Chromosomal location of the regulator of mouse alpha-fetoprotein, Afr-1

Liver size and lipid content differences between BALB/c and BALB/cJ mice on a high-fat diet are due, in part, to Zhx2

BALB/cJ mice exhibit considerable phenotypic differences with other BALB/c substrains. Some of these traits involve the liver, including persistent postnatal expression of genes that are normally expressed only in the fetal liver and reduced expression of major urinary proteins. These traits are due to a mutation that dramatically reduces expression of the gene encoding the transcription factor Zinc fingers and homeoboxes 2 (Zhx2). BALB/cJ mice also exhibit reduced serum lipid levels and resistance to atherosclerosis compared to other mouse strains when placed on a high-fat diet. This trait is also due, at least in part, to the Zhx2 mutation. Microarray analysis identified many genes affecting lipid homeostasis, including Lipoprotein lipase, that are dysregulated in BALB/cJ liver. This led us to investigate whether hepatic lipid levels would be different between BALB/cJ and BALB/c mice when placed on a normal chow or a high-fat chow diet. On the high-fat chow, BALB/cJ mice had increased weight gain, increased liver:body weight ratio, elevated hepatic lipid accumulation and markers of liver damage when compared to BALB/c mice. These traits in BALB/cJ mice were only partially reversed by a hepatocyte-specific Zhx2 transgene. These data indicate that Zhx2 reduces liver lipid levels and is hepatoprotective in mice on a high-fat diet, but the partial rescue by the Zhx2 transgene suggests a contribution by both parenchymal and non-parenchymal cells. A model to account for the cardiovascular and liver phenotype in mice with reduced Zhx2 levels is provided.

Zhx2 (zinc fingers and homeoboxes 2) regulates major urinary protein gene expression in the mouse liver

The mouse major urinary proteins (Mups) are encoded by a large family of highly related genes clustered on chromosome 4. Mups, synthesized primarily and abundantly in the liver and secreted through the kidneys, exhibit male-biased expression. Mups bind a variety of volatile ligands; these ligands, and Mup proteins themselves, influence numerous behavioral traits. Although urinary Mup protein levels vary between inbred mouse strains, this difference is most pronounced in BALB/cJ mice, which have dramatically low urinary Mup levels; this BALB/cJ trait had been mapped to a locus on chromosome 15. We previously identified Zhx2 (zinc fingers and homeoboxes 2) as a regulator of numerous liver-enriched genes. Zhx2 is located on chromosome 15, and a natural hypomorphic mutation in the BALB/cJ Zhx2 allele dramatically reduces Zhx2 expression. Based on these data, we hypothesized that reduced Zhx2 levels are responsible for lower Mup expression in BALB/cJ mice. Using both transgenic and knock-out mice along with in vitro assays, our data show that Zhx2 binds Mup promoters and is required for high levels of Mup expression in the adult liver. In contrast to previously identified Zhx2 targets that appear to be repressed by Zhx2, Mup genes are positively regulated by Zhx2. These data identify Zhx2 as a novel regulator of Mup expression and indicate that Zhx2 activates as well as represses expression of target genes.

Zinc Fingers and Homeoboxes 2 (Zhx2) Regulates Sexually Dimorphic Cyp Gene Expression in the Adult Mouse Liver

The mammalian cytochrome P450 (Cyp) gene family encodes a large number of structurally related enzymes that catalyze a variety of metabolic and detoxification reactions. The liver is the primary site of Cyp expression in terms of expression levels and number of expressed genes, consistent with this organ's essential role in metabolism of endogenous and xenobiotic compounds. Many Cyp genes exhibit sexually dimorphic expression. For example, Cyp2a4 is expressed significantly higher in the adult liver of female mice compared to male mice. An exception to this pattern is seen in BALB/cJ mice, where male hepatic Cyp2a4 mRNA levels are substantially elevated compared to male mice of other strains. The Zinc fingers and homeoboxes 2 (Zhx2) protein governs the silencing of several genes in the postnatal liver, including α-fetoprotein, H19, and glypican 3. Zhx2 also regulates numerous hepatic genes that govern lipid homeostasis. We previously showed that the Zhx2 gene is mutated in BALB/cJ mice, which led us to consider whether elevated male hepatic Cyp2a4 levels in this strain are due to this Zhx2 mutation. Using mice with a conditional Zhx2 deletion, we show here that the absence of Zhx2 in hepatocytes results in increased Cyp2a4 expression in adult male liver. We extend this finding to show that additional Cyp genes are disregulated in the absence of Zhx2. We also show that mRNA levels of Cyp2a4 and several other female-biased Cyp genes are increased, and male-biased Cyp4a12 is decreased in mouse liver tumors. These data indicate that Zhx2 is a novel regulator of sex-biased Cyp gene expression in the normal and diseased liver.

