Human apolipoprotein B gene intestinal control region.

Recently, we reported that a 315 bp enhancer, located over 55 kilobases (kb) upstream of the transcriptional start site of the human apolipoprotein B (apoB) gene, was sufficient to direct high-level expression of human apoB transgenes in mice. In this report, we expand our analysis of the distant apoB intestinal control region (ICR), by examining the function of segments in the vicinity of the 315 bp intestinal enhancer (315 IE). DNaseI hypersensitivity (DH) studies of a 4.8 kb segment from the ICR revealed three new DH sites, in addition to the previously described DH1 region present within the 315 IE. DH2 mapped to a 485 bp segment (485 IE) immediately upstream of the 315 IE that exhibited strong intestinal enhancer activity in transient transfection experiments with intestine-derived CaCo-2 cells. Within the DH2 region, an HNF-4/ARP-1 binding site was demonstrated by gel retardation experiments. A 1.8 kb segment incorporating the 485 IE was capable of driving expression of human apoB transgenes in the intestines of mice. Additionally, a third component of the apoB ICR was found about 1.2 kb downstream of the 315 IE, within a 1031 bp segment (1031 IE) that also harbored two DH sites, DH3 and DH4. This segment did not display enhancer activity but was capable of driving transgene expression in the intestine. The three components of the ICR displayed a similar pattern of apoB mRNA expression along the horizontal axis of the intestine. The previously characterized in vivo liver-specific elements of the apoB gene, namely, the second intron enhancer and the 5' upstream liver enhancer, did not play a role in intestinal expression of apoB transgenes in mice.

The 5' boundary of the human apolipoprotein B chromatin domain in intestinal cells.

The 5' boundary of the chromosomal domain of the human apolipoprotein B (apoB) gene in intestinal cells has been localized and characterized. It is composed of two kinds of boundary elements; the first, functional boundary is an insulator activity exhibited by a 1.8 kb DNA fragment located between -58 and -56 kb upstream of the human apoB promoter. In this region, an enhancer-blocking activity has been mapped to a CTCF binding site that is located upstream of two apoB intestinal enhancers (IEs), the 315 IE and the 485 IE. The CTCF site represents a boundary between two types of chromatin structure: an open, DNaseI-sensitive region 3' of the CTCF site containing the intestinal regulatory elements and a closed, DNaseI-resistant region 5' of the CTCF site. The 1.8 kb fragment harboring the CTCF site also insulated mini-white transgenes against position effects in Drosophila melanogaster. The second, structural boundary is represented by a nuclear matrix attachment region (MAR), situated about 3 kb 5' of the CTCF site. This MAR may represent the 5' anchorage site for a chromosomal loop that functions to bring the intestinal regulatory elements closer to the apoB promoter.

HNF-3 beta, C/EBP beta, and HNF-4 act in synergy to enhance transcription of the human apolipoprotein B gene in intestinal cells.

Recently, we identified a 315-bp intestinal enhancer (IE), localized over 55 kb upstream from the transcriptional start of the human apolipoprotein B (apoB) gene, that confers expression of human apoB transgenes in the intestines of mice. Four functional binding sites for the intestine-enriched transcription factors hepatocyte nuclear factor (HNF)-3beta, CAAT enhancer binding protein (C/EBP)beta, and HNF-4 were demonstrated within the 315-bp IE. In this report, we extend these earlier studies and examine the relative contributions of these three transcription factors to the activity of the enhancer as well as their mechanism of interaction with one another. Cotransfection experiments with the expression vectors for HNF-3beta, C/EBPbeta, and HNF-4 revealed that HNF-3beta bound to Site 1, C/EBPbeta bound to Site 2, and HNF-4 bound to Site 3 within the 315-bp IE and that the sites act synergistically to enhance intestinal expression of apoB. Each one of these four binding sites was mutated, and mutant constructs were transfected into intestine-derived CaCo-2 cells to evaluate the role of each of these binding sites in enhancer activity. The results of the mutagenesis experiments confirmed that the HNF-3beta and HNF-4 sites are most important for the enhancer activity, followed by C/EBPbeta Site 2. All three factors bound to Sites 1, 2, and 3 must act synergistically for optimal activity of the apoB IE.

Identification and characterization of a 315-base pair enhancer, located more than 55 kilobases 5' of the apolipoprotein B gene, that confers expression in the intestine.

