Endocannabinoid 2-Arachidonoylglycerol Synthesis and Metabolism at Neuronal Nuclear Matrix Fractions Derived from Adult Rat Brain Cortex

In this report, we describe the kinetics characteristics of the diacylglycerol lipase-α (DGLα) located at the nuclear matrix of nuclei derived from adult cortical neurons. Thus, using high-resolution fluorescence microscopy, classical biochemical subcellular fractionation, and Western blot techniques, we demonstrate that the DGLα enzyme is located in the matrix of neuronal nuclei. Furthermore, by quantifying the 2-arachidonoylglycerol (2-AG) level by liquid chromatography and mass spectrometry when 1-stearoyl-2-arachidonoyl-sn-glycerol (SAG) was exogenously added as substrate, we describe the presence of a mechanism for 2-AG production through DGLα dependent biosynthesis with an apparent K_m (K_m^app) of 180 µM and a V_max of 1.3 pmol min^-1 µg^-1 protein. We also examined the presence of enzymes with hydrolytic and oxygenase activities that are able to use 2-AG as substrate, and described the localization and compartmentalization of the major 2-AG degradation enzymes, namely monoacylglycerol lipase (MGL), fatty acid amide hydrolase (FAAH), α/β-hydrolase domain 12 protein (ABHD12) and cyclooxygenase-2 (COX2). Of these, only ABHD12 exhibited the same distribution with respect to chromatin, lamin B1, SC-35 and NeuN as that described for DGLα. When 2-AG was exogenously added, we observed the production of arachidonic acid (AA), which was prevented by inhibitors (but not specific MGL or ABHD6 inhibitors) of the ABHD family. Overall, our results expand knowledge about the subcellular distribution of neuronal DGLα, and provide biochemical and morphological evidence to ensure that 2-AG is produced in the neuronal nuclear matrix. Thus, this work paves the way for proposing a working hypothesis about the role of 2-AG produced in neuronal nuclei.

GBPL3 localizes to the nuclear pore complex and functionally connects the nuclear basket with the nucleoskeleton in plants

The nuclear basket (NB) is an essential structure of the nuclear pore complex (NPC) and serves as a dynamic and multifunctional platform that participates in various critical nuclear processes, including cargo transport, molecular docking, and gene expression regulation. However, the underlying molecular mechanisms are not completely understood, particularly in plants. Here, we identified a guanylate-binding protein (GBP)-like GTPase (GBPL3) as a novel NPC basket component in Arabidopsis. Using fluorescence and immunoelectron microscopy, we found that GBPL3 localizes to the nuclear rim and is enriched in the nuclear pore. Proximity labeling proteomics and protein-protein interaction assays revealed that GBPL3 is predominantly distributed at the NPC basket, where it physically associates with NB nucleoporins and recruits chromatin remodelers, transcription apparatus and regulators, and the RNA splicing and processing machinery, suggesting a conserved function of the NB in transcription regulation as reported in yeasts and animals. Moreover, we found that GBPL3 physically interacts with the nucleoskeleton via disordered coiled-coil regions. Simultaneous loss of GBPL3 and one of the 4 Arabidopsis nucleoskeleton genes CRWNs led to distinct development- and stress-related phenotypes, ranging from seedling lethality to lesion development, and aberrant transcription of stress-related genes. Our results indicate that GBPL3 is a bona fide component of the plant NPC and physically and functionally connects the NB with the nucleoskeleton, which is required for the coordination of gene expression during plant development and stress responses.

Components of the LINC and NPC complexes coordinately target and translocate a virus into the nucleus to promote infection

Nuclear entry represents the final and decisive infection step for most DNA viruses, although how this is accomplished by some viruses is unclear. Polyomavirus SV40 transports from the cell surface through the endosome, the endoplasmic reticulum, and the cytosol from where it enters the nucleus to cause infection. Here we elucidate the nuclear entry mechanism of SV40. Our results show that cytosol-localized SV40 is targeted to the nuclear envelope by directly engaging Nesprin-2 of the linker of nucleoskeleton and cytoskeleton (LINC) nuclear membrane complex. Additionally, we identify the NUP188 subunit of the nuclear pore complex (NPC) as a new Nesprin-2-interacting partner. This physical proximity positions the NPC to capture SV40 upon release from Nesprin-2, enabling the channel to facilitate nuclear translocation of the virus. Strikingly, SV40 disassembles during nuclear entry, generating a viral genome-VP1-VP3 subcomplex that efficiently crosses the NPC to enter the nucleus. Our results reveal how two major nuclear membrane protein complexes are exploited to promote targeting and translocation of a virus into the nucleus.

Domain Model of Eukaryotic Genome Organization: From DNA Loops Fixed on the Nuclear Matrix to TADs

The article reviews the development of ideas on the domain organization of eukaryotic genome, with special attention on the studies of DNA loops anchored to the nuclear matrix and their role in the emergence of the modern model of eukaryotic genome spatial organization. Critical analysis of results demonstrating that topologically associated chromatin domains are structural-functional blocks of the genome supports the notion that these blocks are fundamentally different from domains whose existence was proposed by the domain hypothesis of eukaryotic genome organization formulated in the 1980s. Based on the discussed evidence, it is concluded that the model postulating that eukaryotic genome is built from uniformly organized structural-functional blocks has proven to be untenable.

Nuclear envelope mechanobiology: linking the nuclear structure and function

The nucleus, central to cellular activity, relies on both direct mechanical input as well as its molecular transducers to sense external stimuli and respond by regulating intra-nuclear chromatin organization that determines cell function and fate. In mesenchymal stem cells of musculoskeletal tissues, changes in nuclear structures are emerging as a key modulator of their differentiation and proliferation programs. In this review we will first introduce the structural elements of the nucleoskeleton and discuss the current literature on how nuclear structure and signaling are altered in relation to environmental and tissue level mechanical cues. We will focus on state-of-the-art techniques to apply mechanical force and methods to measure nuclear mechanics in conjunction with DNA, RNA, and protein visualization in living cells. Ultimately, combining real-time nuclear deformations and chromatin dynamics can be a powerful tool to study mechanisms of how forces affect the dynamics of genome function.

