In vitro methylation inhibits the promotor activity of a cloned intracisternal A-particle LTR

Gestational arsenic exposure induces site-specific DNA hypomethylation in active retrotransposon subfamilies in offspring sperm in mice

Background

Environmental impacts on a fetus can disrupt germ cell development leading to epimutations in mature germ cells. Paternal inheritance of adverse health effects through sperm epigenomes, including DNA methylomes, has been recognized in human and animal studies. However, the impacts of gestational exposure to a variety of environmental factors on the germ cell epigenomes are not fully investigated. Arsenic, a naturally occurring contaminant, is one of the most concerning environmental chemicals, that is causing serious health problems, including an increase in cancer, in highly contaminated areas worldwide. We previously showed that gestational arsenic exposure of pregnant C3H mice paternally induces hepatic tumor increase in the second generation (F2). In the present study, we have investigated the F1 sperm DNA methylomes genome-widely by one-base resolution analysis using a reduced representation bisulfite sequencing (RRBS) method.

Results

We have clarified that gestational arsenic exposure increases hypomethylated cytosines in all the chromosomes and they are significantly overrepresented in the retrotransposon LINEs and LTRs, predominantly in the intergenic regions. Closer analyses of detailed annotated DNA sequences showed that hypomethylated cytosines are especially accumulated in the promoter regions of the active full-length L1MdA subfamily in LINEs, and 5′LTRs of the active IAPE subfamily in LTRs. This is the first report that has identified the specific positions of methylomes altered in the retrotransposon elements by environmental exposure, by genome-wide methylome analysis.

Conclusion

Lowered DNA methylation potentially enhances L1MdA retrotransposition and cryptic promoter activity of 5′LTR for coding genes and non-coding RNAs. The present study has illuminated the environmental impacts on sperm DNA methylome establishment that can lead to augmented retrotransposon activities in germ cells and can cause harmful effects in the following generation.

Evolution of Epigenetic Regulation in Vertebrate Genomes

Empirical models of sequence evolution have spurred progress in the field of evolutionary genetics for decades. We are now realizing the importance and complexity of the eukaryotic epigenome. While epigenome analysis has been applied to genomes from single-cell eukaryotes to human, comparative analyses are still relatively few and computational algorithms to quantify epigenome evolution remain scarce. Accordingly, a quantitative model of epigenome evolution remains to be established. We review here the comparative epigenomics literature and synthesize its overarching themes. We also suggest one mechanism, transcription factor binding site (TFBS) turnover, which relates sequence evolution to epigenetic conservation or divergence. Lastly, we propose a framework for how the field can move forward to build a coherent quantitative model of epigenome evolution.

Is there a role for endogenous retroviruses to mediate long-term adaptive phenotypic response upon environmental inputs?

Endogenous retroviruses (ERVs) are long terminal repeat-containing virus-like elements that have colonized approximately 10 per cent of the present day mammalian genomes. The intracisternal A particles (IAPs) are a class of ERVs that is currently highly active in the rodents. IAP elements can influence the transcription profile of nearby genes by providing functional promoter elements and modulating local epigenetic landscape through changes in DNA methylation and histone (H3K9) modifications. Despite the potential role for IAPs in gene regulation, the precise genomic locations where these elements are integrated are not well understood. To address this issue, we have identified more than 400 novel IAP insertion sites within/near annotated genes by searching the murine genome, which suggests that the impact of IAP elements on local and/or global gene regulation could be more profound than was previously expected. On the basis of our independent analyses and already published reports, here we argue that IAPs and ERV elements in general could have an evolutionary role for modulating phenotypic plasticity upon environmental inputs, and that this could be mediated through specific stages of embryonic development such as placentation during which the epigenetic constraints on IAP elements are partially relaxed.

Intracisternal A particle genes: Distribution in the mouse genome, active subtypes, and potential roles as species-specific mediators of susceptibility to cancer

Rodents, mice and rats in particular, are the species of choice for evaluating chemical carcinogenesis. However, different species and strains often respond very differently, undermining the logic of extrapolation of animal results to humans and complicating risk assessment. Intracisternal A particles (IAPs), endogenous retroviral sequences, are an important class of transposable elements that induce genomic mutations and cell transformation by disrupting gene expression. Several lines of evidence support a role of IAPs as mouse-specific genetic factors in responses to toxicity and expression of disease phenotypes. Since multiple subtypes and copies of IAPs are present in the mouse genome, their activity and locations relative to functional genes are of critical importance. This study identified the major "active" subtypes of IAPs (subtype 1/1a) that are responsible for newly transposed IAP insertions described in the literature, and confirmed that (1) polymorphisms for IAP insertions exist among different mouse strains and (2) promoter activity of the LTRs can be modulated by chemicals. This study further identified all the genes in the C57BL/6 mouse genome with IAP subtype 1 and 1a sequences inserted in their proximity, and the major biofunctional categories and cellular signaling networks of those genes. Since many "IAP-associated genes" play important roles in the regulation of cell proliferation, cell cycle, and cell death, the associated IAPs, upon activation, can affect cellular responses to xenobiotics and disease processes, especially carcinogenesis. This systemic analysis provides a solid foundation for further investigations of the role of IAPs as species- and strain-specific disease susceptibility factors.

RNA expression microarray analysis in mouse prospermatogonia: identification of candidate epigenetic modifiers

The mammalian totipotent and pluripotent lineage exhibits genome-wide dynamics with respect to DNA methylation content. The first phase of global DNA demethylation and de novo remethylation occurs during preimplantation development and gastrulation, respectively, while the second phase occurs in primordial germ cells and primary oocytes/prospermatogonia, respectively. These dynamics are indicative of a comprehensive epigenetic resetting or reprogramming of the genome in preparation for major differentiation events. To gain further insight into the mechanisms driving DNA methylation dynamics and other types of epigenetic modification, we performed an RNA expression microarray analysis of fetal prospermatogonia at the stage when they are undergoing rapid de novo DNA remethylation. We have identified a number of highly or specifically expressed genes that could be important for determining epigenetic change in prospermatogonia. These data provide a useful resource in the discovery of molecular pathways involved in epigenetic reprogramming in the mammalian germ line.

Chromatin, gene silencing and HIV latency

Cellular defence mechanisms against HIV contribute to its persistence.

One of the cellular defenses against virus infection is the silencing of viral gene expression. There is evidence that at least two gene-silencing mechanisms are used against the human immuno-deficiency virus (HIV). Paradoxically, this cellular defense mechanism contributes to viral latency and persistence, and we review here the relationship of viral latency to gene-silencing mechanisms.

