Still Immunodetectable Nuclear RNPs Are Extruded from the Cytoplasm of Spontaneously Apoptotic Thymocytes

The fate of different nuclear ribonucleoprotein (RNP) components was investigated during spontaneous apoptosis of thymocytes using specific monoclonal antibodies against snRNPs, hnRNPs, and ribosomal proteins at light and electron microscopy levels and by flow cytometry. It was found that, during apoptosis, nuclear RNP-containing structures (perichromatin granules, interchromatin granules, and perichromatin fibrils) segregate in the interchromatin space and cluster into heterogeneous aggregates of granules in which some of the structures may still be recognized morphologically. Along with the progress of apoptosis, the clusters are extruded from the nucleus into the cytoplasm, from which they are finally released via cytoplasmic extrusions. At all these stages, RNPs inside the clusters are always recognized by specific antibodies, even when they bleb out of the cell surface, thus suggesting that degradation of RNPs might be only partial during apoptosis. This could be potentially harmful in genetically susceptible subjects, as the appropriate MHC class II molecules may capture and present normally cryptic self-peptides. It is tempting to speculate that this event might have implications in the etiology of autoimmune diseases.     

Ultrastructural distribution of nuclear ribonucleoproteins as visualized by immunocytochemistry on thin sections

The ultrastructural distribution of nuclear ribonucleoproteins (RNP) has been investigated by incubation of thin sections of mouse or rat liver, embedded in Lowicryl K4M or prepared by cryoultramicrotomy, with antibodies specific for RNP. The antibodies were localized by means of a protein A-colloidal gold complex. Anti-small nuclear (sn)RNP antibodies, specific for determinants of the nucleoplasmic snRNP species containing U1, U2, U4, U5, and U6 RNAs, were found associated preferentially with perichromatin fibrils, interchromatin granules, and coiled bodies. This indicates an early association of snRNP with structural constituents containing newly synthesized heterogeneous nuclear RNA. It also suggests a possible structural role of some snRNPs in nuclear architecture. Antibodies against the core proteins of heterogeneous nuclear RNP particles associate preferentially with the border regions of condensed chromatin, and in particular with perichromatin fibrils and some perichromatin granules. These results are discussed in view of recent knowledge about the possible role of nucleoplasmic RNP-containing components in the functions of the cell nucleus.     

The effects of zinc chloride on the RNP structures in HEp-2 cells: accumulation of perichromatin granules

The effects of zinc on the ribonucleoprotein (RNP) constituents of HEp-2 cells have been analyzed. Pulse-chase autoradiographic experiments show a preferential inhibition of nucleolar RNA synthesis and a block in the transport of nucleolar and extranucleolar RNA in zinc-treated cells. Concomitantly with the disturbance in RNA metabolism and in protein synthesis, nucleolar condensation, accumulation of perichromatin granules and fibrils, condensation of interchromatin fibrils, and appearance of dense granular bodies occur. Accumulation of perichromatin fibrils and condensation of interchromatin fibrils appear to be related to the block in the transport of heterogeneous nuclear RNA. Depletion of certain proteins required for the assembly of RNP particles could share in the abnormal behavior of RNA and lead to the accumulation of perichromatin granules and the appearance of dense granular bodies.     

Ultrastructural distribution of ribonucleoprotein complexes during mitosis. snRNP antigens are contained in mitotic granule clusters

The great majority of snRNP and hnRNP ribonucleoproteins have been shown to be confined to the nucleus except during periods of cell division. We have now determined the fine structure distribution of polypeptides associated with these RNP complexes during interphase and mitosis in mammalian tissue culture cells using immunoelectron microscopy. Many hnRNP antigens are found at the periphery of heterochromatin masses, known to be the sites of non-rRNP proteins initially surround areas of condensing chromatin and later become generally dispersed throughout the mitotic cell. The Sm protein antigens of snRNP complexes are found diffusely distributed in interphase nuclei as well as concentrated in fields of interchromatin granules (ICG). Proteins of snRNP complexes, unlike those of hnRNP, are associated with discernible cellular structures during mitosis. By prometaphase/metaphase, dense granular clusters are observed to contain a high concentration of snRNPs. These mitotic granule clusters (MGCs) are often in close proximity to chromosomal masses by late anaphase/telophase. The MGC structures are morphologically similar to interchromatin granule fields found in interphase nuclei. Furthermore, like interchromatin granules, they are sites of a high concentration of snRNP antigens and do not contain detectable hnRNP proteins or DNA.     

