Characterization of mouse H3.3-like histone genes

Differential effect of histone H3.3 depletion on retroviral repression in embryonic stem cells

BACKGROUND

Integration of retroviruses into the host genome can impair the genomic and epigenomic integrity of the cell. As a defense mechanism, epigenetic modifications on the proviral DNA repress retroviral sequences in mouse embryonic stem cells (ESC). Here, we focus on the histone 3 variant H3.3, which is abundant in active transcription zones, as well as centromeres and heterochromatinized repeat elements, e.g., endogenous retroviruses (ERV).

RESULTS

To understand the involvement of H3.3 in the epigenetic silencing of retroviral sequences in ESC, we depleted the H3.3 genes in ESC and transduced the cells with GFP-labeled MLV pseudovirus. This led to altered retroviral repression and reduced Trim28 recruitment, which consequently led to a loss of heterochromatinization in proviral sequences. Interestingly, we show that H3.3 depletion has a differential effect depending on which of the two genes coding for H3.3, H3f3a or H3f3b, are knocked out. Depletion of H3f3a resulted in a transient upregulation of incoming retroviral expression and ERVs, while the depletion of H3f3b did not have the same effect and repression was maintained. However, the depletion of both genes resulted in a stable activation of the retroviral promoter. These findings suggest that H3.3 is important for regulating retroviral gene expression in mouse ESC and provide evidence for a distinct function of the two H3.3 genes in this regulation. Furthermore, we show that Trim28 is needed for depositing H3.3 in retroviral sequences, suggesting a functional interaction between Trim28 recruitment and H3.3 loading.

CONCLUSIONS

Identifying the molecular mechanisms by which H3.3 and Trim28 interact and regulate retroviral gene expression could provide a deeper understanding of the fundamental processes involved in retroviral silencing and the general regulation of gene expression, thus providing new answers to a central question of stem cell biology.

Histone variants H2A.Z and H3.3 coordinately regulate PRC2-dependent H3K27me3 deposition and gene expression regulation in mES cells

Background

The hierarchical organization of eukaryotic chromatin plays a central role in gene regulation, by controlling the extent to which the transcription machinery can access DNA. The histone variants H3.3 and H2A.Z have recently been identified as key regulatory players in this process, but the underlying molecular mechanisms by which they permit or restrict gene expression remain unclear. Here, we investigated the regulatory function of H3.3 and H2A.Z on chromatin dynamics and Polycomb-mediated gene silencing.

Results

Our ChIP-seq analysis reveals that in mouse embryonic stem (mES) cells, H3K27me3 enrichment correlates strongly with H2A.Z. We further demonstrate that H2A.Z promotes PRC2 activity on H3K27 methylation through facilitating chromatin compaction both in vitro and in mES cells. In contrast, PRC2 activity is counteracted by H3.3 through impairing chromatin compaction. However, a subset of H3.3 may positively regulate PRC2-dependent H3K27 methylation via coordinating depositions of H2A.Z to developmental and signaling genes in mES cells. Using all-trans retinoic acid (tRA)-induced gene as a model, we show that the dynamic deposition of H2A.Z and H3.3 coordinately regulates the PRC2-dependent H3K27 methylation by modulating local chromatin structure at the promoter region during the process of turning genes off.

Conclusions

Our study provides key insights into the mechanism of how histone variants H3.3 and H2A.Z function coordinately to finely tune the PRC2 enzymatic activity during gene silencing, through promoting or impairing chromosome compaction respectively.

Electronic supplementary material

The online version of this article (10.1186/s12915-018-0568-6) contains supplementary material, which is available to authorized users.

Histone variant H3.3-mediated chromatin remodeling is essential for paternal genome activation in mouse preimplantation embryos

Derepression of chromatin-mediated transcriptional repression of paternal and maternal genomes is considered the first major step that initiates zygotic gene expression after fertilization. The histone variant H3.3 is present in both male and female gametes and is thought to be important for remodeling the paternal and maternal genomes for activation during both fertilization and embryogenesis. However, the underlying mechanisms remain poorly understood. Using our H3.3B-HA-tagged mouse model, engineered to report H3.3 expression in live animals and to distinguish different sources of H3.3 protein in embryos, we show here that sperm-derived H3.3 (sH3.3) protein is removed from the sperm genome shortly after fertilization and extruded from the zygotes via the second polar bodies (PBII) during embryogenesis. We also found that the maternal H3.3 (mH3.3) protein is incorporated into the paternal genome as early as 2 h postfertilization and is detectable in the paternal genome until the morula stage. Knockdown of maternal H3.3 resulted in compromised embryonic development both of fertilized embryos and of androgenetic haploid embryos. Furthermore, we report that mH3.3 depletion in oocytes impairs both activation of the Oct4 pluripotency marker gene and global de novo transcription from the paternal genome important for early embryonic development. Our results suggest that H3.3-mediated paternal chromatin remodeling is essential for the development of preimplantation embryos and the activation of the paternal genome during embryogenesis.

Regulation of Reprogramming and Cellular Plasticity through Histone Exchange and Histone Variant Incorporation

Early embryonic cells are totipotent and can generate a complete organism including embryonic and extraembryonic tissues. After division, cells lose their potency as they move toward a pluripotent state characterized by decreased cellular plasticity. During this transition, drastic changes in transcriptional programs occur in parallel with global chromatin reorganization. The epigenetic mechanisms governing the changes in chromatin signatures during the transitions of cellular plasticity states are starting to be understood. Among these mechanisms, recent studies highlight the importance of histone variant incorporation and/or eviction from chromatin in the regulation of the chromatin state that is linked to cellular potential. In this review, we discuss the role of histone variants during in vivo and in vitro reprogramming events. These results sustain the hypothesis that histone variants and histone exchange are key actors in the establishment of cellular plasticity programs.

H3.3 replacement facilitates epigenetic reprogramming of donor nuclei in somatic cell nuclear transfer embryos

Transfer of a somatic nucleus into an enucleated oocyte is the most efficient approach for somatic cell reprogramming. While this process is known to involve extensive chromatin remodeling of the donor nucleus, the maternal factors responsible and the underlying chromatin-based mechanisms remain largely unknown. Here we discuss our recent findings demonstrating that the histone variant H3.3 plays an essential role in reprogramming and is required for reactivation of key pluripotency genes in somatic cell nuclear transfer (SCNT) embryos. Maternal-derived H3.3 replaces H3 in the donor nucleus shortly after oocyte activation, with the amount of replacement directly related to the differentiation status of the donor nucleus in SCNT embryos. We provide additional evidence to suggest that de novo synthesized H3.3 replaces histone H3 carrying repressive modifications in the donor nuclei of SCNT embryos, and hypothesize that replacement may occur at specific loci that must be reprogrammed for gene reactivation.

