Initiation zone of DNA replication at the aldolase B locus encompasses transcription promoter region

Separase prevents genomic instability by controlling replication fork speed

Proper chromosome segregation is crucial for preserving genomic integrity, and errors in this process cause chromosome mis-segregation, which may contribute to cancer development. Sister chromatid separation is triggered by Separase, an evolutionary conserved protease that cleaves the cohesin complex, allowing the dissolution of sister chromatid cohesion. Here we provide evidence that Separase participates in genomic stability maintenance by controlling replication fork speed. We found that Separase interacted with the replication licensing factors MCM2-7, and genome-wide data showed that Separase co-localized with MCM complex and cohesin. Unexpectedly, the depletion of Separase increased the fork velocity about 1.5-fold and caused a strong acetylation of cohesin's SMC3 subunit and altered checkpoint response. Notably, Separase silencing triggered genomic instability in both HeLa and human primary fibroblast cells. Our results show a novel mechanism for fork progression mediated by Separase and thus the basis for genomic instability associated with tumorigenesis.

Binding of AlF-C, an Orc1-binding transcriptional regulator, enhances replicator activity of the rat aldolase B origin

A region encompassing the rat aldolase B gene (aldB) promoter acts as a chromosomal origin of DNA replication (origin) in rat aldolase B-nonexpressing hepatoma cells. To examine replicator function of the aldB origin, we constructed recombinant mouse cell lines in which the rat aldB origin and the mutant derivatives were inserted into the same position at the mouse chromosome 8 by cre-mediated recombination. Nascent strand abundance assays revealed that the rat origin acts as a replicator at the ectopic mouse locus. Mutation of site C in the rat origin, which binds an Orc1-binding protein AlF-C in vitro, resulted in a significant reduction of the replicator activity in the mouse cells. Chromatin immunoprecipitation (ChIP) assays indicated that the reduction of replicator activity was paralleled with the reduced binding of AlF-C and Orc1, suggesting that sequence-specific binding of AlF-C to the ectopic rat origin leads to enhanced replicator activity in cooperation with Orc1. Involvement of AlF-C in replication in vivo was further examined for the aldB origin at its original rat locus and for a different rat origin identified in the present study, which contained an AlF-C-binding site. ChIP assays revealed that both replication origins bind AlF-C and Orc1. We think that the results presented here may represent one mode of origin recognition in mammalian cells.

Replication initiation from a novel origin identified in the Th2 cytokine cluster locus requires a distant conserved noncoding sequence

Lineage commitment of Th cells is associated with the establishment of specific transcriptional programs of cytokines. However, how Th cell differentiation affects the program of DNA replication has not been addressed. To gain insight into interplays between differentiation-induced transcription regulation and initiation of DNA replication, we took advantage of an in vitro differentiation system of naive T cells, in which one can manipulate their differentiation into Th1 or Th2 cells. We searched for replication origins in the murine IL-4/IL-13 locus and compared their profiles in the two Th cell lineages which were derived in vitro from the same precursor T cells. We identified a replication origin (ori(IL-13)) downstream from exon 4 of IL-13 and showed that this origin functions in both Th2 and Th1 cells. A distant regulatory element called CNS-1 (conserved noncoding sequence 1) in the IL-4/IL-13 intergenic region coincides with a Th2-specific DNase I-hypersensitive site and is required for efficient, coordinated expression of Th2 cytokines. Replication initiation from ori(IL-13) is significantly reduced in Th1 and Th2 cells derived from CNS-1-deficient mice. However, the replication timing of this locus is consistently early during S phase in both Th1 and Th2 cells under either the wild-type or CNS-1 deletion background. Thus, the conserved noncoding element in the intergenic region regulates replication initiation from a distant replication origin in a manner independent from its effect on lineage-specific transcription but not the replication timing of the segment surrounding this origin.

A binding site for Pur alpha and Pur beta is structurally unstable and is required for replication in vivo from the rat aldolase B origin

The rat aldolase B promoter acts as a replication origin in vivo, as well as an autonomously replicating sequence (ARS). Here, we examined roles of a polypurine stretch (site PPu) in this origin, which is indispensable to the ARS activity. Purification of site PPu-binding protein revealed that site PPu binds Puralpha and Purbeta, i.e., single-stranded DNA-binding proteins whose roles in replication have been implicated, but less clear. Biochemical analyses showed that site PPu even in a longer DNA fragment is unstable in terms of double-helix, implying that Puralpha/beta may stabilize single-stranded state. Deletion of site PPu from the origin DNA, which was ectopically positioned in the mouse chromosome, significantly reduced replicator activity. Chromatin immunoprecipitation experiments showed that deletion of site PPu abolishes binding of the Puralpha/beta proteins to the origin. These observations suggest functional roles of site PPu and Puralpha/beta proteins in replication initiation.