We recently reported that an 8-kilobase (kb) region, spanning from -54 to -62 kb 5' of the human apolipoprotein B (apoB) gene, contains intestine-specific regulatory elements that control apoB expression in the intestines of transgenic mice. In this study, we further localized the apoB intestinal control region to a 3-kb segment (-54 to -57 kb). DNaseI hypersensitivity studies uncovered a prominent DNaseI hypersensitivity site, located within a 315-base pair (bp) fragment at the 5'-end of the 3-kb segment, in transcriptionally active CaCo-2 cells but not in transcriptionally inactive HeLa cells. Transient transfection experiments with CaCo-2 and HepG2 cells indicated that the 315-bp fragment contained an intestine-specific enhancer, and analysis of the DNA sequence revealed putative binding sites for the tissue-specific transcription factors hepatocyte nuclear factor 3beta, hepatocyte nuclear factor 4, and CAAT enhancer-binding protein beta. Binding of these factors to the 315-bp enhancer was demonstrated in gel retardation experiments. Transfection of deletion mutants of the 315-bp enhancer revealed the relative contributions of these transcription factors in the activity of the apoB intestinal enhancer. The corresponding segment of the mouse apoB gene (located -40 to -83 kb 5' of the structural gene) exhibited a high degree of sequence conservation in the binding sites for the key transcriptional activators and also exhibited enhancer activity in transient transfection assays with CaCo-2 cells. In transgenic mouse expression studies, the 315-bp enhancer conferred intestinal expression to human apoB transgenes.

The nuclear matrix protein CDP represses hepatic transcription of the human cholesterol-7alpha hydroxylase gene.

To date, the molecular mechanisms that govern hepatic-specific transcription of the human cholesterol 7alpha-hydroxylase (CYP7A1) gene are poorly understood. We recently reported that the region extending from -1888 to +46, which includes the promoter, is not capable of conferring expression to human CYP7A1 promoter lacZ transgenes in the livers of mice, but that expression is observed with transgenes containing the entire structural gene. To locate liver-specific elements in other segments of the human gene, DNase I hypersensitivity studies were performed with transcriptionally active, liver-derived HepG2 cells and with transcriptionally inactive HeLa cells. Three DNase I hypersensitivity sites were detected within the first intron of the human CYP7A1 gene, but only in HepG2 cells. Transient transfection experiments with HepG2 cells revealed a transcriptional repressor within intron 1. Five binding sites for the CAAT displacement protein (CDP) were detected within intron 1. Since CDP is a nuclear matrix protein, two methods were employed to localize nuclear matrix attachment sites within intron 1 of the human CYP7A1 gene. A matrix attachment site was found throughout the entirety of intron 1. Gel retardation experiments and cell transfection studies provided evidence for the repression mechanism. Repression is achieved by displacement by CDP of two hepatic activators, namely HNF-1alpha and C/EBPalpha, that bind to three different sites within intron 1. Additionally, CDP represses transactivation mediated by these two activators.

An open chromatin structure in a liver-specific enhancer that confers high level expression to human apolipoprotein b transgenes in mice.

A number of DNaseI-hypersensitive (DH) sites have been mapped within a regulatory region situated upstream of the human apolipoprotein B (apoB) promoter (-5262 to -899) that is required for high level expression of human apoB transgenes in the livers of mice. These DH sites were observed in nuclei from transcriptionally active liver-derived HepG2 cells, but were absent from transcriptionally inactive HeLa cell nuclei. Several nuclear protein binding sites were detected in the DNaseI-hypersensitive region by DNaseI footprinting with HepG2 nuclear extracts, representing putative binding sites for the liver-specific activators. The locations of binding sites for these transcription factors were revealed via computer analysis of the DNA sequence of this region against a transcription factor database. Many micrococcal nuclease hypersensitive (MH) sites were also observed in nuclei from HepG2 cells but not in HeLa cell nuclei, implying that in hepatic cells, nucleosomes are either absent or have been displaced from this region by the liver-specific transcriptional activators, as inferred by the correspondence between the DH sites, the MH sites and the footprints.

Expression of the human cholesterol 7alpha-hydroxylase gene in transgenic mice.

