The Plant Nucleoskeleton: Ultrastructural Organization and Identification of NuMA Homologues in the Nuclear Matrix and Mitotic Spindle of Plant Cells

In the present work we investigate the structural organization of the nucleoskeleton ofAllium cepameristematic root cells. Resinless sections reveal for the first time a residual filamentous network in plant nuclei. This network is composed of branched knobbed filaments with associated globular structures, connected to the lamina and to the dense aggregates of different sizes. Results of immunoblotting show that many components of this network are homologues of intermediate filament-type proteins. NuMA, a coiled-coil protein related to intermediate filaments, found in animal cells, can also be detected in this plant nuclear matrix system. Immunofluorescence reveals a diffuse distribution of the animal NuMA homologues in plant nuclear core filaments in interphase. Resinless immunoelectron microscopy further reveals a distribution along the extended filaments and the dense aggregates. During mitosis, in contrast to the accumulation at the poles in animal cells, NuMA homologues in plant onion cells show a diffuse pattern, which may correspond to the spindle matrix. Our data are the first report of the conservation in plants of NuMA proteins, which may be involved in both nuclear and mitotic spindle organizations.     

Isolation of nuclear shells from plant cells

Abstract. Nuclei from Zea mays and Phaseolus vulgaris root meristematic and differentiated cells were treated according to a recently developed simple procedure for isolation of nuclear lamina of Ehrlich Ascite Tumor (EAT) cells. As revealed by electron microscopy, the residual structures obtained represented empty nuclear shells, resembling those previously isolated from animal cells. Moreover, the composition of the residual nuclear structures from plant cells was found to be very similar to that described previously for the nuclear lamina purified by the adopted procedure. As demonstrated by SDS-polyacrylamide gel electrophoresis, the plant nuclear shells contained a small number of proteins in the 65-45 kD range. Two proteins — 62 and 50 kD—were most characteristic for beans, while a 55-kD protein was abundant in maize. When blotted on nitrocellulose paper, some of the proteins of plant nuclear shells were immunoreactive with sera containing antibodies against the proteins of EAT nuclear envelopes. The degree of phosphorylation of the proteins of plant nuclear shells was found to be higher in meristematic than in differentiated maize root cells, correlating with the mitotic activity of the starting material.     

Quantitative immunofluorescence and immunoelectron microscopy of the topoisomerase IIα associated with nuclear matrices from wild-type and drug-resistant Chinese hamster ovary cell lines

Topo IIα is considered an important constituent of the nuclear matrix, serving as a fastener of DNA loops to the underlying filamentous scaffolding network. To further define a mechanism of drug resistance to topo II poisons, we studied the quantity of topo IIα associated with the nuclear matrix in drug-resistant SMR₁₆ and parental cells in the presence and absence of VP-16. Nuclear matrices were prepared from nuclei isolated in EDTA buffer, followed by nuclease digestion with DNase II in the absence of RNase treatment and extraction with 2 M NaCl. Whole-mount spreading of residual structures permits, by means of isoform-specific antibody and colloidal-gold secondary antibodies, an estimate of the amount of topo IIα in individual nuclear matrices. There are significant variations in topo IIα amounts between individual nuclear matrices due to the cell cycle distribution. The parental cell line contained eight to ten times more nuclear matrix–associated topo IIα than the resistant cell line matrices. Nuclear matrix–associated topo IIα from wild-type and resistant cell lines correlated well with the immunofluorescent staining of the enzyme in nuclei of intact cells. The amount of DNA associated with residual nuclear structures was five times greater in the resistant cell line. This quantity of DNA was not proportional to the quantity of topo IIα in the same matrix; in fact they were inversely related. In situ whole-mount nuclear matrix preparations were obtained from cells grown on grids and confirmed the results from labeling of isolated residual structures. J. Cell. Biochem. 67:112–130, 1997. © 1997 Wiley-Liss, Inc.     

Location of RNase activity in nuclear residual structures

We report here the partial isolation of an RNase activity which copurifies with the nuclear residual structure prepared from both rat liver and Herpes-infected BHK cells. After the successive treatment of purified nuclei with DNase, low salt and high salt, the RNase activity is found both in the high salt soluble supernatant fraction and in the residual nuclear structure. Triton X-100 treatment of this structure solubilizes the RNase activity. From this we conclude that some of the RNase activity associated with the nuclear residual structure may be located in either the phospholipidic or protein moieties that were extracted with Triton X-100. This RNase cuts rRNA non-randomly into characteristic degradation products. Its molecular weight, on a glycerol gradient, was determined to be 25,000.     

