Characterization and purification of H1TF2, a novel CCAAT-binding protein that interacts with a histone H1 subtype-specific consensus element

Modelling Robust Feedback Control Mechanisms That Ensure Reliable Coordination of Histone Gene Expression with DNA Replication

Histone proteins are key elements in the packing of eukaryotic DNA into chromosomes. A little understood control system ensures that histone gene expression is balanced with DNA replication so that histone proteins are produced in appropriate amounts. Disturbing or disrupting this system affects genome stability and gene expression, and has detrimental consequences for human development and health. It has been proposed that feedback control involving histone proteins contributes to this regulation and there is evidence implicating cell cycle checkpoint molecules activated when DNA synthesis is impaired in this control. We have developed mathematical models that incorporate these control modes in the form of inhibitory feedback of histone gene expression from free histone proteins, and alternatively a direct link that couples histone RNA synthesis to DNA synthesis. Using our experimental evidence and related published data we provide a simplified description of histone protein synthesis during S phase. Both models reproduce the coordination of histone gene expression with DNA replication during S phase and the down-regulation of histone RNA when DNA synthesis is interrupted, but only the model incorporating histone protein feedback control was able to effectively simulate the coordinate expression of a simplified histone gene family. Our combined theoretical and experimental approach supports the hypothesis that the regulation of histone gene expression involves feedback control.

A conserved interaction that is essential for the biogenesis of histone locus bodies

Nuclear protein, ataxia-telangiectasia locus (NPAT) and FLICE-associated huge protein (FLASH) are two major components of discrete nuclear structures called histone locus bodies (HLBs). NPAT is a key co-activator of histone gene transcription, whereas FLASH through its N-terminal region functions in 3' end processing of histone primary transcripts. The C-terminal region of FLASH contains a highly conserved domain that is also present at the end of Yin Yang 1-associated protein-related protein (YARP) and its Drosophila homologue, Mute, previously shown to localize to HLBs in Drosophila cells. Here, we show that the C-terminal domain of human FLASH and YARP interacts with the C-terminal region of NPAT and that this interaction is essential and sufficient to drive FLASH and YARP to HLBs in HeLa cells. Strikingly, only the last 16 amino acids of NPAT are sufficient for the interaction. We also show that the C-terminal domain of Mute interacts with a short region at the end of the Drosophila NPAT orthologue, multi sex combs (Mxc). Altogether, our data indicate that the conserved C-terminal domain shared by FLASH, YARP, and Mute recognizes the C-terminal sequence of NPAT orthologues, thus acting as a signal targeting proteins to HLBs. Finally, we demonstrate that the C-terminal domain of human FLASH can be directly joined with its N-terminal region through alternative splicing. The resulting 190-amino acid MiniFLASH, despite lacking 90% of full-length FLASH, contains all regions necessary for 3' end processing of histone pre-mRNA in vitro and accumulates in HLBs.

A survey of 178 NF-Y binding CCAAT boxes

The CCAAT box is one of the most common elements in eukaryotic promoters, found in the forward or reverse orientation. Among the various DNA binding proteins that interact with this sequence, only NF-Y (CBF, HAP2/3/4/5) has been shown to absolutely require all 5 nt. Analysis of a database with 178 bona fide NF-Y binding sites in 96 unrelated promoters confirms this need and points to specific additional flanking nucleotides (C, Pu, Pu on the 5'-side and C/G, A/G, G,A/C, G on the 3'-side) required for efficient binding. The frequency of CCAAT boxes appears to be relatively higher in TATA-less promoters, particularly in the reverse ATTGG orientation. In TATA-containing promoters the CCAAT box is preferentially located in the -80/-100 region (mean position -89) and is not found nearer to the Start site than -50. In TATA-less promoters it is usually closer to the +1 signal (at -66 on average) and is sometimes present in proximity to the Cap site. The consensus and location of NF-Y binding sites parallel almost perfectly a previous general statistical study on CCAAT boxes in 502 unrelated promoters. This is an indication that NF-Y is the major, if not the sole, CCAAT box recognizing protein and that it might serve different roles in TATA-containing and TATA-less promoters.

