Co-existence of two different types of soluble histone complexes in nuclei of Xenopus laevis oocytes

Purification and properties of the Xenopus Hat1 acetyltransferase: association with the 14-3-3 proteins in the oocyte nucleus

We have purified the Xenopus histone acetyltransferase Hat1 holoenzyme from oocytes. The holoenzyme contains the catalytic subunit Hat1, the retinoblastoma associated protein RbAp48, and members of the phosphoserine binding family of 14-3-3 proteins. We have determined that the Hat1 holoenzyme specifically acetylates free histone H4 but not nucleosomal histones. RbAp48 is a phosphoprotein that contains a consensus recognition motif for the 14-3-3 proteins. The 14-3-3 proteins provide a regulatory function for the activity of many phosphoproteins. We find that the hugely abundant Hat1 holoenzyme is present in 10 000-fold excess over somatic cell levels. The holoenzyme is localized in the oocyte nucleus where acetylated histones are stored. The oocyte form of the Xenopus Hat1 holoenzyme may represent a specialized storage form of histone acetyltransferase. Following oocyte maturation and subsequent embryogenesis, the Hat1 enzyme is redistributed to the cytoplasm, where new histones are synthesized.

Sperm chromatin decondensation by template activating factor I through direct interaction with basic proteins

Template activating factor I (TAF-I) was originally identified as a host factor required for DNA replication and transcription of adenovirus genome complexed with viral basic proteins. Purified TAF-I was shown to bind to core histones and stimulate transcription from nucleosomal templates. Human TAF-I consists of two acidic proteins, TAF-Ialpha and TAF-Ibeta, which differ from each other only in their amino-terminal regions. Here, we report that TAF-I decondenses demembraned Xenopus sperm chromatin. Human TAF-Ibeta has a chromatin decondensation activity comparable to that of NAP-I, another histone binding protein, whereas TAF-Ialpha has only a weak activity. Analysis of molecular mechanisms underlying the chromatin decondensation by TAF-I revealed that TAF-I interacts directly with sperm basic proteins. Deletion of the TAF-I carboxyl-terminal acidic region abolishes the decondensation activity. Interestingly, the acidic region itself is not sufficient for decondensation, since an amino acid substitution mutant in the dimerization domain of TAF-I which has the intact acidic region does not support chromatin decondensation. We detected the beta form of TAF-I in Xenopus oocytes and eggs by immunoblotting, and the cloning of its cDNA led us to conclude that Xenopus TAF-Ibeta also decondenses sperm chromatin. These results suggest that TAF-I plays a role in remodeling higher-order chromatin structure as well as nucleosomal structure through direct interaction with chromatin basic proteins.

Maternal histone deacetylase is accumulated in the nuclei of Xenopus oocytes as protein complexes with potential enzyme activity

Reversible acetylation of core histones plays an important regulatory role in transcription and replication of chromatin. The acetylation status of chromatin is determined by the equilibrium between activities of histone acetyltransferases (HATs) and histone deacetylases (HDACs). The Xenopus protein HDACm shows sequence homology to other putative histone deacetylases, but its mRNA is expressed only during early development. Both HDACm protein and acetylated non-chromosomal histones are accumulated in developing oocytes, indicating that the key components for histone deposition into new chromatin during blastula formation are in place by the end of oogenesis. Here we show that the 57 kDa HDACm protein undergoes steady accumulation in the nucleus, where it is organized in a multiprotein complex of approx. 300 kDa. A second, major component of the nuclear complex is the retinoblastoma-associated protein p48 (RbAp48/46), which may be used as an adaptor to contact acetylated histones in newly assembled chromatin. The nuclear complex has HDAC activity that is sensitive to trichostatin A, zinc ions and phosphatase treatment. The 57 kDa protein serves as a marker for total HDAC activity throughout oogenesis and early embryogenesis. The active HDACm complex and its acetylated histone substrates appear to be kept apart until after chromatin assembly has taken place. However, recombinant HDACm, injected into the cytoplasm of oocytes, not only is translocated to the nucleus, but also is free to interact with the endogenous chromatin.

Formaldehyde cross-linking for studying nucleosomal dynamics

Methods are described for the utilization of formaldehyde as a reversible cross-linking agent for the characterization of protein-protein and protein-DNA interactions. The methods include a description of procedures to: (1) isolate and characterize transcriptionally active chromatin from cells cross-linked with formaldehyde; (2) study histone mobility during replication and transcription by the characterization of the formaldehyde-cross-linked histone octamer that is isolated from cells labeled with density-labeled amino acids; and (3) cross-link the in vitro reconstituted histone-DNA complex in order to maintain its structural state during subsequent characterization. Included in these methods are procedures for a second dimensional analysis of protein-protein cross-links in which the monomer components are electrophoretically resolved in the second dimension. The methods also include procedures to selectively reverse protein-DNA cross-links while maintaining the protein-protein cross-links. Potential artifacts are also discussed; i.e., data are presented which indicate that the helical pitch of DNA can be altered if the ionic strength is not properly controlled. The stability of the cross-linked nucleosome in the presence of altered pH or salt/urea concentrations is described in order to indicate that there are limitations to procedures that can be used for the subsequent characterization of the cross-linked complex.

