Functional RNA polymerase II promoters in solitary retroviral long terminal repeats (LTR-IS elements)

The intron-enriched HERV-K(HML-10) family suppresses apoptosis, an indicator of malignant transformation

Background

Human endogenous retroviruses (HERVs) constitute 8% of the human genome and contribute substantially to the transcriptome. HERVs have been shown to generate RNAs that modulate host gene expression. However, experimental evidence for an impact of these regulatory transcripts on the cellular phenotype has been lacking.

Results

We characterized the previously little described HERV-K(HML-10) endogenous retrovirus family on a genome-wide scale. HML-10 invaded the ancestral genome of Old World monkeys about 35 Million years ago and is enriched within introns of human genes when compared to other HERV families. We show that long terminal repeats (LTRs) of HML-10 exhibit variable promoter activity in human cancer cell lines. One identified HML-10 LTR-primed RNA was in opposite orientation to the pro-apoptotic Death-associated protein 3 (DAP3). In HeLa cells, experimental inactivation of HML-10 LTR-primed transcripts induced DAP3 expression levels, which led to apoptosis.

Conclusions

Its enrichment within introns suggests that HML-10 may have been evolutionary co-opted for gene regulation more than other HERV families. We demonstrated such a regulatory activity for an HML-10 RNA that suppressed DAP3-mediated apoptosis in HeLa cells. Since HML-10 RNA appears to be upregulated in various tumor cell lines and primary tumor samples, it may contribute to evasion of apoptosis in malignant cells. However, the overall weak expression of HML-10 transcripts described here raises the question whether our result described for HeLa represent a rare event in cancer. A possible function in other cells or tissues requires further investigation.

Electronic supplementary material

The online version of this article (doi:10.1186/s13100-016-0081-9) contains supplementary material, which is available to authorized users.

Anti-IgM antibodies down modulate mu-enhancer activity and OTF2 levels in LPS-stimulated mouse splenic B-cells

Stimulation of small, resting, splenic B cells with bacterial lipopolysaccharide (LPS) induces proliferation, differentiation to plasma cell formation, and the expression of immunoglobulin heavy chain (IgH). When this is combined with agents which crosslink surface Ig, differentiation and the induction of surface immunoglobulin are suppressed even though proliferation proceeds. We find that anti-mu antibodies suppresses Ig gene expression of transfected mu constructs, even if either the membrane or secretory segments have been deleted. We examined the effects of anti-mu treatment on the IgH enhancer (IgHE) attached to a heterologous test gene (CAT). Indeed the IgH enhancer alone was subject to anti-mu suppression, while the SV40 enhancer was insensitive. To determine what was responsible for suppression of enhancer function by anti-mu we examined nuclear extracts from stimulated splenic B cells for the presence of sequence-specific DNA binding activities to various sites within the enhancer. We found two specific differences--an induction in mu E5 binding activity, and a reduction in octamer transcription factor 2 (OTF2) binding activity, after anti-mu treatment. Analysis of these cells by in situ immunofluorescence with anti-OTF2 antibodies suggests that the nuclear localization of OTF2 in anti-mu treated cells may change, as well as its absolute level.

A developmental-specific factor binds to suppressor sites flanking the immunoglobulin heavy-chain enhancer

We identified a novel nuclear protein, NF-mu NR, that binds to multiple sites flanking the immunoglobulin heavy-chain enhancer. The expression of NF-mu NR shows a unique developmental pattern; the activity is present in all cells representing early stages of B-cell development, but is absent from more mature cells that express a high level of immunoglobulin heavy chains. NF-mu NR also is present in most cell lines outside of the B-cell lineage (e.g., T cells, macrophages, and fibroblasts). The binding sites for NF-mu NR correlate very well with cis-acting negative regulatory elements of the heavy-chain enhancer defined previously. Indeed, when the segments bound by NF-mu NR are deleted from the enhancer, it is now found to function as a positive transcription element in T cells and macrophages. Taken together, these results suggest that NF-mu NR may function as a negative regulator of enhancer function. The observation that the segments bound by NF-mu NR correspond to the segments bound to the nuclear matrix suggests an intriguing model not only of how enhancers might function but also of how negative regulation might occur.