Genome editing a mouse locus encoding a variant histone, H3.3B, to report on its expression in live animals

Chromatin remodeling via incorporation of histone variants plays a key role in the regulation of embryonic development. The histone variant H3.3 has been associated with a number of early events including formation of the paternal pronucleus upon fertilization. The small number of amino acid differences between H3.3 and its canonical counterparts (H3.1 and H3.2) has limited studies of the developmental significance of H3.3 deposition into chromatin due to difficulties in distinguishing the H3 isoforms. To this end, we used zinc-finger nuclease (ZFN) mediated gene editing to introduce a small C-terminal hemagglutinin (HA) tag to the endogenous H3.3B locus in mouse embryonic stem cells (ESCs), along with an internal ribosome entry site (IRES) and a separately translated fluorescent reporter of expression. This system will allow detection of expression driven by the reporter in cells, animals, and embryos, and will facilitate investigation of differential roles of paternal and maternal H3.3 protein during embryogenesis that would not be possible using variant-specific antibodies. Further, the ability to monitor endogenous H3.3 protein in various cell lineages will enhance our understanding of the dynamics of this histone variant over the course of development.

Histone variant H3.3 is an essential maternal factor for oocyte reprogramming

Mature oocyte cytoplasm can reprogram somatic cell nuclei to the pluripotent state through a series of sequential events including protein exchange between the donor nucleus and ooplasm, chromatin remodeling, and pluripotency gene reactivation. Maternal factors that are responsible for this reprogramming process remain largely unidentified. Here, we demonstrate that knockdown of histone variant H3.3 in mouse oocytes results in compromised reprogramming and down-regulation of key pluripotency genes; and this compromised reprogramming for developmental potentials and transcription of pluripotency genes can be rescued by injecting exogenous H3.3 mRNA, but not H3.2 mRNA, into oocytes in somatic cell nuclear transfer embryos. We show that maternal H3.3, and not H3.3 in the donor nucleus, is essential for successful reprogramming of somatic cell nucleus into the pluripotent state. Furthermore, H3.3 is involved in this reprogramming process by remodeling the donor nuclear chromatin through replacement of donor nucleus-derived H3 with de novo synthesized maternal H3.3 protein. Our study shows that H3.3 is a crucial maternal factor for oocyte reprogramming and provides a practical model to directly dissect the oocyte for its reprogramming capacity.

Hira-dependent histone H3.3 deposition facilitates PRC2 recruitment at developmental loci in ES cells

Polycomb repressive complex 2 (PRC2) regulates gene expression during lineage specification through trimethylation of lysine 27 on histone H3 (H3K27me3). In Drosophila, polycomb binding sites are dynamic chromatin regions enriched with the histone variant H3.3. Here, we show that, in mouse embryonic stem cells (ESCs), H3.3 is required for proper establishment of H3K27me3 at the promoters of developmentally regulated genes. Upon H3.3 depletion, these promoters show reduced nucleosome turnover measured by deposition of de novo synthesized histones and reduced PRC2 occupancy. Further, we show H3.3-dependent interaction of PRC2 with the histone chaperone, Hira, and that Hira localization to chromatin requires H3.3. Our data demonstrate the importance of H3.3 in maintaining a chromatin landscape in ESCs that is important for proper gene regulation during differentiation. Moreover, our findings support the emerging notion that H3.3 has multiple functions in distinct genomic locations that are not always correlated with an "active" chromatin state.

Histone regulation in the CNS: basic principles of epigenetic plasticity

Postmitotic neurons are subject to a vast array of environmental influences that require the nuclear integration of intracellular signaling events to promote a wide variety of neuroplastic states associated with synaptic function, circuit formation, and behavioral memory. Over the last decade, much attention has been paid to the roles of transcription and chromatin regulation in guiding fundamental aspects of neuronal function. A great deal of this work has centered on neurodevelopmental and adulthood plasticity, with increased focus in the areas of neuropharmacology and molecular psychiatry. Here, we attempt to provide a broad overview of chromatin regulation, as it relates to central nervous system (CNS) function, with specific emphasis on the modes of histone posttranslational modifications, chromatin remodeling, and histone variant exchange. Understanding the functions of chromatin in the context of the CNS will aid in the future development of pharmacological therapeutics aimed at alleviating devastating neurological disorders.

Histone variants in metazoan development

Embryonic development is regulated by both genetic and epigenetic mechanisms, with nearly all DNA-templated processes influenced by chromatin architecture. Sequence variations in histone proteins, core components of chromatin, provide a means to generate diversity in the chromatin structure, resulting in distinct and profound biological outcomes in the developing embryo. Emerging literature suggests that epigenetic contributions from histone variants play key roles in a number of developmental processes such as the initiation and maintenance of pericentric heterochromatin, X-inactivation, and germ cell differentiation. Here, we review the role of histone variants in the embryo with particular emphasis on early mammalian development.

Histone3 variants in plants

Regulation of chromatin activity by covalent histone modifications has been long recognized. Histones that constitute the nucleosome are encoded by large families of genes and display a strong degree of conservation. However, histone variants exist and it is becoming clear that they play important roles in genome regulation. While most studies of the role of histone3 (H3) variants in transcriptional control comes from animal models, emerging data in plants suggest functional conservation, although plant-specific roles are likely. We review these data and speculate on the biological significance of H3 variants in plants.

Epigenetic regulation of the estrogen receptor alpha promoter in the cerebral cortex following ischemia in male and female rats

Permanent middle cerebral artery occlusion (MCAO) causes neuronal cell death in the striatum and cortex. In rodents, estradiol treatment protects the cortex from cell death in an estrogen receptor alpha (ERalpha) dependent manner. ERalpha is only transiently expressed in the cortex during neonatal development and is very low in uninjured adult cortex. Following MCAO, ERalpha mRNA expression is upregulated in the cortex of female rats, but the mechanism of this increase is still unknown. It is also unknown whether a similar increase in ERalpha expression in seen in males. In the following studies, male and vehicle or estradiol-treated ovariectomized (OVX) female rats underwent MCAO to investigate the regulation of ERalpha expression after ischemia. Twenty-four hours after surgery, mRNA or genomic DNA was collected from 1 mm micropunches taken from 300 mum brain sections for quantitative reverse transcription-polymerase chain reaction (RT-PCR) or methylation-specific (MSP) PCR, respectively. Additionally, adjacent 20 mum sections were processed for ERalpha immunohistochemistry. In OVX females, ERalpha mRNA and protein were increased in the ischemic cortex, but unchanged in males. We hypothesized that this increase in ERalpha in females is due to a reversal of gene silencing by DNA methylation. Using MSP targeting of CpG islands within the 5' untranslated region (UTR) of the rat ERalpha gene, we found that ischemia decreased methylation in the ischemic cortex of both groups of females, but there was no change in methylation in males. Using chromatin immunoprecipitation, we found that MeCP2 associates with ERalpha 5'UTR corresponding with the methylation status of the promoter. These data are the first to demonstrate a difference in the regulation of ERalpha expression in response to MCAO between males and females and that methylation of the ERalpha gene corresponds with mRNA levels in the brain.

