Atomic force microscopy of the cell nucleus

In mammals and plants, the cell nucleus is organized in dynamic macromolecular domains involved in DNA and RNA metabolism. These domains can be visualized by light and electron microscopy and their composition analyzed by using several cytochemical approaches. They are composed of chromatin or ribonucleoprotein structures as interchromatin and perichromatin fibers and granules, coiled bodies, and nuclear bodies. In plants, DNA arrangement defines chromocentric and reticulated nuclei. We used atomic force microscopy to study the in situ structure of the plant cell nucleus. Samples of the plants Lacandonia schismatica and Ginkgo biloba were prepared as for electron microscopy and unstained semithin sections were mounted on glass slides. For comparison, we also examined entire normal rat kidney cells using the same approach. Samples were scanned with an atomic force microscope working in contact mode. Recognizable images of the nuclear envelope, pores, chromatin, and nucleolus were observed. Reticulated chromatin was observed in L. schismatica. Different textures in the nucleolus of G. biloba were also observed, suggesting the presence of nucleolar subcompartments. The observation of nuclear structure in situ with the atomic force microscope offers a new approach for the analysis of this organelle at high resolution.     

Physiological importance of RNA and protein mobility in the cell nucleus

Trafficking of proteins and RNAs is essential for cellular function and homeostasis. While it has long been appreciated that proteins and RNAs move within cells, only recently has it become possible to visualize trafficking events in vivo. Analysis of protein and RNA motion within the cell nucleus have been particularly intriguing as they have revealed an unanticipated degree of dynamics within the organelle. These methods have revealed that the intranuclear trafficking occurs largely by energy-independent mechanisms and is driven by diffusion. RNA molecules and non-DNA binding proteins undergo constrained diffusion, largely limited by the spatial constraint imposed by chromatin, and chromatin binding proteins move by a stop-and-go mechanism where their free diffusion is interrupted by random association with the chromatin fiber. The ability and mode of motion of proteins and RNAs has implications for how they find nuclear targets on chromatin and in nuclear subcompartments and how macromolecular complexes are assembled in vivo. Most importantly, the dynamic nature of proteins and RNAs is emerging as a means to control physiological cellular responses and pathways.     

Three-dimensional analysis of the arrangement of compact chromatin in the nucleus of G0 rat lymphocytes

The arrangement of compact chromatin of G₀ lymphocytes was studied in three-dimensional reconstructions of the ensemble of the chromatin and of individual compact chromatin bodies. Rat spleen was serially cut and sections were contrasted with procedures preferential for DNA. Electron microscopy images were digitized, processed, and displayed using a commercial soft-ware package, complemented by a system for three-dimensional reconstruction and analysis developed by us on an IBM-compatible microcomputer provided with an image acquisition board. The reconstructions showed a continuous layer of compact chromatin in contact with the nuclear envelope that prevents the automatic recognition of individual chromatin clumps. The ensemble of the arrangement of compact chromatin was found to be very similar in different lymphocytes. After morphological filtering procedures, the initial mass was divided into individual bodies of compact chromatin, which were tagged. Most of these bodies contact the nuclear envelope. The number of bodies as well as the number of contacts with the envelope are similar and correspond to a haploid number of chromosomes. The largest body is always the one containing nucleolus-associated chromatin. When the cell has two nucleoli, the nucleolus-associated chromatin bodies contact the envelope in diametrically opposed areas. This feature was also described in rat liver cells. It is concluded that: (a) the individualized compact chromatin bodies do not correspond to an entire chromosome or to a pair of chromosomes; (b) the arrangement of compact chromatin is not identical in each G₀ lymphocyte, but there are patterns that are repeated with limited changes; and (c) there are common features that appear in different cell types of individuals of the same species.     

Cell cycle dependent alterations of chromatin structure in situ as revealed by the accessibility of the nuclear protein AF-2 to monoclonal antibodies.