The E2F transcription factor activates a replication-dependent human H2A gene in early S phase of the cell cycle

Histone gene expression is restricted to the S phase of the cell cycle. Control is mediated by a complex network of sequence-specific DNA-binding factors and protein-protein interactions in response to cell cycle progression. To further investigate the regulatory functions that are associated at the transcriptional level, we analyzed the regulation of a replication-dependent human H2A.1-H2B.2 gene pair. We found that transcription factor E2F binds specifically to an E2F recognition motif in the H2A.1 promoter region. Activation of the H2A.1 promoter by E2F-1 was shown by use of luciferase reporter constructs of the intergenic promoter region. Overexpression of the human retinoblastoma suppressor gene product RB suppressed E2F-1 mediated transcriptional activation, indicating an E2F-dependent regulation of promoter activity during the G1-to-S-phase transition. Furthermore, the activity of the H2A.1 promoter was also downregulated by overexpression of the RB-related p107, a protein that has been detected in S-phase-specific protein complexes of cyclin A, E2F, and cdk2. In synchronized HeLa cells, expression of luciferase activity was induced at the beginning of DNA synthesis and was dependent on the presence of an E2F-binding site in the H2A.1 promoter. Together with the finding that E2F-binding motifs are highly conserved in H2A promoters of other species, our results suggest that E2F plays an important role in the coordinate regulation of S-phase-specific histone gene expression.

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.

Interaction of the CCAAT displacement protein with shared regulatory elements required for transcription of paired histone genes

The H2A and H2B genes of the Xenopus xlh3 histone gene cluster are transcribed in opposite directions from initiation points located approximately 235 bp apart. The close proximity of these genes to one another suggests that their expression may be controlled by either a single bidirectional promoter or by separate promoters. Our analysis of the transcription of histone gene pairs containing deletions and site-specific mutations of intergenic DNA revealed that both promoters are distinct but that they overlap physically and share multiple regulatory elements, providing a possible basis for the coordinate regulation of their in vivo activities. Using the intergenic DNA fragment as a probe and extracts from mammalian and amphibian cells, we observed the formation of a specific complex containing the CCAAT displacement protein (CDP). The formation of the CDP-containing complex was not strictly dependent on any single element in the intergenic region but instead required the presence of at least two of the three CCAAT motifs. Interestingly, similar CDP-containing complexes were formed on the promoters from the three other histone genes. The binding of CDP to histone gene promoters may contribute to the coordination of their activities during the cell cycle and early development.

H1TF2A, the large subunit of a heterodimeric, glutamine-rich CCAAT-binding transcription factor involved in histone H1 cell cycle regulation

H1TF2 is a CCAAT transcription factor that binds to the histone H1 subtype-specific consensus sequence, which has previously been shown to be necessary for temporal regulation of histone H1 transcription during the cell cycle (F. La Bella, P. Gallinari, J. McKinney, and N. Heintz, Genes Dev. 3:1982-1990, 1989). In this study, we report that H1TF2 is a heteromeric CCAAT-binding protein composed of two polypeptide doublets of 33 and 34 kDa and 43 and 44 kDa that are not antigenically related. The 33- and 34-kDa species were not detected in our previous studies (P. Gallinari, F. La Bella, and N. Heintz, Mol. Cell. Biol. 9:1566-1575, 1989) because of technical problems in detection of these heavily glycosylated subunits. The cloning of H1TF2A, the large subunit of this factor, reveals it to be a glutamine-rich protein with extremely limited similarity to previously cloned CCAAT-binding proteins. A monospecific antiserum produced against bacterially synthesized H1TF2A was used to establish that HeLa cell H1TF2A is phosphorylated in vivo and that, in contrast to the H2b transcription factor Oct1 (S. B. Roberts, N. Segil, and N. Heintz, Science 253:1022-1026, 1991; N. Segil, S. B. Roberts, and N. Heintz, Cold Spring Harbor Symp. Quant. Biol. 56:285-292, 1991), no gross change in H1TF2A phosphorylation is evident during the cell cycle. Further immunoprecipitation studies demonstrated that H1TF2 is heterodimeric in the absence of DNA in vivo and identified several H1TF2-interacting proteins that may play a role in H1TF2 function in vivo.

