Nuclear matrix involvement in sperm head structural organization

Summary— In the sperm nuclei the DNA is packaged into a highly condensed form and is not organized into nucleosome and solenoid but is bound and stabilized mainly by the protamines that arrange the DNA in an almost crystalline state. As demonstrated for somatic cells, the sperm DNA has been reported to be organized in loop domains attached to the nuclear matrix structures. However, the possible role of the sperm head matrix in maintaining the loop organization in absence of a typical nucleosomal structures has not been fully elucidated. By using in situ nick translation at confocal and electron microscope level, we analyzed the organization of the DNAprotamine complex and its association with the sperm nuclear matrix. The data obtained indicate that the chromatin organization in sperm nuclei is maintained during the sperm condensation by means of interactions with the nuclear matrix at fixed sites. The fine stucture of sperm nucleus and of sperm nuclear matrix, investigated on sections and replicas of freeze-fractured specimens, suggests that the lamellar array, observed by freeze-fracturing in the sperm nuclei, could depend on the inner matrix which presents a regular organization of globular structures possibly involved in the maintenance of chromatin domains in highly condensed sperm nuclei also.     

Alterations in nuclear anatomy by chemical modification of proteins in isolated rat liver nuclei

Whole rat liver nuclei were treated with citraconic anhydride, a reagent specific for primary amines. Dramatic changes were observed in nuclear morphology and light scattering properties. An analysis for DNA and RNA content suggested that DNA was released from the nuclei with a short half-time, approximately 2-4s demonstrating a biphasic release profile. RNA was similarly released but with a monophasic profile. Analysis of SDS-PAGE gels of modified nuclei demonstrated a progressive enrichment of nuclear matrix (lamins) polypeptides with extent of modification. H1 histone was quantitatively lost as a function of modification reagent concentration, while approx. 50% of the nucleosomal histones cosedimented with DNA- and RNA-free nuclei. Modification in the presence of 2 mM EGTA released all the DNA and RNA [less than or equal to 1% remaining) while retaining structures characteristic of nuclear matrix, nucleoli, and ribonucleoprotein (predominantly hnRNA group A and B). These nucleic acid-deficient structures have been termed nuclear fossils to differentiate them from high salt detergent-prepared empty nuclear sacks, nuclear remnants, or nuclear scaffolds. Modification in the presence of 2% Triton X-100 results in structures similar to the nuclear fossils (EGTA treatment), but missing the double bilayer and a 51K polypeptide that is a major component of the other structures. The use of chemical modification on the nucleus provides an experimental approach for examining the role of ionic interactions in controlling nuclear structure. Citraconylation may thus serve two functions: (a) as a protein-specific perturbant of nuclei capable of simply and rapidly preparing a range of structural variants for the analysis of nuclear interactions; (b) offer a paradigm for control of nucleic acid-polypeptide interactions based on post-translational alterations in protein charge.     

The spatial position and replication timing of chromosomal domains are both established in early G1 phase

Mammalian chromosomal domains replicate at defined, developmentally regulated times during S phase. The positions of these domains in Chinese hamster nuclei were established within 1 hr after nuclear envelope formation and maintained thereafter. When G1 phase nuclei were incubated in Xenopus egg extracts, domains were replicated in the proper temporal order with nuclei isolated after spatial repositioning, but not with nuclei isolated prior to repositioning. Mcm2 was bound both to early- and late-replicating chromatin domains prior to this transition whereas specification of the dihydrofolate reductase replication origin took place several hours thereafter. These results identify an early G1 phase point at which replication timing is determined and demonstrate a provocative temporal coincidence between the establishment of nuclear position and replication timing.     

Nuclear membrane cholesterol can modulate nuclear nucleoside triphosphatase activity

Previous work has suggested that changes in nuclear membrane cholesterol may induce a stimulation in nuclear nucleoside triphosphatase (NTPase) activity. The purpose of the present study was to directly investigate if nuclear membrane cholesterol can stimulate nuclear NTPase activity. The cholesterol content of nuclei was altered with a liposomal methodology. The cholesterol content of nuclei isolated from hepatic tissue was relatively low in comparison to that typically exhibited by other membrane fractions. Because of this, it was difficult to further deplete the nuclear membrane of cholesterol, but we could successfully increase the cholesterol content after exposure to cholesterol-enriched liposomes. Nuclear NTPase activity was potently stimulated (∼︁ 150–200% of control) by an increase in the nuclear membrane cholesterol content. The Vmax of the NTPase activity in the presence of ATP or GTP was significantly increased after cholesterol enrichment without altering the affinity of the enzyme for these moieties. Mg²⁺ dependency of NTPase activity was also altered by cholesterol incorporation into the nuclear membrane. Cholesterol enrichment of the nuclear membrane also left the nuclei more susceptible to damage by salt-induced lysis than control nuclei. Our results clearly demonstrate that the cholesterol content of the nuclear membrane will have significant, direct effects on nuclear integrity and NTPase activity. © 1996 Wiley-Liss, Inc.     