Chromatin binding and polymerization of the endogenous Xenopus egg lamins: the opposing effects of glycogen and ATP

We have previously identified and quantitated three B-type lamin isoforms present in the nuclei of mature Xenopus laevis oocytes, and in cell-free egg extracts. As Xenopus egg extracts are frequently used to analyze nuclear envelope assembly and lamina functions, we felt it was imperative that the polymerization and chromatin-binding properties of the endogenous B-type egg lamins be investigated. While we have demonstrated that soluble B-type lamins bind to chromatin, we have also observed that the polymerization of egg lamins does not require membranes or chromatin. Lamin assembly is enhanced by the addition of glycogen/glucose, or by the depletion of ATP from the extract. Moreover, the polymerization of egg cytosol lamins and their binding to demembranated sperm or chromatin assembled from naked lambda-DNA is inhibited by an ATP regeneration system. These ATP-dependent inhibitory activities can be overcome by the coaddition of glycogen to egg cytosol. We have observed that glycogen does not alter ATP levels during cytosol incubation, but rather, as glycogen-enhanced lamin polymerization is inhibited by okadaic acid, we conclude that glycogen activates protein phosphatases. Because protein phosphatase 1 (PP1) is the only phosphatase known to be specifically regulated by glycogen our data indicate that PP1 is involved in lamin polymerization. Our results show that ATP and glycogen effect lamin polymerization and chromatin binding by separate and opposing mechanisms.

LBP-p40 binds DNA tightly through associations with histones H2A, H2B, and H4

Laminin binding protein precursor p40 (LBP-p40) was long believed to be located exclusively in the cytoplasm. We recently reported localization of epitope-tagged LBP-p40 to the nucleus tightly associated with nuclear structure as well as on ribosomes. In this paper, we analyze the interaction of LBP-p40 with DNA and nuclear proteins in vitro. LBP-p40 was found to bind to a double-stranded DNA cellulose column at moderate salt. However, when mixed with a high salt nuclear extract, LBP-p40 was eluted from the DNA cellulose column only at higher salt. An LBP-p40 affinity column indicated that both histone H1 and in particular the core histones associate with LBP-p40. Using recombinant core histone molecules fused with glutathione S-transferase (GST), we demonstrate that histones H2A, H2B, and H4 are capable of interacting with LBP-p40, whereas H3 is not. These results suggest that association of LBP-p40 with histones H2A, H2B, and H4 confers tight binding of LBP-p40 to chromatin DNA in the nucleus.

Alteration of nucleosome structure as a mechanism of transcriptional regulation

The nucleosome, which is the primary building block of chromatin, is not a static structure: It can adopt alternative conformations. Changes in solution conditions or changes in histone acetylation state cause nucleosomes and nucleosomal arrays to behave with altered biophysical properties. Distinct subpopulations of nucleosomes isolated from cells have chromatographic properties and nuclease sensitivity different from those of bulk nucleosomes. Recently, proteins that were initially identified as necessary for transcriptional regulation have been shown to alter nucleosomal structure. These proteins are found in three types of multiprotein complexes that can acetylate nucleosomes, deacetylate nucleosomes, or alter nucleosome structure in an ATP-dependent manner. The direct modification of nucleosome structure by these complexes is likely to play a central role in appropriate regulation of eukaryotic genes.

Hir proteins are required for position-dependent gene silencing in Saccharomyces cerevisiae in the absence of chromatin assembly factor I

Chromatin assembly factor I (CAF-I) is a three-subunit histone-binding complex conserved from the yeast Saccharomyces cerevisiae to humans. Yeast cells lacking CAF-I (cacDelta mutants) have defects in heterochromatic gene silencing. In this study, we showed that deletion of HIR genes, which regulate histone gene expression, synergistically reduced gene silencing at telomeres and at the HM loci in cacDelta mutants, although hirDelta mutants had no silencing defects when CAF-I was intact. Therefore, Hir proteins are required for an alternative silencing pathway that becomes important in the absence of CAF-I. Because Hir proteins regulate expression of histone genes, we tested the effects of histone gene deletion and overexpression on telomeric silencing and found that alterations in histone H3 and H4 levels or in core histone stoichiometry reduced silencing in cacDelta mutants but not in wild-type cells. We therefore propose that Hir proteins contribute to silencing indirectly via regulation of histone synthesis. However, deletion of combinations of CAC and HIR genes also affected the growth rate and in some cases caused partial temperature sensitivity, suggesting that global aspects of chromosome function may be affected by the loss of members of both gene families.

Identification and characterization of a novel kind of nuclear protein occurring free in the nucleoplasm and in ribonucleoprotein structures of the "speckle" type

We have identified, by cDNA cloning and immunodetection, a novel type of constitutive nuclear protein which occurs in diverse vertebrate species, from Xenopus laevis to man, in the form of two different gene products (79.1 kDa and 82.1 kDa in Xenopus, 81.6 kDa and 84.6 kDa in man), remarkably differing in pI (5.4-7.2). This type of protein is characterized by a carboxyterminal domain extremely rich in hydroxyamino acid residues, notably Ser (S), and tetrapeptide repeats of the type XSRS, and hence is termed "domain rich in serines" (DRS) protein. It has been immunolocalized exclusively in the cell nucleus such as in blood cell smears, cultured cells of very different origins and tissue sections, and has also been identified in Xenopus oocyte nuclei, both in sections and by biochemical methods in manually isolated nuclei. In many cell types the protein appears in two different physical states: (i) nuclear granules, identified as ribonucleoprotein (RNP) structures of the "speckle" category by colocalization and cofractionation with certain splicing factors and Sm-proteins, and (ii) in molecules diffusible throughout the nucleoplasm. During mitosis and also in meiosis (Xenopus eggs) the protein is transiently dispersed throughout the cytoplasm but rapidly reaccumulates into the reforming daughter-nuclei. In agreement with this, biochemical experiments have shown that during meiosis (eggs) the protein is recovered in a approximately 11-13S complex of the fraction of soluble cell components. We discuss general constitutive nuclear functions of this apparently ubiquitous and evolutionarily conserved protein.

