Detection and cloning of unique integration sites of retrotransposon, intracisternal A-particle element in the genome of acute myeloid leukemia cells in mice

A combinatorial approach to the restriction of a mouse genome

BACKGROUND

A fragmentation of genomic DNA by restriction digestion is a popular step in many applications. Usually attention is paid to the expected average size of the DNA fragments. Another important parameter, randomness of restriction, is regularly implied but rarely verified. This parameter is crucial to the expectation, that either all fragments made by restriction will be suitable for the method of choice, or only a fraction of those will be effectively used by the method. If only a fraction of the fragments are used, we often should know whether the used fragments are representative of the whole genome. With a modern knowledge of mouse, human and many other genomes, frequencies and distributions of restriction sites and sizes of corresponding DNA fragments can be analyzed in silico. In this manuscript, the mouse genome was systematically scanned for frequencies of complementary 4-base long palindromes.

FINDINGS AND CONCLUSIONS

The study revealed substantial heterogeneity in distribution of those sites genome-wide. Only few palindromes showed close to random pattern of distribution. Overall, the distribution of frequencies for most palindromes is much wider than expected by random occurrence. In practical terms, accessibility of genome upon restriction can be improved by a selective combination of restrictases using a few combinatorial rules. It is recommended to mix at least 3 restrictases, their recognition sequences (palindrome) should be the least similar to each other. Principles of the optimization and optimal combinations of restrictases are provided.

Translation from nonautonomous type IAP retrotransposon is a critical determinant of transposition activity: implication for retrotransposon-mediated genome evolution

Retrotransposons constitute a major component of the genome and their proliferation significantly impacts genome evolution. Retrotransposons can propagate autonomously or nonautonomously. Nonautonomous type transposition occurs through trans-complementation by autonomous type retrotransposons. While autonomous type retrotransposons have been studied extensively, the translation products from nonautonomous type retrotransposons are not well characterized. In a previous study, we isolated both autonomous and nonautonomous type intracisternal A particle (IAP) elements from the mouse genome and established a tissue culture assay to examine trans-complementation of nonautonomous type IAP element. Using this system in the present study, we determined an active role for the translation product from nonautonomous type IAP element. Point mutations that either eliminated or truncated the IAP protein were introduced and their effects on trans-complementation were examined. Trans-complementation efficiency correlated with the expression of nonautonomous type IAP protein. The effect of nonautonomous type IAP protein was observed only when it was provided in cis, suggesting an interaction of nonautonomous type IAP protein and its transcript immediately after transcription. Interaction of autonomous and nonautonomous type IAP proteins was demonstrated by immunostaining and coimmunoprecipitation assay. Based on these findings, we propose a model in which nonautonomous type IAP protein associates with its transcript, recruits autonomous type IAP protein, and promotes the assembly of transposition competent IAP particle. The active role of the nonautonomous type IAP protein revealed in this study may provide a new insight into retrotransposon proliferation within the genome.

Microarray-based global mapping of integration sites for the retrotransposon, intracisternal A-particle, in the mouse genome

Mammalian genomes contain numerous evolutionary harbored mobile elements, a part of which are still active and may cause genomic instability. Their movement and positional diversity occasionally result in phenotypic changes and variation by causing altered expression or disruption of neighboring host genes. Here, we describe a novel microarray-based method by which dispersed genomic locations of a type of retrotransposon in a mammalian genome can be identified. Using this method, we mapped the DNA elements for a mouse retrotransposon, intracisternal A-particle (IAP), within genomes of C3H/He and C57BL/6J inbred mouse strains; consequently we detected hundreds of probable IAP cDNA-integrated genomic regions, in which a considerable number of strain-specific putative insertions were included. In addition, by comparing genomic DNAs from radiation-induced myeloid leukemia cells and its reference normal tissue, we detected three genomic regions around which an IAP element was integrated. These results demonstrate the first successful genome-wide mapping of a retrotransposon type in a mammalian genome.