Organization of higher-level chromatin structures (chromomere,chromonema and chromatin block) examined using visible light-induced chromatin photo-stabilization

The method of chromatin photo-stabilization by the action of visible light in the presence of ethidium bromide was used for investigation of higher-level chromatin structures in isolated nuclei. As a model we used rat hepatocyte nuclei isolated in buffers which stabilized or destabilized nuclear matrix. Several higher-level chromatin structures were visualized: 100nm globules-chromomeres, chains of chromomeres-chromonemata, aggregates of chromomeres-blocks of condensed chromatin. All these structures were completely destroyed by 2M NaCl extraction independent of the matrix state, and DNA was extruded from the residual nuclei (nuclear matrices) into a halo. These results show that nuclear matrix proteins do not play the main role in the maintenance of higher-level chromatin structures. Preliminary irradiation led to the reduction of the halo width in the dose-dependent manner. In regions of condensed chromatin of irradiated nucleoids there were discrete complexes consisting of DNA fibers radiating from an electron-dense core and resembling the decondensed chromomeres or the rosette-like structures. As shown by the analysis of proteins bound to irradiated nuclei upon high-salt extraction, irradiation presumably stabilized the non-histone proteins. These results suggest that in interphase nuclei loop domains are folded into discrete higher-level chromatin complexes (chromomeres). These complexes are possibly maintained by putative non-histone proteins, which are extracted with high-salt buffers from non-irradiated nuclei.     

Fluorescent in situ hybridization of the telomere repeat sequence in hamster sperm nuclear structures

The flat, hooked-shaped architecture of the hamster sperm nucleus makes this an excellent model for in situ hybridization studies of the three dimensional structure of the genome. We have examined the structure of the telomere repeat sequence (TTAGGG)_n with respect to the various nuclear structures present in hamster spermatozoa, using fluorescent in situ hybridization. In fully condensed, mature sperm nuclei, the telomere sequences appeared as discrete spots of various sizes interspersed throughout the volume of the nuclei. While the pattern of these signals was non-random, it varied significantly in different nuclei. These discrete telomere foci were seen to gradually lengthen into linear, beaded signals as sperm nuclei were decondensed, in vitro, and were not associated with the nuclear annulus. We also examined the relationship of telomeres to the sperm nuclear matrix, a residual nuclear structure that retains the original size and shape of the nucleus. In these structures the DNA extends beyond the perimeter of the nucleus to form a halo around it, representing the arrangement of the chromosomal DNA into loop domains attached at their bases to the nuclear matrix. Telomere signals in these structures were also linear and equal in length to those of the decondensed nuclei, and each signal represented part of a single DNA loop domain. The telomeres were attached at one end to the nuclear matrix and extended into the halo. Sperm nuclear matrices treated with Eco RI retained the telomere signals. These data support sperm DNA packaging models in which DNA is coiled into discrete foci, rather than spread out linearly along the length of the sperm nucleus.     

Differential dynamics of splicing factor SC35 during the cell cycle

Pre-mRNA splicing factors are enriched in nuclear domains termed interchromatin granule clusters or nuclear speckles. During mitosis, nuclear speckles are disassembled by metaphase and reassembled in telophase in structures termed mitotic interchromatin granules (MIGs). We analysed the dynamics of the splicing factor SC35 in interphase and mitotic cells. In HeLa cells expressing green fluorescent protein (GFP)-SC35, this was localized in speckles during interphase and dispersed in metaphase. In telophase, GFP-SC35 was highly enriched within telophase nuclei and also detected in MIGs. Fluorescence recovery after photobleaching (FRAP) experiments revealed that the mobility of GFP-SC35 was distinct in different mitotic compartments. Interestingly, the mobility of GFP-SC35 was 3-fold higher in the cytoplasm of metaphase cells compared with interphase speckles, the nucleoplasm or MIGs. Treatment of cells with inhibitors of cyclin-dependent kinases (cdks) caused changes in the organization of nuclear compartments such as nuclear speckles and nucleoli, with corresponding changes in the mobility of GFP-SC35 and GFP-fibrillarin. Our results suggest that the dynamics of SC35 are significantly influenced by the organization of the compartment in which it is localized during the cell cycle.     