The assembly of a noncanonical LINC complex in Saccharomyces cerevisiae

The linker of nucleoskeleton and cytoskeleton (LINC) complex is a protein complex across the nuclear envelope and has maintained its general assembly mode throughout evolution. SUN and KASH proteins, which are the major components of LINC complex, interact with each other in the nuclear lumen to transmit forces across the nuclear envelope and have diverse functions. However, research of LINC complex in budding yeast has been limited due to the lack of identification of a canonical KASH protein and a cytoskeleton factor. Here, we review recent findings that addressed these puzzles in budding yeast. We highlight the distinct assembly model of the telomere-associated LINC complex in budding yeast, which could be beneficial for identifying LINC variants in other eukaryotes.

Novel functional MAR elements of double minute chromosomes in human ovarian cells capable of enhancing gene expression

Double minute chromosomes or double minutes (DMs) are cytogenetic hallmarks of extrachromosomal genomic amplification and play a critical role in tumorigenesis. Amplified copies of oncogenes in DMs have been associated with increased growth and survival of cancer cells but DNA sequences in DMs which are mostly non-coding remain to be characterized. Following sequencing and bioinformatics analyses, we have found 5 novel matrix attachment regions (MARs) in a 682 kb DM in the human ovarian cancer cell line, UACC-1598. By electrophoretic mobility shift assay (EMSA), we determined that all 5 MARs interact with the nuclear matrix in vitro. Furthermore, qPCR analysis revealed that these MARs associate with the nuclear matrix in vivo, indicating that they are functional. Transfection of MARs constructs into human embryonic kidney 293T cells showed significant enhancement of gene expression as measured by luciferase assay, suggesting that the identified MARS, particularly MARs 1 to 4, regulate their target genes in vivo and are potentially involved in DM-mediated oncogene activation.

Tightly-bound to DNA proteins in rat experimental hepatomas and normal liver cells

Proteins tightly bound to DNA (TBP) comprise a group of proteins that remain bound to DNA even after harsh deproteinization procedures. The amount of these proteins is 20-100 μg for mg of DNA depending on eukaryotic source. This experimental paper examines the possibility to use some TBP for clinical biomarker discovery, e.g. for identification of prognostic and diagnostic cancer markers. The main aim of this study was to designate differences between tightly DNA binding protein patterns extracted from rat liver and rat experimental hepatomas (Zajdela ascites hepatoma and hepatoma G-27) and to evaluate possibility that some of these proteins may be used as biomarkers for cell cancer transformation.

METHODS

We used proteomics aproach as a tool for comparison of pattern of TBP from rat experimental hepatomas and normal liver cells. Combination of 2DE fractionation with mass spectrometry (MALDI TOF-MS) suitable for parallel profiling of complex TBP mixtures.

RESULTS

Intriguingly 2DE protein maps of TBP from rat liver and rat experimental hepatomas (Zajdela acites hepatoma and hepatoma G-27) were quite different. We identified 9 proteins, some of them shared in all TBP patterns. Among identified tightly bound to DNA proteins there were three proteins considered as nuclear matrix proteins (lamin B1, scaffold attachment factor B1, heterogeneous nuclear ribonucleoprotein). Also we identified DNA repair protein RAD50, coiled-coil domain-containing protein 41, structural maintenance of chromosomes protein1A and some ATP -dependent RNA helicases indicating that TBP are of interest with respect to their potential involvement in the topological organization and/ or function of genomic DNA.

CONCLUSIONS

We suppose that proteomic approach for TBP identification may be promising in development of biomarkers, also obtained results may be valuable for further understanding TBP functions in genome.

[Functions of the septin cytoskeleton and its roles in dopaminergic neurotransmission]

Cytoskeletal polymers are component of cellular infrastructure that are required for fundamental biological processes ranging from cell division to brain functions. Unlike the knowledge available for tubulin and actin, our understanding of unconventional cytoskeletal structures composed of GTP-binding proteins belonging to the septin family is limited, despite their ubiquity and implications in human diseases. Recent studies have revealed that septin plays unique modulatory roles as an accessory component of microtubules and the actin cytoskeleton. Morphological analyses of the mammalian brain and neural cells have revealed that septins preferentially cluster beneath the extra-synaptic membrane domains in dendritic shafts and spine necks, presynaptic terminals of major neurons, and astroglial processes. Live imaging analysis revealed that septin polymers are remarkably stable in these clusters, which may serve as local cytoskeleton and/or scaffold for the organization of specialized cortical domains in neurons and glia. This hypothesis has been supported by the hypo-dopaminergic phenotype of mice that lack the Sept4 subunit and the hyper-dopaminergic phenotype of those with excess Sept4. In these cases, the septin scaffold in the dopamine neurons is considered as a determinant of the quantity of a subset of presynaptic molecules, including tSNAREs (membrane-fusion machinery) and the dopamine transporters. This finding in mouse models is in agreement with the recent findings that qualitative and/or quantitative dysregulation of septins is involved in neurodegenerative disorders such as Parkinson disease and psychological disorders such as schizophrenia and bipolar disorder. Studies on tubulin/actin indicate that a better understanding of the septin family of proteins will improve our insight into neuropathological phenomena in neurodegenerative and psychological disorders, which may help develop diagnostic markers and therapeutic strategies for such diseases.

Nuclear microenvironments in biological control and cancer

Nucleic acids and regulatory proteins are compartmentalized in microenvironments within the nucleus. This subnuclear organization may support convergence and the integration of physiological signals for the combinatorial control of gene expression, DNA replication and repair. Nuclear organization is modified in many cancers. There are cancer-related changes in the composition, organization and assembly of regulatory complexes at intranuclear sites. Mechanistic insights into the temporal and spatial organization of machinery for gene expression within the nucleus, which is compromised in tumours, provide a novel platform for diagnosis and therapy.

A map of nuclear matrix attachment regions within the breast cancer loss-of-heterozygosity region on human chromosome 16q22.1

There is abundant evidence that the DNA in eukaryotic cells is organized into loop domains that represent basic structural and functional units of chromatin packaging. To explore the DNA domain organization of the breast cancer loss-of-heterozygosity region on human chromosome 16q22.1, we have identified a significant portion of the scaffold/matrix attachment regions (S/MARs) within this region. Forty independent putative S/MAR elements were assigned within the 16q22.1 locus. More than 90% of these S/MARs are AT rich, with GC contents as low as 27% in 2 cases. Thirty-nine (98%) of the S/MARs are located within genes and 36 (90%) in gene introns, of which 15 are in first introns of different genes. The clear tendency of S/MARs from this region to be located within the introns suggests their regulatory role. The S/MAR resource constructed may contribute to an understanding of how the genes in the region are regulated and of how the structural architecture and functional organization of the DNA are related.