Chromatin Structure Regulation in Transforming Growth Factor-β-Directed Epithelial-Mesenchymal Transition

Epithelial-mesenchymal transitions (EMTs) occur in organogenesis throughout embryonic development and are recapitulated during epithelial tissue injury and in carcinoma progression. EMTs are regulated by complex, precisely orchestrated cell signaling and gene expression networks, with the participation of key developmental pathways. Here we review context-dependent modules of gene regulation by hairy/enhancer-of-split-related (H/E(spl)) repressors downstream of transforming growth factor-beta (TGF-beta)/Smad and Notch signals in EMT and in other phenotype transitions such as differentiation and cancer. Based on multiple models of disease-related EMT, we propose that Polycomb group epigenetic silencers and histone-lysine methyl-transferases EZH1 and EZH2 are candidate targets of H/E(spl)-mediated transcriptional repression, in a process accompanied by replacement of modified core histone H3 with de novo synthesized histone variant H3.3B. Finally, we discuss the potential significance of this scenario for EMT in the light of recent findings on gene regulation by histone modifications and chromatin structure changes.

Translation termination is involved in histone mRNA degradation when DNA replication is inhibited

The levels of replication-dependent histone mRNAs are coordinately regulated with DNA synthesis. A major regulatory step in histone mRNA metabolism is regulation of the half-life of histone mRNAs. Replication-dependent histone mRNAs are the only metazoan mRNAs that are not polyadenylated. Instead, they end with a conserved stem-loop structure, which is recognized by the stem-loop binding protein (SLBP). SLBP is required for histone mRNA processing, as well as translation. We show here, using histone mRNAs whose translation can be regulated by the iron response element, that histone mRNAs need to be actively translated for their rapid degradation following the inhibition of DNA synthesis. We also demonstrate the requirement for translation using a mutant SLBP which is inactive in translation. Histone mRNAs are not rapidly degraded when DNA synthesis is inhibited or at the end of S phase in cells expressing this mutant SLBP. Replication-dependent histone mRNAs have very short 3' untranslated regions, with the stem-loop located 30 to 70 nucleotides downstream of the translation termination codon. We show here that the stability of histone mRNAs can be modified by altering the position of the stem-loop, thereby changing the distance from the translation termination codon.

Regulated degradation of replication-dependent histone mRNAs requires both ATR and Upf1

Eukaryotic cells coordinately regulate histone and DNA synthesis. In mammalian cells, most of the regulation of histone synthesis occurs post-transcriptionally by regulating the concentrations of histone mRNA. As cells enter S phase, histone mRNA levels increase, and at the end of S phase they are rapidly degraded. Moreover, inhibition of DNA synthesis causes rapid degradation of histone mRNAs. Replication-dependent histone mRNAs are the only metazoan mRNAs that are not polyadenylated. Instead, they end with a conserved stem-loop structure, which is the only cis-acting element required for coupling regulation of histone mRNA half-life with DNA synthesis. Here we show that regulated degradation of histone mRNAs requires Upf1, a key regulator of the nonsense-mediated decay pathway, and ATR, a key regulator of the DNA damage checkpoint pathway activated during replication stress.

The oligo(A) tail on histone mRNA plays an active role in translational silencing of histone mRNA during Xenopus oogenesis

Metazoan replication-dependent histone mRNAs end in a stem-loop sequence. The one known exception is the histone mRNA in amphibian oocytes, which has a short oligo(A) tail attached to the stem-loop sequence. Amphibian oocytes also contain two proteins that bind the 3' end of histone mRNA: xSLBP1, the homologue of the mammalian SLBP, and xSLBP2, which is present only in oocytes. xSLBP2 is an inhibitor of histone mRNA translation, while xSLBP1 activates translation. The short A tail on histone mRNAs appears at stage II to III of oogenesis and is present on histone mRNAs throughout the rest of oogenesis. At oocyte maturation, the oligo(A) tail is removed and the xSLBP2 is degraded, resulting in the activation of translation of histone mRNA. Both SLBPs bind to the stem-loop with the oligo(A) tail with similar affinities. Reporter mRNAs ending in the stem-loop with or without the oligo(A) tail are translated equally well in a reticulocyte lysate, and their translation is stimulated by the presence of xSLBP1. In contrast, translation of the reporter mRNA with an oligo(A) tail is not activated in frog oocytes in response to the presence of xSLBP1. These results suggest that the oligo(A) tail is an active part of the translation repression mechanism that silences histone mRNA during oogenesis and that its removal is part of the mechanism that activates translation.

Contrasting patterns and cellular specificity of transcriptional regulation of the nuclear receptor nerve growth factor-inducible B by haloperidol and clozapine in the rat forebrain

This study was designed to investigate the possible involvement of members of the nuclear receptor family of transcription factors in the effects of antipsychotic drugs used in the treatment of schizophrenia. We have identified, using RT-PCR screening, an important modulation of nerve growth factor-inducible B (NGFI-B) mRNA levels by typical and atypical neuroleptics in the rat forebrain. NGFI-B, a member of the nuclear receptor family, can be observed in target structures of dopaminergic pathways. Using in situ hybridization, we also demonstrate that typical and atypical antipsychotics induced contrasting patterns of expression of NGFI-B after both acute and chronic administration. An acute treatment with clozapine or haloperidol induces high NGFI-B mRNA levels in the prefrontal and cingulate cortices and in the nucleus accumbens shell. However, haloperidol, but not clozapine, dramatically increases NGFI-B expression in the dorsolateral striatum. In contrast, chronic treatment with clozapine reduces NGFI-B expression below basal levels in the rat forebrain, whereas haloperidol still induces high NGFI-B mRNA levels in the dorsolateral striatum. Finally, using a double in situ hybridization technique, we show that acute administration of both neuroleptics increases NGFI-B expression in neurotensin-containing neurons in the nucleus accumbens shell, whereas the effects of haloperidol in the dorsolateral striatum are mainly observed in enkephalin-containing neurons. These results are the first demonstration that members of the nuclear receptor family of transcription factors could play an important role in the effects of antipsychotic drugs.

Cytotoxic activity of a recombinant GnRH-PAP fusion toxin on human tumor cell lines

Pokeweed antiviral protein (PAP), a ribosome-inactivating protein isolated from the leaves of Phytolacca americana, reveals potent antiviral activity against viruses or cytotoxic action against cells once inside the cytoplasm. Therefore PAP is a good candidate to be used as an immunotoxin. We constructed a bacterial expression plasmid encoding PAP as a fusion protein with gonadotropin-releasing hormone (GnRH), a neuropeptide with receptor sites on several gynaecologic tumors. The resulting recombinant toxin was produced in Escherichia coli and accumulated in inclusion bodies. After purification under denaturing conditions, renaturated GnRH-PAP shows an IC(50) of 3 nM on in vitro translation assays and selectively inhibits the growth of the GnRH receptor positive Ishikawa cell line (ID(50) of 15 nM); on the other hand, neither GnRH nor PAP alone had any effect.