Regulation effect of zinc fingers and homeoboxes 2 on alpha-fetoprotein in human hepatocellular carcinoma

Aim. To investigate the relationship between alpha-fetoprotein and zinc fingers and homeoboxes 2 in hepatocellular carcinoma. Materials and Methods. The expressions of zinc fingers and homeoboxes 2, nuclear factor-YA, and alpha-fetoprotein mRNA in 63 hepatocellular carcinoma were detected by reverse transcriptase-polymerase chain reaction and compared with the clinical parameters of the patients. Selectively, silence of zinc fingers and homeoboxes 2 in HepG2 cells was detected by RNA interference technique. Results. Alpha-fetoprotein mRNA expression was detected in 60.3% of hepatocellular carcinoma cases. Zinc fingers and homeoboxes 2 mRNA expression (36.5%) was significantly negatively correlated with serum alpha-fetoprotein concentration and mRNA expression. A strong positive correlation was found between zinc fingers and homeoboxes 2 and nuclear factor-YA mRNA expression (42.9%), while the latter was negatively correlated with serum alpha-fetoprotein concentration and mRNA expression. Treatment with zinc fingers and homeoboxes 2 small interfering RNA led to 85% and 83% silence of zinc fingers and homeoboxes 2 mRNA and protein expression and 60% and 61% reduction of nuclear factor-YA mRNA and protein levels in the HepG2 cells, respectively. Downregulation of zinc fingers and homeoboxes 2 also induced a 2.4-fold increase in both alpha-fetoprotein mRNA and protein levels. Conclusions. Zinc fingers and homeoboxes 2 can regulate alpha-fetoprotein expression via the interaction with nuclear factor-YA in human hepatocellular carcinoma and may be used as an adjuvant diagnostic marker for alpha-fetoprotein-negative hepatocellular carcinoma.

Zhx2 and Zbtb20: novel regulators of postnatal alpha-fetoprotein repression and their potential role in gene reactivation during liver cancer

The mouse alpha-fetoprotein (AFP) gene is abundantly expressed in the fetal liver, normally silent in the adult liver but is frequently reactivated in hepatocellular carcinoma. The basis for AFP expression in the fetal liver has been studied extensively. However, the basis for AFP reactivation during hepatocarcinogenesis is not well understood. Two novel factors that control postnatal AFP repression, Zhx2 and Zbtb20, were recently identified. Here, we review the transcription factors that regulate AFP in the fetal liver, as well as Zhx2 and Zbtb20, and raise the possibility that the loss of these postnatal repressors may be involved in AFP reactivation in liver cancer.

Characterization of the ETnII-alpha endogenous retroviral element in the BALB/cJ Zhx2 ( Afr1 ) allele

Integration of mouse endogenous retroviral (MERV) elements is responsible for an estimated 10% of spontaneous mutations that have been characterized in the laboratory mouse. We recently identified a MERV integration in the first intron of the Zinc fingers and homeoboxes 2 (Zhx2) gene in BALB/cJ mice, resulting in reduced Zhx2 expression. This integration is found in BALB/cJ but not in other BALB/c substrains, indicating that it occurred after these substrains separated in the late 1930s. We have characterized this MERV element and show here that it belongs to the ETnII-alpha class of elements. Our analysis reveals that the Zhx2 ETn element lacks a 69-bp sequence compared to most other ETn elements which may be due to recombination between two identical 13-bp elements. Three mature Zhx2 transcripts are found in the liver of BALB/cJ mice. The major transcript is spliced from Zhx2 exon 1 to the 5' ETn LTR and is polyadenylated at the 3' LTR. Of the two less abundant transcripts, one is identical to the wild-type transcript, whereas the second contains 183 bp of ETn sequence spliced between Zhx2 exons 1 and 2. We have also sequenced and analyzed products from the fas ( lpr ) ETn found in MRL/lpr mice and show that it belongs to the ETnII-beta class of elements.