Identification of a small, very acidic constitutive nucleolar protein (NO29) as a member of the nucleoplasmin family

We report the discovery and molecular characterization of a small and very acidic nucleolar protein of an SDS/PAGE mobility corresponding to Mr 29,000 (NO29). The cDNA-deduced sequence of the Xenopus laevis protein defines a polypeptide of a calculated molecular mass of 20,121 and a pI of 3.75, with an extended acidic region near its C terminus, and is related to the major nucleolar protein, NO38, and the histone-binding protein, nucleoplasmin. This member of the nucleoplasmin family of proteins was immunolocalized to nucleoli in Xenopus oocytes and diverse somatic cells. Protein NO29 is associated with nuclear particles from Xenopus oocytes, partly complexed with protein NO38, and occurs in preribosomes but not in mature ribosomes. The location and the enormously high content of negatively charged amino acids lead to the hypothesis that NO29 might be involved in the nuclear and nucleolar accumulation of ribosomal proteins and the coordinated assembly of pre-ribosomal particles.

Functional characterization of human nucleosome assembly protein-2 (NAP1L4) suggests a role as a histone chaperone

Histones are thought to play a key role in regulating gene expression at the level of DNA packaging. Recent evidence suggests that transcriptional activation requires competition of transcription factors with histones for binding to regulatory regions and that there may be several mechanisms by which this is achieved. We have characterized a human nucleosome assembly protein, NAP-2, previously identified by positional cloning at 11p15.5, a region implicated in several disease processes including Wilms tumor (WT) etiology. The deduced amino acid sequence of NAP-2 indicates that it encodes a protein with a potential nuclear localization motif and two clusters of highly acidic residues. Functional analysis of recombinant NAP-2 protein purified from Escherichia coli demonstrates that this protein can interact with both core and linker histones. We demonstrate that recombinant NAP-2 can transfer histones onto naked DNA templates. Deletion mutagenesis of NAP-2 demonstrates that both NH3- and COOH-terminal domains are required for histone transfer activity. Subcellular localization studies of NAP-2 indicate that it can shuttle between the cytoplasm and the nucleus, suggesting a role as a histone chaperone. Given the potential role of the human NAP-2 gene (HGMW-approved symbol NAP1L4) in WT etiology, we have elucidated the exon/intron structure of this gene and have analyzed the mutational status of NAP-2 in sporadic WTs. Our results, coupled with tumor suppression assays in G401 WT cells, do not support a role for NAP-2 in the etiology of WT. A putative role for NAP-2 in regulating cellular differentiation is discussed.

Chromatin assembly in a yeast whole-cell extract

A simple in vitro system that supports chromatin assembly was developed for Saccharomyces cerevisiae. The assembly reaction is ATP-dependent, uses soluble histones and assembly factors, and generates physiologically spaced nucleosomes. We analyze the pathway of histone recruitment into nucleosomes, using this system in combination with genetic methods for the manipulation of yeast. This analysis supports the model of sequential recruitment of H3/H4 tetramers and H2A/H2B dimers into nucleosomes. Using a similar approach, we show that DNA ligase I can play an important role in template repair during assembly. These studies demonstrate the utility of this system for the combined biochemical and genetic analysis of chromatin assembly in yeast.

The ability to organize sperm DNA into functional chromatin is acquired during meiotic maturation in murine oocytes

Following fertilization of meiotically mature eggs, the chromatin of the sperm becomes biochemically and structurally remodeled within the egg cytoplasm. Despite the essential role of the paternal genome during embryogenesis, little is known of when the activities that regulate this chromatin remodeling appear during oogenesis. To determine whether these activities were acquired during meiotic maturation, we inseminated maturing oocytes of mice shortly after germinal vesicle breakdown. As previously shown, insemination at this stage did not activate the maturing oocytes, which became arrested at metaphase II. Immunofluorescent analysis revealed that at 1 hr postinsemination the sperm chromatin was dispersed and contained protamines but was devoid of core histones H2B and H3. At 4 hr postinsemination, both protamine and core histones were detectable on the sperm chromatin. By 8 hr postinsemination protamines were absent, and histones stained maximally. The appearance of immunoreactive histones was correlated with a morphological transition of the sperm chromatin from the dispersed to a condensed state, which suggests that the assembly of the histones reflected modification of the chromatin to a somatic-like state in which it was competent to respond to the metaphase-promoting factor activity of the oocyte. Both the assembly of histones and chromatin condensation were reversibly blocked when protein synthesis was inhibited, indicating that the remodeling process required proteins synthesized during maturation. Injection of core histones into protein synthesis-inhibited oocytes failed to induce condensation of the sperm chromatin, which implies that correct remodeling requires synthesis during maturation of nonhistone proteins. To test the functional capacity of remodeled sperm chromatin, maturing oocytes were inseminated, allowed to continue maturation for 17 hr and then parthenogenetically activated. Following activation, the sperm-derived chromatin as well as that of the oocyte became decondensed within pronuclei and underwent DNA replication, indicating that sperm chromatin remodeled in maturing oocyte cytoplasm was functionally normal. When the postinsemination incubation time was reduced to 11 hr; however, neither the female nor the male pronuclei underwent DNA replication, implying that factors synthesized late during maturation are required for DNA replication after activation. Taken together, these results indicate that the ability to organize sperm DNA into functional somatic-like chromatin develops in oocytes during meiotic maturation, requires proteins synthesized during maturation, and can be expressed independently of activation.