H1TF2A, the large subunit of a heterodimeric, glutamine-rich CCAAT-binding transcription factor involved in histone H1 cell cycle regulation

H1TF2 is a CCAAT transcription factor that binds to the histone H1 subtype-specific consensus sequence, which has previously been shown to be necessary for temporal regulation of histone H1 transcription during the cell cycle (F. La Bella, P. Gallinari, J. McKinney, and N. Heintz, Genes Dev. 3:1982-1990, 1989). In this study, we report that H1TF2 is a heteromeric CCAAT-binding protein composed of two polypeptide doublets of 33 and 34 kDa and 43 and 44 kDa that are not antigenically related. The 33- and 34-kDa species were not detected in our previous studies (P. Gallinari, F. La Bella, and N. Heintz, Mol. Cell. Biol. 9:1566-1575, 1989) because of technical problems in detection of these heavily glycosylated subunits. The cloning of H1TF2A, the large subunit of this factor, reveals it to be a glutamine-rich protein with extremely limited similarity to previously cloned CCAAT-binding proteins. A monospecific antiserum produced against bacterially synthesized H1TF2A was used to establish that HeLa cell H1TF2A is phosphorylated in vivo and that, in contrast to the H2b transcription factor Oct1 (S. B. Roberts, N. Segil, and N. Heintz, Science 253:1022-1026, 1991; N. Segil, S. B. Roberts, and N. Heintz, Cold Spring Harbor Symp. Quant. Biol. 56:285-292, 1991), no gross change in H1TF2A phosphorylation is evident during the cell cycle. Further immunoprecipitation studies demonstrated that H1TF2 is heterodimeric in the absence of DNA in vivo and identified several H1TF2-interacting proteins that may play a role in H1TF2 function in vivo.

Histone H3 transcription in Saccharomyces cerevisiae is controlled by multiple cell cycle activation sites and a constitutive negative regulatory element

The promoters of the Saccharomyces cerevisiae histone H3 and H4 genes were examined for cis-acting DNA sequence elements regulating transcription and cell division cycle control. Deletion and linker disruption mutations identified two classes of regulatory elements: multiple cell cycle activation (CCA) sites and a negative regulatory site (NRS). Duplicate 19-bp CCA sites are present in both the copy I and copy II histone H3-H4 promoters arranged as inverted repeats separated by 45 and 68 bp. The CCA sites are both necessary and sufficient to activate transcription under cell division cycle control. A single CCA site provides cell cycle control but is a weak transcriptional activator, while an inverted repeat comprising two CCA sites provides both strong transcriptional activation and cell division cycle control. The NRS was identified in the copy I histone H3-H4 promoter. Deletion or disruption of the NRS increased the level of the histone H3 promoter activity but did not alter the cell division cycle periodicity of transcription. When the CCA sites were deleted from the histone promoter, the NRS element was unable to confer cell division cycle control on the remaining basal level of transcription. When the NRS element was inserted into the promoter of a foreign reporter gene, transcription was constitutively repressed and did not acquire cell cycle regulation.

Histone H3 transcription in Saccharomyces cerevisiae is controlled by multiple cell cycle activation sites and a constitutive negative regulatory element

The promoters of the Saccharomyces cerevisiae histone H3 and H4 genes were examined for cis-acting DNA sequence elements regulating transcription and cell division cycle control. Deletion and linker disruption mutations identified two classes of regulatory elements: multiple cell cycle activation (CCA) sites and a negative regulatory site (NRS). Duplicate 19-bp CCA sites are present in both the copy I and copy II histone H3-H4 promoters arranged as inverted repeats separated by 45 and 68 bp. The CCA sites are both necessary and sufficient to activate transcription under cell division cycle control. A single CCA site provides cell cycle control but is a weak transcriptional activator, while an inverted repeat comprising two CCA sites provides both strong transcriptional activation and cell division cycle control. The NRS was identified in the copy I histone H3-H4 promoter. Deletion or disruption of the NRS increased the level of the histone H3 promoter activity but did not alter the cell division cycle periodicity of transcription. When the CCA sites were deleted from the histone promoter, the NRS element was unable to confer cell division cycle control on the remaining basal level of transcription. When the NRS element was inserted into the promoter of a foreign reporter gene, transcription was constitutively repressed and did not acquire cell cycle regulation.