Hereditary persistence of alpha-fetoprotein and H19 expression in liver of BALB/cJ mice is due to a retrovirus insertion in the Zhx2 gene

The alpha-fetoprotein (AFP) and H19 genes are transcribed at high levels in the mammalian fetal liver but are rapidly repressed postnatally. This repression in the liver is controlled, at least in part, by the Afr1 gene. Afr1 was defined >25 years ago when BALB/cJ mice were found to have 5- to 20-fold higher adult serum AFP levels compared with all other mouse strains; subsequent studies showed that this elevation was due to higher Afp expression in the liver. H19, which has become a model for genomic imprinting, was identified initially in a screen for Afr1-regulated genes. The BALB/cJ allele (Afr1(b)) is recessive to the wild-type allele (Afr1(a)), consistent with the idea that Afr1 functions as a repressor. By high-resolution mapping, we identified a gene that maps to the Afr1 interval on chromosome 15 and encodes a putative zinc fingers and homeoboxes (ZHX) protein. In BALB/cJ mice, this gene contains a murine endogenous retrovirus within its first intron and produces predominantly an aberrant transcript that no longer encodes a functional protein. Liver-specific overexpression of a Zhx2 transgene restores wild-type H19 repression on a BALB/cJ background, confirming that this gene is responsible for hereditary persistence of Afp and H19 in the livers of BALB/cJ mice. Thus we have identified a genetically defined transcription factor that is involved in developmental gene silencing in mammals. We present a model to explain the liver-specific phenotype in BALB/cJ mice, even though Afr1 is a ubiquitously expressed gene.

The alpha-fetoprotein promoter is the target of Afr1-mediated postnatal repression

The alpha-fetoprotein (AFP) gene is transcribed at high levels in the fetal liver and is repressed at birth, leading to low but detectable levels of AFP mRNA in the adult liver. This repression is regulated, in part, by a locus that is unlinked to AFP called Alpha-fetoprotein regulator 1 (Afr1). Previous studies showed that Afr1 regulation is independent of the AFP enhancers but requires the 1-kb AFP promoter/repressor region. Here, we demonstrate that a transgene with the 250-bp AFP promoter region linked to AFP enhancer element EII is expressed in the fetal liver and is postnatally repressed. In addition, this transgene is regulated by Afr1. These data indicate that the promoter is involved in postnatal AFP repression. Furthermore, we provide a high-resolution map of the Afr1 locus on mouse chromosome 15.

Alpha-fetoprotein gene regulation: lessons from transgenic mice

The mouse alpha-fetoprotein (AFP) gene provides an excellent model system to study developmental gene activation and different aspects of liver-specific transcriptional control. AFP is activated early in hepatogenesis, repressed post-natally, and can be reactivated during liver regeneration and in hepatocellular carcinomas. Transgenic studies have also revealed that AFP enhancers, when linked individually to a heterologous promoter, can confer zonal control in the adult liver. Continued transgenic studies, combined with analysis using in vitro and tissue culture systems, will help elucidate mechanisms of transcriptional regulation during liver development and hepatocarcinogenesis.

Sequence requirements for Afr-2 regulation of alpha-fetoprotein gene expression during liver regeneration

Alpha-fetoprotein (AFP) gene expression occurs in the yolk sac, fetal liver and gut, and in the adult liver during regeneration and tumorigenesis. Polymorphism at a single genetic locus, Afr-2 (formerly known as Rif) between inbred mouse strains C3H/He and C57B1/6, results in different levels of AFP expression during liver regeneration. We examined AFP, histone H3, and albumin gene expression during liver regeneration and found that the strain-specific variance in AFP gene expression could not be attributed to a difference in the numbers of dividing cells. Experiments with transgenic mice revealed sequences required for Afr-2 regulation included 172 bp between -1010 and -838 bp and 118 bp immediately upstream of the AFP transcriptional start site-the same regions required for induction during liver regeneration. This suggests that the Afr-2 phenotype may stem from an allelic difference in a gene regulating gene expression during liver regeneration.

Mouse alpha-fetoprotein gene 5' regulatory elements are required for postnatal regulation by raf and Rif

The mouse alpha-fetoprotein (AFP) gene is expressed at high levels in the yolk sac and fetal liver and at low levels in the fetal gut. AFP synthesis decreases dramatically shortly after birth to low levels that are maintained in the adult liver and gut. AFP expression can be reactivated in the adult liver upon renewed cell proliferation such as during liver regeneration or in hepatocellular carcinomas. Previously, two unlinked genetic loci that modulate postnatal AFP levels were identified. The raf locus controls, at least in part, basal steady-state AFP mRNA levels in adult liver. Rif influences the extent of AFP mRNA induction during liver regeneration. Transgenic mice were used to examine the role of 5' AFP regulatory regions in raf- and Rif-mediated control. A fragment of the AFP 5' region containing enhancer element I, the repressor, and the promoter was linked to the mouse class I H-2Dd structural gene. We demonstrate that this hybrid AFP-Dd transgene is expressed in the appropriate tissues. In addition, it is postnatally repressed and reactivated during liver regeneration in parallel with the endogenous AFP gene. Therefore, proper transcriptional control does not require the AFP structural gene. Furthermore, the AFP 5' control region is sufficient to confer raf and Rif responsiveness to the linked H-2Dd structural gene, suggesting that raf and Rif act at the level of transcriptional initiation.