AND-1, a natural chimeric DNA-binding protein, combines an HMG-box with regulatory WD-repeats

Using a specific monoclonal antibody (mAb AND-1/23-5-14) we have identified, cDNA-cloned and characterized a novel DNA-binding protein of the clawed toad, Xenopus laevis, that is accumulated in the nucleoplasm of oocytes and various other cells. This protein comprises 1,127 amino acids, with a total molecular mass of 125 kDa and a pI of 5.27. It is encoded by a mRNA of approximately 4 kb and contains, in addition to clusters of acidic amino acids, two hallmark motifs: the amino-terminal part harbours seven consecutive ‘WD-repeats’, which are sequence motifs of about 40 amino acids that are characteristic of a large group of regulatory proteins involved in diverse cellular functions, while the carboxy terminal portion possesses a 63-amino-acid-long ‘HMG-box’, which is typical of a family of DNA-binding proteins involved in regulation of chromatin assembly, transcription and replication. The DNA-binding capability of the protein was demonstrated by DNA affinity chromatography and electrophoretic mobility shift assays using four-way junction DNA. Protein AND-1 (acidic nucleoplasmic DNA-binding protein) appears as an oligomer, probably a homodimer, and has been localized throughout the entire interchromatinic space of the interphase nucleoplasm, whereas during mitosis it is transiently dispersed over the cytoplasm. We also identified a closely related, perhaps orthologous protein in mammals. The unique features of protein AND-1, which is a ‘natural chimera’ combining properties of the WD-repeat and the HMG-box families of proteins, are discussed in relation to its possible nuclear functions.

Histones in transit: cytosolic histone complexes and diacetylation of H4 during nucleosome assembly in human cells

The organization and acetylation of nascent histones prior to their stable incorporation into chromatin were examined. Through sedimentation and immunoprecipitation analyses of HeLa cytosolic extracts, two somatic non-nucleosomal histone complexes were detected: one containing nascent H3 and H4, and a second containing H2A (and probably H2B) in association with the nonhistone protein NAP-1. The H3/H4 complex has a sedimentation coefficient of 5-6S, consistent with the presence of one or more escort proteins. H4 in the cytosolic H3/H4 complex is diacetylated, fully in accord with the acetylation state of newly synthesized H4 in chromatin. The diacetylation of nascent human H4 is therefore completed prior to nucleosome assembly. As part of our studies of the nascent H3/H4 complex, the cytoplasmic histone acetyltransferase most likely responsible for acetylating newly synthesized H4 was also investigated. HeLa histone acetyltransferase B (HAT B) acetylates H4 but not H3 in vitro, and maximally diacetylates H4 even in the presence of sodium butyrate. Human HAT B acetylates H4 exclusively on the lysine residues at positions 5 and 12, in complete agreement with the highly conserved acetylation pattern of nascent nucleosomal H4 (Sobel et al., 1995), and has a native molecular weight of approximately 100 kDa. Based on our findings a model is presented for the involvement of histone acetylation and NAP-1 in H2A/H2B deposition and exchange, during nucleosome assembly and chromatin remodeling in vivo.

Effects of spermine and its cytotoxic analogs on nucleosome formation on topologically stressed DNA in vitro

We investigated the effects of the polyamine spermine and two of its cytotoxic analogs 1,11-bis(ethylamino)-4,8-diazaundecane (BE-3-3-3) and 1,19-bis(ethylamino)-5,10,15-tirazanonadecane (BE-4-4-4-4) on the formation of nucleosomes on negatively and positively supercoiled DNA in vitro. Histones H2A, H2B, H3 and H4 were reconstituted onto DNA to form nucleosomes and the polyamines were added either before or after histone addition. The structural state of the nucleosome was monitored by analyzing the DNA topoisomers that were present after topoisomerase I treatment. Although polyamines induced DNA aggregation to various degrees. high concentrations of topoisomerase I were able to relax the aggregated DNA and the helical pitch was found to be unaltered in the aggregates. When histones were associated with negatively coiled DNA, the polyamine-induced aggregation did not alter nucleosome structure. The induced aggregate did inhibit nucleosomal transitions when examined on positively coiled DNA. BE-4-4-4-4 was most effective and BE-3-3-3 least effective. These analogs were also extremely effective in inhibiting histone deposition onto DNA. A potential mechanism for the action of these analogs is both to inhibit histone deposition during DNA replication and also disrupt nucleosomal dynamics due to aberrant chromatin condensation. These results also suggest that BE-4-4-4-4 and BE-3-3-3 may produce their cytotoxic effect through slightly different mechanisms.