A peek into the possible future of management of articular cartilage injuries: gene therapy and scaffolds for cartilage repair

Two rapidly progressing areas of research will likely contribute to cartilage repair procedures in the foreseeable future: gene therapy and synthetic scaffolds. Gene therapy refers to the transfer of new genetic information to cells that contribute to the cartilage repair process. This approach allows for manipulation of cartilage repair at the cellular and molecular level. Scaffolds are the core technology for the next generation of autologous cartilage implantation procedures in which synthetic matrices are used in conjunction with chondrocytes. This approach can be improved further using bioreactor technologies to enhance the production of extracellular matrix proteins by chondrocytes seeded onto a scaffold. The resulting "neo-cartilage implant" matures within the bioreactor, and can then be used to fill cartilage defects.

Nuclear reprogramming by cell fusion

The use of cell fusion to study exchange of information at the molecular level between the nucleus and the cytoplasm of cells during regulation of gene expression was pioneered by Harris and Ringertz more than three decades ago. The ability to make heterokaryons with cells from different species or genetic strains is especially useful because genetic differences in gene products allow the origin of trans-acting regulatory factors to be determined. Heterokaryons between adult nucleated erythroid cells of one species and embryonic/larval nucleated erythroid cells of another species, for example, show cross-induction between the two types of nuclei, resulting in reprogramming of the adult nucleus to embryonic/larval globin gene expression and/or reprogramming of the embryonic/larval cell nucleus to adult globin expression. These experiments provided definitive evidence that developmental program switching is mediated by trans-acting factors. Other possible uses of this cell fusion protocol in stem cell biology and transplantation of genetically engineered cells for tissue regeneration are briefly discussed.

Drosophila dSAP18 is a nuclear protein that associates with chromosomes and the nuclear matrix, and interacts with pinin, a protein factor involved in RNA splicing

SAP18 is a highly conserved protein that was proposed to be involved in multiple cellular processes from autophagy to gene regulation and mRNA processing. In this paper we show that, in Drosophila, dSAP18 is a predominantly nuclear protein that associates to both chromosomes and the nuclear matrix. dSAP18 becomes nuclear early during development, at the onset of cellularization, and remains so all through embryo development. dSAP18 is also nuclear in salivary glands, ovaries and cultured S2 cells. Here we also show that dSAP18 forms a complex with the Drosophila homolog of pinin (dPnn), a protein factor involved in mRNA splicing. dSAP18-dPnn interaction was confirmed in vivo, through co-immunoprecipitation experiments, as well as in vitro, through GST pull-down assays. These results are discussed in the context of the possible functions played by SAP18.

Gene expression induced by copper stress in the diatom Thalassiosira pseudonana

Utilizing a PCR-based subtractive cDNA approach, we demonstrated that the marine diatom Thalassiosira pseudonana exhibits a rapid response at the gene level to elevated concentrations of copper and that this response attenuates over 24 h of continuous exposure. A total of 16 copper-induced genes were identified, 11 of which were completely novel; however, many of the predicted amino acid sequences had characteristics suggestive of roles in ameliorating copper toxicity. Most of the novel genes were not equivalently induced by H2O2- or Cd-induced stress, indicating specificity in response. Two genes that could be assigned functions based on homology were also induced under conditions of general cellular stress. Half of the identified genes were located within two inverted repeats in the genome, and novel genes in one inverted repeat had mRNA levels induced by approximately 500- to 2,000-fold by exposure to copper for 1 h. Additionally, some of the inverted repeat genes demonstrated a dose-dependent response to Cu, but not Cd, and appear to belong to a multigene family. This multigene family may be the diatom functional homolog of metallothioneins.

In silico and wet-bench identification of nuclear matrix attachment regions

Chromatin loops are tethered at discrete regions that are approx 100-1000 bp in length. These regions of attachment serve as specific sequence landmarks, anchoring the DNA to the fibers of the chromosomal scaffold. It has been estimated that our genome contains 70,000 nuclear matrix attachment sites that serve as a dynamic nuclear organizer in both the interphase and metaphase cell. Approximately 30,000-40,000 matrix attachment regions (MARs) serve as origins of replication. MARs can also be associated with chromosomal segments densely populated with transcription factor-binding sites. This may facilitate transcription that is initiated within the region of the chromosome coincident with the surface of the nuclear matrix. Assuming an average somatic loop size of 100 kb, it is reasonable to propose that each cell utilizes 30,000 MARs to anchor each of the approx 20,000 active genic domains. This is sufficient to encompass the 30,000 functional genes in our genome that exist as members of single or multigenic families, each constituting a single chromatin domain. With the sequencing phase of various genome projects complete, in silico tools are being developed to identify the long-range control elements that modulate gene expression. This information is necessary to specifically target the time-intensive wet-bench verification and expression experiments that will provide a unified understanding of gene regulation. In this chapter we review some of the in silico strategies that are currently available and a new in vivo method based on the real-time polymerase chain reaction, to assess regions of matrix association.

A nuclear targeting determinant for SATB1, a genome organizer in the T cell lineage

SATB1 is a nuclear protein, which acts as a cell-type specific genome organizer and gene regulator essential for T cell differentiation and activation. Several functional domains of SATB1 have been identified. However, the region required for nuclear localization remains unknown. To delineate this region, we employed sequence analysis to identify phylogenetically diverse members of the SATB1 protein family, and used hidden Markov model (HMM)-based analysis to define conserved regions and motifs in this family. One of the regions conserved in SATB1- and SATB2-like proteins in mammals, fish, frog and bird, is located near the N-terminus of family members. We found that the N-terminus of human SATB1 was essential for the nuclear localization of the protein. Furthermore, fusing residues 20-40 to a cytoplasmic green fluorescence protein (GFP) fused to pyruvate kinase (PK) was sufficient to quantitatively translocate the pyruvate kinase into the nucleus. The nuclear targeting sequence of human SATB1 (residues 20-40) is novel and does not contain clusters of basic residues, typically found in 'classical' nuclear localization signals (NLSs). We investigated the importance of four well-conserved residues (Lys29, Arg32, Glu34, and Asn36) in this nuclear targeting sequences. Remarkably, full-length SATB1 harboring a single point mutation at either Lys29 or Arg32, but not Glu34 or Asn36, did not enter the nucleus. Our results indicate that SATB1 N-terminal residues 20-40 represent a novel determinant of nuclear targeting.