Considerations in the isolation of rat liver nuclear matrix,nuclear envelope,and pore complex lamina

A number of recent studies have demonstrated a salt-, nuclease, and detergent-resistant subnuclear structure termed the nuclear protein matrix which consists of a fibrogranular intranuclear network, residual components of the nucleolus, and a peripheral lamina. Other workers, however, have shown that somewhat similar methods result in the isolation of the peripheral lamina devoid of the intranuclear components. In this report we demonstrate that seemingly slight changes in the isolation procedure cause major changes in the morphology of the residual structures obtained. When freshly purified rat liver nuclei were digested with DNase I and RNase A and then extracted with buffers of low magnesium ion concentration (LS buffer) and high ionic strength (HS buffer), the resulting structures isolated prior to or after Triton X-100 extraction lacked the extensive intranuclear network and the easily identifiable residual nucleoli present in the nuclear protein matrix. Systematic modification of this extraction procedure revealed that morphologically identifiable residual nucleoli were present when digestion with RNase A followed extraction with HS buffer but were absent when the order of these steps was reversed. The removal of the nucleolus by RNase A and HS buffer correlated with the removal of nuclear RNA by the same treatments. These coordinate events could not be prevented by treatment with protease inhibitors but were prevented by treatment of the RNase A with diethylpyrocarbonate, an RNase inhibitor. The extensive intranuclear network seen in the nuclear protein matrix was sparse or absent when residual structures were prepared from DNase- and RNase-treated nuclei under conditions which minimized the oxidation of protein sulfhydryl groups. In contrast, an extensive non-chromatin intranuclear network was seen if the formation of intermolecular protein disulfide bonds was promoted by extraction of nuclei with cationic detergents, by overnight incubation, or by treatment with oxidizing agents like sodium tetrathionate prior to nuclease digestion and subsequent extraction. By varying the order of extraction steps and the extent of disulfide cross-linking, it is possible to isolate from a single batch of nuclei residual structures with a wide range of morphologies and compositions.     

Residual structure and constituent proteins of the peripheral framework of the cell nucleus in somatic embryos from Daucus carota L.

Nuclei were isolated from somatic embryos of carrot (Daucus carota L.) using a buffer system containing non-ionic detergent. To prepare nuclear matrices, the purified membrane-depleted nuclei were digested with DNase I in combination with RNase A, followed by extraction with 1 M NaCl. The DNA residue in the final insoluble fraction was less than 4% of that in isolated nuclei, and most of the residual nuclei retained their sphericity. Electron microscopy revealed that the nuclear matrix was composed of a distinct peripheral layer, an internal matrix structure and some fibrils; residual nucleoli were observed when exogeneous RNase was not incorporated. The proteins extracted from the nuclei and nuclear subfractions were compared by gel electrophoresis, which showed that the residual fraction contained many minor proteins. To identify proteins showing specific localization at the nuclear periphery, we prepared monoclonal antibodies (MAbs) against an ion-exchange chromatography fraction extracted from carrot nuclear matrices. Immunofluorescence microscopy with one of the MAbs, CML-1, showed exclusive staining of the nuclear periphery. The MAb recognized several spots showing microheterogeneity, with a narrow range of pI and molecular mass upon immunoblotting. A complete set of these spots was shown to be conserved in nuclear matrices. On the other hand, MAb CML-13 appeared to react with the nuclear interior as well as the periphery, recognizing a 96-kDa polypeptide of the nuclear matrix. These proteins were thus demonstrated to lie at the nuclear periphery, and to constitute the nuclear matrices in carrot. The 96-kDa polypeptide is suggested to be similar to the 92-kDa nuclear protein reported by Beven et al. in carrot (Beven et al., 1991, J. Cell Sci. 98, 293–302).Abbreviations DEAE diethylaminoethyl - MAb monoclonal antibody - NEPHGE nonequilibrium pH gradient electrophoresis We wish to thank Ms. Akiko Itoh for excellent technical assistance. This work was supported by a Grant-in-Aid (05640738) from the Ministry of Education of Japan.     