ATP-facilitated chromatin assembly with a nucleoplasmin-like protein from Drosophila melanogaster

To gain a better understanding of the factors that can mediate chromatin assembly, we have purified and cloned a core histone-binding protein from Drosophila melanogaster embryos. This protein resembles Xenopus laevis nucleoplasmin, and it has therefore been termed dNLP, for Drosophila nucleoplasmin-like protein. dNLP is a nuclear protein that is present throughout development. Both purified native and recombinant dNLP bind to core histones and can function in the assembly of approximately regularly spaced nucleosomal arrays in a reaction that additionally requires DNA, purified core histones, ATP, and a partially purified fraction (containing at least one other assembly activity). We also analyzed the properties of an N-terminally truncated version of dNLP, termed dNLP-S, and found that the deletion of the N-terminal 31 residues of dNLP results in a loss of the specificity of the interaction of dNLP with core histones. We then compared the abilities of dNLP and Drosophila nucleosome assembly protein-1 (dNAP-1) to promote the decondensation of Xenopus sperm chromatin, a process that can be mediated by nucleoplasmin. We observed that dNAP-1, but not dNLP, was able to promote the decondensation of sperm chromatin. These and other data collectively suggest that dNLP may participate in parallel with other histone-binding proteins such as dNAP-1 in the assembly of chromatin.

Chromatin assembly coupled to DNA repair: a new role for chromatin assembly factor I

DNA repair in the eukaryotic cell disrupts local chromatin organization. To investigate whether the resetting of nucleosomal arrays can be linked to the repair process, we developed model systems, with both Xenopus egg extract and human cell extracts, to follow repair and chromatin assembly in parallel on circular DNA templates. Both systems were able to carry out nucleotide excision repair of DNA lesions. We observed that UV-dependent DNA synthesis occurs simultaneously with chromatin assembly, strongly indicating a mechanistic coupling between the two processes. A complementation assay established that chromatin assembly factor I (CAF1) is necessary for this repair associated chromatin formation.

Dissociation of protamine-DNA complexes by Xenopus nucleoplasmin and minichromosome assembly in vitro

Nucleoplasmin, an acidic thermostable protein abundant in the nucleus of Xenopus laevis oocytes, has been found to dissociate complexes of pUC19 DNA and protein phi 1, an intermediate protamine present in ripe sperm from the mollusc Mytilus edulis. Cruder preparations of nucleoplasmin, such as the amphibian oocyte S150 extract and its thermostable fraction, also dissociate the heterologous DNA-phi 1 complexes and, in addition, promote the assembly of plasmid DNA into a minichromosome displaying regular nucleosomal periodicity, as revealed by micrococcal nuclease digestion. In contrast, purified nucleoplasmin complemented with rat hepatocyte core histone octamers in the presence of DNA topoisomerase I, although capable of inducing nucleoprotein formation onto the complexed DNA, fails to position nucleosomes at the native spacings seen in chromatin in vivo. These data favour the existence of a general mechanism to bring about, in a concerted manner, removal of sperm-specific nuclear proteins and reconstitution of somatic chromatin following fertilization.

The p150 and p60 subunits of chromatin assembly factor I: a molecular link between newly synthesized histones and DNA replication

Chromatin assembly factor I (CAF-I) from human cell nuclei is a three-subunit protein complex that assembles histone octamers onto replicating DNA in a cell-free system. Sequences of cDNAs encoding the two largest CAF-I subunits reveal that the p150 protein contains large clusters of charged residues, whereas p60 contains WD repeats. p150 and p60 directly interact and are both required for DNA replication-dependent assembly of nucleosomes. Deletion of the p60-binding domain from the p150 protein prevents chromatin assembly. p150 and p60 form complexes with newly synthesized histones H3 and acetylated H4 in human cell extracts, suggesting that such complexes are intermediates between histone synthesis and assembly onto replicating DNA.

Stimulation of GAL4 derivative binding to nucleosomal DNA by the yeast SWI/SNF complex

The SWI/SNF protein complex is required for the enhancement of transcription by many transcriptional activators in yeast. Here it is shown that the purified SWI/SNF complex is composed of 10 subunits and includes the SWI1, SWI2/SNF2, SWI3, SNF5, and SNF6 gene products. The complex exhibited DNA-stimulated adenosine triphosphatase (ATPase) activity, but lacked helicase activity. The SWI/SNF complex caused a 10- to 30-fold stimulation in the binding of GAL4 derivatives to nucleosomal DNA in a reaction that required adenosine triphosphate (ATP) hydrolysis but was activation domain-independent. Stimulation of GAL4 binding by the complex was abolished by a mutant SWI2 subunit, and was increased by the presence of a histone-binding protein, nucleoplasmin. A direct ATP-dependent interaction between the SWI/SNF complex and nucleosomal DNA was detected. These observations suggest that a primary role of the SWI/SNF complex is to promote activator binding to nucleosomal DNA.

Analysis of nucleosome assembly and histone exchange using antibodies specific for acetylated H4

Using antibodies that specifically recognize the acetylated forms of histone H4, we show that it is possible to immunoprecipitate newly assembled (acetylated) nucleosomes. Newly replicated HeLa cell chromatin was labeled for 5-30 min with [3H]thymidine in the presence of sodium butyrate (thus inhibiting the deacetylation of newly deposited H4); bulk chromatin DNA was labeled for 24 h with [14C]thymidine. When soluble nucleosomes were incubated with immobilized antibodies, a comparison of the bound and unbound fractions showed up to a 65-fold enrichment for new chromatin DNA in the immunoprecipitate (bound), relative to the supernatant (unbound). No enrichment for new DNA was observed when preimmune control serum was used in a similar fashion. The enrichment for new DNA in the immunopellet was paralleled by a similar enrichment for all four newly synthesized histones. Acetylation was required for antibody recognition: When chromatin was replicated in the absence of butyrate (permitting histone deacetylation and chromatin maturation), equally low levels of new and old chromatin were immunoprecipitated, and no enrichment for new DNA was observed. Competition experiments confirmed these results. Analyses of histone deposition during the inhibition of DNA replication established that acetylated chromatin is the preferential target for H2A/H2B exchange. These experiments provide evidence for the highly selective assembly of newly synthesized H3, H2A, and H2B with acetylated H4, and for the involvement of histone acetylation in dynamic chromatin remodeling. In addition, immunoprecipitations of radiolabeled cytosolic extracts identified a possible somatic chromatin preassembly complex, containing newly synthesized H3 and new (acetylated) H4.