Structure and expression of mobile ETnII retroelements and their coding-competent MusD relatives in the mouse

ETnII elements are mobile members of the repetitive early transposon family of mouse long terminal repeat (LTR) retroelements and have caused a number of mutations by inserting into genes. ETnII sequences lack retroviral genes, but the recent discovery of related MusD retroviral elements with regions similar to gag, pro, and pol suggests that MusD provides the proteins necessary for ETnII transposition in trans. For this study, we analyzed all ETnII elements in the draft sequence of the C57BL/6J genome and classified them into three subtypes (alpha, beta, and gamma) based on structural differences. We then used database searches and quantitative real-time PCR to determine the copy number and expression of ETnII and MusD elements in various mouse strains. In 7.5-day-old embryos of a mouse strain in which two mutations due to ETnII-beta insertions have been identified (SELH/Bc), we detected a three- to sixfold higher level of ETnII-beta and MusD transcripts than in control strains (C57BL/6J and LM/Bc). The increased ETnII transcription level can in part be attributed to a higher number of ETnII-beta elements, but 70% of the MusD transcripts appear to have been derived from one or a few MusD elements that are not detectable in C57BL/6J mice. This element belongs to a young MusD subgroup with intact open reading frames and identical LTRs, suggesting that the overexpressed element(s) in SELH/Bc mice might provide the proteins for the retrotransposition of ETnII and MusD elements. We also show that ETnII is expressed up to 30-fold more than MusD, which could explain why only ETnII, but not MusD, elements have been positively identified as new insertions.

Epigenetic regulation of an IAP retrotransposon in the aging mouse: progressive demethylation and de-silencing of the element by its repetitive induction

The recent insertion of a murine intracisternal A-particle (IAP) retrotransposon within one of the introns of a housekeeping gene, the circadian m.nocturnin gene, revealed a singular expression profile, both throughout the daytime and the mouse life span. Measurement of the levels of transcripts from this element by quantitative real-time RT-PCR, in organs of 1-24-month-old mice, disclosed that the inserted element--which is part of a large family of otherwise severely repressed mobile elements--becomes active upon aging, specifically in the liver where the m.nocturnin housekeeping gene is expressed in a circadian manner and induces a circadian expression of the IAP sequence. This age-dependent induction is cell-autonomous, as it persists in hepatocytes in primary culture. We further show, using methylation-sensitive enzymes, a correlation between the life-time kinetics of this process and a liver-specific demethylation of the IAP promoter. These results strongly support a model whereby the progressive demethylation and turning on of the IAP sequence is the sole result of the transient, daily activation-throughout the mouse life span--of its promoter. This phenomenon, which develops on a timescale of months to years in the aging mouse, might reveal a general epigenetic--and stochastic--process, which could account for a large series of events associated with cell and animal aging.

Identification of a novel tumor-specific CTL epitope presented by RMA, EL-4, and MBL-2 lymphomas reveals their common origin

C57BL/6 mice generate a vigorous H-2Db-restricted CTL response against murine leukemia virus (MuLV)-induced tumors. For many years it has been suggested that this response is directed to an MuLV-encoded peptide as well as to a nonviral tumor-associated peptide. Recently, a peptide from the leader sequence of gag was demonstrated to be the MuLV-derived epitope. Here we describe the molecular identification of the tumor-associated epitope. Furthermore, we show that the CTL response against this epitope can restrict the outgrowth of MuLV-induced tumors in vivo. The epitope is selectively presented by the MuLV-induced T cell tumors RBL-5, RMA, and MBL-2 as well as by the chemically induced T cell lymphoma EL-4. Intriguingly, these tumors share expression of the newly identified epitope because they represent variants of the same clonal tumor cell line, as evident from sequencing of the TCR alpha- and beta-chains, which proved to be identical. Our research shows that all sources of RBL-5, RMA, RMA-S, MBL-2, and EL-4 tumors are derived from a single tumor line, most likely EL-4.

Increased expression of intracisternal A-particle RNA in regenerated myeloid cells after X irradiation in C3H/He inbred mice

Myeloid Cells after X Irradiation in C3H/He Inbred Mice. Myeloid leukemia cells were derived from regenerated hematopoietic cells damaged by sublethal doses of X radiation in C3H/He inbred mice. We previously found that within the genome of the myeloid leukemia cells, a retrotransposon, the intracisternal A-particle (IAP) element, is integrated. Levels of IAP RNA, the source of cDNA for the integration, were analyzed quantitatively in C3H mice. Higher levels of IAP transcripts were observed in normal cells, particularly in hematopoietic cells, from C3H/He mice, than in those from C57BL/6J and STS/A mice. In the C3H/He mice, an approximately twofold increase in IAP RNA was found in the regenerated spleen and bone marrow cells at 5 days and from 12 to 90 days after whole-body X irradiation. In addition, an increased level of IAP RNA was observed in all the myeloid leukemia cells derived from C3H/He mice. This suggests that the elevated levels of IAP RNA in the regenerated hematopoietic cells after irradiation contribute to the increase in retrotransposition of IAP found in myeloid leukemia cells from C3H/He mice.

The noncalcemic vitamin D analogues EB1089 and 22-oxacalcitriol interact with the vitamin D receptor and suppress parathyroid hormone-related peptide gene expression

Humoral hypercalcemia of malignancy, a frequent complication of squamous cell carcinomas of the lung, is mediated by the parathyroid hormone-related peptide (PTHrP). This study was undertaken to determine whether 1,25-dihydroxyvitamin D(3) [1,25(OH)(2)D(3)] and two nonhypercalcemic analogues. EB1089 and 22-oxa-1,25(OH)(2)D(3) (OCT), suppress PTHrP gene expression in a human lung squamous cancer cell line, NCI H520. All three compounds (1) decreased steady-state PTHrP mRNA and secreted peptide levels via a transcriptional mechanism; (2) modulated promoter activity of 1,25(OH)(2)D(3)-responsive DNA sequences; and (3) activated the vitamin D receptor (VDR) both in vitro and in vivo. Thus, EB1089 and OCT inhibit PTHrP gene expression in NCI H520 cells and modulate gene expression through the same mechanism as 1,25(OH)(2)D(3), namely, activation of the VDR. 1,25(OH)(2)D(3) is hypercalcemic in vivo. However, the noncalcemic analogues EB1089 and OCT have a therapeutic potential through suppression of PTHrP gene transcription.