We have recently described a novel nuclear antigen, AF-2, which is related to cell cycle dependent alterations of chromatin structure. We show by two parameter flow cytometry on a cell by cell basis that the antigen is accessible to specific monoclonal antibodies only in mitotic and postmitotic early G1-phase cells. The evaluation of nuclease susceptibility and AF-2 antigen accessibility reveals different subcompartments of the G1-phase of the cell cycle with distinct chromatin conformations. Digestion with DNase I seems to alter the chromatin structure according to concentration and this is reflected by an increase of the antigen accessibility. Chromatin in the more condensed early G1-phase is specifically digested by lower concentrations of the enzyme than chromatin in later stages of interphase. Chromatin from cells in the late-G1, S-, and G2-phases shows a higher relative resistance to DNase I and a reduced accessibility of the AF-2 antigen to monoclonal antibodies. Nuclease S1 has a similar effect on chromatin topology, as revealed by the reaction with anti-AF-2 antibodies, without digestion of detectable amounts of DNA. The antigen becomes available to the antibodies in almost all cells by digestion with high concentrations of DNase I or Nuclease S1.     

Cellular death by apoptosis in some radiosensitive and radioresistant mammalian tissues

A number of facts suggest that chromatin autodigestion, occurring in the early phase of apoptosis, is carried out by an enzymatic system, composed of an endonuclease and a protease, which yields oligonucleosomic chromatin fragments. Though this enzymatic system appears to be present in most mammalian cell nuclei, radiation-induced apoptosis takes place, with a high frequency, only in cell populations having less well-developed nuclear matrices, such as lymphoid cells. Moreover, apoptosis seems to occur in a different manner in cells with less well-developed nuclear matrices (radiosensitive cells) compared with cells that contain dense nuclear matrices (radioresistant cells). Thus, dying lymphocytes progressively release their degraded chromatin from nuclei, without displaying the cellular budding and formation of apoptotic bodies. Nevertheless, apoptosis remains the main cause of cell death and cell depletion in irradiated lymphoid tissues. In contrast, the process of cellular budding and formation of apoptotic bodies appears to be specific for cells having well-developed nuclear matrix, such as those from small intestine and liver. However, in these tissues the frequency of apoptosis is relatively low and cannot be considered as the main cause of radiation-induced tissue involution.     

The nuclear bodies formed by histone demethylase KDM7A

Dear Editor, In the nucleus of higher eukaryotes, chromatin occupies only a small proportion of the nuclear space, while many proteins and RNAs segregate into membrane-less nuclear bodies (NBs).These NBs follow a stochastic or ordered assembly model and constantly exchange components with the surrounding nucleoplasm (Jain et al., 2016).Typical NBs include nucleoli, nuclear speckles, paraspeckles, PML bodies, Cajal bodies, polycomb bodies and Sam68 bodies,which play critical roles in various biological processes such as ribosome assembly, RNA processing, and protein modification.The dysfunction of nuclear bodies may cause diseases, such as cancer (Li et al., 2019).     

The C. elegans Polycomb gene SOP-2 encodes an RNA binding protein

Epigenetic silencing of Hox cluster genes by Polycomb group (PcG) proteins is thought to involve the formation of a stably inherited repressive chromatin structure. Here we show that the C. elegans-specific PcG protein SOP-2 directly binds to RNA through three nonoverlapping regions, each of which is essential for its localization to characteristic nuclear bodies and for its in vivo function in the repression of Hox genes. Functional studies indicate that the RNA involved in SOP-2 binding is distinct from either siRNA or microRNA. Remarkably, the vertebrate PcG protein Rae28, which is functionally and structurally related to SOP-2, also binds to RNA through an FCS finger domain. Substitution of the Rae28 FCS finger for the essential RNA binding region of SOP-2 partially restores localization to nuclear bodies. These observations suggest that direct binding to RNA is an evolutionarily conserved and potentially important property of PcG proteins.     

