Abstract
Most of the transposons so far characterized from mosquito genomes are retroelements which seem to be distributed worldwide. The Juan transposons constitute a family of non-LTR retroelements, or LINE-retroposons, which are dispersed in the genomes of several mosquito species. Three different Juan subfamilies have been characterized, each being amplified in the genomes of many strains, if not all, of a given mosquito species. These subfamilies have been designated respectively Juan-C inCulex pipiens, Juan-Ct inCulex tarsalis and Juan-A inAedes aegypti. A large number of the Juan retroposons which are amplified in the mosquito genomes are apparently full-length copies and potentially encode the enzymes necessary for their transposition, a nucleic acid binding protein and a reverse transcriptase. However, these complete Juan copies seem to be most frequently transcriptionally silent in insects reared under laboratory conditions. A few of them are transcribed inC. pipiens cells grownin vitro, but from an external promoter, the Juan-C specific RNA being fused to an upstream RNA sequence. Therefore, the transcription of Juan retroposons seems to depend on external promoters which are most frequently inactive. The occurrence and distribution of Juan retroposon subfamilies among mosquito species do not reflect the phylogeny of these species. Furthermore, complete Juan-C and Juan-A copies which are reiterated in strains collected from regions covering different continents are nearly identical. Juan-C copies belonging to geographically differentC. pipiens strains display low levels of divergence between their nucleotide sequences and many of the mutations which have occurred among these copies do not alter their coding potential. These results indicate that the Juan retroposons occur as homogeneous subfamilies distributed worldwide and that selective constraints against amino acid change have been acting recently on these elements, despite the fact that they are now highly repeated through mosquito genomes. Therefore, Juan transposons have most probably been recently amplified in mosquito genomes. Each subfamily may have been amplified from one master element present in a unique population which has since spread worldwide. Alternatively, this amplification may have arisen in many mosquito populations, but from highly conserved master elements submitted to selection pressures. Horizontal transfers between species may also have contributed to the spread of these transposons.
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Abbreviations
- A. :
-
Aedes
- aa:
-
amino acid(s)
- An. :
-
Anopheles
- bp:
-
base pair(s)
- C. :
-
Culex
- D. :
-
Drosophila
- Juan:
-
family of elements reiterated in the genome ofAedes andCulex mosquitoes
- kb:
-
kilobase(s) or 1,000 bp
- LINE:
-
long interspersed repetitive element
- LTR:
-
long terminal repeat
- ORF:
-
open reading frame
- RFLP:
-
restriction fragment length polymorphism
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Bensaadi-Merchermek, N., Salvado, J.C. & Mouchès, C. Mosquito transposable elements. Genetica 93, 139–148 (1994). https://doi.org/10.1007/BF01435246
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DOI: https://doi.org/10.1007/BF01435246