Heterochromatin on the inactive X chromosome delays replication timing without affecting origin usage

DNA replication origins (ORIs) map close to promoter regions in many organisms, including mammals. However, the relationship between initiation of replication and transcription is not well understood. To address this issue, we have analyzed replication timing and activity of several CpG island-associated ORIs on the transcriptionally active and silent X chromosomes. We find equivalent ORI usage and efficiency of both alleles at sites that are replicated late on the inactive X chromosome. Thus, in contrast to its repressive effect on transcription, heterochromatin does not influence ORI activity. These findings suggest that the relationship between sites of transcription and replication initiation at CpG island regions is restricted to early development, and that subsequent gene silencing and heterochromatin formation influence only the timing of ORI activation.

Identification of a cis-element that determines autonomous DNA replication in eukaryotic cells

A 36-bp human consensus sequence (CCTMDAWKSGBYTSMAAWTWBCMYTTRSCAAATTCC) is capable of supporting autonomous replication of a plasmid after transfection into eukaryotic cells. After transfection and in vitro DNA replication, replicated plasmid DNA containing a mixture of oligonucleotides of this consensus was found to reiterate the consensus. Initiation of DNA replication in vitro occurs within the consensus. One version, A3/4, in pYACneo, could be maintained under selection in HeLa cells, unrearranged and replicating continuously for >170 cell doublings. Stability of plasmid without selection was high (> or =0.9/cell/generation). Homologs of the consensus are found consistently at mammalian chromosomal sites of initiation and within CpG islands. Versions of the consensus function as origins of DNA replication in normal and malignant human cells, immortalized monkey and mouse cells, and normal cow, chicken, and fruit fly cells. Random mutagenesis studies suggest an internal 20-bp consensus sequence of the 36 bp may be sufficient to act as a core origin element. This cis-element consensus sequence is an opportunity for focused analyses of core origin elements and the regulation of initiation of DNA replication.

Functional domains involved in the interaction between Orc1 and transcriptional repressor AlF-C that bind to an origin/promoter of the rat aldolase B gene

The promoter of the rat aldolase B (AldB) gene functions in vivo as an origin of DNA replication in the cells in which transcription of the gene is repressed. Previously, we identified two closely related DNA-binding proteins, AlF-C1 and AlF-C2, which repressed the AldB gene promoter. We also reported that the binding site of these proteins, site C, is one of the required DNA elements of the AldB gene origin/promoter for autonomously replicating activity in transfected cells. In the present study, we show that AlF-C1 and AlF-C2 bind directly to Orc1, a subunit of the origin recognition complex (ORC). Deletion analyses revealed a functional domain in AlF-C2 for binding to Orc1, which is located separately from the DNA-binding domain. In addition, we found a novel protein-interacting domain in Orc1 required for the binding of AlF-C2, which was conserved in human, mouse and Chinese hamster, but not in Drosophila, frog and yeast. Thus, it is assumed that in mammalian cells, sequence- specific DNA-binding proteins are involved in recruiting ORC to regulate replication initiation and/or transcription repression.

Replication of the rat aldolase B locus differs between aldolase B-expressing and non-expressing cells

We previously reported a rat chromosomal origin of DNA replication (oriA1) that encompassed the aldolase B (AldB) gene promoter. Here, we examined utilization of oriA1 in AldB-expressing and non-expressing cells. The results suggested the occurrence of mutually exclusive regulation between DNA replication and transcription. Nascent strand abundance as assayed by competitive polymerase chain reaction using bromodeoxyuridine-labeled nascent DNA indicated that oriA1 is not utilized in AldB-expressing cells, while it is fired in non-expressing cells. In the latter non-expressing cells, the replication fork seemed to slow at 20-22 kb downstream of oriA1.