We have generated transgenic mice expressing human CYP7A1 transgenes. Only 1.5 kilobases (kb) of 5' upstream sequence and 6.5 kb of 3' sequence were sufficient for hepatic transcription of the transgenes. However, the 5' end segment alone was not sufficient to direct liver expression, suggesting that additional hepatic regulatory elements reside in the 3' extension or within introns. The level of expression of these transgenes was low in comparison to the levels of the endogenous mouse CYP7A1 mRNA. To generate mice expressing higher levels of CYP7A1 mRNA, we injected a large human genomic PAC clone, extending up to -105 kb 5' of the structural gene and about 50 kb 3' of the gene. These transgenic mice expressed CYP7A1 mRNA at higher levels, suggesting that additional hepatic regulatory elements are found either 5' of -1520 or beyond 6.5 kb 3' of the gene.

Hepatocyte nuclear factor 1 binds to and transactivates the human but not the rat CYP7A1 promoter.

Cholesterol 7alpha-hydroxylase (CYP7A1), a liver-specific enzyme, catalyzes the rate-limiting step in the degradation pathway of cholesterol to bile acids, and thus plays a key role in cholesterol homeostasis. To elucidate the mechanisms that control hepatic expression of the human CYP7A1 gene, we are studying the promoter region. Initially, we observed that up to 40% of the overall transcriptional activity of the promoter in HepG2 cells was associated with DNA sequences from -65 to -1 of the human gene. Within this region, a binding site for the liver-enriched transcription factor HNF-1 (-56 to -49) has been identified. Binding of HNF-1 to this site leads to transcriptional activation of the human promoter. The corresponding segment from the rat CYP7A1 gene does not bind HNF-1; instead, it is bound by the orphan receptors ARP-1 (COUP-TFII) and LXRalpha, that are implicated in dietary regulation.

Characterization of hepatic-specific regulatory elements in the promoter region of the human cholesterol 7alpha-hydroxylase gene.

Cholesterol 7alpha-hydroxylase is the rate-limiting enzyme in the degradation of cholesterol to bile salts and plays a central role in regulating cholesterol homeostasis. The mechanisms involved in the transcriptional control of the human gene are largely unknown. HepG2 cells represent an appropriate model system for the study of the regulation of the gene. To identify liver-specific DNA sequences in the promoter of the human CYP7 gene, we first examined the DNase I hypersensitivity in the 5'-region of the gene. An area of hypersensitivity was observed in the region from -50 to -200 of the human gene in nuclei from transcriptionally active HepG2 cells, but was absent in transcriptionally inactive HeLa cell nuclei or in free DNA. Various 5'-promoter deletion constructs were made and transfected into HepG2 cells. About 300 base pairs of upstream sequence are required for high level promoter activity of the human CYP7 gene in HepG2 cells. DNase I footprinting of the hypersensitive region revealed nine protected sequences. Gel retardation experiments demonstrated binding of HNF-3 to the segment from -80 to -70 and of hepatocyte nuclear factor HNF-4 (and ARP-1) to the segment from -148 to -127 of the human CYP7 promoter. Deletion of either of these sites depressed promoter activity in HepG2 cells. A third region from -313 to -285 is bound by members of the HNF-3 family and acts as an enhancer. Additionally, the segment from -197 to -173 binds a negative regulatory protein that is present in Chinese hamster ovary cell extracts and in HepG2 cell extracts. These experiments define the key control elements responsible for basal transcription of the human CYP7 gene in HepG2 cells.

Evaluation of the function of the human apolipoprotein B gene nuclear matrix association regions in transgenic mice.

The human apolipoprotein B (apoB) gene resides in a 47.5 kb DNasel-sensitive chromosomal domain in hepatic and intestinal cells, flanked by the 5' distal matrix association region (MAR) and the 3' proximal MAR. A third MAR, the 5' proximal MAR, is found only in transcriptionally active hepatic (HepG2) cells. Hepatic expression of the apoB gene requires a tissue-specific promoter (-898 to +121) and an enhancer from the second intron of the gene (+360 to +1064). A vector containing this portion of the gene linked to the beta-galactosidase reporter is sufficient for low level expression in the livers of transgenic mice. Expression in transgenic mice was increased when the promoter-enhancer beta-gal vector was flanked by MARs. The results were similar whether the 5' distal, the 5' proximal or the 3' proximal MARs were placed at both ends of the construct, or whether the construct was flanked by the 5' distal and the 3' MAR, suggesting that the apoB MARs play a role in gene expression in vivo. When the MAR-containing constructs were transiently transfected into HepG2 cells, the resulting beta-gal activities were similar to that of the construct lacking MARs, thus demonstrating that the MARs do not exhibit any enhancer activity. Recent experiments (Kalos, M., and R. E. K. Fournier. 1995. Mol. Cell. Biol. 15: 198-207) examining stable integration of some of our constructs into human and rat hepatoma transfectants suggest that in single and double copy transfectants, the apoB MARs behave as boundary "insulators", protecting the integrated transgenes against position effects regardless of their site of integration. However, multicopy transfectants are transcriptionally inactive and when the MARs are absent, expression of the transgenes drops to background levels. Our results to date with single and low-copy number transgenes do not support an insulator function for the apoB MARs, although they appear to be required to increase the levels of expression.