Changing cell fate by nuclear reprogramming

The differentiated state of somatic cells is remarkably stable, but nuclear transfer can efficiently override the stability of cell differentiation by nuclear reprogramming. Genes that were silent in the differentiated state are activated, whereas genes specific for the differentiated state are switched off during the reprogramming process. The epigenetic changes that occur after nuclear transfer to Xenopus oocytes involve chromatin remodelling and DNA demethylation. In particular, we have reported that reactivation of the mouse stem cell specific gene oct-4 depends on demethylation of CpG:s in the proximal oct-4 promoter. Here we discuss molecular mechanisms of nuclear reprogramming, with special emphasis on DNA demethylation.

TM2, a novel strong matrix attachment region isolated from tobacco, increases transgene expression in transgenic rice calli and plants

Nuclear matrix attachment regions (MARs) are thought to influence the expression of the flanking genes. TM2, a new DNA fragment isolated from tobacco, can bind with the rice nuclear matrix in vitro. In this study, we investigated the effect of TM2 on transgene expression under the control of three different promoters in stably transformed rice calli and plants. The presence of TM2 flanking the transgene increased the expression of constructs based on the constitutive CaMV 35S and maize ubiquitin gene promoters in both resistant calli and transformed plants. The GUS expression directed by the photosynthetic-tissue-specific PNZIP promoter was also increased in photosynthetic tissues of transformants. However, TM2 did not change the gene expression pattern controlled by the PNZIP promoter. The effect of TM2 in transgenic plants was stronger than that in transgenic calli based on all three promoters. Our results indicate that TM2, as a novel strong MAR, can be used to increase the transgene expression levels in the whole plant or in particular tissues of monocotyledons.

Nuclear structure in cancer cells

Nuclear architecture - the spatial arrangement of chromosomes and other nuclear components - provides a framework for organizing and regulating the diverse functional processes within the nucleus. There are characteristic differences in the nuclear architectures of cancer cells, compared with normal cells, and some anticancer treatments restore normal nuclear structure and function. Advances in understanding nuclear structure have revealed insights into the process of malignant transformation and provide a basis for the development of new diagnostic tools and therapeutics.

Approaches for monitoring nuclear translation

The nuclear membrane is the defining feature of eukaryotes. It divides the cell into two functionally specialized compartments, and it is widely assumed that translation is restricted to only one: the cytoplasm. However, recent results suggest that some translation takes place in nuclei closely coupled to transcription. Various labeling techniques are described that enable nascent peptides to be labeled and then localized wherever they might be in the cell.

Nuclear microenvironments support physiological control of gene expression

There is growing recognition that the organization of nucleic acids and regulatory proteins is functionally linked to the assembly, localization and activity of gene regulatory machinery. Cellular, molecular, biochemical and in-vivo genetic evidence support an obligatory relationship between nuclear microenvironments where regulatory complexes reside and fidelity of transcriptional control. Perturbations in mechanisms governing the intranuclear trafficking of transcription factors and the temporal/spatial organization of regulatory proteins within the nucleus occur with compromised gene expression that abrogates skeletal development and mediates leukemogenesis.

The principles of nuclear structure

In multicellular eukaryotes, chromatin function is regulated by numerous extremely sophisticated mechanisms. Recent developments in our ability to monitor the organization and dynamic properties of the components involved in processes such as gene expression and DNA synthesis have emphasised how both global nuclear architecture and chromosome structure can influence these fundamental processes. This review sets out to evaluate our present views of the principles that dictate nuclear structure. Particular emphasis is placed on architectural themes and the concept of spatial epigenetics.

[Semi-centennial history of the nuclear matrix at the turn of the 21st century]

In 1974, Berezney and Coffey described what they called the nuclear matrix (NM), thus ignoring our priority, since we had isolated and characterized virtually the same skeletal structure 25 years before this discovery. The presence of NM in the live cell was doubted, because of unsuccessful attempts to recognize it in vivo. NM comprises the lamina, extracted nucleoli and an intranuclear fibrogranular network. The internal matrix is very labile, its presence and abundance depending on methods of isolation, whereas the isolated NM can be revealed as granules 25-30 nm in diameter. As the state of the interchromatin space changes with varying in vivo conditions, temperature and methods of isolation, doubts cast upon the very existence of NM are to be regarded as hardly valid, and new progress in its study may be expected in the XXI century.

Characterisation and high-resolution distribution of a matrix attachment region-binding protein (MFP1) in proliferating cells of onion

The first matrix attachment region (MAR)-binding protein sequenced in plants, MFP1, has been characterised in two dicot species. Based on their antigenic relationship, we report here the conservation of MFP1-like proteins in proliferating root cells of onion (Allium cepa L). Two MFP1-like proteins with different molecular masses and solubilities were detected. The most abundant was a 90-kDa basic protein, presenting several separate spots in two-dimensional blots. The MFP1 was partially soluble and, similar to the proliferating cell nuclear antigen (PCNA)-labelled replication factories in the nucleus and nuclear matrix, was localised at discrete foci as detected by confocal microscopy. High-resolution immunolocalisation of MFP1 by electron microscopy identified the foci as nuclear structures, some of them containing PCNA, which are ultrastructurally similar to the replication factories described in animal cells. Our data provide the first report on MFP1-like proteins in the Alliaceae. In addition, we present evidence of the presence of AcMFP1 in the putative replication factories.

In vitro and in vivo effects of vitamin D (calcitriol) administration on the normal neonatal and prepubertal prostate

PURPOSE

Although many studies have investigated the role of calcitriol in the growth regulation of normal and cancerous prostates, little is known about its role in early prostatic development. The interactions between calcitriol and androgens, and their actions on the normal prostate have similarly been proposed but not evaluated. Previous studies in our laboratory have revealed that in utero administration of 1,25-dihydroxycholecalciferol or calcitriol can influence prostate growth and differentiation throughout the life of the animal. We further examined the influence of calcitriol on the normal prostate in vitro and in vivo by focusing on early stages of prostatic development.

MATERIALS AND METHODS

The effects of calcitriol on the growth of the normal human neonatal prostatic epithelial cell line 267B-1 was determined in the presence and absence of dihydrotestosterone (DHT). We also examined the effect of calcitriol on the growth of maturing rat prostates in vivo. Before puberty 4 groups of rats 27 to 38 days old were treated with vehicle (controls) or calcitriol. When the rats reached adulthood at age 100 to 110 days a control group and a calcitriol group were sacrificed. The other 2 groups were given exogenous DHT for 5 days. For the animals to become adapted to DHT they were kept alive for 1 additional week and sacrificed at about age 120 days.