A novel growth-related nuclear protein binds and inhibits rat aldolase B gene promoter

The promoter of the rat aldolase B (AldB) gene that confers liver-specific transcription has an additional role. It functions in vivo as an origin region of DNA replication in the cells in which the gene is repressed (Zhao, Y., Tsutsumi, R., Yamaki, M., Nagatsuka, N., Ejiri, S., Tsutsumi, K., 1994. Initiation zone of DNA replication at the rat aldolase B locus encompasses transcription promoter region. Nucleic Acids Res. 22, 5385-5390). This promoter/origin region has multiple protein-binding sites and, thus, binding of a particular set of protein factors in AldB-expressing or non-expressing cells seems to correlate with functional switch of this promoter/origin region. In the present study, we characterized two closely related proteins, termed AlF-C1 and AlF-C2, which are assumed to be involved in repression of the AldB gene. These two proteins share an identical amino acid sequence except for a 47-residue-insertion in AlF-C1, and are members of a gene family including heterogeneous nuclear ribonucleoprotein (hnRNP) and CCAAT-binding factor subunit A (CBF-A) genes. Bacterially expressed AlF-C1 can bind sequence-specifically to the AldB gene promoter, whereas AlF-C2 can only weakly. Transfection experiments using mammalian expression vectors showed that AlF-C1 down-regulates the AldB gene promoter in rat hepatoma cells, while AlF-C2 had no or little effect. Expressions of mRNAs encoding these two proteins are enriched in fetal livers and in regenerating livers. These results implied that AlF-C1 and/or C2 is involved in growth-regulated repression of the AldB gene.

An overlapping set of DNA elements in the rat aldolase B gene origin/promoter regulates transcription and autonomous replication

Promoter of the rat aldolase B (AldB) gene is centered on an origin of chromosomal DNA replication in vivo, and it directs autonomous replication upon transfection into cultured cells. Previous studies showed that the 200 bp promoter fragment is necessarily required for the autonomous replication. Here, we identified three cis-elements required for replication within the 200 bp promoter, using autonomously replicating plasmids carrying various mutations and deletions. One is an element that is previously defined as a regulatory element for liver-specific transcription (site C). Other two, purine-rich (site PPu) and A (T)-rich (site A/T) sequences, were those often found in eukaryotic origin regions. Sites C and PPu were found to bind specific nuclear factors in transfected cells, and the results of competitive binding assay implied direct or indirect interaction between sites C and PPu.

Initiation of eukaryotic DNA replication: conservative or liberal?

The mechanism for initiation of eukaryotic DNA replication is highly conserved: the proteins required to initiate replication, the sequence of events leading to initiation, and the regulation of initiation are remarkably similar throughout the eukaryotic kingdom. Nevertheless, there is a liberal attitude when it comes to selecting initiation sites. Differences appear to exist in the composition of replication origins and in the way proteins recognize these origins. In fact, some multicellular eukaryotes (the metazoans) can change the number and locations of initiation sites during animal development, revealing that selection of initiation sites depends on epigenetic as well as genetic parameters. Here we have attempted to summarize our understanding of this process, to identify the similarities and differences between single cell and multicellular eukaryotes, and to examine the extent to which origin recognition proteins and replication origins have been conserved among eukaryotes. Published 2000 Wiley-Liss, Inc.

Interference of the simian virus 40 origin of replication by the cytomegalovirus immediate early gene enhancer: evidence for competition of active regulatory chromatin conformation in a single domain

Replication origins are often found closely associated with transcription regulatory elements in both prokaryotic and eukaryotic cells. To examine the relationship between these two elements, we studied the effect of a strong promoter-enhancer on simian virus 40 (SV40) DNA replication. The human cytomegalovirus (CMV) immediate early gene enhancer-promoter was found to exert a strong inhibitory effect on SV40 origin-based plasmid replication in Cos-1 cells in a position- and dose-dependent manner. Deletion analysis indicated that the effect was exerted by sequences located in the enhancer portion of the CMV sequence, thus excluding the mechanism of origin occlusion by transcription. Insertion of extra copies of the SV40 origin only partially alleviated the inhibition. Analysis of nuclease-sensitive cleavage sites of chromatin containing the transfected plasmids indicate that the chromatin was cleaved at one of the regulatory sites in the plasmids containing more than one regulatory site, suggesting that only one nuclease-hypersensitive site existed per chromatin. A positive correlation was found between the degree of inhibition of DNA replication and the decrease of P1 cleavage frequency at the SV40 origin. The CMV enhancer was also found to exhibit an inhibitory effect on the CMV enhancer-promoter driving chloramphenicol acetyltransferase expression in a dose-dependent manner. Together these results suggest that inhibition of SV40 origin-based DNA replication by the CMV enhancer is due to intramolecular competition for the formation of active chromatin structure.

