Abstract
Alu and LINE-1 (L1), which constitute ~11% and ~17% of the human genome, respectively, are transposable non-LTR retroelements. They transpose not only in germ cells but also in somatic cells, occasionally causing cancer. We have previously demonstrated that antiretroviral restriction factors, human APOBEC3 (hA3) proteins (A–H), differentially inhibit L1 retrotransposition. In this present study, we found that hA3 members also restrict Alu retrotransposition at differential levels that correlate with those observed previously for L1 inhibition. Through deletion analyses based on the best-characterized hA3 member human APOBEC3G (hA3G), its N-terminal 30 amino acids were required for its inhibitory activity against Alu retrotransposition. The inhibitory effect of hA3G on Alu retrotransposition was associated with its oligomerization that was affected by the deletion of its N-terminal 30 amino acids. Through structural modeling, the amino acids 24 to 28 of hA3G were predicted to be located at the interface of the dimer. The mutation of these residues resulted in abrogated hA3G oligomerization, and consistently abolished the inhibitory activity of hA3G against Alu retrotransposition. Importantly, the anti-L1 activity of hA3G was also associated with hA3G oligomerization. These results suggest that the inhibitory activities of hA3G against Alu and L1 retrotransposition might involve a common mechanism.
Highlights
Retrotransposons compose ~42% of the human genome, and these elements are classified into the non-LTR and LTR classes
Our present study demonstrated that human APOBEC3 (hA3) family proteins inhibit Alu retrotransposition at differential levels, which are very similar to the levels at which these host proteins block L1 retrotransposition
With respect to human APOBEC3G (hA3G), the N-terminal 30 amino acids are important for the anti-Alu activity
Summary
Retrotransposons compose ~42% of the human genome, and these elements are classified into the non-LTR and LTR classes. L1 elements harbor two ORFs: ORF1, which encodes an RNA-binding protein, and ORF2, which encodes an endonuclease-like and reverse transcriptase-like protein. Retrotransposition by L1 and Alu occurs in germ cells, causing several genetic diseases [6,7,8,9,10,11,12,13], and in somatic cells, such as brain tissues [14,15], and malignant tissues and cells such as B-cell lymphoma cells [16], breast carcinoma tissue [17], colon carcinoma tissue [18], and hepatocellular carcinoma tissue [19]. These facts indicate that an intrinsic protection system should function properly to suppress these types of retrotransposition in normal somatic cells
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