Abstract
L1 retrotransposons have a prominent role in reshaping mammalian genomes. To replicate, the L1 ribonucleoprotein particle (RNP) first uses its endonuclease (EN) to nick the genomic DNA. The newly generated DNA end is subsequently used as a primer to initiate reverse transcription within the L1 RNA poly(A) tail, a process known as target-primed reverse transcription (TPRT). Prior studies demonstrated that most L1 insertions occur into sequences related to the L1 EN consensus sequence (degenerate 5′-TTTT/A-3′ sites) and frequently preceded by imperfect T-tracts. However, it is currently unclear whether—and to which degree—the liberated 3′-hydroxyl extremity on the genomic DNA needs to be accessible and complementary to the poly(A) tail of the L1 RNA for efficient priming of reverse transcription. Here, we employed a direct assay for the initiation of L1 reverse transcription to define the molecular rules that guide this process. First, efficient priming is detected with as few as 4 matching nucleotides at the primer 3′ end. Second, L1 RNP can tolerate terminal mismatches if they are compensated within the 10 last bases of the primer by an increased number of matching nucleotides. All terminal mismatches are not equally detrimental to DNA extension, a C being extended at higher levels than an A or a G. Third, efficient priming in the context of duplex DNA requires a 3′ overhang. This suggests the possible existence of additional DNA processing steps, which generate a single-stranded 3′ end to allow L1 reverse transcription. Based on these data we propose that the specificity of L1 reverse transcription initiation contributes, together with the specificity of the initial EN cleavage, to the distribution of new L1 insertions within the human genome.
Highlights
Retrotransposons are highly repetitive and dispersed sequences, accounting for almost half of our DNA [1]
L1 elements are the only autonomously active jumping genes in the human genome. They replicate through an RNA–mediated copy-and-paste mechanism by cleaving the host genome and using this new DNA end as a primer to reverse transcribe its own RNA, generating a new L1 DNA copy
We highlight the importance of partial sequence complementarity between the target site and the L1 RNA extremity, and the high level of flexibility of this process, since detrimental terminal mismatches can be compensated by an increasing number of interacting nucleotides
Summary
Retrotransposons are highly repetitive and dispersed sequences, accounting for almost half of our DNA [1] These elements have the ability to proliferate in genomes through an RNA-mediated copy-and-paste mechanism, called retrotransposition. After its export to the cytoplasm, the bicistronic L1 mRNA is translated into two proteins (ORF1p and ORF2p), which associate preferentially in cis with their encoding mRNA [8,9,10,11] This is a critical feature of the L1 replication mechanism since it limits the association of the L1 machinery with other cellular mRNAs, including defective L1 RNA sequences, and increases the specificity of the reverse transcription process. The L1 RNP is imported into the nucleus where reverse transcription and integration into the host genome take place [30]
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