Overlapping and CpG methylation-sensitive protein-DNA interactions at the histone H4 transcriptional cell cycle domain: distinctions between two human H4 gene promoters

Transcriptional regulation of vertebrate histone genes during the cell cycle is mediated by several factors interacting with a series of cis-acting elements located in the 5' regions of these genes. The arrangement of these promoter elements is different for each gene. However, most histone H4 gene promoters contain a highly conserved sequence immediately upstream of the TATA box (H4 subtype consensus sequence), and this region in the human H4 gene FO108 is involved in cell cycle control. The sequence-specific interaction of nuclear factor HiNF-D with this key proximal promoter element of the H4-FO108 gene is cell cycle regulated in normal diploid cells (J. Holthuis, T.A. Owen, A.J. van Wijnen, K.L. Wright, A. Ramsey-Ewing, M.B. Kennedy, R. Carter, S.C. Cosenza, K.J. Soprano, J.B. Lian, J.L. Stein, and G.S. Stein, Science, 247:1454-1457, 1990). Here, we show that this region of the H4-FO108 gene represents a composite protein-DNA interaction domain for several distinct sequence-specific DNA-binding activities, including HiNF-D, HiNF-M, and HiNF-P. Factor HiNF-P is similar to H4TF-2, a DNA-binding activity that is not cell cycle regulated and that interacts with the analogous region of the H4 gene H4.A (F. LaBella and N. Heintz, Mol. Cell. Biol. 11:5825-5831, 1991). The H4.A gene fails to interact with factors HiNF-M and HiNF-D owing to two independent sets of specific nucleotide variants, indicating differences in protein-DNA interactions between these H4 genes. Cytosine methylation of a highly conserved CpG dinucleotide interferes with binding of HiNF-P/H4TF-2 to both the H4-FO108 and H4.A promoters, but no effect is observed for either HiNF-M or HiNF-D binding to the H4-FO108 gene. Thus, strong evolutionary conservation of the H4 consensus sequence may be related to combinatorial interactions involving overlapping and interdigitated recognition nucleotides for several proteins, whose activities are regulated independently. Our results also suggest molecular complexity in the transcriptional regulation of distinct human H4 genes.

Overlapping and CpG methylation-sensitive protein-DNA interactions at the histone H4 transcriptional cell cycle domain: distinctions between two human H4 gene promoters

Transcriptional regulation of vertebrate histone genes during the cell cycle is mediated by several factors interacting with a series of cis-acting elements located in the 5' regions of these genes. The arrangement of these promoter elements is different for each gene. However, most histone H4 gene promoters contain a highly conserved sequence immediately upstream of the TATA box (H4 subtype consensus sequence), and this region in the human H4 gene FO108 is involved in cell cycle control. The sequence-specific interaction of nuclear factor HiNF-D with this key proximal promoter element of the H4-FO108 gene is cell cycle regulated in normal diploid cells (J. Holthuis, T.A. Owen, A.J. van Wijnen, K.L. Wright, A. Ramsey-Ewing, M.B. Kennedy, R. Carter, S.C. Cosenza, K.J. Soprano, J.B. Lian, J.L. Stein, and G.S. Stein, Science, 247:1454-1457, 1990). Here, we show that this region of the H4-FO108 gene represents a composite protein-DNA interaction domain for several distinct sequence-specific DNA-binding activities, including HiNF-D, HiNF-M, and HiNF-P. Factor HiNF-P is similar to H4TF-2, a DNA-binding activity that is not cell cycle regulated and that interacts with the analogous region of the H4 gene H4.A (F. LaBella and N. Heintz, Mol. Cell. Biol. 11:5825-5831, 1991). The H4.A gene fails to interact with factors HiNF-M and HiNF-D owing to two independent sets of specific nucleotide variants, indicating differences in protein-DNA interactions between these H4 genes. Cytosine methylation of a highly conserved CpG dinucleotide interferes with binding of HiNF-P/H4TF-2 to both the H4-FO108 and H4.A promoters, but no effect is observed for either HiNF-M or HiNF-D binding to the H4-FO108 gene. Thus, strong evolutionary conservation of the H4 consensus sequence may be related to combinatorial interactions involving overlapping and interdigitated recognition nucleotides for several proteins, whose activities are regulated independently. Our results also suggest molecular complexity in the transcriptional regulation of distinct human H4 genes.

