Stem-loop binding protein, the protein that binds the 3' end of histone mRNA, is cell cycle regulated by both translational and posttranslational mechanisms.

The expression of the replication-dependent histone mRNAs is tightly regulated during the cell cycle. As cells progress from G(1) to S phase, histone mRNA levels increase 35-fold, and they decrease again during G(2) phase. Replication-dependent histone mRNAs are the only metazoan mRNAs that lack polyadenylated tails, ending instead in a conserved stem-loop. Much of the cell cycle regulation is posttranscriptional and is mediated by the 3' stem-loop. A 31-kDa stem-loop binding protein (SLBP) binds the 3' end of histone mRNA. The SLBP is necessary for pre-mRNA processing and accompanies the histone mRNA to the cytoplasm, where it is a component of the histone messenger RNP. We used synchronous CHO cells selected by mitotic shakeoff and HeLa cells synchronized at the G(1)/S or the M/G(1) boundary to study the regulation of SLBP during the cell cycle. In each system the amount of SLBP is regulated during the cell cycle, increasing 10- to 20-fold in the late G(1) and then decreasing in the S/G(2) border. SLBP mRNA levels are constant during the cell cycle. SLBP is regulated at the level of translation as cells progress from G(1) to S phase, and the protein is rapidly degraded as they progress into G(2). Regulation of SLBP may account for the posttranscriptional component of the cell cycle regulation of histone mRNA.

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.

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.

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.

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.

Cell cycle-regulated binding of nuclear proteins to elements within a mouse H3.2 histone gene.

The histone gene family in mammals consists of 15-20 genes for each class of nucleosomal histone protein. These genes are classified as either replication-dependent or -independent in regard to their expression in the cell cycle. The expression of the replication-dependent histone genes increases dramatically as the cell prepares to enter S phase. Using mouse histone genes, we previously identified a coding region activating sequence (CRAS) involved in the upregulation of at least two (H2a and H3) and possibly all nucleosomal replication-dependent histone genes. Mutation of two seven-nucleotide elements, alpha and omega, within the H3 CRAS causes a decrease in expression in stably transfected Chinese hamster ovary cells comparable with the effect seen upon deletion of the entire CRAS. Further, nuclear proteins interact in a highly specific manner with nucleotides within these sequences. Mutation of these elements abolishes DNA/protein interactions in vitro. Here we report that the interactions of nuclear factors with these elements are differentially regulated in the cell cycle and that protein interactions with these elements are dependent on the phosphorylation/dephosphorylation state of the nuclear factors.

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.

A common transcriptional activator is located in the coding region of two replication-dependent mouse histone genes.

There is a region in the mouse histone H3 gene protein-encoding sequence required for high expression. The 110-nucleotide coding region activating sequence (CRAS) from codons 58 to 93 of the H3.2 gene restored expression when placed 520 nucleotides 5' of the start of transcription in the correct orientation. Since identical mRNA molecules are produced by transcription of the original deletion gene and the deletion gene with the CRAS at -520, effects of the deletions on mRNA stability or other posttranscriptional events are completely ruled out. Inversion of the CRAS sequence in its proper position in the H3 gene resulted in only a threefold increase in expression, and placing the CRAS sequence 5' of the deleted gene in the wrong orientation had no effect on expression. In-frame deletions in the coding region of an H2a.2 gene led to identification of a 105-nucleotide sequence in the coding region between amino acids 50 and 85 necessary for high expression of the gene. Additionally, insertion of the H3 CRAS into the deleted region of the H2a.2 gene restored expression of the H2a gene. Thus, the CRAS element has an orientation-dependent, position-independent effect. Gel mobility shift competition studies indicate that the same proteins interact with both the H3 and H2a CRAS elements, suggesting that a common factor is involved in expression of histone genes.

A region in the coding sequence is required for high-level expression of murine histone H3 gene.

Replication-dependent histone genes are expressed at high rates in S phase to provide the histone proteins required for chromosomal replication. Two genes, an H2a and H3 gene, located on chromosome 3 in the mouse and cloned together in a single 3-kilobase (plasmid MM614) restriction fragment are highly expressed. By transfecting mouse histone gene constructs into Chinese hamster ovary cells, we have identified a 110-nucleotide region within the coding sequence of the H3.2-614 gene that is required for high-level expression. Deletion of this region reduces expression of the gene by 20-fold. Additionally, the histone-coding region activates the human alpha-globin promoter, which is normally not expressed well in Chinese hamster ovary cells. Similar results with deletion constructions involving the H2a-614 gene suggest that an intragenic region plays an important role in transcription of these genes.

Transformation of DNA repair-deficient human diploid fibroblasts with a simian virus 40 plasmid.

Fibroblasts from patients with xeroderma pigmentosum (XP) complementation groups A, C, D, E, and G, as well as Bloom syndrome (BS) and Fanconi anemia (FA) have been transfected with a plasmid, pSV7, containing the early region of Simian virus 40 (SV40). All of the cultures exhibited cytologic changes characteristic of transformed cells and expressed T-antigen. They also contained integrated copies of DNA derived from the vector, and in several cases, extrachromosomally replicated DNA. Not all of the transfected cultures became immortalized. The transformed xeroderma pigmentosum (XP) cultures retained their UV-sensitive phenotype in all but one case. The BS and FA cell lines retained their characteristic phenotype. All of the cultures, except the BS cells, can be readily transfected with the plasmids, pSV2neo and pSV2gpt.