Spectrin-like proteins in plant nuclei

We analysed the presence and localization of spectrin-like proteins in nuclei of various plant tissues, using several anti-erythrocyte spectrin antibodies on isolated pea nuclei and nuclei in cells. Western blots of extracted purified pea nuclei show a cross-reactive pair of bands at 220-240 kDa, typical for human erythrocyte spectrin, and a prominent 60 kDa band. Immunolocalization by means of confocal laser scanning microscopy reveals spectrin-like proteins in distinct spots equally distributed in the nucleoplasm and over the nuclear periphery, independent of the origin of the anti-spectrin antibodies used. In some nuclei tracks of spectrin-like proteins are also observed. No signal is present in nucleoli. The amount and intensity of signal increases when nuclei were extracted, successively, with detergents, DNase I and RNase A, and high salt, indicating that the spectrin-like protein is associated with the nuclear matrix. The labelling is similar in nuclei of various plant tissues. These data are the first that show the presence and localization of spectrin-like epitopes in plant nuclei, where they may stabilize specific interchromatin domains.     

Matrix-associated DNA from maize is enriched in repetitive sequences

In order to elucidate some features of the topological organization of DNA within the plant nucleus, DNA fragments involved in the attachment of the DNA loops to the nuclear matrix in maize were studied. The matrix-associated DNA from dry embryo and meristematic cells after extensive digestion with DNase I and high salt treatment was about 2% of the total DNA, sized within the range of 50 and 250 bp. This DNA was found to be enriched in repetitive DNA sequences, both for nuclei from dry embryo and meristematic cells. The loop size of the DNA in cells of Zea mays appeared to be between 5 and 25 kbp.Abbreviations EDTA Diamino-ethanetetraacetic acid - EtBr Ethidium bromide - LIS Lithium diiodosalicylate - PMSF Phenylmethylsulfonyl fluoride - SDS Sodium dodecyl sulfate     

Nuclear spectrin-like proteins are structural actin-binding proteins in plants

Background information. Although actin is a relevant component of the plant nucleus, only three nuclear ABPs (actin‐binding proteins) have been identified in plants to date: cofilin, profilin and nuclear myosin I. Although plants lack orthologues of the main structural nuclear ABPs in animals, such as lamins, lamin‐associated proteins and nesprins, their genome does contain sequences with spectrin repeats and N‐terminal calponin homology domains for actin binding that might be distant relatives of spectrin. We investigated here whether spectrin‐like proteins could act as structural nuclear ABPs in plants. Results. We have investigated the presence of spectrins in Allium cepa meristematic nuclei by Western blotting, confocal and electron microscopy, using antibodies against α‐ and β‐spectrin chains that cross‐react in plant nuclei. Their role as nuclear ABPs was analysed by co‐immunoprecipitation and IF (immunofluorescence) co‐localization and their association with the nuclear matrix was investigated by sequential extraction of nuclei with non‐ionic detergent, and in low‐ and high‐salt buffers after nuclease digestion. Our results demonstrate the existence of several spectrin‐like proteins in the nucleus of onion cells that have different intranuclear distributions in asynchronous meristematic populations and associate with the nuclear matrix. These nuclear proteins co‐immunoprecipitate and co‐localize with actin. Conclusions. These results reveal that the plant nucleus contains spectrin‐like proteins that are structural nuclear components and function as ABPs. Their intranuclear distribution suggests that plant nuclear spectrin‐like proteins could be involved in multiple nuclear functions.     

Presence of small-nuclear-ribonucleoprotein-containing nuclear bodies in quiescent and early germinatingZea mays embryos

Summary Nucleolus-associated bodies (NABs) occur in interphase nuclei of many plant species. The present work shows that, inZea mays, NABs are present in dry seeds as well as in germinating tissues. The frequency of these nuclear bodies remains more or less constant during the first 24 h of imbibition but decreases significantly during the next 24 h. By the time the nucleolus reaches maturation and contains granular zones, these bodies are still found in close association with the surface of this organelle, as is the case in mature root meristematic cells. Immunocytochemical observations on both dry seeds and germinating tissues further revealed that NABs reacted positively with a monoclonal antibody (mAbK121) recognizing the m3G cap of sn(small nuclear)RNAs. It is, therefore, concluded that the NABs present in such tissues already contain components characterizing snRNPs (small nuclear ribonucleoproteins) in mature tissues. The possible function of NABs as storage deposits of snRNPs in dry seeds and early germinating tissues is discussed. In view of their many similarities with the coiled bodies described in both animal and plant cells, it is most likely that NABs correspond to those structures.Abbreviations BSA bovine serum albumin - DABCO 1,4-diazabicyclo (2.2.2)octane - EDTA ethylenediaminetetraacetic acid - IgM immunoglobulin M - NAB nucleolus-associated body - AO acridine orange - NAC nucleolus-associated chromatin - PBS phosphate-buffered saline - snRNA small nuclear ribonucleic acid - snRNP small nuclear ribonucleoprotein     