RESULTS

In vitro studies demonstrated that 267B-1 cells possess vitamin D receptors and their growth was inhibited by calcitriol with an IC50 (concentration resulting in 50% cytotoxicity) of 30 microM. Proliferation of these neonatal prostate cells was also inhibited by calcitriol in the presence of DHT in vitro. Our studies indicate that, although calcitriol was administered at the apparently important prepubertal period, there was no difference in prostatic weights between the control and calcitriol treated rats. Exogenous administration of DHT decreased prostatic weight of control rats but in rats treated with 1,25-dihydroxycholecalciferol DHT did not have any significant effect on prostatic weight. No statistically significant differences were observed in seminal vesicle weights among the different groups of animals. Analysis of the nuclear matrix protein composition of the prostatic tissue showed differences in composition between the DHT, and calcitriol and DHT treated rat prostates.

CONCLUSIONS

These studies indicate that calcitriol administered just before puberty does not significantly influence prostatic growth in the presence of endogenous or exogenous administered DHT, and has an inhibitory effect on neonatal prostate epithelial cell growth in vitro in the presence and absence of DHT. Treatment with calcitriol and DHT also results in differences in nuclear matrix protein composition. Prepubertal administration of calcitriol may inhibit the exogenous DHT action in decreasing epithelial growth and stimulating stromal proliferation in the rat prostate.

Region-specific DNA damage by AT-specific DNA-reactive drugs is predicted by drug binding specificity

Bizelesin and adozelesin are DNA-reactive antitumor drugs that alkylate adenines at the 3' ends of their preferred binding sites [5'T(A/T)(4)A3'and 5'(A/T)(3)(-4)A3', respectively]. We used these drugs to examine the determinants for region-specific damage of human genomic DNA. The distribution of bizelesin binding motifs in several regions analyzed "in silico" correlated well with the experimentally determined lesions in these regions assessed by quantitative polymerase chain reaction (QPCR) stop assay. In contrast to the typically low motif density, clusters of potential bizelesin binding sites were found in the matrix-associated regions (MAR domains) of the c-myc and apolipoprotein B (apoB) genes. Accordingly, lesions induced by bizelesin in these domains (2.13 and 7.06 lesions kbp(-1) microM(-1), respectively) markedly exceeded lesions in bulk DNA (0.87 lesions kbp(-1) microM(-1)) or in regions with typically low motif density (e.g., 0.75 and 0.87 lesions kbp(-1) microM(-1) in a beta-globin gene and c-myc origin of replication regions, respectively). Consistent with the more frequent, less localized adozelesin motif, actual lesions induced by adozelesin exceeded by severalfold lesions by bizelesin in four selected regions (within the c-myc and HPRT loci). Whereas adozelesin is likely to affect similar regions as bizelesin, adozelesin's more promiscuous binding probably compromises its relative specificity for such targets. In contrast, findings for bizelesin provide for the first time a proof of principle that a small molecular weight drug can preferentially damage specific regions in cellular DNA. Targeting of critical repetitive sequences, such as AT-rich MAR domains, which allow for clustering of drug binding motif, can be the paradigm for region specificity of small molecular weight agents.

Regulation of matrix attachment region-dependent, lymphocyte-restricted transcription through differential localization within promyelocytic leukemia nuclear bodies

Bright (B cell regulator of IgH transcription) transactivates the immunoglobulin heavy chain (IgH) intronic enhancer, Emicro, by binding to matrix attachment regions (MARs), sites necessary for DNA attachment to the nuclear matrix. Here we report that Bright interacts with the ubiquitous autoantigen Sp100, a component of promyelocytic leukemia nuclear bodies (PML NBs), and with LYSp100B/Sp140, the lymphoid-restricted homolog of Sp100. Both in intact cells and in nuclear matrix preparations, the majority of Bright and Sp100 colocalize within PML NBs. In contrast, Bright colocalizes with only a small fraction of LYSp100B while inducing a redistribution of the majority of LYSp100B from its associated nuclear domains (LANDs) into nucleoplasm and cytoplasm. Sp100 represses the MAR-binding and transactivation activity of Bright. LYSp100B interacts more weakly with Bright but requires significantly higher levels than Sp100 to inhibit MAR binding. However, it strongly stimulates Bright transactivation through E mu. We suggest that Sp100 and LYSp100B interactions with Bright have different consequences for IgH transcription, potentially through differential association of E mu MARs with nuclear matrix- associated PML NBs and LANDs.

Formation of a complex between nucleolin and replication protein A after cell stress prevents initiation of DNA replication

We used a biochemical screen to identify nucleolin, a key factor in ribosome biogenesis, as a high-affinity binding partner for the heterotrimeric human replication protein A (hRPA). Binding studies in vitro demonstrated that the two proteins physically interact, with nucleolin using an unusual contact with the small hRPA subunit. Nucleolin significantly inhibited both simian virus 40 (SV-40) origin unwinding and SV-40 DNA replication in vitro, likely by nucleolin preventing hRPA from productive interaction with the SV-40 initiation complex. In vivo, use of epifluorescence and confocal microscopy showed that heat shock caused a dramatic redistribution of nucleolin from the nucleolus to the nucleoplasm. Nucleolin relocalization was concomitant with a tenfold increase in nucleolin-hRPA complex formation. The relocalized nucleolin significantly overlapped with the position of hRPA, but only poorly with sites of ongoing DNA synthesis. We suggest that the induced nucleolin-hRPA interaction signifies a novel mechanism that represses chromosomal replication after cell stress.

[Theory of integrating cellular tension and consequences from it]

Tensegrity model and implications from it have been reviewed. Experimental data confirming the model are shown. While signal vectorization is well confirmed and well depicted by the model, the vectorization of expression implied by the model has not yet been elaborated. Molecular mechanisms of functional connection between the nuclear matrix and the cytoskeleton need further observations.