Nuclear export of proteins: the role of nuclear retention

Proteins that shuttle between nucleus and cytoplasm are implicated in transport and signal transduction processes. Using assays based on interspecies heterokaryons and microinjection of Xenopus oocytes, we examined what structural features determine nuclear export of shuttling proteins. Three classes of proteins were studied: first, wild-type and mutant forms of nucleolin, one of the first shuttling proteins identified; second, artificial nuclear reporter proteins derived from cytoplasmic pyruvate kinase; and third, wild-type and mutant lamins differing in their abilities to be incorporated into the lamina. Our results show that a protein does not require positively acting export signals to be transported from nucleus to cytoplasm; instead, its shuttling ability is limited primarily by intranuclear interactions. We conclude that nucleocytoplasmic shuttling is a general phenomenon not restricted to proteins involved in nucleocytoplasmic transport.

Protein localization to the nucleolus: a search for targeting domains in nucleolin

Nucleolin, a major nucleolar phosphoprotein, is presumed to function in rDNA transcription, rRNA packaging and ribosome assembly. Its primary sequence was highly conserved during evolution and suggests a multi-domain structure. To identify structural elements required for nuclear uptake and nucleolar accumulation of nucleolin, we used site-directed mutagenesis to introduce point- and deletion-mutations into a chicken nucleolin cDNA. Following transient expression in mammalian cells, the intracellular distribution of the corresponding wild-type and mutant proteins was determined by indirect immunofluorescence microscopy. We found that nucleolin contains a functional nuclear localization signal (KRKKEMANKSAPEAKKKK) that conforms exactly to the consensus proposed recently for a bipartite signal (Robbins, J., Dilworth, S.M., Laskey, R.A. and Dingwall, C. (1991) Cell 64, 615-623). Concerning nucleolar localization, we found that the N-terminal 250 amino acids of nucleolin are dispensible, but deletion of either the centrally located RNA-binding motifs (the RNP domain) or the glycine/arginine-rich C terminus (the GR domain) resulted in an exclusively nucleoplasmic distribution. Although both of these latter domains were required for correct subcellular localization of nucleolin, they were not sufficient to target non-nucleolar proteins to the nucleolus. From these results we conclude that nucleolin does not contain a single, linear nucleolar targeting signal. Instead, we propose that the protein uses a bipartite NLS to enter the nucleus and then accumulates within the nucleolus by virtue of binding to other nucleolar components (probably rRNA) via its RNP and GR domains.

Ultrastructural localization of a nuclear autoantigenic sperm protein in spermatogenic cells and spermatozoa

This study demonstrates the ultrastructural localization of rabbit nuclear autoantigenic sperm protein (NASP) in spermatogenic cells and spermatozoa. NASP is present in rabbits, rats, mice, and human testes and spermatozoa. It has recently been sequenced in rabbits and humans and characterized as an acidic, histone binding protein. Currently it has been proposed that NASP may play a role in regulating early events of spermatogenesis through its ability to bind and translocate testicular histone variants to nucleosomes. The ultrastructural localization of NASP confirms that it is initially present in primary spermatocytes in their Golgi regions and nucleus. In round spermatids it is present in the nucleus as well as in the acrosome and subacrosomal space. In later spermatids, testicular spermatozoa, and ejaculated spermatozoa, NASP is concentrated over the nucleus, although some is still present in the acrosome. It is likely that NASP would be carried into the ovum with the sperm nucleus at fertilization.

Unfolded structure and reactivity of nucleosome core DNA-histone H2A,H2B complexes in solution as studied by synchrotron radiation X-ray scattering

It has been previously found using different physicochemical techniques [Aragay, A., Diaz, P., & Daban, J.-R. (1988) J. Mol. Biol. 204, 141-154] that histones H2A,H2B in the absence of H3,H4 can associate with nucleosome core DNA (146 base pairs). Here we describe a synchrotron X-ray scattering study of core DNA-(H2A,H2B) complexes in solution. Our results obtained using different histone to DNA weight ratios and ionic conditions ranging from very low ionic strength to 0.2 M NaCl show that histones H2A,H2B are unable to fold core DNA. Model calculations indicate that histones H2A,H2B produce very elongated structures even when the reconstituted complexes are prepared at physiological ionic strength. In contrast, our scattering data indicate that the reconstituted complexes prepared at physiological salt concentration either with the four core histones or with histones H3,H4 without H2A,H2B are completely folded particles with a radius of gyration similar to that corresponding to the native nucleosome core (4.2 nm). Furthermore, our results show that the DNA of the extended complexes containing histones H2A,H2B becomes completely folded after the histone pair exchange reaction that occurs spontaneously between preformed DNA-(H2A,H2B) and DNA-(H3,H4) complexes. These observations, together with our previous studies, suggest that the open conformation of DNA-(H2A,H2B) complexes facilitates the involvement of this structure as a transient intermediate in the reaction of nucleosome formation at physiological ionic strength.