Tissue restricted expression and chromosomal localization of the YB-1 gene encoding a 42 kD nuclear CCAAT binding protein

YB-1 cDNA clones were isolated by binding site screening of a Hela expression library using a human papillomavirus type 18 enhancer oligonucleotide. YB-1 belongs to a family of transcription factors which bind to recognition sequences containing a core CCAAT element. YB-1 bound to its single stranded recognition sequence on the sense strand but not to the anti-sense strand. A synthetic peptide antiserum derived from the predicted YB-1 amino acid sequence identified a 42 kD nuclear protein in immunoblots. A protein with the same size was detected by binding site blotting experiments using the HPV18 enhancer oligonucleotide which bound YB-1. YB-1 gene expression was restricted in tissues from a human 24 week old fetus. High levels of YB-1 mRNA were present in heart, muscle, liver, lung, adrenal gland and the brain, in contrast, low amounts of YB-1 mRNA were found in thymus, kidney, bone marrow and spleen. In pancreas, bladder, stomach and testis YB-1 mRNA could not be detected by Northern hybridization. Finally, we have identified four YB-1 related loci in the mouse genome and have mapped these loci to four different mouse chromosomes by interspecific backcross analysis.

Unusual DNA binding characteristics of an in vitro translation product of the CCAAT binding protein mYB-1

We have isolated a cDNA that encodes the murine CCAAT-binding protein mYB-1. The deduced amino acid sequence shows 95% identity with its presumed human homologue (hYB-1A) which was originally isolated as a protein that binds to the Y box of MHC class II genes. In vitro translated mYB-1 binds to CCAAT boxes of the MHCIIE alpha, HSVTK and mouse PCNA promoters but not to alpha-globin or human thymidine kinase CCAAT boxes. Interestingly, complexes formed between the in vitro translated protein and the various CCAAT boxes display the property of being competed more efficiently with self competitor DNA, regardless of the CCAAT box initially used as a probe. A similar phenomenon was observed in a cell extract of Con-A stimulated murine splenocytes when the same competition assays were performed. These results may reflect the generation of multiple forms of a particular CCAAT-binding protein, such as mYB-1, that display distinct, yet overlapping, DNA binding specificities.

Identification and functional characterization of a cis-acting positive DNA element regulating CYP 2B1/B2 gene transcription in rat liver

A positive cis-acting DNA element in the near 5'-upstream region of the CYP2B1/B2 genes in rat liver was found to play an important role in the transcription of these genes. An oligonucleotide covering -69 to -98 nt mimicked the gel mobility shift pattern given by the fragment -179 to +29 nt, which was earlier found adequate to confer the regulatory features of this gene. Two major complexes were seen, of which the slower and faster moving complexes became intense under uninduced and Phenobarbitone-induced conditions respectively. Minigene cloned DNA plasmid covering -179 to +181 nt in pUC 19 and Bal 31 mutants derived from this parent were transcribed in whole nuclei and cell free transcription extracts and mutants containing only upto -75 nt of the upstream were poorly transcribed. Transcription extracts from phenobarbitone-injected rat liver nuclei were significantly more active than extracts from uninduced rats in transcribing the minigene constructs. Addition of the oligonucleotide (-69 to -98nt) specifically inhibited the transcription of the minigene construct (-179 to +181 nt) in the cell free transcription system. It is therefore, concluded that the region -69 to -98 nt acts as a positive cis-acting element in the transcription of the CYP2B1/B2 genes and in mediating the inductive effects of phenobarbitone.