raf regulates the postnatal repression of the mouse alpha-fetoprotein gene at the posttranscriptional level

The mouse alpha-fetoprotein (AFP) gene is transcribed at a high rate in liver during the second half of gestation. Its steady-state mRNA levels decrease 10(4)-fold shortly after birth, at least in part as the consequence of a dramatic decrease in its transcription rate. The final basal level of AFP mRNA in adult liver is influenced by a trans-acting locus on chromosome 15 termed raf. Two strategies were used to demonstrate that the raf gene acts posttranscriptionally to affect the processing and/or stability of AFP transcripts. Transgenic mouse studies demonstrated that raf gene action is independent of both positive and negative transcription control elements of the AFP gene. Nuclear run-on analysis was used to confirm that transcriptions of both AFP transgenes and another endogenous raf-responsive gene, H19, are invariant with respect to the raf genotype. Thus, the postnatal repression of the AFP gene is mediated by both transcriptional and posttranscriptional mechanisms.

Chemistry and biology of alpha-fetoprotein

Alpha-Fetoprotein (AFP) is a product of specific fetal tissues and of neoplastic cells of hepatocyte or germ cell origin in adults. This protein belongs to a gene family that is phylogenetically most closely related to serum albumin. Its primary, secondary, and tertiary structural aspects appear similar to the three-domain concept proposed for the latter protein. The primary sequence of AFP departs most widely from serum albumin in the first 135 amino acid residues, with about 42% of the remaining 590 residues of the human proteins being identical. Some evidence exists that there are limited sequence differences in the AFP of a given animal species. AFP shows considerable charge heterogeneity that appears to relate mostly to its glycoid moiety. The proteins of some species such as the rat show more pronounced heterogeneities than that of humans. The variations in extent and type of glycosylations are evidenced by differences in the binding to various lectins. These interactions are being extensively explored in attempts to differentiate the sources of the protein produced by various normal and neoplastic cells and may provide valuable diagnostic methods. AFP, like serum albumin, shows relatively strong binding affinities for a variety of ligands. The most notable difference is the strong preferential binding of polyunsaturated fatty acids by AFP. This protein may play a role in transporting these substances to developing and to malignant cells. Various agents affect the synthesis of this protein both by specific fetal tissues and by neoplastic cells. Marked differences in the responses of cells, particularly those of neoplastic types, are indicative of variations in the genetic factors responsible for control of its synthesis. The subject of the genomic repression of the synthesis of AFP seen in fetal life upon maturation of the liver and the reoccurrence of synthesis upon malignant conversion of hepatocytes and of certain germ cells are of particular interest. The regulation of the closely related AFP and albumin genes is providing a powerful and attractive model to examine molecular events in the activation and inactivation of specific genes during development and in oncogenic processes. Extensive measurements of AFP during pregnancy and in the course of neoplasias, notably hepatoma, are being made to aid in following changes in such developments. Various specific physiological roles for this protein are also being proposed. One of these is its possible action in the regulation of immune processes.(ABSTRACT TRUNCATED AT 400 WORDS)

Genes on chromosomes 1 and 4 in the mouse are associated with repair of radiation-induced chromatin damage

Early-passage skin fibroblasts from different inbred and congenic strains of mice were X-irradiated (1 Gy), and the number of chromatid breaks was determined at 2.0 h after irradiation. The cells from DBA/2N, C3H/HeN, STS/A, C57BL/6N, BALB/cJ, and AKR/N had 25 to 42 chromatid breaks per 100 metaphase cells (efficient repair phenotype). NZB/NJ had greater than 78 and BALB/cAn had 87 to 110 chromatid breaks per 100 cells (inefficient repair phenotype). Differences between BALB/cAn and BALB/c. DBA/2 congenic strains which carry less than 1% of the DBA/2 genome indicate that two genes, one on chromosome 1 linked to bcl-2-Pep-3 and the other on chromosome 4 closely linked to Fv-1, affect the efficiency with which the cells repair radiation-induced chromatin damage.