Ultrastructural detection of nucleic acids within heat shock-induced perichromatin granules of HeLa cells by cytochemical and immunocytological methods

The perichromatin granules (PGs) are enigmatic structures of the cell nucleus. The major drawbacks for a biological study are their rare occurrence and their small size in normal conditions.As heat shock has been shown to increase their number, we applied a hyperthermal shock on HeLa cells to investigate the nucleic acid content of PGs by means of cytochemical and immunocytological approaches. These heat shock-induced PGs (hsiPGs) appeared as clusters organized in the form of honeycomb structures and were always associated with some blocks of condensed chromatin, such as the perinucleolar chromatin shell. A stalk connecting the hsiPG to the chromatin could be observed.For the detection of RNA, we applied an immunocytological method involving two anti-RNA antibodies and quantified the gold labelling obtained. The results clearly revealed that hsiPGs contained RNA.Regarding to the detection of DNA, we used three different methods followed by quantitative analyses. The results seemed to indicate that a small amount of DNA was present in hsiPGs.Together, these findings suggest that hsiPGs might be RNP structures associated with particular regions of DNA.     

Ultrastructural studies of H-1 parvovirus replication. II. Induced changes in the deoxyribonucleoprotein and ribonucleoprotein components of human NB cell nuclei.

Ultrastructural changes in the nuclear DNP and RNP components of human NB cells induced by synchronous infection with H-1 parvovirus were studied using Bernhard's EDTA method of staining. Early events (12 h after infection) occurred in the nucleolus. Chromatin within the nucleolar fibrous centers condensed thereby converting the centers to vacuoles. DNP associated with the granular nucleolonema also contracted markedly, causing a disruption of this skein-like structure; it then migrated peripherally forming a heterochromatic cortex surrounding the granular nucleolar vestige. Subsequently (24–36 h after inoculation), condensation of extranucleolar chromatin took place concurrently with the accumulation of extensive amounts of interchromatin granules in the nucleus and cytoplasm. Conglomerates of perichromatin fibrils and interchromatin granules were frequently juxtapposed to the condensing chromatin. Large clumps of interchromatin granules were also closely associated with fragmenting nucleoli, and the apparent transformation of nucleolar granules into interchromatin granules was observed. Accumulation of H-1 protein on chromatin evidently fostered its condensation resulting in the pathology described.     

Further cytochemical studies on the perichromatin granules

Summary The perichromatin granules were studied in hepatocytes of experimental rats injected with cycloheximide because the increased number of these nuclear components after such treatment facilitated their cytochemical investigation. Most perichromatin granules were sensitive to the digestion with pepsin and ribonuclease. In contrast, small population of perichromatin granules was resistent to such digestion under conditions which remove known RNA containing components such as ribosomes, nucleolar RNP components and interchromatin granules. The size of these resistent perichromatin granules was reduced and they consisted of filaments the width of which was similar to that of filaments in the chromatin. Moreover, a small population of perichromatin granules was sensitive to the digestion with pepsin and deoxyribonuclease. The size of these granules was only slightly reduced. All these observations indicate that most perichromatin granules contain the RNA and some the DNA. A possibility also exists that the perichromatin granules might contain both RNA and DNA but in various proportions. In addition, partial digestion with pepsin followed by a complete digestion with ribonuclease and deoxyribonuclease removed perichromatin granules as well as other nucleoprotein structures. On the other hand, such digestion facilitated the visualization of the nuclear and cytoplasmic skeleton (matrix) in situ.Dedicated to the memmory of Dr. W. Bernhard     

Immunoelectron microscope localization of snRNP,hnRNP, and ribosomal proteins in mouse spermatogenesis