Atm inactivation results in aberrant telomere clustering during meiotic prophase

A-T (ataxia telangiectasia) individuals frequently display gonadal atrophy, and Atm-/- mice show spermatogenic failure due to arrest at prophase of meiosis I. Chromosomal movements take place during meiotic prophase, with telomeres congregating on the nuclear envelope to transiently form a cluster during the leptotene/zygotene transition (bouquet arrangement). Since the ATM protein has been implicated in telomere metabolism of somatic cells, we have set out to investigate the effects of Atm inactivation on meiotic telomere behavior. Fluorescent in situ hybridization and synaptonemal complex (SC) immunostaining of structurally preserved spermatocytes I revealed that telomere clustering occurs aberrantly in Atm-/- mice. Numerous spermatocytes of Atm-/- mice displayed locally accumulated telomeres with stretches of SC near the clustered chromosome ends. This contrasted with spermatogenesis of normal mice, where only a few leptotene/zygotene spermatocytes I with clustered telomeres were detected. Pachytene nuclei, which were much more abundant in normal mice, displayed telomeres scattered over the nuclear periphery. It appears that the timing and occurrence of chromosome polarization is altered in Atm-/- mice. When we examined telomere-nuclear matrix interactions in spermatocytes I, a significant difference was observed in the ratio of soluble versus matrix-associated telomeric DNA sequences between meiocytes of Atm-/- and control mice. We propose that the severe disruption of spermatogenesis during early prophase I in the absence of functional Atm may be partly due to altered interactions of telomeres with the nuclear matrix and distorted meiotic telomere clustering.

The RNA polymerase II core subunit 11 interacts with keratin 19, a component of the intermediate filament proteins

We have previously cloned the human RNA polymerase II subunit 11, as a doxorubicin sensitive gene product. We suggested multiple tasks for this subunit, including structural and regulatory roles. With the aim to clarify the human RNA polymerase II subunit 11 function, we have identified its interacting protein partners using the yeast two-hybrid system. Here, we show that human RNA polymerase II subunit 11 specifically binds keratin 19, a component of the intermediate filament protein family, which is expressed in a tissue and differentiation-specific manner. In particular, keratin 19 is a part of the nuclear matrix intermediate filaments. We provide evidence that human RNA polymerase II subunit 11 interacts with keratin 19 via its N-terminal alpha motif, the same motif necessary for its interaction with the human RNA polymerase II core subunit 3. We found that keratin 19 contains two putative leucine zipper domains sharing peculiar homology with the alpha motif of human RNA polymerase II subunit 3. Finally, we demonstrate that keratin 19 can compete for binding human RNA polymerase II subunit 11/human RNA polymerase II subunit 3 in vitro, suggesting a possible regulatory role for this molecule in RNA polymerase II assembly/activity.

Immunocytochemical detection of structural and regulatory proteins in rat adrenal nuclear matrix

The nuclear matrix is a specific cell structure consisting of a residual nucleoskeleton that extends from the nucleoli to the nuclear envelope. The nuclear matrix of steroidogenic cells was isolated previously from a purified nuclear fraction. We present here an in situ extraction method, modified Lutz's method, for rat glandular adrenal cell nuclear matrix. This residual organelle was characterized and studied using immunocytochemical methods. The adrenal glands were removed, the cells prepared in suspension and deposited by cytospin onto Poly-L-lysine glass slides. The nuclear matrix was extracted with Nonidet P-40, DNase I and high and low ionic strength buffers. Structural proteins, nuclear lamins, coilin and fibrillarin were detected immunocytochemically. The adrenal fasciculata cells were easily identified by this method because of their large nuclei and abundant lipid droplets in the cytoplasm. After immunocytochemical detection by antibodies against lamins A and C, a marked brown layer at the periphery of the nucleus was observed. The intensity of the staining was lower using the antibody against nuclear lamin B. Immunocytochemical detection of the protein coilin revealed punctuated stained areas, 2-6 per nucleus, that probably correspond to the coiled bodies. The protein fibrillarin was detected at the nucleolus and coiled bodies. Our technique is simple, reveals well preserved adrenal nuclear matrices, and may be a useful method for immunocytochemical analysis and in situ hybridization.

Subcellular localization of mineralocorticoid receptors in living cells: effects of receptor agonists and antagonists

Results on the subcellular localization of the mineralocorticoid receptor (MR) have been controversial. To determine the subcellular distribution and trafficking of the MR in living cells after binding of agonists and antagonists, we expressed a MR-green fluorescent protein (GFP) chimera in mammalian cells lacking endogenous MR. The GFP-tagged MR (GFP-MR) remained transcriptionally active, as determined in cotransfection experiments with the MR-responsive reporter, TAT3-LUC. The subcellular localization of GFP-MR was monitored by fluorescence time-lapse microscopy. In the absence of hormone, MR was present both in the cytoplasm and nucleus. Aldosterone induced a rapid nuclear accumulation of the MR. Aldosterone-bound GFP-MR was concentrated in prominent clusters within the nucleus, whereas GFP-MR did not form clusters in the absence of hormone. Similar subnuclear distribution was observed with corticosterone, another MR agonist. In the presence of the MR antagonists spironolactone or ZK91587 the rate of nuclear translocation was significantly slower and the final nuclear-to-cytoplasmic ratio in steady state was significantly lower than with aldosterone. In addition, MR antagonists did not induce formation of nuclear GFP-MR clusters. MR antagonists also were able to disrupt pre-existing nuclear clusters formed in the presence of aldosterone. GFP-MR clusters were retained in nuclear matrix preparations after in vivo crosslinking. These data strongly suggest that hormone-activated MRs accumulate in dynamic discrete clusters in the cell nucleus, and this phenomenon occurs only with transcriptionally active mineralocorticoids.

Structural protein 4.1 in the nucleus of human cells: dynamic rearrangements during cell division

Structural protein 4.1, first identified as a crucial 80-kD protein in the mature red cell membrane skeleton, is now known to be a diverse family of protein isoforms generated by complex alternative mRNA splicing, variable usage of translation initiation sites, and posttranslational modification. Protein 4.1 epitopes are detected at multiple intracellular sites in nucleated mammalian cells. We report here investigations of protein 4.1 in the nucleus. Reconstructions of optical sections of human diploid fibroblast nuclei using antibodies specific for 80-kD red cell 4.1 and for 4.1 peptides showed 4.1 immunofluorescent signals were intranuclear and distributed throughout the volume of the nucleus. After sequential extractions of cells in situ, 4.1 epitopes were detected in nuclear matrix both by immunofluorescence light microscopy and resinless section immunoelectron microscopy. Western blot analysis of fibroblast nuclear matrix protein fractions, isolated under identical extraction conditions as those for microscopy, revealed several polypeptide bands reactive to multiple 4.1 antibodies against different domains. Epitope-tagged protein 4.1 was detected in fibroblast nuclei after transient transfections using a construct encoding red cell 80-kD 4.1 fused to an epitope tag. Endogenous protein 4.1 epitopes were detected throughout the cell cycle but underwent dynamic spatial rearrangements during cell division. Protein 4.1 was observed in nucleoplasm and centrosomes at interphase, in the mitotic spindle during mitosis, in perichromatin during telophase, as well as in the midbody during cytokinesis. These results suggest that multiple protein 4.1 isoforms may contribute significantly to nuclear architecture and ultimately to nuclear function.