Histone gene transcription factor binding in extracts of normal human cells

Transcriptional regulation of mammalian histone genes during S phase is achieved through activation of specific factors which interact with subtype-specific histone gene promoter sequences. It has previously been shown that in HeLa cells this induction is not mediated by obligatory changes in the DNA binding activity of histone gene transcription factors as cells progress through the cell cycle. Recently, it has been reported that the DNA binding properties of a putative histone gene transcription factor may be quite different in normal and transformed cells (J. Holthuis, T. A. Owen, A. J. van Wijnen, K. L. Wright, A. Ramsey-Ewing, M. B. Kennedy, R. Carter, S. C. Cosenza, K. J. Soprano, J. B. Lian, J. L. Stein, and G. S. Stein, Science 247:1454-1457, 1990). To determine whether the properties of well-characterized histone gene transcription factors are altered in transformed versus normal cells, we have examined the DNA binding activity of human histone transcription factors during the WI38 (a primary line of normal human fetal lung fibroblasts) cell cycle. The results demonstrate that the properties of Oct1, H4TF1, and H4TF2 are similar in WI38 and HeLa cells and that their DNA binding activities are constitutive during interphase of both normal and transformed cell lines. Although it remains possible that these factors are directly or indirectly perturbed as a result of cellular transformation, it appears unlikely that transformation results in gross changes in DNA binding activity as cells progress toward division.

Histone gene transcription factor binding in extracts of normal human cells

Transcriptional regulation of mammalian histone genes during S phase is achieved through activation of specific factors which interact with subtype-specific histone gene promoter sequences. It has previously been shown that in HeLa cells this induction is not mediated by obligatory changes in the DNA binding activity of histone gene transcription factors as cells progress through the cell cycle. Recently, it has been reported that the DNA binding properties of a putative histone gene transcription factor may be quite different in normal and transformed cells (J. Holthuis, T. A. Owen, A. J. van Wijnen, K. L. Wright, A. Ramsey-Ewing, M. B. Kennedy, R. Carter, S. C. Cosenza, K. J. Soprano, J. B. Lian, J. L. Stein, and G. S. Stein, Science 247:1454-1457, 1990). To determine whether the properties of well-characterized histone gene transcription factors are altered in transformed versus normal cells, we have examined the DNA binding activity of human histone transcription factors during the WI38 (a primary line of normal human fetal lung fibroblasts) cell cycle. The results demonstrate that the properties of Oct1, H4TF1, and H4TF2 are similar in WI38 and HeLa cells and that their DNA binding activities are constitutive during interphase of both normal and transformed cell lines. Although it remains possible that these factors are directly or indirectly perturbed as a result of cellular transformation, it appears unlikely that transformation results in gross changes in DNA binding activity as cells progress toward division.

Identification of a 70-base-pair cell cycle regulatory unit within the promoter of the human thymidine kinase gene and its interaction with cellular factors

The promoter of the human thymidine kinase gene contains cis-regulatory elements responsible for its cell-cycle-regulated expression. We report here that a 70-bp region between -133 and -64 is sufficient to confer cell cycle regulation on a heterologous promoter. The 20-bp region between -64 and -83, which contains an inverted CCAAT motif, is important for transcriptional stimulation of this functional unit. The sequence of this CCAAT motif is nearly identical to the consensus sequence for the transcriptional factor CP1. We also examined the specificity and binding activities of cellular factors interacting with the 70-bp fragment. We showed that the cellular factors binding to the 70-bp region are similar during the G1, S, and G2 phases, suggesting that the cell cycle regulatory activity observed must involve processes other than factor binding to the DNA.