Sequence and localization of human NASP: conservation of a Xenopus histone-binding protein

In this study the sequence and localization of human testicular NASP (nuclear autoantigenic sperm protein) are reported. NASP cDNA contains 2561 nt encoding a protein of 787 amino acids. The open reading frame contains 2446 nt followed by an ochre stop codon (TAA) and 104 nucleotides of untranslated sequence containing a poly(A) addition signal 10 bases upstream of the poly(A) tail. Northern blot analysis of human testis poly(A) mRNA indicates a message of approximately 3.2 kb. Multiple sequence alignment (MSA) analysis of the encoded human NASP amino acid sequence with the sequence for the Xenopus histone-binding protein N1/N2 and the rabbit NASP amino acid sequence demonstrates that the human sequence and the Xenopus sequence have extensive amino acid homology upstream of the rabbit initiation codon. Significantly, there is an 85% identity between the human and the rabbit NASP sequences when the alignment starts at the N-terminal of the rabbit sequence and at amino acid 101 of the human sequence. The nuclear translocation signal found in N1/N2 and rabbit NASP is completely conserved in human NASP. The first histone-binding domain of Xenopus is 70% identical and 90% similar to the human NASP domain. The second histone-binding domain of Xenopus is 48% identical and 71% similar to the human NASP domain. MSA analysis of the three sequences generated an unrooted ancestral tree with two branches, indicating that fewer amino acid changes have occurred between the Xenopus and the human sequences than between the Xenopus and the rabbit sequences. In the human testis, NASP is localized predominantly in primary spermatocytes and round spermatids. Spermatogonia, Sertoli cells, Leydig cells, peritubular cells, and other somatic cells do not stain. Human spermatozoa contain NASP in the acrosomal region. Following the acrosome reaction, some NASP remains in the equatorial and postacrosomal regions. We propose that mammalian testes and sperm contain a histone-binding protein which may play a role in regulating the early events of spermatogenesis.

Reactivation of DNA replication in erythrocyte nuclei by Xenopus egg extract involves energy-dependent chromatin decondensation and changes in histone phosphorylation

Reactivation of chicken erythrocyte nuclei for DNA replication in Xenopus egg extracts involves two phases of chromatin remodelling: a fast decondensation leading to a small volume increase and chromatin dispersion occurring within a few minutes (termed stage I decondensation), followed by a slower membrane-dependent decondensation and enlargement of up to 40-fold from the initial volume (stage II decondensation). Chromatin decondensation as measured by nuclear swelling and micrococcal nuclease digestion required ATP. We observed a characteristic change in the phosphorylation pattern of erythrocyte proteins upon incubation in egg extract. While histones H5, H2A, and H4 became selectively phosphorylated during decondensation, the phosphorylation of histone H3 and of several nonhistone proteins was prevented. Furthermore, histone H5 was selectively released from erythrocyte nuclei in an energy-dependent reaction. These molecular changes already occurred during stage I decondensation and they persisted during stage II decondensation. DNA replication was confined to nuclei of stage II decondensation which incorporated lamin LIII from the egg extract. These results show that initiation of DNA replication in chicken erythrocytes requires in addition to ATP-dependent chromatin remodelling (stage I), further changes in chromatin structure that correlates with lamin LIII incorporation, and stage II decondensation.

Nucleoplasmin remodels sperm chromatin in Xenopus egg extracts

Nucleoplasmin is necessary and sufficient for the initial stage of Xenopus sperm decondensation in egg extracts. In this article we show that sperm decondensation is accompanied by loss of two sperm-specific basic proteins (X and Y) and gain of histones H2A and H2B, resulting in nucleosome formation. Purified nucleoplasmin alone removes X and Y and assembles purified H2A and H2B on decondensing sperm chromatin, forming nucleosome cores. Immunodepletion of nucleoplasmin from extract prevents removal of X and Y and addition of H2A and H2B, while adding back nucleoplasmin restores decondensation and X and Y removal. Thus, nucleoplasmin acts as both an assembly and a disassembly factor for remodeling sperm chromatin at fertilization.

Chromatin replication

Just as the faithful replication of DNA is an essential process for the cell, chromatin structures of active and inactive genes have to be copied accurately. Under certain circumstances, however, the activity pattern has to be changed in specific ways. Although analysis of specific aspects of these complex processes, by means of model systems, has led to their further elucidation, the mechanisms of chromatin replication in vivo are still controversial and far from being understood completely. Progress has been achieved in understanding: 1. The initiation of chromatin replication, indicating that a nucleosome-free origin is necessary for the initiation of replication; 2. The segregation of the parental nucleosomes, where convincing data support the model of random distribution of the parental nucleosomes to the daughter strands; and 3. The assembly of histones on the newly synthesized strands, where growing evidence is emerging for a two-step mechanism of nucleosome assembly, starting with the deposition of H3/H4 tetramers onto the DNA, followed by H2A/H2B dimers.