Germ line-specific expression of intracisternal A-particle retrotransposons in transgenic mice

Intracisternal A-particle (IAP) sequences are endogenous retrovirus-like mobile elements, or retrotransposons, present at 1,000 copies in the mouse genome. These elements transpose in a replicative manner via an RNA intermediate and its reverse transcription, and their transposition should therefore be tightly controlled by their transcription level. To analyze the in vivo pattern of expression of these retrovirus-like elements, we constructed several independent transgenic mice with either a complete IAP element marked with an intron or with the IAP promoter, or long terminal repeat (LTR), alone controlling the expression of a lacZ reporter gene with a nuclear localization signal. For all transgenic lines analyzed, IAP expression as determined by reverse transcription-PCR analysis was found to be essentially restricted to the male germ line. Furthermore, in situ 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (X-Gal) staining of all organs disclosed specific beta-galactosidase-positive blue cells only within the testis, found as patches along the seminiferous tubules and often organized as assemblies of 2, 4, 8, or 16 cells. Histochemical analyses of tissues from 13.5-day-old embryos to adults demonstrated that this LTR activity is restricted to gonocytes and premeiotic undifferentiated spermatogonia. Finally, analysis of the methylation status of both transgenes and endogenous IAP LTRs demonstrated identical patterns, with methylation in somatic tissues and hypomethylation in the testis. Transgenic mice therefore reveal an intrinsic, highly restricted IAP expression which had escaped detection in previous global Northern (RNA) blot analyses and with possible strong biological relevance, as IAP activation specifically within the germ line might be a way to generate diversity at the evolutionary level without being deleterious to individuals.

Molecular basis of the pleiotropic phenotype of mice carrying the hypervariable yellow (Ahvy) mutation at the agouti locus

The murine agouti locus regulates a switch in pigment synthesis between eumelanin (black/brown pigment) and phaeomelanin (yellow/red pigment) by hair bulb melanocytes. We recently described a spontaneous mutation, hypervariable yellow (Ahvy) and demonstrated that Ahvy is responsible for the largest range of phenotypes yet identified at the agouti locus, producing mice that are obese with yellow coats to mice that are of normal weight with black coats. Here, we show that agouti expression is altered both temporally and spatially in Ahvy mutants. Agouti expression levels are positively correlated with the degree of yellow pigmentation in individual Ahvy mice, consistent with results from other dominant yellow agouti mutations. Sequencing of 5' RACE and genomic PCR products revealed that Ahvy resulted from the integration of an intracisternal A particle (IAP) in an antisense orientation within the 5' untranslated agouti exon 1C. This retrovirus-like element is responsible for deregulating agouti expression in Ahvy mice; agouti expression is correlated with the methylation state of CpG residues in the IAP long terminal repeat as well as in host genomic DNA. In addition, the data suggest that the variable phenotype of Ahvy offspring is influenced in part by the phenotype of their Ahvy female parent.

IAP retrotransposons in the mouse liver as reporters of ageing

IAP are endogenous retrovirus-like elements present at a thousand copies in the murine genome. They can modulate the level of expression of the tagged genes into which they have inserted, and conversely their activity could be influenced by the level of activity of the genes and/or DNA sequences into which they are embedded. In this report, we have analysed by Northern blots the pattern of expression of the IAP-related transcripts in the organs of young and ageing mice. We show that IAP transcripts of unexpected size (namely 10 kb and 6 kb) are induced in the liver of ageing mice from all inbred and hybrid strains tested. These transcripts are not detected in young mice, and their intensity disclose variations depending on the strain, as those observed for the two canonical 7.2 and 5.4 kb IAP transcripts. It is suggested that these age-dependent IAP transcripts originate from unique sites within the mouse genome that are 'tagged' by an IAP sequence, which would be sensitive both to strain-dependent cellular factors acting at the level of all IAPs, and to an age-dependent liver-specific cellular factor and/or DNA state, responsible for the position-dependent effect. These age-dependent transcripts should allow the identification of putative genes or factors of 'senescence'.

Expression of bacterial cysteine biosynthesis genes in transgenic mice and sheep: toward a new in vivo amino acid biosynthesis pathway and improved wool growth

It is possible to improve wool growth through increasing the supply of cysteine available for protein synthesis and cell division in the wool follicle. As mammals can only synthesise cysteine indirectly from methionine via trans-sulphuration, expression of transgenes encoding microbial cysteine biosynthesis enzymes could provide a more efficient pathway to cysteine synthesis in the sheep. If expressed in the rumen epithelium, the abundant sulphide, produced by ruminal microorganisms and normally excreted, could be captured for conversion to cysteine. This paper describes the characterisation of expression of the cysteine biosynthesis genes of Salmonella typhimurium, cysE, cysM and cysK, and linked cysEM, cysME and cysKE genes as transgenes in mice and sheep. The linked transgenes were constructed with each gene driven by a separate promoter, either with the Rous sarcoma virus long terminal repeat (RSVLTR) promoter or the mouse phosphoglycerate kinase-1 (mPgk-1) promoter, and with human growth hormone (hGH) polyadenylation sequences. Transgenesis of mice with the RSVLTR-cysE gene afforded tissue-specific, heritable expression of the gene. Despite high levels of expression in a number of tissues, extremely low levels of expression occurred in the stomach and small intestine. Results of a concurrent sheep transgenesis experiment using the RSVLTR-cysEM and -cysME linked transgenes revealed that the RSVLTR promoter was inadequate for expression in the rumen. Moreover, instability of transgenes containing the RSVLTR sequence was observed. Expression of mPgk-cysME and -cysKE linked transgenes in most tissues of the mice examined, including the stomach and small intestine, suggested this promoter to be a better candidate for expression of these transgenes in the analogous tissues of sheep. However, a subsequent sheep transgenesis experiment indicated that use of the mPgk-1 promoter, active ubiquitously and early in development, may be inappropriate for expression of the cysteine biosynthesis transgenes. In summary, these results indicate that enzymically active bacterial cysteine biosynthesis gene products can be coexpressed in mammalian cells in vivo but that expression of the genes should be spatio-temporally restricted to the adult sheep rumen epithelium.