The role of insulator elements in defining domains of gene expression

Insulators are naturally occurring DNA sequences that protect transgenes from genomic position effects, thereby establishing independent functional domains within the chromosome. Recent studies have focused on the identification of the cis and trans requirements for insulator activity. These experiments demonstrate that insulators contain multiple components that cooperate to confer their unique properties. Additionally, they suggest that the mechanism of insulation is related to that of enhancer function. Two models of insulator can be considered: a domain boundary and a transcriptional decoy model.

Structure and dynamic organization of centromeres/prekinetochores in the nucleus of mammalian cells

Although considerable research has been focused on understanding the structure and molecular organization of the centromere-kinetochore complex of mitotic chromosomes, few reports have dealt with the centromere (prekinetochore) in the interphase nucleus. In the present study, we utilized anti-centromere antibodies from the serum of patients with the autoimmune disease, scleroderma CREST (calcinosis, Raynaud's phenomenon, esophageal dismotility, sclerodactyly, telangiectasia), as probes to investigate the structure and morphogenesis of the centromere in interphase nuclei of three cell lines using laser scanning confocal microscopy and immunoelectron microscopy. Of particular interest were the chromosomes of the Indian muntjac (2n = 6 in females and 2n = 7 in males), whose large centromeres are thought to have evolved through the tandem fusion of smaller centromeres of a Chinese muntjac-like progenitor species (2n = 46). The various forms and patterns of centromeres observed in the nucleus correlated with stages in the cell cycle as determined by bromodeoxyuridine labeling and apparently represent stages in prereplication, replication and maturation. Immunoelectron microscopic studies using CREST antisera indicated that the high order structure of chromatin associated with each prekinetochore undergoes a regular unfolding-refolding cycle, displaying small bead-like subunits tandemly arranged along a linear thread of centromeric DNA, much like that reported for mitotic chromosomes. Individual centromeres/prekinetochores form a stable association with the 9–13 nm core filaments of the nucleoskeletal network in the nucleus that later become the chromosome scaffold of mitotic chromosomes. Our findings provide morphological support for the hypothesis that the spatial arrangements of individual centromeres within the nucleus may have influenced centromeric translocations and fusions during chromosome evolution. Therefore, the centromere-kinetochore complex, best known for its essential role in partitioning chromosomes in mitosis and meiosis, may also function in chromosome movements and associations in interphase.

Dynamic continuity of nuclear and mitotic matrix proteins in the cell cycle

The eukaryotic cell nucleus is a membrane-enclosed compartment containing the genome and associated molecules supported by a highly insoluble filamentous network known as the nucleoskeleton or nuclear matrix. The nuclear matrix is believed to play roles in maintaining nuclear architecture and organizing nuclear metabolism. Recently, advances in microscopic techniques and the availability of new molecular probes have made it possible to localize functional domains within the nuclear matrix and demonstrate dynamic interactions between both soluble and insoluble components involved in the control of multiple nuclear transactions. Like the cytoplasm and its skeleton, the nucleoplasm is highly structured and very crowded with an equally complex skeletal framework. In fact, there is growing evidence that the two skeletal systems are functionally contiguous, providing a dynamic cellular matrix connecting the cell surface with the genome. If we impose cell cycle dynamics upon this skeletal organization, it is obvious that the genome and associated nuclear matrix must undergo a major structural transition during mitosis, being disassembled and/or reorganized in late G2 and reassembled again in daughter nuclei. However, recent evidence from our laboratory and elsewhere suggests that much of the nuclear matrix is used to form the mitotic apparatus (MA). Indeed, both facultative and constitutive matrix-associated proteins such as NuMA, CENP-B, CENP-F, and the retinoblastoma protein (Rb) associate within and around the MA. During mitosis, the nuclear matrix proteins may either become inert "passengers" or assume critical functions in partitioning the genome into newly formed G1 nuclei. Therefore, we support the view that the nuclear matrix exists as a dynamic architectural continuum, embracing the genome and maintaining cellular regulation throughout the cell cycle.

Neuron specificity of the neurofilament light promoter in transgenic mice requires the presence of DNA unwinding elements

Three reporter genes, the chloramphenicol acetyltransferase (CAT), the lacZ, and the intronless NF-L DNA, were used to test the activity of the proximal promoter region (-292 bp) of the human neurofilament light (hNF-L) gene in transgenic mice. Surprisingly, the hNF-L/CAT construct was highly sensitive to position effect, and its expression was found at low levels in several tissues of adult transgenic mice (Beaudet, L., Charron, G., Houle, D., Tretjakoff, I. Peterson, A., and Julien, J.-P. (1992) Gene (Amst.) 116, 205-214). In contrast, the hNF-L/lacZ or the hNF-L/intronless constructs were expressed exclusively in the nervous system during embryonic development and in adult animals. The DNA sequences analysis of the different reporter genes revealed the presence of matrix attachment regions (MARs) within the 3'-untranslated regions of all three transgenes. DNA unwinding elements were found within the MARs of lacZ and hNF-L gene constructs but not in the CAT gene construct. When this element was removed from the lacZ construct, expression of the hNF-L/lacZ transgene became susceptible to position effect and was no longer tissue-specific. These results indicate that DNA unwinding elements are essential for position effect independence conferred by MARs to the hNF-L basal promoter.

Long-range fragmentation of the eukaryotic genome by exogenous and endogenous nucleases proceeds in a specific fashion via preferential DNA cleavage at matrix attachment sites

Small cell lung cancer cells (OC-NYH-VM) were permeabilized and treated with different nucleases. The long-range distribution of DNA cleavage sites in the amplified c-myc gene locus was then analyzed by pulsed field gel electrophoretic separation of the released 50-kilobase to 1-megabase DNA fragments followed by indirect end labeling. Exogenous DNase I and nucleases specific for the single-stranded DNA were found to generate similar nonrandom patterns of large DNA fragments. The cleavage sites were located close to or even colocalized with matrix attachment regions, which were mapped independently using a recently developed procedure for DNA loop excision by DNA topoisomerase II-mediated DNA cleavage. Endogenous acidic nuclease with the properties of DNase II also digested DNA preferentially in proximity to the matrix attachment regions, generating characteristic patterns of excised DNA loops and their oligomers. A similar, although less specific, pattern of DNA fragmentation was observed after incubation of permeabilized cells under conditions favoring the activity of endogenous neutral Ca(2+)- and Mg(2+)-dependent nucleases. These findings are discussed in the context of the current model of the spatial domain organization of eukaryotic genome.