Identification of a 70-base-pair cell cycle regulatory unit within the promoter of the human thymidine kinase gene and its interaction with cellular factors

The promoter of the human thymidine kinase gene contains cis-regulatory elements responsible for its cell-cycle-regulated expression. We report here that a 70-bp region between -133 and -64 is sufficient to confer cell cycle regulation on a heterologous promoter. The 20-bp region between -64 and -83, which contains an inverted CCAAT motif, is important for transcriptional stimulation of this functional unit. The sequence of this CCAAT motif is nearly identical to the consensus sequence for the transcriptional factor CP1. We also examined the specificity and binding activities of cellular factors interacting with the 70-bp fragment. We showed that the cellular factors binding to the 70-bp region are similar during the G1, S, and G2 phases, suggesting that the cell cycle regulatory activity observed must involve processes other than factor binding to the DNA.

Involvement of the cell cycle-regulated nuclear factor HiNF-D in cell growth control of a human H4 histone gene during hepatic development in transgenic mice

Regulation of the cell cycle-controlled histone gene promoter factor HiNF-D was examined in vivo. Proliferative activity was measured by DNA replication-dependent histone mRNA levels, and HiNF-D binding activity was found to correlate with cell proliferation in most tissues. Furthermore, HiNF-D is down-regulated during hepatic development, reflecting the onset of differentiation and quiescence. The contribution of transcription to histone gene expression was directly addressed in transgenic mice by using a set of fusion constructs containing a human H4 histone gene promoter linked to three different genes. Transgene expression in both fetal and adult mice paralleled endogenous mouse histone mRNA levels in most tissues, consistent with this promoter conferring developmental, cell growth-related transcriptional regulation. Our results suggest that HiNF-D is stringently regulated in vivo in relation to cell growth and support a primary role for HiNF-D in the proliferation-specific expression of H4 histone genes in the intact animal. Further, the data presented here provide an example in which apparent tissue specificity of gene expression reflects the proliferative state of various tissues and demonstrate that multiple levels of histone gene regulation are operative in vivo.

A variant octamer motif in a Xenopus H2B histone gene promoter is not required for transcription in frog oocytes

Xenopus oocytes, arrested in G2 before the first meiotic division, accumulate histone mRNA and protein in the absence of chromosomal DNA replication and therefore represent an attractive biological system in which to examine histone gene expression uncoupled from the cell cycle. Previous studies have shown that sequences necessary for maximal levels of transcription in oocytes are present within 200 bp at the 5' end of the transcription initiation site for genes encoding each of the five major Xenopus histone classes. We have defined by site-directed mutagenesis individual regulatory sequences and characterized DNA-binding proteins required for histone H2B gene transcription in injected oocytes. The Xenopus H2B gene has a relatively simple promoter containing several transcriptional regulatory elements, including TFIID, CBP, and ATF/CREB binding sites, required for maximal transcription. A sequence (CTTTACAT) in the H2B promoter resembling the conserved octamer motif (ATTTGCAT), the target for cell-cycle regulation of a human H2B gene, is not required for transcription in oocytes. Nonetheless, substitution of a consensus octamer motif for the variant octamer element activates H2B transcription. Oocyte factors, presumably including the ubiquitous Oct-1 factor, specifically bind to the consensus octamer motif but not to the variant sequence. Our results demonstrate that a transcriptional regulatory element involved in lymphoid-specific expression of immunoglobulin genes and in S-phase-specific activation of mammalian H2B histone genes can activate transcription in nondividing amphibian oocytes.

A variant octamer motif in a Xenopus H2B histone gene promoter is not required for transcription in frog oocytes

Xenopus oocytes, arrested in G2 before the first meiotic division, accumulate histone mRNA and protein in the absence of chromosomal DNA replication and therefore represent an attractive biological system in which to examine histone gene expression uncoupled from the cell cycle. Previous studies have shown that sequences necessary for maximal levels of transcription in oocytes are present within 200 bp at the 5' end of the transcription initiation site for genes encoding each of the five major Xenopus histone classes. We have defined by site-directed mutagenesis individual regulatory sequences and characterized DNA-binding proteins required for histone H2B gene transcription in injected oocytes. The Xenopus H2B gene has a relatively simple promoter containing several transcriptional regulatory elements, including TFIID, CBP, and ATF/CREB binding sites, required for maximal transcription. A sequence (CTTTACAT) in the H2B promoter resembling the conserved octamer motif (ATTTGCAT), the target for cell-cycle regulation of a human H2B gene, is not required for transcription in oocytes. Nonetheless, substitution of a consensus octamer motif for the variant octamer element activates H2B transcription. Oocyte factors, presumably including the ubiquitous Oct-1 factor, specifically bind to the consensus octamer motif but not to the variant sequence. Our results demonstrate that a transcriptional regulatory element involved in lymphoid-specific expression of immunoglobulin genes and in S-phase-specific activation of mammalian H2B histone genes can activate transcription in nondividing amphibian oocytes.