Interaction of Xenopus lamins A and LII with chromatin in vitro mediated by a sequence element in the carboxyterminal domain

Morphological data suggest an interaction of the nuclear lamina with chromatin which markedly changes during the cell cycle. To study the molecular basis of this interaction we developed a novel lamin/chromatin binding assay that quantitated the binding of soluble, radiolabeled lamins to minichromosomes assembled in Xenopus laevis oocyte nuclear extracts. Lamins were derived from couple in vitro transcription and translation of the corresponding cDNAs. Chromatin binding was detected by monitoring the cofractionation with assembled minichromosomes in gel filtration and sucrose gradient centrifugation. Binding of lamins to chromatin increased with chromatin concentration and was accompanied by lamin polymerization. Lamins of the A-(Xenopus LA and human LC) as well as the B-type (Xenopus LI and LII) showed strikingly different chromatin binding capacities. Lamins A and LII bound efficiently of lamins LI and LC was detected. Using site-directed mutagenesis, we were able to define carboxy-terminal sequence elements of LA and LII required for the observed lamin/chromatin interaction that are rich in serine, threonine, and glycine residues. Competition experiments with a synthetic peptide containing the chromatin binding motif of lamin A corroborate the importance of these sequence elements in the lamin/chromatin interaction.

Sperm decondensation in Xenopus egg cytoplasm is mediated by nucleoplasmin

At fertilization, sperm chromatin decondenses in two stages, which can be mimicked in extracts of Xenopus eggs. Rapid, limited decondensation is followed by slower, membrane-dependent decondensation and swelling. Nucleoplasmin, an acidic nuclear protein, occurs at high concentration in Xenopus eggs and has a histone-binding role in nucleosome assembly. Immunodepleting nucleoplasmin from egg extracts inhibits the initial rapid stage of sperm decondensation, and also the decondensation of myeloma nuclei, relative to controls of mock depletion and TFIIIA depletion. Readdition of purified nucleoplasmin recues depleted extracts. A physiological concentration of purified nucleoplasmin alone decondenses both sperm and myeloma nuclei. We conclude that nucleoplasmin is both necessary and sufficient for the first stage of sperm decondensation in Xenopus eggs.

How proteins enter the nucleus

Nuclear protein import is a selective process. Proteins destined for the nucleus contain NLSs. These short stretches of amino acids interact with proteins located in the cytoplasm, on the nuclear envelope, and/or at the nuclear pore complex. Following binding at the pore complex, proteins are translocated through the pore into the nucleus in a manner requiring ATP. The biochemical dissection of the nuclear pore complex has begun. Alteration of protein import into the nucleus is emerging as a new and complex form of regulation. However, we are left with the following problems: How do proteins move through the cytoplasm to reach the nuclear pore? How does the nuclear pore complex open and close in a selective manner? How is ATP utilized during import? And finally, how is bi-directional traffic of both proteins and RNA through the pore regulated?

Two interdependent basic domains in nucleoplasmin nuclear targeting sequence: identification of a class of bipartite nuclear targeting sequence

Point mutagenesis of the nuclear targeting sequence of nucleoplasmin has identified two interdependent basic domains. These are separated by 10 intervening "spacer" amino acids that tolerate point mutations and some insertions. Amino acids in both basic domains are required for nuclear targeting, and the transport defect of a mutation in one domain is amplified by a simultaneous mutation in the other. Therefore, these basic domains are interdependent. A strikingly similar motif of two clusters of basic residues is seen in the nuclear targeting sequence of Xenopus N1. It is also conserved in the related nucleolar protein NO38. Several other short sequences known to be necessary for nuclear targeting fall within a similar motif.

Functions of maternal mRNA in early development

In this review, the types of mRNAs found in oocytes and eggs of several animal species, particularly Drosophila, marine invertebrates, frogs, and mice, are described. The roles that proteins derived from these mRNAs play in early development are discussed, and connections between maternally inherited information and embryonic pattern are sought. Comparisons between genetically identified maternally expressed genes in Drosophila and maternal mRNAs biochemically characterized in other species are made when possible. Regulation of the meiotic and early embryonic cell cycles is reviewed, and translational control of maternal mRNA following maturation and/or fertilization is discussed with regard to specific mRNAs.

S phase of the cell cycle

In each cell cycle the complex structure of the chromosome must be replicated accurately. In the last few years there have been major advances in understanding eukaryotic chromosome replication. Patterns of replication origins have been mapped accurately in yeast chromosomes. Cellular replication proteins have been identified by fractionating cell extracts that replicate viral DNA templates in vitro. Cell-free systems that initiate eukaryotic DNA replication in vitro have demonstrated the importance of complex nuclear architecture in the control of DNA replication. Although the events of S phase were relatively neglected for many years, knowledge of DNA replication is now advancing rapidly in step with other phases of the cell cycle.

Phosphorylation of sea urchin histone CS H2A

Phosphorylation of cleavage stage (CS) histones was studied during the first cell cycle in male pronuclei of the sea urchin. Histone CS H2A rapidly incorporated 32PO4 during the replication period, but not before. Peptide mapping and amino acid analysis of radiolabelled CS H2A showed that phosphorylation occurred mainly on serine residues located in the C-terminal region of the molecule. When DNA replication was inhibited with aphidicolin both CS H2A and CS H2B accumulated in male pronuclei at the same rate as in the control culture, whereas accumulation of H3 and H4 histones was reduced. Incorporation of 32PO4 by CS H2A doubled when DNA synthesis was inhibited with aphidicolin. Thus phosphorylation of CS H2A was correlated with transport of CS histones from the egg storage pool to the male pronucleus, but not with chromatin synthesis, indicating that this event precedes nucleosome formation. A role for phosphorylation and dephosphorylation of the CS H2A C-terminal region in modulating transport of stored CS histone dimers and their assembly into nucleosomes is discussed.