We have studied the ultrastructural distribution of heterogeneous nuclear ribonucleoproteins (hnRNPs), small nuclear ribonucleoproteins (snRNPs), and ribosomal proteins during mouse spermatogenesis and spermiogenesis by means of specific antibodies and immunocytochemistry. All the above components were detectable from primary spermatocytes until the spermatid elongation phase, when the RNA synthetic activity is known to cease. Ribosomal protein (P1/P2 and L7) labeling disappeared as early as during the acrosome phase, and nucleoli were no longer labeled even during the cap phase. The nucleoplasmic structures labeled with the different anti-nucleoplasmic RNP immunoprobes corresponded, until the acrosome phase, to those previously observed as targets of the same antibodies in the nucleoplasm of somatic cell nuclei. Clusters of interchromatin granules of spermatocyte and early spermatid nuclei exhibit some labeling for hnRNP when compared with nuclei of Sertoli cells or previously analyzed liver or tissue culture cells, where these structural constituents usually remain weakly labeled or unlabeled. In spermatids in step 10, another type of nuclear granule, resembling perichromatin granules, but occurring in aggregates, can be observed. These structural constituents were labeled with antibodies recognizing nucleoplasmic snRNP antigens and therefore suggesting a non-nucleolar origin of these granules. Finally, we have observed nucleoplasmic areas of fibrogranular material, occurring only in primary spermatocytes. These components were labeled with anti-ribosomal protein antibodies but did not contain either hnRNPs or snRNPs. © 1993 Wiley-Liss, Inc.     

Fine structural organization of a non-reticulate plant cell nucleus

We studied the fine structural organization of the meristematic nucleus in roots of Lycopesicon esculentum (tomato) using ultracytochemical and immunocytochemical approaches. The nucleus has a non-reticulate (i.e. low DNA content) structure whose supramolecular organization differs in some respects from that in reticulate nuclei, principally in the organization of the chromocentres associated with the nuclear envelope, with which centromeric structures appear to be associated. The main difference at the nucleolar level is found in the fibrillar centres, which have a low amount of DNA labelling and in which inclusions of condensed chromatin are present only very rarely. The distribution of nucleolar DNA amongst the nucleolar compartments is similar to that in reticulate nucleoli as demonstrated using an anti-DNA monoclonal antibody. Tomato nuclei have nucleolus-associated bodies or karyosomes, like other plant species with a low DNA content and non-reticulate nuclear organization. The nuclear ribonucleoprotein structures in the inter- and perichromatin regions, namely inter- and perichromatin fibrils and granules, show similar ultrastructural and cytochemical characteristics in both types of nuclei.Abbreviations NAC nucleolus associated chromatin - CES centromeric structures - NOR nucleolar organizing region - NAB nucleolus associated body - IG interchromatin granules - RNP ribonucleoprotein - Mab monoclonal antibody by M.F. Trendelenburg     

Ribonucleoprotein components in liver cell nuclei as visualized by cryoultramicrotomy.

The interphase nucleus of the normal rat hepatocyte has been studied in ultrathin frozen sections after glutaraldehyde fixation and the modification of various staining procedures known to be specific for DNA structures (Moyne's thallium stain, Gautier's osmium-ammine) or preferential for RNP carriers and basic proteins (regressive stains based on the use of EDTA or citrate, negatively charged colloidal iron). The results are comparable to those obtained after classical dehydration and embedding. Particular attention has been paid to the nucleolus and extranucleolar RNP components, such as perichromatin fibrils and granules, as well as interchromatin granules. A striking observation was the uneven size and the strongly increased number of perichromatin granules, and the appearance of a contiguous interchromatin net, containing nucleoproteins. Cryoultramicrotomy without embedding appears to be very useful for the exploration of the nucleus in thick sections which remain sufficiently transparent even with the usual accelerating voltages.     

Immunocytochemical identification of nuclear structures containing snRNPs in isolated rat liver cells