Transcriptional control of the rat hepatic CYP2E1 gene

The rat hepatic CYP2E1 gene becomes transcriptionally activated within 1 day after birth. This activation can be mimicked by using the 5' end of the gene in a cell-free nuclear extract prepared from hepatocytes taken from rats at different developmental stages. Deletion analysis revealed that a positive element located between -127 and -89 was responsible for 90% of the in vitro transcription activity of adult liver extracts. Protein binding studies revealed that this region was operationally equivalent to the binding site for the factor HNF-1. Two other protein-binding regions were uncovered, one of which corresponded to the site for a CCAAT-binding factor NFY. The other site was a palindrome sequence unique to the CYP2E1 gene. These latter two factors did not significantly contribute to transcriptional activity in vitro and were not conserved between the rat and human CYP2E1 genes. Extracts prepared from fetal and newborn livers were transcriptionally inactive, whereas extracts from livers of 3-day-old rats were fully active toward the CYP2E1 gene. DNase I footprinting patterns indistinguishable between fetal and adult extracts were obtained for all three factors. However, gel mobility shift assays revealed a second, higher-mobility band produced by fetal and newborn liver extracts bound to the HNF-1 oligomer. UV-cross-linking studies showed that adult and fetal extracts had only a single 98-kilodalton protein that bound to this oligomer. In contrast, adult lung samples, also transcriptionally inactive toward the CYP2E1 gene, contained two proteins of slightly greater than 110 kilodaltons. These results suggest that the CYP2E1 gene is positively regulated in adult rats by HNF-1 or a protein similar in DNA-binding properties to HNF-1. The role of this factor or other protein-protein interactions in the lack of CYP2E1 transcription in fetal and newborn animals remains unclear.

Transcriptional control of the rat hepatic CYP2E1 gene

The rat hepatic CYP2E1 gene becomes transcriptionally activated within 1 day after birth. This activation can be mimicked by using the 5' end of the gene in a cell-free nuclear extract prepared from hepatocytes taken from rats at different developmental stages. Deletion analysis revealed that a positive element located between -127 and -89 was responsible for 90% of the in vitro transcription activity of adult liver extracts. Protein binding studies revealed that this region was operationally equivalent to the binding site for the factor HNF-1. Two other protein-binding regions were uncovered, one of which corresponded to the site for a CCAAT-binding factor NFY. The other site was a palindrome sequence unique to the CYP2E1 gene. These latter two factors did not significantly contribute to transcriptional activity in vitro and were not conserved between the rat and human CYP2E1 genes. Extracts prepared from fetal and newborn livers were transcriptionally inactive, whereas extracts from livers of 3-day-old rats were fully active toward the CYP2E1 gene. DNase I footprinting patterns indistinguishable between fetal and adult extracts were obtained for all three factors. However, gel mobility shift assays revealed a second, higher-mobility band produced by fetal and newborn liver extracts bound to the HNF-1 oligomer. UV-cross-linking studies showed that adult and fetal extracts had only a single 98-kilodalton protein that bound to this oligomer. In contrast, adult lung samples, also transcriptionally inactive toward the CYP2E1 gene, contained two proteins of slightly greater than 110 kilodaltons. These results suggest that the CYP2E1 gene is positively regulated in adult rats by HNF-1 or a protein similar in DNA-binding properties to HNF-1. The role of this factor or other protein-protein interactions in the lack of CYP2E1 transcription in fetal and newborn animals remains unclear.