Retrotransposons influence the mouse transcriptome: implication for the divergence of genetic traits

Massive accumulation of retrotransposons, comprising >40% of human and mouse genomes, is one of the major events in the evolution of the genome. However, most retrotransposons have lost retrotransposition competency, which makes studying their role in genome evolution elusive. Intracisternal A-particle (IAP) elements are long terminal repeat (LTR)-type mouse retrotransposons consisting of full-length and internally deleted types. Some are retrotransposition competent and their upregulated activity has been reported in mutant mice deficient in genome defense systems, suggesting that IAP elements provide a unique platform for studying the interaction between retrotransposons and mammalian genomes. Using the IAP element as a model case, here we show that mobilization of retrotransposons alters the mouse transcriptome. Retrotransposition assay in cultured cells demonstrated that a subset of internally deleted IAP elements, called IDelta1 type, retrotranspose efficiently when supplied with functional IAP proteins. Furthermore, the IDelta1 type IAP element exhibited substantial transcription-inducing activity in the flanking region. Genomewide transcript analysis of embryonic stem (ES) cells identified IAP-induced transcripts, including fusion transcripts between IAP sequence and endogenous genes. Unexpectedly, nearly half of these IAP elements obtained from ES cells derived from 129 mouse strain were absent in the C57BL/6 genome, suggesting that IAP-driven transcription contributes to the unique trait of the individual mouse strain. On the basis of these data, we propose that retrotransposons are one of the drivers that shape the mammalian transcriptome.

Retrotransposition of limited deletion type of intracisternal A-particle elements in the myeloid leukemia Clls of C3H/He mice

The murine genome has about 1,000 copies of DNA elements for the intracisternal A-particle (IAP) that resembles a retrovirus. We previously reported that the genomic DNA of the cells from radiation-induced acute myeloid leukemia (AML) lines derived from C3H/He inbred mice was frequently rearranged by the integration of the IAP element. In this study, 8 IAP elements from the characteristic integration sites in 6 cell lines of radiation-induced AML from different mice were characterized and compared in structure with 114 IAP elements isolated from the normal C3H/He genome. One of the 8 elements was a full-length type I IAP, and 7 were of type-I Delta 1 with a common deletion site. Although the type I Delta 1 form is a minor population accounting for about 6% of total genomic IAP elements, it is predominantly retrotransposed in the AML cells from different C3H/He mice. This indicates that limited populations of the IAP elements contribute to the unique retrotransposition in AML cells.

Redox regulation of a novel L1Md-A2 retrotransposon in vascular smooth muscle cells

Activation and reintegration of retrotransposons into the genome is linked to several diseases in human and rodents, but mechanisms of gene activation remain largely unknown. Here we identify a novel gene of L1Md-A2 lineage in vascular smooth muscle cells and show that environmental hydrocarbons enhance gene expression and activate monomer-driven transcription via a redox-sensitive mechanism. Site-directed mutagenesis and progressive deletion analyses identified two antioxidant/electrophile response-like elements (5'-GTGACTCGAGC-3') within the A2/3 and A3 region. These elements mediated activation, with the A3 monomer playing an essential role in transactivation. This signaling pathway may contribute to gene instability during the course of atherogenesis.

Enhanced expression of the early retrotransposon in C3H mouse-derived myeloid leukemia cells

Cells of acute myeloid leukemia (AML) from C3H/He mice express an increased amount of RNA for an endogenous retrovirus-like retrotransposon, intracisternal A-particle element. We analyzed the transcription of other mouse retrotransposons in C3H-derived tumor cells and found that all the AML lines from different mice overexpress early-transposon (ETn) RNA. In contrast, only faint levels of ETn were detected in the cells from other tumors, including hepatoma and lymphoma. The polyadenylation sites of the ETn RNA in the AML cells varied. We also determined the binding site for the nuclear extract of the AML cells in the long terminal repeat sequence of ETn. The overexpression of ETn as a common phenotype of AML cells suggests that myeloid cells with this phenotype are the origin of all the AML cells or that the phenotype is acquired during leukemogenesis.

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.