Ultrastructure of the nuclear apparatus of the lower ciliateRemanella granulosa Kahl (Karyorelictida)

Summary The nuclear apparatus ofRemanella granulosa has been investigated using conventional TEM methods and Bernhard's technique of preferential RNP staining. This species has two (rarely three) macronuclei and a single micronucleus (rarely two micronuclei). The nuclei always form a single group.The macronuclei contain a fibro-granular matrix resistant to EDTA destaining, and several nucleoli and chromatin bodies. The chromatin bodies are readily bleached with EDTA and are often clustered, or even fused, forming chromocenters. The nuclei are of the compact concentric type. Some macronuclei contain nuclear bodies, as finely fibrous spheres or bundles of coarse fibers, or both. Neither type of nuclear body is destained with EDTA. The spheres are frequently associated with nucleoli. There is no evidence of any transition between the two types of nuclear bodies. The macronuclear envelope contains numerous pore complexes and is strengthened with an electron dense layer. The micronucleus is filled with spongy condensed chromatin and surrounded by an envelope with occasional pores. This nucleus lacks nucleoli and nuclear bodies.     

Segregation of RNA and separate packaging of DNA and RNA in apoptotic bodies during apoptosis

Apoptosis is characterized by a complex and remarkably ordered choreography of events consisting of the preparatory and execution steps that all culminate in disposal of the cell remnants. The disposal occurs in a manner that is the least destructive to the tissue: the remains of nuclear chromatin and cytoplasm are packaged in apoptotic bodies which are then phagocytized by neighboring live cells without invoking inflammatory or autoimmune response. In the present study we describe that in the course of apoptosis cellular RNA becomes sequestered and packaged into granules and then into apoptotic bodies, separately from DNA. This separation, which appears to be initiated by the nucleolar segregation, was observed in HL-60 cells that were undergoing spontaneous apoptosis in cultures or were treated with the DNA-damaging drug, DNA topoisomerase I inhibitor camptothecin (CPT), or with the cell death ligand, tumor necrosis factor-alpha. RNA separation was also observed in apoptotic MCF-7 cells following treatment with CPT. RNA and DNA in apoptotic cells were identified histochemically, by their differential stainability with pyronin Y and Hoechst 33342 fluorochromes, respectively, and immunocytochemically, by labeling the RNA with BrU for various periods of time and detection of the incorporated precursor with fluoresceinated anti-BrU mAb; DNA was counterstained with 7-aminoactinomycin D. Over 90% of apoptotic bodies that contained RNA had no detectable DNA and vice versa, the apoptotic bodies containing DNA had no detectable RNA. Packaging RNA and DNA into separate apoptotic bodies suggests that the phagosomes of the cells that ingest these particles are specialized: some of them are responsible for DNA degradation, others for degradation of RNA. Such specialization may facilitate heterophagic degradation of nucleic acids during apoptosis.     

The ultrastructure of the nuclei and the behaviour of the sex chromosomes of human spermatogonia

Summary The nuclear structure of human spermatogonia has been studied with electron microscopical and histochemical methods. Type B spermatogonia have chromatin clumps without any special ultrastructure and several nucleoli. Five different types of nuclear bodies, and besides, a nuclear vacuole, have been observed in type A spermatogonia. Type I bodies are typical nucleoli consisting of three regions: amorphous, fibrillar and granular. Type II, III and V are considered to be atypical nucleoli. Type IV bodies are small chromatin condensations. Type I bodies are the only ones in which RNA was demonstrated by light histochemical techniques and no PAS positive material was found inside the nuclei. The absence of any special ultrastructure in the chromatin from spermatogonia, and the small mass of the chromatin condensations, show that the human X chromosome and perhaps the Y chromosome are not heteropycnotic in the interphasic nuclei of human spermatogonia.Abbreviations Used RNA ribonucleic acid - gonia spermatogonia This work has been supported by a grant (No. 2623) of the Consejo Nacional de Investigaciones Cientificas y Tecnicas, and partially by a grant (C.M. 6522) from the Population Council.We wish to thank Professor R. E. Mancini for his suggestions during this investigation and his support for its achievement, and to Dr. J. C. Lavieri for providing the biopsies.