Effects of AF64A on gene expression of choline acetyltransferase (ChAT) in the septo-hippocampal pathway and striatum in vivo

AF64A (ethylcholine mustard aziridinium ion) was stereotaxically administered bilaterally (1 nmol/side) into rat lateral cerebral ventricles. Choline acetyltransferase (ChAT) activity and ChAT mRNA levels were measured at predetermined time points in the septo-hippocampal pathway and striatum, both well identified as rich in cholinergic neurons. AF64A caused a rapid but transient increase in ChAT mRNA (167%, P < 0.05) and ChAT activity (164%, P < 0.01) in the septum. By day 7 post treatment, there was a significant decrease in ChAT mRNA (42.5% of control, P < 0.05) in the septum although the ChAT activity still stayed high. This decreased ChAT mRNA level in the septum lasted for at least four weeks, and was paralleled by a long-lasting decrease in ChAT activity in the hippocampus. In the striatum, on the other hand, there were no observed changes in either ChAT activity or ChAT mRNA. These data suggest that the long term effect of AF64A on the septo-hippocampal cholinergic pathway may, at least in part, be due to an action of AF64A on gene expression in the cholinergic neuron. The difference in the response to AF64A between the septo-hippocampal and striatal cholinergic systems might be due to their difference in neuron types.

Role for a YY1-binding element in replication-dependent mouse histone gene expression

Expression of the highly conserved replication-dependent histone gene family increases dramatically as a cell enters the S phase of the eukaryotic cell cycle. Requirements for normal histone gene expression in vivo include an element, designated alpha, located within the protein-encoding sequence of nucleosomal histone genes. Mutation of 5 of 7 nucleotides of the mouse H3.2 alpha element to yield the sequence found in an H3.3 replication-independent variant abolishes the DNA-protein interaction in vitro and reduces expression fourfold in vivo. A yeast one-hybrid screen of a HeLa cell cDNA library identified the protein responsible for recognition of the histone H3.2 alpha sequence as the transcription factor Yin Yang 1 (YY1). YY1 is a ubiquitous and highly conserved transcription factor reported to be involved in both activation and repression of gene expression. Here we report that the in vitro histone alpha DNA-protein interaction depends on YY1 and that mutation of the nucleotides required for the in vitro histone alpha DNA-YY1 interaction alters the cell cycle phase-specific up-regulation of the mouse H3.2 gene in vivo. Because all mutations or deletions of the histone alpha sequence both abolish interactions in vitro and cause an in vivo decrease in histone gene expression, the recognition of the histone alpha element by YY1 is implicated in the correct temporal regulation of replication-dependent histone gene expression in vivo.

Castration differentially regulates nitric oxide synthase in the hypothalamus and pituitary

Mammalian reproductive function is under control of the integrated hypothalamic-pituitary-gonadal (HPG) axis. Castration in male rats has been utilized as an effective tool to investigate hormonal interactions in the mammalian HPG axis. Recently, nitric oxide (NO) has been suggested to play a role in HPG hormonal regulation. In order to gain further insight into the function of the NO-NOS system in reproductive neuroendocrine control, particularly in the gonadal feedback regulation of the hypothalamic-pituitary unit, we examined steady state levels of nNOS mRNA, nNOS protein, and the important physiological index, NOS enzyme activity, of the intrinsic NOergic system in both hypothalamus and pituitary in castrated male rats and their sham-operated counterparts one week after surgery. In the pituitary, we found a significant four-fold increase in nNOS mRNA, p < 0.0003 compared to sham. Castration also resulted in a four-fold rise in pituitary nNOS protein, p < 0.02 compared to sham. Pituitary NOS enzyme activity was stimulated 2 fold, p < 0.003 after castration. In the hypothalamus, conversely, we observed no significant castration-modulated difference in either nNOS mRNA, nNOS protein or NOS enzyme activity. Thus, it appears that the hypothalamic NO-NOS system is either not required for hypothalamic adaptations to castration, although important in the release of LHRH under normal physiological conditions, or alternatively, the hypothalamus may become more sensitive to the effects of NO in the castrated state. In the pituitary, NO may attenuate the gonadotropin response to castration as a local balancing mediator.

Differential expression of the murine histone genes H3.3A and H3.3B

The histone family of proteins is subdivided into two major groups: the main type histones, which are synthesized in coordination with DNA replication during the S-phase of the cell cycle, and the replacement histones, which can be synthesized in the absence of DNA replication substituting main type histone isoforms. Accumulation of replacement histone variants has been observed in several terminally differentiated tissues that have stopped cell division. The replacement subtype of the H3 class is termed H3.3. This protein is encoded by two different genes (H3.3A and H3.3B) that both code for the same amino acid sequence, but differ in nucleotide sequences and gene organization. This has been shown for human and avian H3.3A and H3.3B genes and for a murine H3.3B cDNA. In an attempt to define patterns of replacement histone H3.3 gene expression during male germ cell differentiation, we have constructed mouse testicular cDNA libraries and have isolated cDNAs corresponding to the murine H3.3A and H3.3B genes. Using probes specific for these two different genes we show by RNase protection analysis and by nonradioactive in situ hybridization with testis sections that H3.3A mRNA is present in pre- and postmeiotic cells, whereas expression of the H3.3B gene is essentially restricted to cells of the meiotic prophase.

A mouse histone H1 variant, H1b, binds preferentially to a regulatory sequence within a mouse H3.2 replication-dependent histone gene

H1 histones, found in all multicellular eukaryotes, associate with linker DNA between adjacent nucleosomes, presumably to keep the chromatin in a compact, helical state. The identification of multiple histone H1 subtypes in vertebrates suggests these proteins have specialized roles in chromatin organization and thus influence the regulation of gene expression in the multicellular organism. The mechanism by which the association of H1 with nucleosomal DNA is regulated is not completely understood, but affinity for different DNA sequences may play a role. Here we report that a specific H1 subtype in the mouse, namely H1b, selectively binds to a regulatory element within the protein-encoding sequence of a replication-dependent mouse H3.2 gene. We have previously shown that this coding region element, Omega, is the target of very specific interactions in vitro with another nuclear factor called the Omega factor. This element is required for normal gene expression in stably transfected rodent cells. The mouse H1b protein interacts poorly (100-fold lower affinity) with the comparable "Omega" sequence of a replication-independent mouse H3.3 gene. This H3.3 sequence differs at only 4 out of 22 nucleotide positions from the H3.2 sequence. Our findings raise the possibility that this H1b protein plays a specific role in regulation of expression of the replication-dependent histone gene family.

H3.3A variant histone mRNA containing an alpha-globin insertion: modulated expression during mouse gametogenesis correlates with meiotic onset

Replacement-variant H3.3 histones have been isolated and sequenced in different eukaryotes, but no functional H3.3A gene has been characterized in the mouse so far. We have cloned an H3.3A cDNA from a mouse fetal ovary library, differentially screened with testis versus somatic cDNA probes. We showed this gene contains a region homologous to the reverse and complementary alpha-globin gene. We believe such a structure could have been generated by retroposition during the evolution of both globin and histone gene families. The sequence coding for H3.3A is 76.6% homologous to the mouse H3.3B gene at the nucleotide level and differs in only one amino acid at the protein level. The high degree of homology between these genes and the H3.3 variant histones from other eukaryotes reveals the conservation of these replication-independent class of histones throughout evolution. Analysis of gene expression reveals a developmental regulation concurrent with meiotic progression, with the highest level of transcript detection coincident with meiotic onset during both oogenesis and spermatogenesis.