Small nuclear ribonucleoproteins (snRNPs) containing U1, U2, U4, U5, and U6 small nuclear RNAs were detected by ultrastructural immunocytochemistry in the nuclei of isolated rat hepatocytes using Fab fragments of anti-Sm and anti-RNP autoantibodies. Their localization was carried out in normal cells and in cells treated with two drugs, the adenosine analog DRB and CdCl2, which alter the number and distribution of nuclear RNP components. It was found that more precise determination of the distribution of these small RNAs could be obtained by using two complementary procedures in parallel rather than either one alone. They consisted of an indirect immunoperoxidase labeling carried out before embedment and an indirect immunogold labeling applied to thin sections of cells embedded in Lowicryl K4M. The results indicate that snRNPs are associated with all extranucleolar perichromatin fibrils and granules and interchromatin fibrils, which confirms that they occur in structures involved in the synthesis and processing of hnRNA. The snRNPs are not associated with nucleolar perichromatin granules induced by DRB, which confirms that there may be two kinds of perichromatin granules. The snRNPs are also associated with the still enigmatic interchromatin granules which apparently do not contain hnRNA but at least in DRB-treated cells, also contain ribosomal RNA.     

Cadmium induced apoptotic changes in chromatin structure and subphases of nuclear growth during the cell cycle in CHO cells

CHO cells were grown in the presence of 1 M CdCl₂ and subjected to ATP-dependent replicative DNA synthesis after permeabilization. By decreasing the density of the cell culture replicative DNA synthesis was diminishing. At higher than 2 × 10⁶ cell/ml concentration Cd had virtually no effect on the rate of DNA replication. Growth at higher cell concentrations could be supressed by increasing Cd concentration. After Cd treatment cells were synchronized by counterflow centrifugal elutriation. Cadmium toxicity on cell growth in early and mid S phase led to the accumulation of enlarged cells in late S phase. Flow cytometry showed increased cellular and nuclear sizes after Cd treatment. As the cells progressed through the S phase, 11 subpopulations of nuclear sizes were distinguished. Apoptotic chromatin changes were visualized by fluorescent microscopy in a cell cycle dependent manner. In the control untreated cells the main transitory forms of chromatin corresponded to those we have published earlier (veil-like, supercoiled chromatin, fibrous, ribboned structures, chromatin strings, elongated prechromosomes, precondensed chromosomes). Cadmium treatment caused: (a) the absence of decondensed veil-like structures and premature chromatin condensation in the form of apoptotic bodies in early S phase (2.2–2.4 average C-value), (b) the absence of fibrous structures, the lack of supercoiled chromatin, the appearance of uncoiled ribboned chromatin and perichromatin semicircles, in early mid S phase (2.5–2.9 C), (c) the presence of perichromatin fibrils and chromatin bodies in mid S phase (2.9–3.2 C), (d) early intra-nuclear inclusions, elongated forms of premature chromosomes, the extrusion and rupture of nuclear membrane later in mid S phase (3.3–3.4 C), (e) the exclusion of chromatin bodies and the formation of clusters of large-sized perichromatin granules in late S phase (3.5–3.8 C) and (f) large extensive disruptions and holes in the nuclear membrane and the clumping of incompletely folded chromosomes (3.8–4. C).     

Protein Kinases Are Associated with Multiple,Distinct Cytoplasmic Granules in Quiescent Yeast Cells

The cytoplasm of the eukaryotic cell is subdivided into distinct functional domains by the presence of a variety of membrane-bound organelles. The remaining aqueous space may be further partitioned by the regulated assembly of discrete ribonucleoprotein (RNP) complexes that contain particular proteins and messenger RNAs. These RNP granules are conserved structures whose importance is highlighted by studies linking them to human disorders like amyotrophic lateral sclerosis. However, relatively little is known about the diversity, composition, and physiological roles of these cytoplasmic structures. To begin to address these issues, we examined the cytoplasmic granules formed by a key set of signaling molecules, the protein kinases of the budding yeast Saccharomyces cerevisiae. Interestingly, a significant fraction of these proteins, almost 20%, was recruited to cytoplasmic foci specifically as cells entered into the G₀-like quiescent state, stationary phase. Colocalization studies demonstrated that these foci corresponded to eight different granules, including four that had not been reported previously. All of these granules were found to rapidly disassemble upon the resumption of growth, and the presence of each was correlated with cell viability in the quiescent cultures. Finally, this work also identified new constituents of known RNP granules, including the well-characterized processing body and stress granule. The composition of these latter structures is therefore more varied than previously thought and could be an indicator of additional biological activities being associated with these complexes. Altogether, these observations indicate that quiescent yeast cells contain multiple distinct cytoplasmic granules that may make important contributions to their long-term survival.