Multilocus genomic mapping with intracisternal A-particle proviral oligonucleotide probes hybridized to mouse DNA in dried agarose gels

Recently, oligonucleotide probes that detect intracisternal A-particle (IAP) gene subfamilies with a limited number of proviral copies have been shown to be useful multilocus markers. A procedure for hybridization of these probes has been developed and is described. In summary, the main features of the method are the following: (i) A pulse controller is used during agarose gel electrophoresis to improve resolution of restriction fragments in genomic DNA. (ii) Hybridization is performed in a dried gel. (iii) The hybridized gel is washed in tetramethylammonium chloride to eliminate differences in oligonucleotide composition on hybrid stability. Use of the procedure is demonstrated by genomic mapping of IAP loci in the AXB BXA recombinant inbred mouse strains, identification of hypomethylated loci in tumor cells, and detection of a transposed IAP provirus previously identified as the basis for a mutation at the agouti locus.

Interacisternal A-particle (IAP) genes show similar patterns of hypomethylation in established and primary mouse plasmacytomas

Alterations in cell programming associated with neoplastic transformation may involve widespread changes in patterns of DNA methylation. Increased expression of IAP elements in plasmacytomas compared with LPS-stimulated normal B-cells is accompanied by extensive hypomethylation of IAP sequences (Mietz and Kuff 1990), subsets of which are revealed with the LS2, LS3 and T1 probes. Multiple common LS- and PC-specific IAP loci are hypomethylated in established plasmacytomas, showing that hypomethylation does not occur entirely randomly. Many of the same IAP loci are hypomethylated in primary plasmacytomas induced by two different methods, as soon as recognizable tumor tissue can be isolated. In primary tumors hypomethylation frequently appears to occur in DNA flanking the IAP elements. In the established tumors the hypomethylated sites occur primarily in the IAP LTR, suggesting that for these loci hypomethylation begins in the flanking DNA and is extended into the IAP LTRs during progression of the tumors. The newly hypomethylated IAP LTRs in primary plasmacytomas (as compared to normal B cells) may provide a set of reporter genes for chromosomal regions that are characteristically hypomethylated in these transformed cells and that may contain cellular genes whose activation is related to the transformation process.

The molecular basis for dominant yellow agouti coat color mutations

Agouti expression during the middle portion of the mouse hair growth cycle induces melanocytes to synthesize yellow instead of black pigment, generating black hairs with a yellow band. Dominant agouti alleles increase the amount of yellow pigment in the coat and are associated with pleiotropic effects including obesity, diabetes and increased tumor susceptibility. Four dominant agouti alleles (Aiapy, Aiy, and Avy) were recently shown to result from insertions that cause ubiquitous expression of chimeric transcripts encoding a wild-type agouti protein(1,2). Three insertions were identified as intracisternal A-particles, which helps explain the variable coat colors and parental imprinting effects associated with some dominant agouti alleles.

Differential expression of a new dominant agouti allele (Aiapy) is correlated with methylation state and is influenced by parental lineage

The agouti gene normally confers the wild-type coat color of mice. Dominant mutations at the agouti locus result in a pleiotropic syndrome that is characterized by excessive amounts of yellow pigment in the coat, obesity, a non-insulin-dependent diabetic-like condition, and the propensity to form a variety of tumors. Here, we describe a new dominant mutation at the agouti locus in which an intracisternal A-particle (IAP) has integrated in an antisense orientation immediately 5' of the first coding exon of the gene. This mutation, which we have named Aiapy, results in the ectopic expression of the agouti gene through the utilization of a cryptic promoter within the IAP 5' long terminal repeat (LTR). The coat color of Aiapy/-mice ranges from solid yellow to a pigment pattern that is similar to wild type (pseudoagouti), and the expressivity of this mutant phenotype varies with parental inheritance. Those offspring with a yellow coat ectopically express agouti mRNA at high levels and exhibit marked obesity, whereas pseudoagouti mice express agouti mRNA at a very low level and their weights do not differ from wild-type littermates. Data are presented to show that the differential expressivity of the Aiapy allele is correlated with the methylation status of the inserted IAP 5' LTR. These data further support the hypothesis that in dominant yellow mutations at the agouti locus, it is the ubiquitous expression of the wild-type agouti coding sequence that is responsible for the yellow coat color, obesity, diabetes, and tumorigenesis.

Selective expression of intracisternal A-particle genes in established mouse plasmacytomas

Mouse plasmacytomas generally express higher levels of RNA transcripts from endogenous intracisternal A-particle (IAP) proviral elements than do lipopolysaccharide-stimulated normal lymphocytes. Lymphocytes express a limited and highly characteristic set of IAP elements (lymphocyte-specific [LS] elements). In this study, we examined whether LS elements are expressed at higher levels after transformation of the cells and/or whether new IAP elements are activated. The IAP elements expressed in plasmacytoma MPC11 were characterized by sequence analysis of 22 cDNA clones. The long terminal repeats (LTRs) of the tumor cDNAs proved to be highly related in sequence. None of the clones was of the LS cDNA type. The MPC11 LTRs were five- to sixfold more active than an LS cDNA LTR when tested for promoter activity by transfection into plasmacytoma cells. The LTRs of the tumor-derived cDNAs contained a canonical ATF core sequence (ATF-PC), while the LS cDNAs contained an altered sequence (ATF-LS). An ATF-PC oligonucleotide probe detected multiple IAP transcripts on Northern (RNA) blots of RNA from several plasmacytoma but gave no reaction with RNA from stimulated B lymphocytes. In contrast, an ATF-LS probe detected higher levels of RNA in lymphocyte than in tumor RNAs. Thus, expression of IAP elements in transformed B cells is selective for a different set of regulatory sequence variants than those expressed in normal B cells. Other oligonucleotide probes representing LS- and PC-specific sequence variants detected multiple common hypomethylated IAP proviral loci in three independently derived plasmacytomas. Overall, the results show that established plasmacytomas exhibit a characteristic pattern of IAP proviral hypomethylation and regulatory sequence selection.