Beyond Repair Foci: Subnuclear Domains and the Cellular Response to DNA Damage

In the mid to late 1990's several groups identified DNA damage-dependent focal accumulations in nuclei of both DNA repair factors and the phosphorylated form of the histone variant H2A.X. The term "repair foci" has since been used to describe these protein accumulations. As a molecular marker for DNA damage, they have been immensely useful in the study of signal transduction pathways triggered by DNA damage while aiding in the identification of new factors involved in DNA repair. In spite of their importance, many other changes in the nuclear landscape correlate with DNA damage and repair processes. These include dramatic changes in chromatin ultrastructure and epigenetic modifications, which occur at the site of DNA breaks as well as globally throughout the nucleus. Besides chromatin, DNA damage also affects the dynamic behaviour, morphology and biochemical composition of various subnuclear domains, including the nucleolus, promyelocytic leukemia (PML) nuclear bodies and Cajal bodies. These changes in the nuclear landscape, the topic of this review, appear to be intimately linked to the cellular response to DNA damage and may prove as useful as repair foci in elucidating mechanisms of DNA repair.     

Universal nuclear domains of somatic and germ cells: some lessons from oocyte interchromatin granule cluster and Cajal body structure and molecular composition

It is now clear that two prominent nuclear domains, interchromatin granule clusters (IGCs) and Cajal bodies (CBs), contribute to the highly ordered organization of the extrachromosomal space of the cell nucleus. These functional domains represent structurally stable but highly dynamic nuclear organelles enriched in factors that are required for different nuclear activities, especially RNA biogenesis. IGCs are considered to be the main sites for storage, assembly, and/or recycling of the essential spliceosome components. CBs are involved in the biogenesis of several classes of small RNPs as well as the modification of newly assembled small nuclear RNA. We have summarized data on the molecular composition, structure, and functional roles of IGCs and CBs in the nuclei of mammalian somatic cells and oocytes of some animals with a special focus on insects. We have focused on similarities and differences between the IGCs and CBs of oocytes and the well‐studied CBs and IGCs of cultured mammalian somatic cells. We have shown the heterogeneous character of oocyte IGCs and CBs, both in structure and molecular content. We have also demonstrated the unique capacity of oocytes to form close structural interactions between IGC and CB components. We proposed to consider these joint structures as integrated entities, sharing the features of both IGCs and CBs.     

The study of chromatin and chromosome structure on preparations of interphase nucleus derivatives resulting from nuclear wall removal. IV. Structural heterogeneity of stretched chromatin in membrane-free cell nuclei from human peripheral lymphocytes

Densely aggregated chromatin of mature human or animal peripheral lymphocytes is inaccessible for structural investigation on preparations of both intact cell and conventionally spread chromatin. Giemsa- and DAPI-positive "free chromatin" structures, in addition to amembraneous nuclei, were isolated from intact lymphocytes gently treated with Triton-X-100. Surface stretching of both these nuclei and structures, shortly fixed in methanol-glacial acetic acid (3:1), revealed three main types of these "free chromatin" structures: dense chromatin structures (DCS), loose chromatin structures (LCS) and nuclear spreads (NS). The share of each nuclear derivative may be shifted by changing either detergent concentration and(or) the time of incubation in detergent solution. Each DSC consists of condensed "residual" nucleus, similar in from and size with an intact lymphocyte nucleus, and involves 1-15 uni- or olygonemic chromatin sprouts of different length. LSC contain heterogeneously loosened spindle-shape or drop-like nuclei, being several times longer and wider than DCS-nuclei, and 1-3 long uni- or olygonemic chromatin tail-pieces and incidentally observed lateral chromatin sprouts. The majority of LCS contain either a chromocenter of different number of end-to-end associated spindle-shape domains of condensed chromatin. The latter reached 2-5 x 1.5 microns being cross-striated or spiral in structure. NS represent spread chromatin fibrillar structures varying from 150 to 500 microns in length and from 1.5 to almost 50 microns in width. NS consist of 0.3-0.4 micron smooth and 0.4-0.8 micron beaded chromatin fibres. Thin fibres produce web-like domains of NS. and thick fibres form olygonemic bundles or end-to-end association of unit chromatin fibres within NS. Some portion of thick unit fibres of NS gave rise to local splitting into two thin fibres with a similar bead patterns. Thick argyrophilic fibers of the nucleolus also displayed a beaded structure and commonly spread hand-in-hand with the basic chromatin fibre aggregations.     

