a component of interchromatin granules

Monoclonal antibodies raised against the La antigen were used to localize by preembedding immunoelectron microscopy, snRNPs containing this protein. The results demonstrate that La RNPs are localized in clusters of interchromatin granules, both in Triton X-100-extracted and DNase-digested nuclei. DNase-digested salt-extracted nuclei contained, in addition, labeled structures identified as perichromatin granules and fibers. A close association of labeled granules with the nucleoli was also observed. Digestion of nuclei with DNase yielded residual scaffolds of intermediate filaments and nuclear lamina devoid of interchromatin granules and La immunostaining. Release of the La antigen was tested in the presence of ATP and cytochalasin B. Only cytochalasin was effective suggesting a role for nuclear actin in anchorage of snRNPs.

Functional role of newly formed pore complexes in postmitotic nuclear reorganization

Many nuclear proteins are released into the cytoplasm at prometaphase and are transported back into the daughter nuclei at the end of mitosis. To determine the role of this reentry in nuclear remodelling during early interphase, we experimentally manipulated nuclear protein uptake in dividing cells. Recently we and others have shown that signal-dependent, pore complex-mediated uptake of nuclear protein is blocked in living cells on microinjection of the lectin wheat germ agglutinin (WGA), or of antibodies such as PI1 that are directed against WGA-binding pore complex glycoproteins. In the present study, we microinjected mitotic PtK2 cells with WGA or antibody PI1 and followed nuclear reorganization of the daughter cells by immunofluorescence and electron microscopy. The inhibitory effect on nuclear protein uptake was monitored by co-injection of the karyophilic protein nucleoplasmin. When injected by itself early in mitosis, nucleoplasmin became sequestered into the daughter nuclei as they entered telophase. In contrast, nucleoplasmin was excluded from the daughter nuclei in the presence of WGA or antibody PI1. Although PtK2 cells with blocked nuclear protein uptake completed cytokinesis, their nuclei showed a telophase-like completed cytokinesis, their nuclei showed a telophase-like organization characterized by highly condensed chromatin surrounded by a nuclear envelope containing a few pore complexes. These findings suggest that pore complexes become functional as early as telophase, in close coincidence with nuclear envelope reformation. They further indicate that the extensive structural rearrangement of the nucleus during the telophase-G1 transition is dependent on the influx of karyophilic proteins from the cytoplasm through the pore complexes, and is not due solely to chromosome-associated components.

SnRNP core protein enrichment in the nuclear matrix

The D protein (16 kDa) is part of a protein core, common to U1, U2, U5, U4/U6 small nuclear RNA containing ribonucleoprotein particles. Monoclonal antibodies reactive with the D protein were used in quantitative dot blotting and Western blotting to demonstrate that this protein was a component of salt resistant nuclear structures and was enriched greater than 3 to 5-fold in RNAase-protected nuclear matrix preparations.

Analysis of chromatin pattern in blood lymphocytes of healthy donors and in lymphoid cells of patients with chronic lymphocytic leukaemia

The optical Fourier transformation was used to analyse the chromatin/interchromatin pattern of lymphocytes of healthy subjects and lymphoid cells of patients with chronic lymphocytic leukaemia (CLL, type B, stage O). Peripheral blood smears were prepared routinely, fixed, and stained by the Feulgen method, and the photographic images of the nuclei were quantitatively analysed. From the radial distribution of light intensity of diffractograms, several Feulgen chromatin (F-chromatin/interchromatin) descriptors were evaluated. Four showed the strongest discriminant power and these descriptors discriminated well between lymphocytes of healthy donors and lymphoid cells of CLL patients, although F-chromatin/interchromatin components of the same sizes were found in lymphocytes and lymphoid cells.

Ultrastructural and biochemical comparisons of nuclear matrices prepared by high salt or LIS extraction

We have directly compared two independently published methods for isolating operationally defined nuclear matrices by studying EM ultrastructure, protein composition and distribution of replicating DNA. Nuclear matrices prepared by extraction with 2 M NaCl consisted of fibrous pore complex lamina, residual fibrillar and granular components of nucleoli and interchromatin granules, and an extensive anastomosing internal fibrous network. These matrices were enriched in high molecular weight nonhistone proteins but were virtually devoid of histones. Consistent with previously published data, newly-replicated DNA was resistant to this high salt extraction. Nuclear matrices prepared by extraction of nuclei with 25 mM lithium 3,5-diiodosalicylate, LIS, also contained fibrous pore complex lamina, but lacked morphologically distinct residual nucleoli and were markedly depleted in internal structure. The reduced amounts and complexity of proteins associated with the LIS matrix were consistent with the ultrastructural data. Moreover, much less newly-replicated DNA was recovered in LIS matrices. The data show that LIS dissociates nuclear ultrastructure and extracts both protein and DNA in proportion to the concentration used, regardless of whether nuclei or high salt nuclear matrices are used as starting material. While the data suggest that LIS may not necessarily be an optimal reagent for preparing nuclear matrices containing internal structural elements from all tissue sources, it may be useful for selectively solubilizing and analyzing components of the nuclear matrix.