Selective expression of intracisternal A-particle genes in established mouse plasmacytomas

Mouse plasmacytomas generally express higher levels of RNA transcripts from endogenous intracisternal A-particle (IAP) proviral elements than do lipopolysaccharide-stimulated normal lymphocytes. Lymphocytes express a limited and highly characteristic set of IAP elements (lymphocyte-specific [LS] elements). In this study, we examined whether LS elements are expressed at higher levels after transformation of the cells and/or whether new IAP elements are activated. The IAP elements expressed in plasmacytoma MPC11 were characterized by sequence analysis of 22 cDNA clones. The long terminal repeats (LTRs) of the tumor cDNAs proved to be highly related in sequence. None of the clones was of the LS cDNA type. The MPC11 LTRs were five- to sixfold more active than an LS cDNA LTR when tested for promoter activity by transfection into plasmacytoma cells. The LTRs of the tumor-derived cDNAs contained a canonical ATF core sequence (ATF-PC), while the LS cDNAs contained an altered sequence (ATF-LS). An ATF-PC oligonucleotide probe detected multiple IAP transcripts on Northern (RNA) blots of RNA from several plasmacytoma but gave no reaction with RNA from stimulated B lymphocytes. In contrast, an ATF-LS probe detected higher levels of RNA in lymphocyte than in tumor RNAs. Thus, expression of IAP elements in transformed B cells is selective for a different set of regulatory sequence variants than those expressed in normal B cells. Other oligonucleotide probes representing LS- and PC-specific sequence variants detected multiple common hypomethylated IAP proviral loci in three independently derived plasmacytomas. Overall, the results show that established plasmacytomas exhibit a characteristic pattern of IAP proviral hypomethylation and regulatory sequence selection.

The intracisternal A-particle upstream element interacts with transcription factor YY1 to activate transcription: pleiotropic effects of YY1 on distinct DNA promoter elements

Murine intracisternal A-particle long terminal repeats contain an intracisternal A-particle upstream enhancer (IUE) element that binds to a 65-kDa IUE binding protein (IUEB) present in both undifferentiated F9 embryonal carcinoma cells and differentiated parietal endoderm-like PYS-2 cells. This IUE element confers a CpG methylation-sensitive IUEB binding and enhancer activity. Using gel retardation, methylation interference, CpG methylation sensitivity binding, and cotransfection assays, we have now identified the 65-kDa IUEB as YY1 (also called NF-E1, delta, or UCRBP), a zinc finger protein related to the Krüppel family. YY1 binds to a number of similar but distinct DNA motifs, and cotransfection assays indicate that these motifs have different enhancer potentials in PYS-2 cells. The relative strengths of these elements are as follows: IUE > kappa E3' from the human immunoglobulin kappa light-chain 3' enhancer > upstream conserved region from the Moloney murine leukemia virus promoter. Results of DNA binding assays suggest that the differences in enhancer potentials are due to the different binding affinities of YY1 to the various motifs and the binding of two other transcription factors to the IUE sequence.

The intracisternal A-particle upstream element interacts with transcription factor YY1 to activate transcription: pleiotropic effects of YY1 on distinct DNA promoter elements

Murine intracisternal A-particle long terminal repeats contain an intracisternal A-particle upstream enhancer (IUE) element that binds to a 65-kDa IUE binding protein (IUEB) present in both undifferentiated F9 embryonal carcinoma cells and differentiated parietal endoderm-like PYS-2 cells. This IUE element confers a CpG methylation-sensitive IUEB binding and enhancer activity. Using gel retardation, methylation interference, CpG methylation sensitivity binding, and cotransfection assays, we have now identified the 65-kDa IUEB as YY1 (also called NF-E1, delta, or UCRBP), a zinc finger protein related to the Krüppel family. YY1 binds to a number of similar but distinct DNA motifs, and cotransfection assays indicate that these motifs have different enhancer potentials in PYS-2 cells. The relative strengths of these elements are as follows: IUE > kappa E3' from the human immunoglobulin kappa light-chain 3' enhancer > upstream conserved region from the Moloney murine leukemia virus promoter. Results of DNA binding assays suggest that the differences in enhancer potentials are due to the different binding affinities of YY1 to the various motifs and the binding of two other transcription factors to the IUE sequence.

Demethylation of somatic and testis-specific histone H2A and H2B genes in F9 embryonal carcinoma cells

In contrast to many other genes containing a CpG island, the testis-specific H2B (TH2B) histone gene exhibits tissue-specific methylation patterns in correlation with gene activity. Characterization of the methylation patterns within a 20-kb segment containing the TH2A and TH2B genes in comparison with that in a somatic histone cluster revealed that: (i) the germ cell-specific unmethylated domain of the TH2A and TH2B genes is defined as a small region surrounding the CpG islands of the TH2A and TH2B genes and (ii) somatic histone genes are unmethylated in both liver and germ cells, like other genes containing CpG islands, whereas flanking sequences are methylated. Transfection of in vitro-methylated TH2B, somatic H2B, and mouse metallothionein I constructs into F9 embryonal carcinoma cells revealed that the CpG islands of the TH2A and TH2B genes were demethylated like those of the somatic H2A and H2B genes and the metallothionein I gene. The demethylation of those CpG islands became significantly inefficient at a high number of integrated copies and a high density of methylated CpG dinucleotides. In contrast, three sites in the somatic histone cluster, of which two sites are located in the long terminal repeat of an endogenous retrovirus-like sequence, were efficiently demethylated even at a high copy number and a high density of methylated CpG dinucleotides. These results suggest two possible mechanisms for demethylation in F9 cells and methylation of CpG islands of the TH2A and TH2B genes at the postblastula stage during embryogenesis.

Demethylation of somatic and testis-specific histone H2A and H2B genes in F9 embryonal carcinoma cells

In contrast to many other genes containing a CpG island, the testis-specific H2B (TH2B) histone gene exhibits tissue-specific methylation patterns in correlation with gene activity. Characterization of the methylation patterns within a 20-kb segment containing the TH2A and TH2B genes in comparison with that in a somatic histone cluster revealed that: (i) the germ cell-specific unmethylated domain of the TH2A and TH2B genes is defined as a small region surrounding the CpG islands of the TH2A and TH2B genes and (ii) somatic histone genes are unmethylated in both liver and germ cells, like other genes containing CpG islands, whereas flanking sequences are methylated. Transfection of in vitro-methylated TH2B, somatic H2B, and mouse metallothionein I constructs into F9 embryonal carcinoma cells revealed that the CpG islands of the TH2A and TH2B genes were demethylated like those of the somatic H2A and H2B genes and the metallothionein I gene. The demethylation of those CpG islands became significantly inefficient at a high number of integrated copies and a high density of methylated CpG dinucleotides. In contrast, three sites in the somatic histone cluster, of which two sites are located in the long terminal repeat of an endogenous retrovirus-like sequence, were efficiently demethylated even at a high copy number and a high density of methylated CpG dinucleotides. These results suggest two possible mechanisms for demethylation in F9 cells and methylation of CpG islands of the TH2A and TH2B genes at the postblastula stage during embryogenesis.