A conserved element in the protein-coding sequence is required for normal expression of replication-dependent histone genes in developing Xenopus embryos

Replication-dependent histone genes in the mouse and Xenopus share a common regulatory element within the protein-encoding sequence called the CRAS alpha element (coding region activating sequence alpha) which has been shown to mediate normal expression in vivo and to interact with nuclear factors in vitro in a cell cycle-dependent manner. Thus far, the alpha element has only been studied in rodent cells in culture, and its effect on histone gene expression during development has not been determined. Here we examine the role of the alpha element in histone gene expression during Xenopus development which features a switch in histone gene expression from a replication-independent mode in oocytes to a replication-dependent mode in embryos after midblastula stage. In vivo expression experiments involving wild-type or alpha-mutant mouse H3.2 genes show that mutation of the CRAS alpha element results in a fourfold decline of expression in embryos, but does not affect expression in oocytes. Two distinct alpha sequence-specific binding activities were detected in both oocyte and embryonic extracts. A slowly migrating DNA-binding complex was present at relatively constant levels throughout development from the earliest stages of oogenesis through larval stages. In contrast, levels of a rapidly migrating complex were high in stage I and II oocytes, declined in stage II-VI oocytes, remained low in unfertilized eggs and cleavage stage embryos, and rose dramatically after the midblastula transition. The molecular masses of the factors forming the slow and rapidly migrating complexes were estimated to be approximately 110 and 85 kDa, respectively. DNA-binding activity of the 85 kDa alpha-binding factor was affected by phosphorylation, binding with higher affinity in the dephosphorylated state. The abrupt increase in DNA-binding activity of the 85-kDa alpha-binding factor at late blastula coincides with the switch to the replication-dependent mode of histone gene expression. We propose that the conserved alpha element present in the coding sequence of mouse and Xenopus core histone genes is required for normal replication-dependent histone expression in the developing Xenopus embryo.

NMDAR1 mRNA expression and glutamate receptor stimulated increase in cytosolic calcium concentration in rat and mouse cerebellar granule cells

We have previously reported that, unlike their rat counterparts, the survival of mouse cerebellar granule cells is independent of chronic stimulation whether owing to elevated K(+)-induced depolarization or NMDA (N-methyl-D-aspartate) receptor activation. One explanation could be that during the critical period mouse granule cells are very sensitive to NMDA receptor stimulation by endogenous glutamate released in the cultures. If so, this might be reflected by an increased expression of NMDA receptors or an increased response to their activation. We tested this hypothesis by measuring (a) the concentration of mRNA for the obligatory NMDA receptor subunit, NMDAR1, and (b) the glutamate/NMDA stimulated increase in cytosolic Ca(2+)-ion concentration in cultures at physiological or elevated K(+)-ion concentration. The expression of NMDAR1 mRNA was measured by competitive PCR of reversely transcribed mRNA and was normalized to that of the constitutively expressed H3.3 histone mRNA. The glutamate and NMDA stimulated increase in cytosolic Ca(2+)-ion concentration was measured using the fluorescent Ca(2+)-chelator Fluo3. In contrast to the hypothesis, we found NMDAR1 mRNA expression to be lower in mouse than in rat granule cells cultured for 4 days at physiological K(+)-ion concentration. However, the NMDA stimulated increase in cytosolic Ca(2+)-ion concentration did not differ in 4-day rat and mouse cultures. Although the glutamate-stimulated increase in cytosolic Ca(2+)-ion concentration in 2-day cultures was higher in mouse granule cells than in rat granule cells, the developmental profile of the glutamate-stimulated increase in cytosolic Ca(2+)-ion concentration was the same in both cases. In conclusion, we found no obvious evidence for increased NMDA receptor activity in mouse cerebellar granule cells cultured at physiological K(+)-ion concentration.

An H3 coding region regulatory element is common to all four nucleosomal classes of mouse histone-encoding genes

We have previously identified the alpha element within the mouse H2A and H3 histone gene coding region activating sequences (CRAS). This common element is required for normal in vivo expression of these two replication-dependent genes and interacts with nuclear factor(s). Here we report that the CRAS alpha element is present in the coding region sequences of two other replication-dependent mouse H genes, H2B and H4. The DNA-protein interactions were examined by DNase I footprinting and methylation-interference assays, and are very similar, if not identical, for these replication-dependent genes, confirming that the alpha element is the binding site for common nuclear protein(s) in H genes of all four nucleosomal classes. Moreover, we show that the same nuclear factor is involved in these DNA-protein interactions. Our findings, together with the fact that a replication-independent H gene, H3.3, has a mutated alpha element that fails to interact with nuclear proteins, suggest that this regulatory element is involved in the coordinate expression of the replication-dependent core H genes in the eukaryotic cell cycle.

Galanin gene expression in radiothyroidectomy-induced thyrotroph adenomas

Galanin gene expression is markedly increased in the anterior pituitary glands of estrogen-treated rats (lactotroph hyperplasia) as well as human growth hormone-releasing hormone transgenic mice (somatotroph hyperplasia). The objective of this study was to examine galanin in a mouse model of thyrotroph adenoma formation. Male mice were radiothyroidectomized by use of iodine-131 (131I), and galanin peptide levels were assessed in the hypothalamic-pituitary axis. Immunoreactive galanin concentrations in the anterior pituitaries of 131I-treated mice were decreased 80% at 3, 6, 9, and 12 mo after radiothyroidectomy. Galanin peptide levels in the hypothalamus were decreased 20-25% at these times. Treatment with either estradiol or 3,3',5-triiodo-L-thyronine increased galanin peptide concentrations in the anterior pituitaries of 131I-treated mice, but neither treatment restored galanin concentrations. Galanin mRNA levels were decreased > 80% 1 yr after radiothyroidectomy. We conclude that, unlike animal models of lactotroph and somatotroph hyperplasia, galanin gene expression is suppressed throughout the development of thyrotroph adenomas, suggesting that galanin does not have a stimulatory role in the proliferation of thyrotrophs. Moreover, these data show that thyroid hormones are important positive regulators of galanin gene expression in the mouse and that estrogen may stimulate galanin gene expression in the absence of thyroid hormones.