Quantitative analysis of a nuclear antigen in interphase and mitotic cells

The quantification of an interchromatin-associated antigen, designated p 105, during cellular passage through mitosis is described. Indirect immunofluorescence microscopy and immunogold electron microscopy demonstrated a qualitative increase in p 105 within the mitotic cytoplasm. Multiparameter flow cytometric analysis was performed on fixed cells sequentially stained with anti-p 105 immunofluorescence and/or propidium iodide. This analysis demonstrated approximately a tenfold increase in intracellular p 105 content as a function of progression from the G2 to the M phase. This increase was corroborated by the quantitative immunoblot analysis of colchicine-treated cell cultures and of cells sorted on the basis of anti-p 105 immunofluorescence. The data reveal that the increased levels of anti-p 105 immunofluorescence in conjunction with flow cytometry may be used effectively to quantitate mitotic index and isolate mitotic cells. The function and modulation of p 105 throughout the cell cycle is discussed.

Modulation of the nuclear antigen p105 as a function of cell-cycle progression

The characterization of the proliferation-associated nuclear antigen designated p105 in quiescent and proliferating lymphocytes is described. Through the use of novel flow cytometric and cell-sorting strategies the intracellular content of p105 was assessed in situ on a per cell basis. These analyses demonstrated the presence of multiple cellular subpopulations within the cell cycle differing significantly in p105 content. The data revealed that the flow cytometric quantitation of p105 levels may effectively discriminate cycling from noncycling cells. Immunogold electron microscopy revealed that the modulation of this interchromatin-associated antigen was correlated with a significant degree of nuclear restructuring. In conjunction with cell sorting, immunogold electron microscopy and immunoblot controls demonstrated that the cell-cycle-related modulation in p105 cannot be accounted for by increased cellular mass or antigen sequestration. The significance of these controls and of the potential role of p105 in cellular proliferation is discussed.

Intranuclear appearance of the phosphorylated form of cytoskeleton-associated 350-kDa proteins in U1-ribonucleoprotein regions after growth stimulation of fibroblasts

Cytoskeleton-associated 350-kDa and 80-kDa polypeptides, which were immunoprecipitated with polyclonal antibody against microtubule-associated protein 1 (MAP-1), were rapidly phosphorylated on mitogenic stimulation of quiescent fibroblasts with serum or growth factors. The enhanced phosphorylation was evident within 5 min and reached a maximum 2 hr after the stimulation. Phosphorylated MAP-1 analogues were first detected in the cytoplasm around the microtubule-organizing center and then in the nucleus by immunofluorescent staining with a monoclonal antibody that recognized the phosphorylated form of MAP-1. The monoclonal antibody reacted with the 350-kDa protein in immunoblot analysis and immunostained intranuclear speckles; both immunoreactions were abolished by treatment with alkaline or acid phosphatase. The nuclear speckles stained by the monoclonal antibody were also stained by anti-U1 small nuclear ribonucleoprotein antibodies on double immunofluorescence, suggesting that the stained regions are sites of maturation of messenger RNA. These results support the idea that part of the cytoskeleton-associated 350-kDa protein is phosphorylated and transferred to the nuclear region of mRNA modification as a common early process after growth stimulation.

Macromolecular domains containing nuclear protein p107 and U-snRNP protein p28: further evidence for an in situ nuclear matrix

Polyclonal antibodies have been produced which react with a nuclear protein having a molecular weight of 107kD and a pI of 8.7-8.8 (designated p107). This protein is shown to be a component of the residual ribonucleoprotein (RNP) network of the nuclear matrix. P107 localized exclusively to the nuclear interior but not within nucleolar or chromatin domains. We have taken advantage of this unique probe to examine whether the RNP network of the isolated nuclear matrix has a physical counterpart in situ. We show that RNA, p107, divalent cations and the 28 kD Sm antigen of U-snRNPs are components of in situ macromolecular assemblies. While the morphology and intranuclear distribution of these assemblies are insensitive to the removal of chromatin, they are markedly altered by degradation of RNA. Digestion in situ of RNA in the presence of EDTA followed by extraction with high ionic strength buffers solubilized the components of these assemblies. Electron microscopic and immunobiochemical data are presented which support the concept that the residual RNP network of the nuclear matrix is an isolate of a pre-existing structure, and that perturbations in this internal network can be created by RNA degradation, depletion of essential metal ions and proteolysis.