Methylation of an alpha-foetoprotein gene intragenic site modulates gene activity

By comparing the methylation pattern of Mspl/Hpall sites in the 5' region of the mouse alpha-foetoprotein (AFP) gene of different cells (hepatoma cells, foetal and adult liver, fibroblasts), we found a correlation between gene expression and unmethylation of a site located in the first intron of the gene. Other sites did not show this correlation. In transfection experiments of unmethylated and methylated AFP-CAT chimeric constructions, we then showed that methylation of the intronic site negatively modulates expression of CAT activity. We also found that a DNA segment centered on this site binds nuclear proteins; however methylation did not affect protein binding.

Selective activation of a discrete family of endogenous proviral elements in normal BALB/c lymphocytes

Intracisternal A-particle (IAP) proviral elements are abundant and widely dispersed in the mouse genome. IAP-related transcripts have been detected in normal mouse tissues where expression is under genetic control. In this study, we sought to determine whether IAP expression in BALB/c thymus and lipopolysaccharide-stimulated B cells was due to selective or indiscriminate activation of IAP elements. cDNA libraries were prepared from each source. A total of 86 IAP cDNA clones were isolated from both libraries, and 37 of these were sequenced over a common 0.7- to 1.0-kb region of the IAP genome that included the 3' long terminal repeat (LTR). Three highly related families of elements were found to be expressed in the two cell types examined. All of the related elements had a distinctive U3 regulatory region. Thirteen individual IAP proviral elements were distinguished on the basis of sequence differences within the R region of the LTR. Hybridization of genomic DNA with element-specific oligonucleotide probes confirmed the presence of a restricted number of proviral copies in the lymphocyte-specific family of elements. Most of these copies were found to be methylated in the lymphocyte DNA, but at least seven were hypomethylated in their 5' LTRs. This study shows that activation of IAP elements in normal normal mouse lymphocytes is highly selective. Activation is probably a function of both sequence specificity and methylation status of the proviral LTR.

Selective activation of a discrete family of endogenous proviral elements in normal BALB/c lymphocytes

Intracisternal A-particle (IAP) proviral elements are abundant and widely dispersed in the mouse genome. IAP-related transcripts have been detected in normal mouse tissues where expression is under genetic control. In this study, we sought to determine whether IAP expression in BALB/c thymus and lipopolysaccharide-stimulated B cells was due to selective or indiscriminate activation of IAP elements. cDNA libraries were prepared from each source. A total of 86 IAP cDNA clones were isolated from both libraries, and 37 of these were sequenced over a common 0.7- to 1.0-kb region of the IAP genome that included the 3' long terminal repeat (LTR). Three highly related families of elements were found to be expressed in the two cell types examined. All of the related elements had a distinctive U3 regulatory region. Thirteen individual IAP proviral elements were distinguished on the basis of sequence differences within the R region of the LTR. Hybridization of genomic DNA with element-specific oligonucleotide probes confirmed the presence of a restricted number of proviral copies in the lymphocyte-specific family of elements. Most of these copies were found to be methylated in the lymphocyte DNA, but at least seven were hypomethylated in their 5' LTRs. This study shows that activation of IAP elements in normal normal mouse lymphocytes is highly selective. Activation is probably a function of both sequence specificity and methylation status of the proviral LTR.

Intracisternal A-type particle-mediated activations of cytokine genes in a murine myelomonocytic leukemia: generation of functional cytokine mRNAs by retroviral splicing events

Previously we have described the derivation of three distinct classes of leukemic cell clones from a single in vivo-passaged myelomonocytic leukemia, WEHI-274, that arose in a mouse infected with the Abelson leukemia virus/Moloney leukemia virus complex (K. B. Leslie and J. W. Schrader, Mol. Cell. Biol. 9:2414-2423, 1989). The three classes of cell clones were characterized by distinct patterns of growth in vitro, the production of cytokines, and the presence of cytokine gene rearrangements. However, all three classes of WEHI-274 clones bore a common rearrangement of the c-myb gene, suggesting that all were derived from the one ancestral cell and that at least three distinct and independent autostimulatory events were involved in the progression of a single myeloid leukemic disease. In this article, we demonstrate that the autocrine growth factor production by the WEHI-274 leukemic clones resulted from cytokine gene activations mediated by the insertion of an intracisternal A-type particle (IAP) sequence 5' to the interleukin-3 (IL-3) gene, in the case of the class I clone, or 5' to the gene for granulocyte-macrophage colony-stimulating factor (GM-CSF), in the case of the class II clones. IAPs are defective murine retroviruses encoded by endogenous genetic elements which may undergo transpositions and act as endogenous mutagens. The functional IL-3 and GM-CSF mRNAs were generated by mechanisms in which the splice donor apparatus of the IAP sequence has been used in IAP gag-to-IL-3 or -GM-CSF splicing events.

Intracisternal A-type particle-mediated activations of cytokine genes in a murine myelomonocytic leukemia: generation of functional cytokine mRNAs by retroviral splicing events

Previously we have described the derivation of three distinct classes of leukemic cell clones from a single in vivo-passaged myelomonocytic leukemia, WEHI-274, that arose in a mouse infected with the Abelson leukemia virus/Moloney leukemia virus complex (K. B. Leslie and J. W. Schrader, Mol. Cell. Biol. 9:2414-2423, 1989). The three classes of cell clones were characterized by distinct patterns of growth in vitro, the production of cytokines, and the presence of cytokine gene rearrangements. However, all three classes of WEHI-274 clones bore a common rearrangement of the c-myb gene, suggesting that all were derived from the one ancestral cell and that at least three distinct and independent autostimulatory events were involved in the progression of a single myeloid leukemic disease. In this article, we demonstrate that the autocrine growth factor production by the WEHI-274 leukemic clones resulted from cytokine gene activations mediated by the insertion of an intracisternal A-type particle (IAP) sequence 5' to the interleukin-3 (IL-3) gene, in the case of the class I clone, or 5' to the gene for granulocyte-macrophage colony-stimulating factor (GM-CSF), in the case of the class II clones. IAPs are defective murine retroviruses encoded by endogenous genetic elements which may undergo transpositions and act as endogenous mutagens. The functional IL-3 and GM-CSF mRNAs were generated by mechanisms in which the splice donor apparatus of the IAP sequence has been used in IAP gag-to-IL-3 or -GM-CSF splicing events.