The role of scaffold attachment regions in the structural and functional organization of plant chromatin

Studies on nuclear scaffolds and scaffold attachment regions (SARs) have recently been extended to different plant species and indicate that SARs are involved in the structural and functional organization of the plant genome, as is the case for other eukaryotes. One type of SAR seems to delimit structural chromatin loops and may also border functional units of gene expression and DNA replication. Another group of SARs map close to regulatory elements and may be directly involved in gene expression. In this overview, we summarize the structural and functional properties of plant SARs in comparison with those of SARs from animals and yeast.

Elements regulating somatic hypermutation of an immunoglobulin kappa gene: critical role for the intron enhancer/matrix attachment region

Following encounter with antigen, the immunoglobulin genes in B lymphocytes undergo somatic hypermutation. Most nucleotide substitutions are introduced into a region flanked by the V gene promoter and intron enhancer. Experiments described here using transgenic mice revealed that the V kappa promoter does not contain specific signals since hypermutation was retained on substituting it by a beta-globin promoter. However, both the kappa intron and kappa 3' enhancer regions were found to be essential for full hypermutation. This dependence of hypermutation on both enhancers contrasts with transgene expression in hybridomas in which only the 3' enhancer (and not the intron enhancer) is necessary to achieve high mRNA levels. The results show that full hypermutation depends on multiple elements, removal of some of which may drastically impair but not totally abolish the process.

Nature of DNA sequences at the attachment regions of genes to the nuclear matrix

Matrix-attached regions (MARs) have been demonstrated to nest origins of replication and transcriptional enhancers. A set of 13 rules is proposed aimed at facilitating the classification of a DNA sequence as a matrix attachment region.(ABSTRACT TRUNCATED AT 250 WORDS)

Homeodomain protein binding sites, inverted repeats, and nuclear matrix attachment regions along the human beta-globin gene complex

beta-Globin genes in primates arose during evolution by duplication of an ancestral gene, and their order of arrangement along the DNA is related to their timing of expression during development. We believe that nuclear matrix anchorage sites (MARs) along the beta-globin gene complex considered to be mass binding sites for transcription protein factors, some of which are developmental stage specific and others ubiquitous, play a decisive role in cell memory by determining the developmental stage-specific expression of the genes. The AT-rich class of MARs appears to possess a significant number of ATTA and ATTTA motifs known to be mass binding sites for homeodomain proteins that determine body formation in development. MARs also appear to harbor origins of replication, to be enriched in inverted repeats (dyad symmetry motifs) and were proposed to include the DNase I hypersensitive sites of a particular gene determined at the chromatin level. This study is an attempt to finely identify MARs at the nucleotide level along the beta-globin gene complex. Searches of a contiguous stretch of about 73.3 kb of human sequences comprising and surrounding the epsilon, gamma G-, gamma A-, delta-, and beta-globin genes of the human beta-globin gene complex for homeotic protein binding sites as well as for inverted repeats has shown that these elements are clustered nonrandomly at particular sites within the beta-globin gene complex. These sites are presumed to be the AT-rich class of MARs of the beta-globin gene complex. The inverted repeats which are characteristic of origins of replication and some promoter/enhancer regions and the homeotic protein sites seem to include the DNase I hypersensitive sites of the gene complex. Indeed, dyad symmetry sequences are present close to the four DNase I HS sites in the locus control region (LCR) of the gene complex as well as in the 5' flanking regions and the large introns of the delta- and beta-globin genes. A search of the putative MAR regions of the gene complex suggests that, in addition to their enrichment in ATTA motifs, palindromes, and DNase I hypersensitive sites, these regions may comprise TG-rich motifs and potential Z-DNA as well as polypurine and polypyrimidine blocks. From the positions of palindromes and clusters of homeodomain protein sites along the complex we propose that an extended origin of replication able to initiate at several sites is present in the LCR and two others surrounding the delta- and beta-globin genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Code domains in tandem repetitive DNA sequence structures

Traditionally, many people doing research in molecular biology attribute coding properties to a given DNA sequence if this sequence contains an open reading frame for translation into a sequence of amino acids. This protein coding capability of DNA was detected about 30 years ago. The underlying genetic code is highly conserved and present in every biological species studied so far. Today, it is obvious that DNA has a much larger coding potential for other important tasks. Apart from coding for specific RNA molecules such as rRNA, snRNA and tRNA molecules, specific structural and sequence patterns of the DNA chain itself express distinct codes for the regulation and expression of its genetic activity. A chromatin code has been defined for phasing of the histone-octamer protein complex in the nucleosome. A translation frame code has been shown to exist that determines correct triplet counting at the ribosome during protein synthesis. A loop code seems to organize the single stranded interaction of the nascent RNA chain with proteins during the splicing process, and a splicing code phases successive 5' and 3' splicing sites. Most of these DNA codes are not exclusively based on the primary DNA sequence itself, but also seem to include specific features of the corresponding higher order structures. Based on the view that these various DNA codes are genetically instructive for specific molecular interactions or processes, important in the nucleus during interphase and during cell division, the coding capability of tandem repetitive DNA sequences has recently been reconsidered.

Developmental regulation of an snRNP core protein epitope during pig embryogenesis and after nuclear transfer for cloning

The appearance and stabilization of a core protein epitope of the snRNP is developmentally regulated during pig embryogenesis. The epitope recognized by the monoclonal antibody Y12 is present in the germinal vesicle of mature oocytes and interphase nuclei of late 4-cell stage (24 to 30 hours post cleavage to the 4-cell stage) to blastocyst stage embryos. There was no antibody localization within pronuclei, or nuclei of 2-cell or early 4-cell stage embryos. Zygotes or 2-cell stage embryos cultured in the presence of alpha-amanitin to the late 4-cell stage showed no immunoreactivity, whereas control embryos had immunoreactivity. Thus antibody localization was correlated with RNA synthesis and RNA processing that begins by 24 hours post cleavage to the 4-cell stage. A final experiment showed no detectable immunoreactivity in 16-cell stage nuclei that had been transferred to enucleated activated meiotic metaphase II oocytes. Since immunoreactivity is associated with active RNA synthesis and RNA processing, it suggests that the 16-cell stage nucleus, which is RNA synthetically active, does not process RNA after nuclear transfer to an enucleated activated meiotic metaphase II oocyte.