Negative regulatory element associated with potentially functional promoter and enhancer elements in the long terminal repeats of endogenous murine leukemia virus-related proviral sequences

Three series of recombinant DNA clones were constructed, with the bacterial chloramphenicol acetyltransferase (CAT) gene as a quantitative indicator, to examine the activities of promoter and enhancer sequence elements in the 5' long terminal repeat (LTR) of murine leukemia virus (MuLV)-related proviral sequences isolated from the mouse genome. Transient CAT expression was determined in mouse NIH 3T3, human HT1080, and mink CCL64 cultured cells transfected with the LTR-CAT constructs. The 700-base-pair (bp) LTRs of three polytropic MuLV-related proviral clones and the 750-bp LTRs of four modified polytropic proviral clones, in complete structures either with or without the adjacent downstream sequences, all showed very little or negligible activities for CAT expression, while ecotropic MuLV LTRs were highly active. The MuLV-related LTRs were divided into three portions and examined separately. The 3' portion of the MuLV-related LTRs that contains the CCAAC and TATAA boxes was found to be a functional promoter, being about one-half to one-third as active as the corresponding portion of ecotropic MuLV LTRs. A MboI-Bg/II fragment, representing the distinct 190- to 200-bp inserted segment in the middle, was found to be a potential enhancer, especially when examined in combination with the simian virus 40 promoter in CCL64 cells. A PstI-MboI fragment of the 5' portion, which contains the protein-binding motifs of the enhancer segment as well as the upstream LTR sequences, showed moderate enhancer activities in CCL6 cells but was virtually inactive in NIH 3T3 cells and HT1080 cells; addition of this fragment to the ecotropic LTR-CAT constructs depressed CAT expression. Further analyses using chimeric LTR constructs located the presence of a strong negative regulatory element within the region containing the 5' portion of the enhancer and the immediate upstream sequences in the MuLV-related LTRs.

Insertion of a retrotransposon within the 3' end of a mouse gene provides a new functional polyadenylation signal

A site of genomic insertion of the mouse retrotransposon LTR-IS/MuRRS was analysed. The comparison of the genomic and the cDNA clones indicates the insertion of the LTR-IS element into the 3' untranslated region of a mouse gene. The fact that the isolated cDNA clone ends with a poly A tail 20 nucleotides downstream from the LTR-IS AATAAA box and the result of the S1-nuclease mapping provides evidence that the 3' end of the mouse gene transcript was generated under the control of the LTR-IS polyadenylation signal.

The 3' long terminal repeat of a transcribed yet defective endogenous retroviral sequence is a competent promoter of transcription

Although actively transcribed and present as multiple genomic copies, a distinct class of endogenous murine leukemia virus-related sequence does not give rise to infectious virus. Since the long terminal repeat at the 3' terminus provides the transcriptional start site after reintegration, we determined the structure and potential promoter activity of that sequence obtained from cDNA of endogenous retroviral transcripts. These studies demonstrate that the distinctive 3' long terminal repeat sequence of these transcripts could serve as an effective promoter of transcription and, therefore, may not be the primary defect in the infectious cycle of retroviral replication but may result in the propagation of these endogenous retroviral sequences in the genome as retrotransposons.

Transcriptional control of mu- and kappa-gene expression in resting and bacterial lipopolysaccharide-activated normal B cells

When murine resting B cells are polyclonally stimulated by bacterial lipopolysaccharide (LPS) in vitro for a short period of 4 days, they are activated to DNA synthesis and cell division, and they also differentiate to immunoglobulin (Ig)-secreting plasma cells. These two events are accompanied with several qualitative changes at the Ig mRNA level: the disappearance of delta mRNA after stimulation, the switch from membrane to secretory form of mu-mRNA, and the late appearance of IgM joining chain (J-chain) mRNA. There is also a quantitative increase of Ig-gene expression at the level of: Ig gene transcription, mu-, kappa- and J-chain mRNA accumulation, and Ig translation and secretion. A comparison of Ig transcription rates before and in the course of LPS stimulation, as determined by in vitro transcriptional run-on assays, has shown that there is a large increase of the RNA polymerase density on both mu- and kappa-loci (30-60-fold), which is quantitatively comparable with the accumulation of both mu- and kappa-mRNAs at the steady state mRNA level. These data therefore suggest that former results obtained with tumor cells regarding post-transcriptional control of Ig gene expression do not reflect the physiological behavior of normal B cells with respect to the molecular events of B cell triggering. We also propose that additional molecular events such as RNA processing and the transcriptional activation of J-chain gene might be essential for controlling the maximal transcriptional rate across the Ig loci.