Binding of the transcription factor EBP-80 mediates the methylation response of an intracisternal A-particle long terminal repeat promoter

Intracisternal A-particle (IAP) expression in mouse cells has been correlated with hypomethylation of HhaI and HpaII sites in proviral long terminal repeats (LTRs). In a previous study, in vitro methylation of three HhaI sites in the U3 region of the LTR from the cloned genomic IAP element, MIA14, was shown to inhibit promoter activity in vivo. In this study, we found by site-directed mutagenesis that the two more downstream HhaI sites within this LTR were responsible for the methylation effects on promoter activity in vivo; methylation of the other (5') HhaI site, which lies within a putative SP1 binding domain, did not affect promoter activity. Methylation of the HhaI sites also inhibited promoter activity of the LTR in a cell-free transcription system. Exonuclease III footprinting demonstrated methylation-induced changes in protein binding over the region encompassing the downstream HhaI site, designated the Enh2 domain. The protein that interacts specifically with this domain, EBP-80, was characterized in a previous study (M. Falzon and E. L. Kuff, J. Biol. Chem. 264:21915-21922, 1989). We show here that the presence of methylcytosine in the HhaI site within the Enh2 domain inhibited binding of EBP-80 in vitro. The methylated MIA14 LTR construct was much less responsive to added EBP-80 in an in vitro transcription system than was the unmethylated construct. These data suggest that CpG methylation within the Enh2 domain may exert its effect on transcription in vivo by altering the interaction between EBP-80 and its cognate DNA sequence.

CpG methylation of an endogenous retroviral enhancer inhibits transcription factor binding and activity

The endogenous retrovirus, intracisternal A-particle (IAP), is expressed at unique stages during murine embryogenesis and is also activated during the in vitro differentiation of F9 cells. We have examined the DNA elements and protein factors that control IAP expression during F9 differentiation. In the present study an IAP upstream enhancer (IUE) is identified by transient transfection assays and found to be active in both undifferentiated and differentiated cells. Further analyses reveal that a ubiquitous 65 kDa protein factor, the IUE binding protein (IUEB), binds with the IUE. Site-specific methylation within the IUEB binding site strongly inhibits both IUEB binding and IUE transcriptional activity, suggesting that methylation may regulate IUE function and IAP expression.

Binding of the transcription factor EBP-80 mediates the methylation response of an intracisternal A-particle long terminal repeat promoter

Intracisternal A-particle (IAP) expression in mouse cells has been correlated with hypomethylation of HhaI and HpaII sites in proviral long terminal repeats (LTRs). In a previous study, in vitro methylation of three HhaI sites in the U3 region of the LTR from the cloned genomic IAP element, MIA14, was shown to inhibit promoter activity in vivo. In this study, we found by site-directed mutagenesis that the two more downstream HhaI sites within this LTR were responsible for the methylation effects on promoter activity in vivo; methylation of the other (5') HhaI site, which lies within a putative SP1 binding domain, did not affect promoter activity. Methylation of the HhaI sites also inhibited promoter activity of the LTR in a cell-free transcription system. Exonuclease III footprinting demonstrated methylation-induced changes in protein binding over the region encompassing the downstream HhaI site, designated the Enh2 domain. The protein that interacts specifically with this domain, EBP-80, was characterized in a previous study (M. Falzon and E. L. Kuff, J. Biol. Chem. 264:21915-21922, 1989). We show here that the presence of methylcytosine in the HhaI site within the Enh2 domain inhibited binding of EBP-80 in vitro. The methylated MIA14 LTR construct was much less responsive to added EBP-80 in an in vitro transcription system than was the unmethylated construct. These data suggest that CpG methylation within the Enh2 domain may exert its effect on transcription in vivo by altering the interaction between EBP-80 and its cognate DNA sequence.

Gene expression of an endogenous retrovirus-like element during murine development and aging

We have measured intracisternal A-particle (IAP) RNA levels during development and aging in C57BL/6J mouse tissues to determine possible age-dependent changes in gene expression of these retrovirus-like sequences. Total RNA was isolated from tissues of embryonic and new born mice and mice ranging in age from 2 months to 32 months of age. RNA samples were either slot-blotted directly or fractionated on denaturing agarose gels and transferred to nylon membranes. Hybridization with cloned, 32P-labeled IAP sequences showed that both the mass amounts and the relative proportions of IAP transcripts varied between tissues and as a function of age. IAP gene products were higher in brain and kidney tissues than in liver and heart tissues. The relative proportion of transcripts increased in embryonic tissues until birth and following birth, was highest in neonatal or 2-month-old tissues. The adult levels of IAP-related RNAs did not change significantly from 6 to 24 months of age. However, 32-month-old tissues exhibited the lowest content of IAP transcripts, with the exception of heart tissue which did not change with age. A 5.4-kb RNA was the predominant IAP transcript in most samples, but each tissue had a characteristic size distribution of IAP-related transcripts. These results demonstrate that transcription of IAP genes continues throughout the life span of this mouse strain with tissue-specific and age-dependent regulation of expression.

Tissue and strain-specific patterns of endogenous proviral hypomethylation analyzed by two-dimensional gel electrophoresis

Proviral sequences related to the intracisternal A particle (IAP) are amplified and dispersed in the mouse genome. Their expression is associated with hypomethylation at CpG sites in the 5' long terminal repeat. We have used two-dimensional agarose gel electrophoresis to examine patterns of IAP hypomethylation in mouse DNA. The method is sensitive to both the methylation status of a conserved Hae II site in the 5' long terminal repeat and the location of the closest BamHI site in the flanking DNA upstream of each hypomethylated long terminal repeat. The method also defects restriction fragments derived from IAP elements that are themselves methylated but have an unmethylated Hae II site in their 5' adjacent DNA. DNAs from each of four inbred mouse strains (BALB/c, C3H/He, C57BL/6, and DBA/2) gave distinctive two-dimensional patterns of BamHI/Hae II restriction fragments detected by hybridization with an IAP probe. This constitutive pattern was largely conserved among several tissues of each strain, but some tissue-specific variations were observed. The site-specific hypomethylations reflected in the two-dimensional patterns were heritable properties, since DNA from progeny of an interstrain cross contained both parental sets of fragments. IAP elements may be useful endogenous reporters of genomic methylation patterns.

Isolation and characterization of a family of rat endogenous retroviral sequences

The complete nucleotide sequence of one representative rat genomic unit flanked on both sides with RAL elements, which have structural features specific to retroviral LTRs (1), was determined. The total unit was about 7.5 kbp long, and there was a partial homology to known retroviral sequences in gag, pol, and env regions. The sequence also contained minus- and plus-strand primer binding sites, thereby indicating a retroviral nature in replication. Transcription of the sequence was extensive in tumor cells and was strongly correlated with the state of methylation within 5' LTRs, which were highly methylated in the normal but not in the tumor state. In functional assays with bacterial chloramphenicol acetyltransferase constructs containing a series of deleted LTRs, there seemed to be both positive and negative cis-acting effector sequences.