Identification of a second conserved element within the coding sequence of a mouse H3 histone gene that interacts with nuclear factors and is necessary for normal expression

Replication-dependent histone genes of all four nucleosomal classes are coordinately up-regulated at the beginning of S phase of the eukaryotic cell cycle. The universality and importance of this process in eukaryotic cells suggest that common regulatory mechanisms are involved in controlling the high level of expression of these histone genes. We have previously identified the alpha element within mouse H2a.2 and H3.2 coding region activating sequences (CRAS), which is involved in regulation of these two replication-dependent genes. Here we report the identification of a second element within the mouse histone CRAS, the omega element. This element interacts with nuclear proteins and we present in vivo evidence that this sequence is required for normal expression. Omega nucleotides involved in interaction with nuclear proteins have been precisely mapped by menas of DNase I footprinting and methylation interference assays. A naturally occurring mutation in the omega sequence is found in a replication-independent H3.3 gene. Mutation of the H3.2 omega element to that of the H3.3 sequence (3 nt changes) caused a 4-fold drop in in vivo expression of the H3.2 gene in stably transfected CHO cells, equally the effect of mutation of all 7 nt of the element. By UV cross-linking we have determined the approximate molecular weight of the omega binding protein to be 45 kDa. Finally, we identify putative omega sequences in the coding region of mouse H2B and H4 histone genes.

The coding sequences of mouse H2A and H3 histone genes contains a conserved seven nucleotide element that interacts with nuclear factors and is necessary for normal expression

Expression of replication-dependent histone genes of all classes is up-regulated coordinately at the onset of DNA synthesis. The cellular signals involved in coordinate regulation of these genes are not known. Here we report identification of an alpha element, present within the mouse histone coding region activating sequence (CRAS). We show evidence that this element is present in histone genes from two classes, H2a and H3, in the mouse. This element has two biological functions in histone gene expression, i.e. the element interacts with nuclear proteins in regulation of gene expression, as well as encoding the amino acids of the histone proteins. We present both in vivo and in vitro evidence that interaction of nuclear proteins with this element is required for normal expression. The binding site for nuclear protein(s) has been precisely defined by means of synthetic oligonucleotides, as well as DNase I protection and methylation interference. It is interesting to note that the histone CRAS alpha element is mutated in a replication-independent H3.3 gene; 5 of 7 nt in the CRAS alpha box are changed in this gene.

Structure and expression of histone H3.3 genes in Drosophila melanogaster and Drosophila hydei

We demonstrate that in Drosophila melanogaster the histone H3.3 replacement variant is encoded by two genes, H3.3A and H3.3B. We have isolated cDNA clones for H3.3A and cDNA and genomic clones for H3.3B. The genes encode exactly the same protein but are widely divergent in their untranslated regions (UTR). Both genes are expressed in embryos and adults; they are expressed in the gonads as well as in somatic tissues of the flies. However, only one of them, H3.3A, shows strong testes expression. The 3' UTR of the H3.3A gene is relatively short (approximately 250 nucleotides (nt)). H3.3B transcripts can be processed at several polyadenylation sites, the longest with a 3' UTR of more than 1500 nt. The 3' processing sites, preferentially used in the gonads and somatic tissues, are different. We have also isolated the Drosophila hydei homologues of the two H3.3 genes. They are quite similar to the D. melanogaster genes in their expression patterns. However, in contrast to their vertebrate counterparts, which are highly conserved in their noncoding regions, the Drosophila genes display only limited sequence similarity in these regions.

Reduced insulin-like growth factor-I mRNA content in liver, adrenal glands and spinal cord of diabetic rats

Circulating insulin-like growth factor I (IGF-I) concentrations are known to be reduced in experimental and clinical diabetes mellitus. The IGF-I mRNA content was measured in several tissues of rats treated with streptozotocin to determine whether a correlation with neuropathy could be found. IGF-I mRNA content was sharply reduced relative to total and poly(A)+ RNA in diabetic liver and adrenal glands. In contrast, histone 3.3 mRNA content was not significantly reduced relative to poly(A)+ RNA in liver, and alpha-tubulin mRNA content instead was increased in adrenal glands, showing that the decline in IGF-I mRNAs in these tissues was selective. In addition, spinal cord IGF-I mRNA content was significantly reduced per tissue, total RNA, and poly(A)+ RNA after 1 and 2 weeks of diabetes. This was correlated with a concurrent and significant decrease in conduction velocity in both spinal cord and peripheral nerves in a separate study. The decline in liver and spinal cord IGF-I mRNA was not due to streptozotocin toxicity, because it was significantly opposed by insulin which was continuously infused beginning the day after diabetes induction. These results, when taken together with those of others, indicate that the reduction in IGF-I mRNA content may be widespread among diabetic tissues, and might contribute in part to certain syndromes of diabetes, such as neuropathy.

Regulation of lipoprotein lipase activity and mRNA in the mammary gland of the lactating mouse

We examined the effects of reproductive stage and fasting on lipoprotein lipase (LPL) activity and mRNA in the mouse mammary gland. Heparin-releasable and cell-associated LPL activity rose immediately after birth, followed 1-2 days later by an increase in LPL mRNA. Fasting decreased LPL activity in the mammary gland at all reproductive stages. During lactation, both milk and heparin-releasable LPL were substantially decreased by an overnight fast, whereas cell-associated LPL was less affected and LPL mRNA did not change. These studies indicate that the extracellular, heparin-releasable, fraction of mammary LPL activity responds most rapidly to alterations in physiological state, usually accompanied by smaller changes in cellular enzyme activity. Changes in the level of LPL mRNA were seen only during the transition from pregnancy to lactation, and these tended to follow, rather than precede, changes in enzyme activity. We conclude that in the mammary gland as in adipose tissue, LPL is regulated primarily at the translational and post-translational level.

Induction of H3.3 replacement histone mRNAs during the precommitment period of murine erythroleukemia cell differentiation

Differential hybridization to a cDNA library made from the mRNA of differentiating mouse erythroleukemia (MEL) cells has been used to identify sequences that are induced during the early stages of MEL cell differentiation. One of the differentially expressed genes identified encodes the H3.3 histone subtype. We show here that the three polyadenylated mRNAs produced from the H3.3B gene, as well as the single mRNA produced from the related H3.3A gene, are coordinately induced during the first few hours of MEL cell differentiation and subsequently down regulated as cells undergo terminal differentiation. Nuclear run-on transcription experiments indicate that the accumulation and decay of these mRNAs are controlled at the post-transcriptional level. Unlike the polyadenylated mRNAs of two H1 histone genes that exhibit similar kinetics of induction and decay controlled by c-myc, induction of the H3.3 mRNAs is unaffected by deregulated expression of c-myc.

Coupled reverse transcription-polymerase chain reaction (RT-PCR) technique is comparative, quantitative, and rapid: uses in alcohol research involving low abundance mRNA species such as hypothalamic LHRH and GRF

The measurement of alterations in low abundance mRNAs such as the hypothalamic hormones luteinizing hormone-releasing hormone (LHRH) and growth hormone-releasing hormone (GHRH or GRF) from individual hypothalamic tissues in rats has previously been difficult and usually required either isolation of poly(A) mRNA or the pooling of numerous animals to obtain a reasonable signal on Northern blots. Although more sensitive detection methods exist, such as the use of RNA probes or solution hybridization (RNase protection), we have found the most reliable, sensitive, rapid, and accurate method is the reverse transcription-polymerase chain reaction (RT-PCR) using histone H3.3 as an internal control for both steps of this procedure. H3.3 is a cell-cycle independent and constitutively expressed gene in all tissues. We have developed an RT-PCR assay for LHRH and GRF mRNA quantitation and comparative analysis for hypothalamic and extrahypothalamic brain tissues and present the use of RT-PCR for LHRH quantitation in ethanol (EtOH) studies.