Members of the caudal family of homeodomain proteins repress transcription from the human apolipoprotein B promoter in intestinal cells.

Apolipoprotein B (apoB) is the major protein component of low density lipoproteins, and plays a central role in cholesterol transport and metabolism. The apoB gene is transcribed in the liver and in the intestine in humans. Although much is known about the DNA sequence elements and protein factors that are important for transcription of the human apolipoprotein B gene in the liver, less is known about the mechanisms that control transcription of this gene in the intestine. The sucrose isomaltase gene (SI), is expressed exclusively in the intestine. Two sequences from the promoter region of the SI gene, namely SIF-1 and SIF-3, are essential for promoter activity of the SI gene in intestinal cells. Sequences displaying a high degree of similarity to those of SIF-1 and SIF-3 are present in the third intron of the apoB gene. Rather than stimulating apoB promoter activity, the BSIF-1 and BSIF-3 sequences repressed transcription in CaCo-2 cells. Gel retardation studies demonstrated that BSIF-1, like SIF-1, binds to proteins related to the caudal family of proteins such as mCdx-4 and mCdx-2. These proteins appear to repress transcription from the apoB promoter by a mechanism that involves an interaction with members of the C/EBP family of proteins, that bind to a target sequence for the repressor in the segment from -139 to -111 of the apoB promoter. On the other hand, BSIF-3, like SIF-3, binds to HNF-1 and also represses transcription from the apoB promoter.

Sequences containing the second-intron enhancer are essential for transcription of the human apolipoprotein B gene in the livers of transgenic mice.

To identify DNA sequence elements from the human apolipoprotein B (apoB) gene required for high-level, correct tissue-specific expression in transgenic mice, we made several constructs that included one or more of the key regulatory elements that were previously characterized with cultured liver-derived and intestine-derived cell lines. Our data show that the apoB promoter alone (-898 to +121) is not sufficient to direct transcription in transgenic mice. An enhancer located in the second intron is absolutely required to specify transcription by the homologous apoB promoter in the livers of transgenic mice; this enhancer does not direct transcription in the small intestines. Thus, the elements controlling transcriptional activation of the apoB gene in the liver and the intestine in vivo are distinct and separable. Analysis of the DNase I hypersensitivity of the integrated human transgenes in various lines of expressing and nonexpressing mice suggests that the formation of DH4, a strong hypersensitive site in intron 2, may be a prerequisite for hepatic expression of the apoB gene. Nuclear matrix association regions (MARs) of the apoB gene may play a role in transgene expression. Constructs including MAR sequences displayed higher levels of expression than those lacking them. However, these MARs did not completely insulate the associated transgenes from position effects.

The mechanism by which the human apolipoprotein B gene reducer operates involves blocking of transcriptional activation by hepatocyte nuclear factor 3.

Previously, we showed that when a DNA fragment extending from -3067 to -2734 of the human apolipoprotein B (apo-B) gene is inserted immediately upstream of an apo-B promoter segment (-139 to +121), transcription from this promoter is reduced by about 10-fold in cultured colon carcinoma cells (CaCo-2) but not in cultured hepatoma cells (HepG2). We postulated that this reducer operates by a mechanism involving active repression of a transcriptional activator that binds to the segment from -111 to -88 of the apo-B promoter (B. Paulweber and B. Levy-Wilson, J. Biol. Chem. 266:24161-24168 1991). In the current study, the reducer element has been localized to a 24-bp sequence from -2801 to -2778 of the apo-B gene that contains a binding site for the negative regulatory protein ARP-1. Furthermore, we have demonstrated that the transcription factor hepatocyte nuclear factor 3 alpha (HNF-3 alpha) binds to the sequence 5'-TGTTTGCTTTTC-3' from -95 to -106 of the apo-B promoter, to stimulate transcription. Transcriptional activation by HNF-3 is repressed when the reducer sequence is inserted immediately upstream of the HNF-3 binding site, suggesting a mechanism by which the reducer-bound protein blocks the activation promoted by HNF-3. Data from cotransfection experiments in which ARP-1 is overexpressed in the absence of its binding site suggest that ARP-1 interacts either directly or via a mediator protein with proteins recognizing the HNF-3 site and that this interaction is sufficient to repress transcriptional activation by HNF-3. Because transcriptional activation by Sp1 is not affected by the reducer, it is unlikely that the reducer interacts directly with basic components of the transcriptional machinery.