Inhibition of rat growth hormone promoter activity by site-specific DNA methylation

The effect of methylation on rat growth hormone (rGH) promoter activity was determined in GH3 cells by measuring rGH-Neo and rGH-CAT fusion gene expression with or without prior in vitro treatment with the site-specific DNA methyltransferases, M-BsuE and M-HhaI. To assay for rGH-promoter-specific effects of DNA methylation, RSV-Neo and RSV-CAT activities with or without M-BsuE, M-HhaI and M-HpaII treatment were measured in parallel cultures of GH3 cells. GH1-Neo and RSV-Neo fusion gene expression was inhibited by in vitro methylation from 44 to 83% as measured by the number of Geneticin-resistant GH3 cell colonies. Methylation of the GH1 promoter by M-BsuE exhibited some selective inhibition of Neo expression as determined by colony numbers, although extensive methylation of non-promoter DNA in GH1-Neo and RSV-Neo by M-HhaI and M-HpaII also inhibited Neo expression. Southern blot analysis of genomic DNA isolated from the Geneticin-resistant GH3 cells indicated that Geneticin-resistance was accompanied by demethylation of the BsuE (ThaI) sites in stably incorporated GH1-Neo DNA but not RSV-Neo DNA. Transient expression of the CAT gene in GH3 cells was selectively inhibited by 60% upon methylation of two BsuE (ThaI) sites in the GH1 promoter of GH1-CAT by M-BsuE. The data demonstrate, for the first time, to our knowledge, a direct effect of DNA methylation on the activity of the rat growth hormone promoter.

Expression of intracisternal A-type particles is increased when a B-cell lymphoma differentiates into an immunoglobulin-secreting cell

The murine B-cell lymphoma CH12, like many other murine cells, expresses intracisternal A-type particles (IAPs). When CH12 cells are treated with lipopolysaccharide, the cells differentiate and secrete immunoglobulin M. The expression of IAP genes was also increased, in parallel with the increased expression of immunoglobulin genes. The amount of IAP mRNA increased within 48 h of lipopolysaccharide treatment and reached a level fivefold higher than that in unactivated CH12 cells. The two major IAP transcripts (7.2 and 5.4 kilobases) were induced to similar extents. The increased level of mRNA was reflected in higher levels of the major IAP structural protein p70, whose abundance increased 3.6-fold. The number of IAP particles per cell also increased upon activation of CH12, from 67 in nonsecreting CH12 to 290 in secreting cells. All of the IAPs were confined to the cisternae of the endoplasmic reticulum (ER), regardless of the differentiation state of the cell. Accompanying the induction of p70 was the induction of the related IAP polypeptide p102. A third viral polypeptide, p120, was also made in CH12; its abundance was almost unchanged. Localization of the IAP proteins on ultrathin frozen sections showed that most were assembled into particles in the ER. However, there were small pools of unassembled proteins both in the ER and on the plasma membrane. p70 and p120 could be detected, by iodination, on the surfaces of both secreting and nonsecreting CH12 cells. Unlike p70 and p120, p102 did not seem to be membrane associated. Taken together, these observations show that IAP expression is regulated developmentally in B lymphocytes. Also, these observations point to possible interactions between IAP genes and other cellular genes.

Cytosine methylation prevents binding to DNA of a HeLa cell transcription factor required for optimal expression of the adenovirus major late promoter

Cytosine methylation within CpG dinucleotides has been implicated in the regulation of gene expression in vertebrates and, in some cases, has been shown to be causative in repression of transcription. We have examined whether methylation of CpG dinucleotides located within the binding site for a specific transcription factor, MLTF or USF, affects its binding to DNA. This HeLa cell factor binds to the adenovirus major late promoter (AdMLP), as well as endogenous cellular genes, and stimulates transcription in an in vitro assay. Synthetic oligonucleotides in which 5-methylcytosine replaces cytosine at specific sites were used to generate duplex DNAs, and the formation of complexes of these oligomers with MLTF was studied using a gel retardation assay. Methylation at a CpG site centrally located within the binding site strongly inhibited complex formation, whereas methylation at a site 6 bases away had no demonstrable effect. Methylation at the central site was also shown to inhibit specific transcription in vitro from the AdMLP. Methylation at the central site on only one strand caused a partial inhibition of binding, the effect being greater when the noncoding strand was methylated. The results indicate that in some cases, site-specific methylation may inhibit gene expression directly by blocking binding to DNA of factors required for optimal transcription. Along with other recent findings, they suggest an interplay between DNA methylation and transcription factors in the regulation of gene expression.

Nearly identical members of the heterogeneous IAP gene family are expressed in thymus of different mouse strains

Poly(A)RNAs prepared from the thymuses of C57BL/6J and DBA/2J mice were used to construct cDNA libraries in the bacterial expression vector lambda gt11. The libraries were scanned first for protein production with polyvalent antiserum prepared against the 73kDa gag protein of mouse intracisternal A-particles (IAP). Reactive plaques were crossed-screened by hybridization with an IAP-specific DNA probe. Two IAP-specific protein-producing plaques were obtained from the C57BL/6 library and 4 from the DBA/2 library. One C57BL/6 cDNA clone (B12) and two DBA cDNA clones (D8 and D20) were sequenced in their entirety. Clones B12 and D8 were remarkably similar, particularly when compared to the 6 other IAP elements that have been sequenced thus far. We discuss the evidence which leads us to suggest that these clones may be derived from allelic IAP elements expressed in mouse thymus.

Specific association between type-II intracisternal A-particle elements and other repetitive sequences in the mouse genome

The majority of type-II intracisternal A-particle (IAP) element clones isolated from a mouse genomic library also contained highly repetitive DNA sequences in addition to the moderately repetitive IAP elements. Further analysis revealed that eleven of the twelve clones contained sequences of the mouse L1 family. One clone contained four copies of a limited region of the 3' end of the L1 element in a 12-kb stretch of sequence. This clone also contained a newly identified repetitive sequence which is found associated with type-II IAP elements. Type-II IAP elements were completely methylated in mouse embryo DNA; in myeloma cells, partial demethylation of the sequences correlated with known transcriptional activity of the IAP subclasses. Analysis of genomic DNA showed that association with other repetitive sequences appears to be a general property of many type-II IAP elements and may reflect their location in a particular chromosomal environment.