Isolation and initial characterization of residual nuclear structures from yeast

Residual nuclear structures have previously been isolated from a wide range of eukaryotic organisms. When nuclei are isolated from Saccharomyces cerevisiae and then treated with 1.95 M NaCl and DNase I, sedimentable residual structures are obtained similar in several respects to structures isolated from organisms previously studied. These yeast residual nuclear structures retain less than 7% of nuclear DNA, less than 17% of nuclear RNA and less than 50% of nuclear proteins. Electron microscopy suggests that these structures are derived from the nuclear interior and are composed of a sparse fibrogranular network. Replicating DNA is preferentially bound to these yeast residual nuclear structures, just as it is to residual nuclear structures from other organisms.     

Intranuclear relocalization of matrix binding sites during T cell activation detected by amplified fluorescence in situ hybridization

We describe a method for analyzing the nuclear localization of specific DNA sequences, with special emphasis on their binding status to the nuclear matrix, depending on the developmental stage of the cells. This method employs high-resolution fluorescence in situ hybridization procedures. For our studies, it was important to examine the nuclear localization of a particular gene locus. Previously, however, it was not possible to detect a single-copy genomic sequence using a DNA probe less than several kilobases in size. We describe here a signal amplification technique based on tyramide which makes such a task possible. Using this method, we monitored single-copy loci using a short, 509-bp DNA sequence that binds in vivo to the T cell factor SATB1 within T cell nuclei, high-salt-extracted nuclei (histone-depleted nuclei generating "halos" with distended chromatin loops), and the nuclear matrix, before and after T cell activation. We found that these loci were anchored onto the nuclear matrix, creating new bases of chromatin loops, only after T cell activation. This experimental strategy, therefore, enabled us to detect the changes in higher order chromatin structure upon activation and study gene regulation at a new dimension: the loop domain structure. The methods shown here can be widely applied to explore other functions involving chromatin, including recombination and replication.     

DNA-polymerase activity and DNA synthesis in the hepatocyte nuclear matrix

The comparative analysis of DNA-synthetase activity of hepatocytes, isolated nuclei and nuclear matrix from normal and regenerating rat liver was performed. The highest enrichment with newly-synthesized DNA was registered in the DNA fraction associated with the nuclear matrix both in vivo and in vitro. The functioning of DNA polymerases alpha and beta in the matrix was shown. Our results indicate that DNA polymerase beta is more firmly bound with the nuclear matrix in the cells of normal liver but this enzyme is eluted almost completely from the nuclei of regenerating liver cells. At the first moment after gamma-irradiation of rats the preferential initiation of unscheduled DNA synthesis in vivo has been observed on the nuclear skeletal structures. This may serve as an indication on the possibility that DNA repair process occurs on the nuclear matrix.     

Aging and Loss of Germination in Rye Seeds Is Accompanied by a Decreased Fragmentation of Nuclear DNA at Loop Domain Boundaries

To investigate the processes that occur in the embryo cell nuclei in the course of natural and accelerated aging of rye seeds, nuclear DNA structural organization into chromatin loop domains was studied. The loss of germination was shown to be accompanied by a decreased excision of chromatin loop domains. The study of chromatin accessibility to DNase I did not reveal any considerable changes in chromatin architecture that would explain the decreased DNA fragmentation at matrix attachment regions. A soluble nuclear protein of ca. 31 kD was found to manifest nuclease activity, which declined with the loss of germination. The study of DNA fragmentation in histone-depleted nuclei (nucleoids) disclosed a nuclease activity resistant to 2 M NaCl extraction and sensitive to the specific inhibitors of DNA topoisomerase II; the latter activity also declined with aging. The authors conclude that the changes in DNA fragmentation patterns in aging seeds were primarily caused by a decreased activity of the enzymes accounting for the excision of chromatin loop domains.