Histone H2A.X gene transcription is regulated differently than transcription of other replication-linked histone genes

Histone H2A.X is a replication-independent histone H2A isoprotein species that is encoded by a transcript alternatively processed at the 3' end to yield two mRNAs: a 0.6-kb mRNA ending with the stem-loop structure characteristic of the mRNAs for replication-linked histone species, and a second, polyadenylated 1.6-kb mRNA ending about 1 kb further downstream (C. Mannironi, W. M. Bonner, and C. L. Hatch, Nucleic Acids Res. 17:9113-9126, 1989). Of the two, the 0.6-kb H2A.X stem-loop mRNA predominates in many cell lines, indicating that the presence of two types of mRNA may not completely account for the replication independence of H2A.X protein synthesis. The ambiguity is resolved by the finding that the level of the 0.6-kb H2A.X mRNA is only weakly downregulated during the inhibition of DNA replication and only weakly upregulated during the inhibition of protein synthesis, while the levels of other replication-linked mRNAs are strongly down- or upregulated under these two conditions. Analysis of the nuclear transcription rates of specific H2A genes showed that while the rates of transcription of replication-linked H2A genes decreased substantially during the inhibition of DNA synthesis and increased substantially during the inhibition of protein synthesis, the rate of H2A.X gene transcription decreased slightly under both conditions. These differences in transcriptional regulation between the H2A.X gene and other replication-linked histone genes are sufficient to account for the differences in regulation of their respective stem-loop mRNAs.

Histone H2A.X gene transcription is regulated differently than transcription of other replication-linked histone genes

Histone H2A.X is a replication-independent histone H2A isoprotein species that is encoded by a transcript alternatively processed at the 3' end to yield two mRNAs: a 0.6-kb mRNA ending with the stem-loop structure characteristic of the mRNAs for replication-linked histone species, and a second, polyadenylated 1.6-kb mRNA ending about 1 kb further downstream (C. Mannironi, W. M. Bonner, and C. L. Hatch, Nucleic Acids Res. 17:9113-9126, 1989). Of the two, the 0.6-kb H2A.X stem-loop mRNA predominates in many cell lines, indicating that the presence of two types of mRNA may not completely account for the replication independence of H2A.X protein synthesis. The ambiguity is resolved by the finding that the level of the 0.6-kb H2A.X mRNA is only weakly downregulated during the inhibition of DNA replication and only weakly upregulated during the inhibition of protein synthesis, while the levels of other replication-linked mRNAs are strongly down- or upregulated under these two conditions. Analysis of the nuclear transcription rates of specific H2A genes showed that while the rates of transcription of replication-linked H2A genes decreased substantially during the inhibition of DNA synthesis and increased substantially during the inhibition of protein synthesis, the rate of H2A.X gene transcription decreased slightly under both conditions. These differences in transcriptional regulation between the H2A.X gene and other replication-linked histone genes are sufficient to account for the differences in regulation of their respective stem-loop mRNAs.

Genes encoding a histone H3.3-like variant in Arabidopsis contain intervening sequences

Two genes encoding a particular H3 histone variant were isolated from Arabidopsis thaliana. These genes differ from the H3 genes previously cloned from Arabidopsis and other plants by several interesting properties: (1) the two genes are located close to each other; (2) their coding regions are interrupted by two or three small introns, the two closest to the initiation codon being located at the same place in the two genes; (3) another, long intron is located in the 5'-untranslated region just before the initiation codon of gene I as deduced from the sequence of several corresponding cDNAs, and very likely also of gene II; (4) these genes do not show preferential expression in organs containing meristematic tissues contrary to the classical intronless replication-dependent histone genes, thus suggesting that their expression is not replication-dependent; (5) the protein encoded by both genes is the same and corresponds to a minor H3 variant highly conserved among all the plant species studied up to now. All these characteristics are common with the animal replication-independent H3.3 histone genes and it is assumed that the genes described here are the first example of the equivalent H3.3 gene family in plants. Interestingly, the promoter regions of the two genes have the same general structure as the Arabidopsis intronless genes. Possible implications on the regulation of H3 genes expression are discussed.

Effects of insulin and insulin-like growth factors on neurofilament mRNA and tubulin mRNA content in human neuroblastoma SH-SY5Y cells

Insulin-like growth factors (IGFs) are implicated in the development of the vertebrate neural circuitry, and increase neurite growth in vitro and in vivo. The construction of the cytoskeleton is necessary for growth of axons and dendrites, and the neurofilament (NF) 68 kDa and 170 kDa proteins assemble to help form major fibrillar elements of the neurite cytoskeleton. We report that physiological concentrations of insulin, IGF-I or IGF-II increased the contents of 68 kDa NF, 170 kDa NF, alpha-tubulin, and beta-tubulin mRNAs, relative to total RNA, in cultured human neuroblastoma SH-SY5Y cells. In contrast, the relative contents of histone 3.3 mRNA, and poly(A)+ RNA were not increased. Ligand concentrations which increased NF mRNAs were very similar to those which increased neurite outgrowth. Although each gene was evidently independently regulated, the 68 kDa NF, 170 kDa NF, alpha-tubulin, and beta-tubulin mRNAs were nevertheless all transiently elevated over approximately the same time interval in response to insulin. These data, when considered together with studies by others with nerve growth factor, show that the 68 kDa and 170 kDa NF mRNAs are elevated in a biochemical pathway activated in common during neurite outgrowth directed by insulin, IGF-I, IGF-II, and nerve growth factor.

Isolation and characterization of a library of cDNA clones that are preferentially expressed in the embryonic telencephalon

In order to isolate genes involved in development of the mammalian telencephalon we employed an efficient cDNA library procedure. By subtracting an adult mouse telencephalic cDNA library from an embryonic day 15 (E15) mouse telencephalic cDNA library we generated two subtracted libraries (ES1 and ES2). We estimate that ES1 contains between 200 and 600 different cDNA clones, which approximates the number of genes that are preferentially expressed in the E15 telencephalon, compared to the adult telencephalon. Northern analysis of 20 different cDNA clones shows that 14 of these are expressed at least 5-fold more in the E15 telencephalon than the adult telencephalon. Limited sequencing of the 14 differentially expressed clones reveals that 10 have no significant identity to sequences in GenBank and EMBL databases, whereas the other 4 have significant sequence identity to vimentin, histone 3.3, topoisomerase I and the B2 repeat element. In situ hybridization using one of the differentially expressed cDNAs, TES-1, demonstrates that it is transiently expressed in the anlage of the basal ganglia. In situ hybridization with another differentially expressed cDNA clone, TES-4, shows that it is specifically expressed in differentiating cells of the neural axis with a distinctive rostral-caudal temporal pattern. These findings, and the methods that we have developed, provide a framework for future investigations of the genetic control of telencephalon development.