Nuclease-hypersensitive sites define a region with enhancer activity in the third intron of the human apolipoprotein B gene.

The positions of several DNase I-hypersensitive (DH) sites have been mapped in the second and third introns of the human apolipoprotein B gene. Two such DH sites, I and V, are present both in human hepatoma (HepG2) and colon carcinoma (CaCo-2) cells that express the gene but absent from HeLa cells that do not express the gene. These DH sites map near sequence elements that have been highly conserved between the human and mouse genes. A PvuII-EcoRI fragment (+1064 to +2977) from the hypersensitive region exhibited enhancer activity, which was further localized by means of deletion experiments to a 155-base pair segment located entirely within the third intron and flanked by two DH sites. Three DNase I footprints were observed within this core enhancer, one of which contains putative binding sites for three liver specific nuclear proteins. Experiments are presented that suggest that this enhancer operates by a similar mechanism as that described previously for the strong second intron enhancer, involving an interaction with the basal transcriptional machinery. Digestions with low levels of micrococcal nuclease were performed to ascertain whether nucleosomes were present in the DNase I sensitive enhancer region. Nine different micrococcal nuclease-hypersensitive (MH) sites were detected in HepG2 cells but not in HeLa cells; one MH site was common to both cell types, and HeLa cells exhibited three unique MH sites. The first six MH sites (I-VI) are spaced approximately 200 base pairs apart, suggesting the presence of positioned nucleosomes in that region. MH sites VI-X are more closely spaced, suggesting either additional cutting sites within the core particle or the absence of one or two nucleosomes in this segment of the third intron enhancer.

Hepatocyte nuclear factor 1 and C/EBP are essential for the activity of the human apolipoprotein B gene second-intron enhancer.

The tissue-specific transcriptional enhancer of the human apolipoprotein B gene contains multiple protein-binding sites spanning 718 bp. Most of the enhancer activity is found in a 443-bp fragment (+621 to +1064) that is located entirely within the second intron of the gene. Within this fragment, a 147-bp region (+806 to +952) containing a single 97-bp DNase I footprint exhibits significant enhancer activity. We now report that this footprint contains four distinct protein-binding sites that have the potential to bind nine distinct liver nuclear proteins. One of these proteins was identified as hepatocyte nuclear factor 1 (HNF-1), which binds with relatively low affinity to the 5' half of a 20-bp palindrome located at the 5' end of the large footprint. A binding site for C/EBP (or one of the related proteins that recognize similar sequences) was identified in the center of the 97-bp footprint. This binding site is coincident or overlaps with the binding sites for five other proteins, two of which appear to be distinct from the C/EBP-related family of proteins. The binding site for a nuclear factor designated protein I is located between the HNF-1 and C/EBP binding sites. Finally, the 3'-most 15 bp of the footprinted sequence contain a binding site for another nuclear protein, which we have called protein II. Mutations that abolish the binding of either HNF-1, protein II, or the C/EBP-related proteins severely reduce enhancer activity. However, deletion experiments demonstrated that neither the HNF-1-binding site alone, nor the combination of binding sites for HNF-1, protein I, and C/EBP, nor the C/EBP-binding site plus the protein II-binding site is sufficient to enhance transcription from a strong apolipoprotein B promoter. Rather, HNF-1 and C/EBP act synergistically with protein II to enhance transcription of the apolipoprotein B gene.

Similarities and differences in the function of regulatory elements at the 5' end of the human apolipoprotein B gene in cultured hepatoma (HepG2) and colon carcinoma (CaCo-2) cells.