Interchromatin granules in plant nuclei

The interchromatin granules (IG) are well characterized subnuclear structures in animal cell nuclei which form a part of the internal nuclear matrix and are supposed to correspond to accummulation sites of snRNPs and/or maturation and transport of rRNPs; but similar structures have not yet been characterized in plant nuclei. Using the bismuth impregnation technique of Locke and Huie, preferential for the staining of IG, we describe here a kind of positive granules 20–25 nm in diameter in plants. The putative plant IG have a series of common characteristics with animal IG, which are not found as a whole in any other subnuclear structures. These are: size, morphology and ultrastructural organization, presence in groups, EDTA and bismuth oxynitrate positive reactions, resistance to double digestion with proteases and RNase I and their high content in phosphorylated proteins. For all the above and also because they are ubiquitous structures in the plant nuclei, we identified these granules with the IG described in animal cells.     

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     

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.     

Evidence for the existence of a nucleolar skeleton attached to the pore complex-lamina in human fibroblasts

This work deals with the types of nuclear skeletal structures obtained from human fibroblast nuclei isolated by different procedures. It is confirmed that, in somatic vertebrate cells, the pore complex-lamina is always observed, whereas the presence of internal nucleolar and extranucleolar residual structures depends upon the method of nuclear isolation used. Furthermore, the results reported here argue for the existence of a nucleolar skeleton different from the nucleolar matrix often observed in different cell types by other investigators. The conditions of nuclear isolation which allow us to visualize this nucleolar skeleton without any other internal residual structures are described. The attachment of the nucleolar skeleton to the lamina suggested by the present data is considered in relation to the in situ position of nucleoli near the nuclear envelope.     

Association of poly(ADP-ribose) polymerase with the nuclear matrix: the role of intermolecular disulfide bond formation, RNA retention, and cell type.

The recovery of the enzyme poly(ADP-ribose) polymerase (pADPRp) in the nuclease- and 1.6 M NaCl-resistant nuclear subfraction prepared from a number of different sources was assessed by Western blotting. When rat liver nuclei were treated with DNase I and RNase A followed by 1.6 M NaCl, approximately 10% of the nuclear pADPRp was recovered in the sedimentable fraction. The proportion of pADPRp recovered with the residual fraction decreased to less than 5% of the total nuclear polymerase when nuclei were prepared in the presence of the sulfhydryl blocking reagent iodoacetamide and increased to approximately 50% of the total nuclear pADPRp when nuclei were treated with the sulfhydryl cross-linking reagent sodium tetrathionate (NaTT) prior to fractionation. To determine whether this effect of disulfide bond formation was unique to rat liver nuclei, nuclear matrix/cytoskeleton structures were prepared in situ by sequentially treating monolayers of tissue culture cells with Nonidet-P40, DNase I and RNase A, and 1.6 M NaCl (S.H. Kaufmann and J.H. Shaper (1991) Exp. Cell Res. 192, 511-523). When nuclear monolayers were prepared from HTC rat hepatoma cells, CaLu-1 human lung carcinoma cells, and CHO hamster ovary cells in the absence of NaTT, pADPRp was undetectable in the nuclease- and 1.6 M NaCl-resistant fraction. In contrast, when nuclear monolayers were isolated in the presence of NaTT, from 5% (CaLu-1) to 26% (HTC cells) of the total nuclear pADPRp was recovered with the nuclease- and salt-resistant fraction. Examination of these residual structures by SDS-polyacrylamide gel electrophoresis under nonreducing conditions suggested that pADPRp was present as a component of disulfide cross-linked complexes. Further analysis by immunofluorescence revealed that the pADPRp was diffusely distributed throughout the CaLu-1 or CHO nuclear matrix. In addition, when matrices were prepared in the absence of RNase A, pADPRp was also observed in the residual nucleoli. These observations reveal that the recovery of pADPRp with a nuclease- and salt-resistant nuclear subfraction is dependent on the source of the nuclei and on the conditions used to fractionate those nuclei. In addition, these observations raise the possibility that there might be different functional classes of pADPRp molecules within the nucleus.     