A Drosophila melanogaster H3.3 cDNA encodes a histone variant identical with the vertebrate H3.3

A cDNA encoding an H3.3 histone variant in Drosophila melanogaster predicts a protein with an amino acid (aa) sequence identical with that in vertebrates. The D. melanogaster H3.3 nucleotide (nt) sequence has diverged significantly from that of both the H3.3 gene of vertebrates and the H3.1 gene of D. melanogaster, largely through third nt changes in its codons. The perfect H3.3 aa sequence conservation between organisms as phylogenetically divergent as vertebrates and flies suggests that the H3.3 histone variant itself is an important structural component of chromatin, apart from the value of its replication-independent expression pattern.

Regulation of histone mRNA in the unperturbed cell cycle: evidence suggesting control at two posttranscriptional steps

The levels of histone mRNA increase 35-fold as selectively detached mitotic CHO cells progress from mitosis through G1 and into S phase. Using an exogenous gene with a histone 3' end which is not sensitive to transcriptional or half-life regulation, we show that 3' processing is regulated as cells progress from G1 to S phase. The half-life of histone mRNA is similar in G1- and S-phase cells, as measured after inhibition of transcription by actinomycin D (dactinomycin) or indirectly after stabilization by the protein synthesis inhibitor cycloheximide. Taken together, these results suggest that the change in histone mRNA levels between G1- and S-phase cells must be due to an increase in the rate of biosynthesis, a combination of changes in transcription rate and processing efficiency. In G2 phase, there is a rapid 35-fold decrease in the histone mRNA concentration which our results suggest is due primarily to an altered stability of histone mRNA. These results are consistent with a model for cell cycle regulation of histone mRNA levels in which the effects on both RNA 3' processing and transcription, rather than alterations in mRNA stability, are the major mechanisms by which low histone mRNA levels are maintained during G1.

Regulation of histone mRNA in the unperturbed cell cycle: evidence suggesting control at two posttranscriptional steps

The levels of histone mRNA increase 35-fold as selectively detached mitotic CHO cells progress from mitosis through G1 and into S phase. Using an exogenous gene with a histone 3' end which is not sensitive to transcriptional or half-life regulation, we show that 3' processing is regulated as cells progress from G1 to S phase. The half-life of histone mRNA is similar in G1- and S-phase cells, as measured after inhibition of transcription by actinomycin D (dactinomycin) or indirectly after stabilization by the protein synthesis inhibitor cycloheximide. Taken together, these results suggest that the change in histone mRNA levels between G1- and S-phase cells must be due to an increase in the rate of biosynthesis, a combination of changes in transcription rate and processing efficiency. In G2 phase, there is a rapid 35-fold decrease in the histone mRNA concentration which our results suggest is due primarily to an altered stability of histone mRNA. These results are consistent with a model for cell cycle regulation of histone mRNA levels in which the effects on both RNA 3' processing and transcription, rather than alterations in mRNA stability, are the major mechanisms by which low histone mRNA levels are maintained during G1.

Stabilization of tubulin mRNAs by insulin and insulin-like growth factor I during neurite formation

Neurotrophic factors may increase axon and dendrite growth in part by regulating the content of cytoskeletal elements such as microtubules, which are comprised of tubulin subunits. The mechanism by which insulin, insulin-like growth factors (IGFs), and nerve growth factor (NGF) can increase the relative abundance of tubulin mRNAs as a prelude to neurite formation was studied. Insulin significantly increased the abundance of tubulin mRNAs relative to total RNA in cultured human neuroblastoma SH-SY5Y cells. This increase was not the result of a generalized elevation of all transcripts, because tubulin mRNAs were elevated relative to poly(A)+ RNA as well. Moreover, whereas polymerases I and III were elevated in activity, polymerase II was not. Tubulin mRNAs were stabilized against degradation in the presence of actinomycin D by both insulin and IGF-I. In contrast, actin and histone 3.3 mRNAs were neither increased nor stabilized. Insulin did not alter alpha- or beta-tubulin gene transcription rates in nuclear run-off experiments, and did increase the relative synthesis of tubulin proteins. These results suggest that tubulin mRNA levels are increased mainly through selective stabilization by insulin and IGFs. Because NGF is known to stabilize tubulin mRNA levels also, stabilization of tubulin mRNAs is suggested to be a common event in the pathway leading to neurite elongation directed by neuritogenic polypeptides.

Different 3'-end processing produces two independently regulated mRNAs from a single H1 histone gene

We describe the isolation of a mouse H1 histone gene that encodes two mRNA transcripts. One mRNA ends just beyond the coding region, near a highly conserved palindrome sequence typical of cell cycle-regulated histone genes. The level of this transcript is coupled to DNA replication. The second mRNA ends nearly 1 kilobase downstream near a polyadenylation signal. This mRNA is polyadenylylated, and its accumulation is not coupled to DNA replication. The two mRNAs are regulated independently and in some circumstances in opposite directions under several physiological conditions. The production of a polyadenylylated mRNA from an otherwise cell cycle-regulated histone gene may allow for continued synthesis of the histone protein when DNA synthesis ceases in nondividing cells.

The early and late sea urchin histone H4 mRNAs respond differently to inhibitors of DNA synthesis

The effect of inhibiting DNA synthesis on the concentration of the alpha-histone mRNA and the late histone mRNAs in sea urchin embryos was measured. The alpha-histone mRNA concentrations did not change, while the late histone mRNA concentrations were rapidly reduced at the three developmental stages (morula, blastula, and mesenchyme blastula) tested. The rapid degradation of the late histone mRNAs was prevented when protein synthesis was inhibited.

Histone gene switching in murine erythroleukemia cells is differentiation specific and occurs without loss of cell cycle regulation

We investigated the expression characteristics of the fully replication-dependent (FRD) and the partially replication-dependent (PRD) histone gene variants by measuring changes in steady-state mRNA levels during hexamethylene bisacetamide (HMBA)-induced differentiation of murine erythroleukemia (MEL) cells. Between 24 and 60 h after induction, there was a dramatic switch in histone gene expression, such that the ratio of PRD to FRD transcripts increased severalfold over that found in uninduced MEL cells. We demonstrated that this gene switching was not simply a partial or complete uncoupling of PRD gene expression from DNA synthesis. PRD and FRD transcript levels were regulated coordinately upon treatment of uninduced or induced MEL cells with inhibitors of DNA synthesis, protein synthesis, or both. Using several criteria, we were unable to detect any difference in PRD and FRD gene expression under any conditions except in cells undergoing differentiation. MEL cells were arrested at a precommitment stage of differentiation by induction with HMBA in the presence of dexamethasone (DEX). If DEX was subsequently removed, DNA synthesis resumed, the cells underwent commitment, and histone gene switching was observed. In contrast, if both DEX and HMBA were removed, DNA synthesis still resumed, but commitment did not occur and no gene switching was observed. These results imply that histone gene switching is intimately related to the differentiation process.