Selection and mapping of replication origins from a 500-kb region of the human X chromosome and their relationship to gene expression

In higher eukaryotes the mechanism controlling initiation of DNA replication remains largely unknown. New technologies are needed to shed light on how DNA replication initiates along the genome in specific regions. To identify the human DNA sequence requirements for initiation of replication, we developed a new method that allows selection of replication origins starting from large genomic regions of human DNA. We repeatedly isolated 15 new putative replication origins (PROs) from a human DNA region of 500 kb in which 17 genes have previously been characterized. Fine-mapping of these PROs showed that DNA replication can initiate at many specific points along actively transcribed DNA in the cell lines used for our selection. In conclusion, in this paper we describe a new method to identify PROs that suggests that the availability of initiation sites is dependent on the transcriptional state of the DNA.

CpG islands as genomic footprints of promoters that are associated with replication origins

The primary target for DNA methylation in mammalian genomes is cytosine in the dinucleotide CpG. High densities of CpG dinucleotides are found in CpG islands, but paradoxically CpG islands are normally in a non-methylated state. Here, we speculate why CpG islands are immune to methylation and why they are so rich in guanine and cytosine relative to the surrounding DNA. We propose that CpG islands are associated with promoters that are transcriptionally active at totipotent stages of development and can also act as origins of DNA replication. CpG islands may be 'footprints' caused by early DNA replication intermediates at dual function promoters of this kind.

Differentiation-related mechanisms which suppress DNA replication

Differentiation of mammalian cells implies cessation of DNA replication and cell proliferation; the potential controls of this coupling are examined here. It is clear that the known or proposed mechanisms of down-regulation of replicative cellular activities vary in different lineages of cell differentiation, and occur in all phases of the cell cycle. In G1 these regulators include p21/Cip1 or p27/Kip1, pRb, and p53; the novel, recently reported mechanisms of their action are summarized. In S phase the availability of nucleotide precursors, the origin recognition complex (ORC), and other replication proteins may be important in differentiation, and in G2 phase the cdc2/cyclin B complex and replication licensing factors determine normal G2 traverse versus an arrest or polyploidisation. Other replication-related mechanisms include transcription factors, e.g., Sp1, telomerase, and nuclear matrix changes. Thus, differentiation alters the activity not only of the various checkpoint proteins, but also of the components of the replicative machinery itself.

Replication origins in metazoan chromosomes: fact or fiction?

The process by which eukaryotic cells decide when and where to initiate DNA replication has been illuminated in yeast, where specific DNA sequences (replication origins) bind a unique group of proteins (origin recognition complex) next to an easily unwound DNA sequence at which replication can begin. The origin recognition complex provides a platform on which additional proteins assemble to form a pre-replication complex that can be activated at S-phase by specific protein kinases. Remarkably, multicellular eukaryotes, such as frogs, flies, and mammals (metazoa), have counterparts to these yeast proteins that are required for DNA replication. Therefore, one might expect metazoan chromosomes to contain specific replication origins as well, a hypothesis that has long been controversial. In fact, recent results strongly support the view that DNA replication origins in metazoan chromosomes consist of one or more high frequency initiation sites and perhaps several low frequency ones that together can appear as a nonspecific initiation zone. Specific replication origins are established during G1-phase of each cell cycle by multiple parameters that include nuclear structure, chromatin structure, DNA sequence, and perhaps DNA modification. Such complexity endows metazoa with the flexibility to change both the number and locations of replication origins in response to the demands of animal development.