Ultrastructure and enzyme digestion of nucleoli and associated structures in hypothalamic nerve cells viewed in resinless sections

Estrogen has been shown to affect ventromedial hypothalamic (VMH) nerve cell nucleoli in ovariectomized rats, by causing an increase in the number of electron-dense aggregates associated with nucleoli. In order to characterize these nucleolus-associated structures and other nuclear components, we examined the ultrastructure of ventromedial hypothalamic nucleoli and nuclei revealed by enzyme digestions (pepsin, RNase and DNase) in resinless thin sections. Digestion by pepsin did not cause obvious alterations in the morphology of the nucleolus or its related structures. Pepsin treatment followed by RNase, however, reduced the density of the nucleolus, while that of the nucleolus-associated structure and other related structures remained unchanged. Conversely pepsin treatment followed by DNase, reduced the density of nucleolus-associated and other chromatin structures, but had no effect on the density of the nucleolus. Pepsin treatment followed by RNase and then DNase treatment, reduced the density of the nucleolus and nucleolus-associated structures. A residual nucleolus and nucleolus-associated structure remained after this treatment. Stereo viewing of resinless sections shows that the nucleolus, its associated structures, and other related structures, are associated with fine filaments that may comprise the nuclear matrix. The nucleolus-associated structure containing DNA may direct RNA synthesis at an increased rate in estrogen-treated hypothalamic cells.     

Effect of chromatin decondensation on the intranuclear matrix

We have studied the effect of chromatin condensation on the morphology of the residual structures isolated from rat liver nuclei. DNAse I digestion followed by high salt extraction of nuclei in the presence of Mg++ yields residual structures consisting of a dense peripheral layer surrounding an internal network, similar to those described by Berezney and Coffey [6]. These structures are stable at low ionic strength in the presence of EDTA. When nuclei swollen in EDTA are digested with DNAse II in the presence of EDTA, structures devoid of internal network are obtained even without subsequent treatment with high salt. When swollen nuclei are exposed to Mg++ a specific recondensation of chromatin takes place. The residual structures from recondensed nuclei are similar to those isolated from control nuclei in the presence of Mg++. The results suggest that the integrity and stability of the intranuclear matrix are acquired in the course of the isolation procedure and this is favoured by chromatin condensation.     

The nuclear matrix of duck erythroblasts is associated with globin mRNA coding sequences but not with the major proteins of 40S nuclear RNP

A residual protein matrix has been prepared from avian erythroblast nuclei by extensive extraction with salines and detergent and subsequent digestion with high concentrations of RNase and DNase. Ultrastructural examination reveals considerable internal structure, the most prominent feature being the remains of the nucleoli embedded in a network of fibres of fairly uniform diameter of 50 Å. The proteins which make up this structure have been examined by two-dimensional electrophoresis and are shown to consist of a characteristic set of about 30, mainly acidic components, including four prominent species of 43 000, 52 000, 66 000 and 68 000 molecular weight (MW). In parallel preparations of the nuclear matrix digested with DNase alone, much of the nuclear RNA is found associated with the residual structure, including globin-coding sequences. These results correlate well with the ultrastructural appearance of DNase-digested matrix preparations which show that superimposed on the 50 Å fibrous network is a 200–300 Å granular component, the combined fibrillo-granular structure resembling the interchromatin RNP previously identified in situ. However, the proteins of the DNase-digested matrix seen by two-dimensional electrophoresis are indistinguishable from the proteins of matrix preparations digested with both DNase and RNase. Furthermore, two-dimensional comparison between the proteins of the DNase-digested matrix and purified 40S nuclear RNP particles shows that the bulk of the proteins found associated with nuclear RNA in vitro are extracted during matrix preparation, and only two, with MWs of 43 000 and 73 000, remain. The latter species co-migrates with the poly(A)-binding protein.     

Effect of salt-treatment on manually isolated polytene chromosomes from Chironomus tentans

A method for the rapid manual isolation of polytene chromosomes and nuclear membranes from salivary glands of Chironomus tentans is presented and the analysis of some of their RNA and protein components before and after treatment with 2 M salt solutions is summarized. — After salt-incubation the chromosomes still display a considerable number of bands which stain with ethidium bromide and which are sensitive to treatment with DNase, RNase, trypsin, and proteinase K, to a lesser extent with pronase and papain. Analysis of the iodinated residual proteins on SDS gels yield three major and two minor bands (MW between 50,000 and 70,000 dalton) which were also shown to be present in interphase chromosomes of Ehrlich ascites cells which had been treated similarly and are also tightly bound constituents of DNA prepared according to Gross-Bellard et al. (1973). This result indicates the existence of a general class of non-histone proteins involved in keeping the DNA in a supercoiled state. Furthermore their presence in salt-treated nuclear membranes of Chironomus salivary gland cells (and Xenopus oocytes, unpubl.) will be of interest with respect to functional aspects of the nuclear matrix.