Conversion of replicative intermediates in human DNA-repair defective cells.

We have examined the conversion of intermediates of DNA replication in normal human skin fibroblasts and fibroblasts isolated from patients with genetic diseases caused by putative DNA repair defects. Experiments were performed in non-transformed, unchallenged cells using alkaline sucrose sedimentation analysis to demonstrate precursor low molecular weight (LMW) DNA molecules which converted into high molecular weight (HMW) DNA with time. Analyses of conversion of replicative intermediates were conducted in cells from patients with ataxia telangiectasia (AT), Fanconi anemia (FA), Bloom syndrome (BS), Cockayne syndrome (CS) and xeroderma pigmentosum (XP). Our studies show that conversion of replicative intermediates occurs in all cell strains examined. However, XP cells (complementation groups A and E) show evidence of abnormalities in the conversion of LMW replicative intermediates, with the most dramatic alterations shown by cells from complementation group A.

Abnormal response of xeroderma pigmentosum cells to bleomycin.

The repair of bleomycin-damaged DNA was examined in human fibroblasts isolated from patients having the disease xeroderma pigmentosum (XP). In normal fibroblasts, the appearance of low-molecular-weight DNA was observed in the presence of increasing amounts of the drug. The studies in XP fibroblasts produced results which differed from those obtained in normal cells in two ways. (a) Prelabeled XP cells from most complementation groups contained more low-molecular-weight DNA than observed in the other human fibroblasts examined. (b) When XP cells were exposed to low doses of bleomycin, the low-molecular-weight DNA disappeared, suggesting induction of a repair process. If the XP cells were exposed to bleomycin in the presence of hydroxyurea and 1-beta-D-arabinofuranosylcytosine, the disappearance of low-molecular-weight DNA was not observed; instead, a normal dose response to the drug was observed. Our results suggest that XP cells show an "induced" repair response following bleomycin treatment and that blocking DNA chain elongation uncovers normal incisions in bleomycin-treated DNA.

Stable low molecular weight DNA in xeroderma pigmentosum cells.

Xeroderma pigmentosum (XP) cells from several complementation groups contained more low molecular weight DNA upon alkaline sucrose gradient centrifugation than did other human cells examined. Under conditions in which only 5% of the DNA in normal cells sedimented at 16 S or less, 20% of the DNA in XP cells from complementation group A sedimented at 16 S or less. Because cells were layered directly onto the gradients for lysing of cells and denaturing of the DNA, it appears that this low molecular weight material is due to naturally existing gaps or alkali-sensitive sites, or both, in the cellular DNA. The increase in low molecular weight DNA seen in XP complementation group A cells also is seen in complementation groups C, D, and E. When prelabeled cells were incubated for increasing times after removal of the radioactive label, the amount of low molecular weight material remained constant over a 3-hr period. The introduction of the DNA-damaging agent, bleomycin, to prelabeled XP cells produced a surprising effect. The normal response of human cells to bleomycin is an increase in low molecular weight DNA, dependent on the dose of the drug and time of treatment. In XP cells the reverse was observed. That is, the low molecular weight DNA observed in untreated XP cells disappeared upon addition of the drug. The process responsible for the unusual response of XP cells to bleomycin is unknown, but these results are compatible with an inducible repair process.

Repair response of human fibroblasts to bleomycin damage.

The ability of human fibroblasts to repair the specific types of DNA damage caused by bleomycin (BLM) was examined in whole-cell experiments. The method utilized for analysis was alkaline sucrose-gradient centrifugation of DNA. The results of these studies show that a repair pathway exists for the damage produced in DNA by bleomycin. DNA from BLM-treated cells shows a decrease in molecular weight, caused by chemical or enzymatic incision at sites of drug action. If the drug is removed, the DNA rapidly returns to high molecular weight, demonstrating reformation of damaged DNA. This repair response to BLM-damage was also confirmed in fibroblasts isolated from patients with putative DNA-repair defects. We observed that the response (to BLM) of cells from patients with Fanconi anemia was altered in that the fall in molecular weight of DNA from treated cells was not as great as that observed in other cell strains after drug treatment.

Repair of Bleomycin-damaged DNA by human fibroblasts.

The ability of human fibroblasts to repair bleomycin-damaged DNA was examined in vivo. Repair of the specific lesions caused by bleomycin (BLM) was investigated in normal cell strains as well as those isolated from patients with apparent DNA repair defects. The diseases ataxia telangiectasia (AT), Bloom syndrome (BS), Cockayne syndrome (CS), Fanconi anemia (FA), and xeroderma pigmentosum (XP) were those selected for study. The method used for studying the repair of DNA after BLM exposure was alkaline sucrose gradient centrifugation. After exposure to BLM, a fall in the molecular weight of DNA was observed, and after drug removal the DNA reformed rapidly to high molecular weight. The fall in molecular weight upon exposure to BLM was observed in all cells examined with the exception of some XP strains. Prelabeled cells from some XP complementation groups were found to have a higher percentage of low molecular weight DNA on alkaline gradients than did normal cells. This prelabeled low molecular weight DNA disappeared upon exposure to BLM.