Identification of primary initiation sites for DNA replication in the hamster dihydrofolate reductase gene initiation zone

Mammalian replication origins appear paradoxical. While some studies conclude that initiation occurs bidirectionally from specific loci, others conclude that initiation occurs at many sites distributed throughout large DNA regions. To clarify this issue, the relative number of early replication bubbles was determined at 26 sites in a 110-kb locus containing the dihydrofolate reductase (DHFR)-encoding gene in CHO cells; 19 sites were located within an 11-kb sequence containing ori-beta. The ratio of approximately 0.8-kb nascent DNA strands to nonreplicated DNA at each site was quantified by competitive PCR. Nascent DNA was defined either as DNA that was labeled by incorporation of bromodeoxyuridine in vivo or as RNA-primed DNA that was resistant to lambda-exonuclease. Two primary initiation sites were identified within the 12-kb region, where two-dimensional gel electrophoresis previously detected a high frequency of replication bubbles. A sharp peak of nascent DNA occurred at the ori-beta origin of bidirectional replication where initiation events were 12 times more frequent than at distal sequences. A second peak occurred 5 kb downstream at a previously unrecognized origin (ori-beta'). Thus, the DHFR gene initiation zone contains at least three primary initiation sites (ori-beta, ori-beta', and ori-gamma), suggesting that initiation zones in mammals, like those in fission yeast, consist of multiple replication origins.

Hereditary fructose intolerance

Hereditary fructose intolerance (HFI, OMIM 22960), caused by catalytic deficiency of aldolase B (fructose-1,6-bisphosphate aldolase, EC 4.1.2.13), is a recessively inherited condition in which affected homozygotes develop hypoglycaemic and severe abdominal symptoms after taking foods containing fructose and cognate sugars. Continued ingestion of noxious sugars leads to hepatic and renal injury and growth retardation; parenteral administration of fructose or sorbitol may be fatal. Direct detection of a few mutations in the human aldolase B gene on chromosome 9q facilitates the genetic diagnosis of HFI in many symptomatic patients. The severity of the disease phenotype appears to be independent of the nature of the aldolase B gene mutations so far identified. It appears that hitherto there has been little, if any, selection against mutant aldolase B alleles in the population: in the UK, approximately 1.3% of neonates harbour one copy of the prevalent A149P disease allele. The ascendance of sugar as a major dietary nutrient, especially in western societies, may account for the increasing recognition of HFI as a nutritional disease and has shown the prevalence of mutant aldolase B genes in the general population. The severity of clinical expression correlates well with the immediate nutritional environment, age, culture, and eating habits of affected subjects. Here we review the biochemical, genetic, and molecular basis of human aldolase B deficiency in HFI, a disorder which responds to dietary therapy and in which the principal manifestations of disease are thus preventable.

Initiation of DNA replication at CpG islands in mammalian chromosomes

CpG islands are G+C-rich regions approximately 1 kb long that are free of methylation and contain the promoters of many mammalian genes. Analysis of in vivo replication intermediates at three hamster genes and one human gene showed that the CpG island regions, but not their flanks, were present in very short nascent strands, suggesting that they are replication origins (ORIs). CpG island-like fragments were enriched in a population of short nascent strands from human erythroleukaemic cells, suggesting that islands constitute a significant fraction of endogenous ORIs. Correspondingly, bulk CpG islands were found to replicate coordinately early in S phase. Our results imply that CpG islands are initiation sites for both transcription and DNA replication, and may represent genomic footprints of replication initiation.

Mapping replication origins by nascent DNA strand length

The mapping of replication origins by nascent DNA strand length determination is a very sensitive generally applicable method that identifies even single-copy origins in mammalian chromosomes. A major advantage of this procedure is that there is no need for synchronization of cells or treatment with metabolic agents, which allows the origin to be studied under physiological conditions. This technique is based upon the amplification of specific sequence markers on nascent DNA strands that initiated replication within the region of the putative origin. Therefore, this method requires detailed sequence information of the locus to be analyzed. As a first step, nascent DNA of proliferating cells is pulse-labeled with BrdU followed by size fractionation and purification with anti-BrdU antibodies. The position of putative origins can then be determined via identification of the shortest nascent strands that can be amplified by PCR and hybridized to probes homologous to the amplified segments. Here, we give a detailed description of the theory behind the method and a full recipe for its application. Advantages and limitations of the procedure are discussed.