The arrangement of regulatory elements along the apolipoprotein B promoter region (positions -898 to +1) has been examined in transient transfection experiments performed in HepG2 and Hep3B (hepatic) and CaCo-2 (intestinal) cell lines, all of which express the apoB gene, and also in Chinese hamster ovary cells, which do not express the gene. The overall distribution of positive and negative regulatory segments was very similar in the two hepatoma cell lines (HepG2 and Hep3B) but different from that observed in the colon carcinoma cells (CaCo-2). Thus, whereas 260 base pairs of 5'-flanking sequence were sufficient for maximal expression of the promoter in HepG2 cells, only 139 nucleotides were required for maximal expression in CaCo-2 cells. Promoter activity in Chinese hamster ovary cells was exhibited by short constructs, with maximal activity for the -85 construct. DNase I footprinting of the apolipoprotein B promoter region using hepatic and intestinal extracts revealed multiple sites of interaction between the DNA and nuclear proteins. Gel retention experiments using the region from -262 to -88 (the region of greatest contrast between HepG2 and CaCo-2 cells) revealed interesting variations in the relative abundance of various nuclear proteins between the two cell types. A major functional difference between HepG2 and CaCo-2 cells was localized to the region between -111 and -88, which harbors the sequence TGTTTGCT, a motif present in the promoter region of several liver-specific genes. The molecular basis for the functional differences between these two cell types may be attributable to a difference in the relative abundance of three proteins that bind to sequences between -111 and -88.

The mechanisms by which a human apolipoprotein B gene enhancer and reducer interact with the promoter are different in cultured cells of hepatic and intestinal origin.

In the preceding paper (Paulweber, B., Onasch, M. A., Nagy, B. P., and Levy-Wilson, B. (1991) J. Biol. Chem. 266, 24149-24160) we demonstrated that the segment of the apolipoprotein B promoter extending from -260 to -85 is functionally different in hepatic (HepG2) and intestinal (CaCo-2) cells. These functional differences could be explained at least in part by differences in binding of three nuclear proteins to the region from -111 to -88. In this article we present further evidence suggesting that the mechanisms involved in transcriptional control of the apolipoprotein B gene in HepG2 and CaCo-2 cells are different, by demonstrating that an enhancer and a reducer can alter the activity of various apolipoprotein B promoter segments in widely differing ways in these two cell lines. Furthermore, we have localized a 329-base pair segment that is found within a negative regulatory region in the 5' distal portion of the gene. It displays a strong reducer effect upon promoter sequences that exhibit maximal transcriptional activity in CaCo-2 cells, but not in HepG2 cells.

Identification of a negative regulatory region 5' of the human apolipoprotein B promoter.

We have identified a negative regulatory region between positions -1802 and -3211 of the human apolipoprotein B gene that reduces expression of the gene. This "reducer" effect was detected in transient transfection experiments performed with hepatic (HepG2 and Hep3B) cells as well as intestinal (CaCo-2) cells. It appears to be specific for the apolipoprotein B promoter because it did not affect expression from the heterologous thymidine kinase promoter. This reducer segment operated in the presence or absence of the transcriptional enhancer from the second intron of the apolipoprotein B gene, suggesting that the protein factors involved in the enhancer and reducer effect can interact with the transcriptional machinery independently of each other. Deletion experiments further localized the positions of the negative regulatory elements in HepG2 cells: sequences between positions -2738 and -2470 together with those from -2118 to -1802 are required for the reducer activity. DNase I footprinting of these two reducer DNA segments identified several DNA sequences that are bound by nuclear proteins from HepG2 cells. Analysis of the nucleotide sequences within these footprints demonstrated a high degree of similarity with sequences within negative regulatory regions of other genes.

Comparative analysis of sequences at the 5' end of the human and mouse apolipoprotein B genes.

A comparison was made between the DNA sequences in two regions of the mouse and the human apolipoprotein B genes: the 5'-flanking sequence and the region between the first exon and the second intron. Considerable homology was observed, particularly in the immediate 5' region and in the second intron. Because promoter and enhancer elements have been previously localized to these regions in the human apolipoprotein B gene, it is proposed that regions of conserved base sequence delineate binding regions for regulatory proteins. In some cases, contiguous regions of homology are longer than expected for regions designed as recognition sites for individual nuclear proteins, and may define regions recognizable by a cluster of interacting proteins. Both the human and mouse genes contain repetitive elements and a hypervariable dinucleotide repeat.