Sequence requirement for replication initiation at the rat aldolase B locus implicated in its functional correlation with transcriptional regulation

Transcription promoter of the aldolase B gene was previously shown to be centered on an initiation region of DNA replication in rat hepatoma cells in vivo. Here, we defined an essential region required for replication in a plasmid form upon transfection. Deletion analyses around the origin region revealed that the proximal 200 bp promoter was necessary, but not sufficient for replication as flanking sequence restored replication activity. Therefore, the 200 bp region seemed to cooperate with the flanking sequence to play an important role in replication. Electrophoretic mobility shift assays using nuclear extracts from synchronously growing hepatoma cells showed that some protein factors bound to this region in a cell cycle-regulated manner. Since transcription of the aldolase B gene is repressed in the hepatoma cells, the cell cycle-regulated protein-binding is considered to be involved in regulation of replication initiation.

Induction of DNA replication by transcription in the region upstream of the human c-myc gene in a model replication system

An important relationship between transcription and initiation of DNA replication in both eukaryotes and prokaryotes has been suggested. In an attempt to understand the molecular mechanism of this interaction, we examined whether transcription can induce DNA replication in vitro by constructing a system in which both replication and transcription were combined. Relaxed circular DNA possessing a replication initiation zone located upstream of the human c-myc gene and a T7 promoter near the P1 promoter of the gene was replicated in the presence of T7 RNA polymerase. In our model system, replication was carried out with the proteins required for simian virus 40 DNA replication. DNA synthesis, which was dependent on both T7 RNA polymerase and the replication proteins, was detected mainly in the promoter and upstream regions of the c-myc gene. Blocking RNA synthesis at the initial stage of the reaction severely reduced DNA synthesis, suggesting that RNA chain elongation is required to induce DNA synthesis. The results indicated that transcription can induce DNA replication in the upstream region of the transcribed gene, most likely by introducing negative supercoiling into the region, which results in unwinding of the DNA duplex.

Chromatin domains and prediction of MAR sequences

Polynuceosomes are constrained into loops or domains and are insulated from the effects of chromatin structure and torsional strain from flanking domains by the cross-complexation of matrix-attached regions (MARs) and matrix proteins. MARs or SARs have an average size of 500 bp, are spaced about every 30 kb, and are control elements maintaining independent realms of gene activity. A fraction of MARs may cohabit with core origin replication (ORIs) and another fraction might cohabit with transcriptional enhancers. DNA replication, transcription, repair, splicing, and recombination seem to take place on the nuclear matrix. Classical AT-rich MARs have been proposed to anchor the core enhancers and core origins complexed with low abundancy transcription factors to the nuclear matrix via the cooperative binding to MARs of abundant classical matrix proteins (topoisomerase II, histone H1, lamins, SP120, ARBP, SATB1); this creates a unique nuclear microenvironment rich in regulatory proteins able to sustain transcription, replication, repair, and recombination. Theoretical searches and experimental data strongly support a model of activation of MARs and ORIs by transcription factors. A set of 21 characteristics are deduced or proposed for MAR/ORI sequences including their enrichment in inverted repeats, AT tracts, DNA unwinding elements, replication initiator protein sites, homooligonucleotide repeats (i.e., AAA, TTT, CCC), curved DNA, DNase I-hypersensitive sites, nucleosome-free stretches, polypurine stretches, and motifs with a potential for left-handed and triplex structures. We are establishing Banks of ORI and MAR sequences and have undertaken a large project of sequencing a large number of MARs in an effort to determine classes of DNA sequences in these regulatory elements and to understand their role at the origins of replication and transcriptional enhancers.

Developmental alteration of the chromatin state at promoter/replication origin region of the aldolase B locus precedes transcriptional activation in the liver

Liver-specific expression of the rat aldolase B (AldB) gene is conferred by proximal promoter region (-200 bp to + 1 bp), which is centered on an origin region of DNA replication. Transcriptional activation of the gene in the liver occurs during the late one-third of fetal stage. To know the mechanism involved in such activation, we studied developmental changes in chromatin structure and in the extent of CpG methylation in the promoter/origin region of the gene. At an early fetal stage, when the AldB gene in the liver is not yet activated, the gene chromatin had two DNase 1-hypersensitive sites in the promoter region. One corresponded to that typical of AldB-expressing cells in the adult. The other, located approximately 200 bp upstream of the above site, disappeared as the activation of transcription started. A CpG dinucleotide in the promoter/origin region was heavily methylated at an early stage of gestation, but progressively demethylated as the liver develops. This CpG site is located at the center of an important binding site for a transcription factor. These changes occurred early in the fetal stage, prior to the gene activation, and were thus thought to be associated with differentiation of the liver cell or with cessation of cell proliferation.