Mattos VF et al. (2018), Insights into the origin of the high variabilit...

ECB-ART-46144

PLoS One 2018 Feb 08;132:e0192070. doi: 10.1371/journal.pone.0192070.

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Insights into the origin of the high variability of multivalent-meiotic associations in holocentric chromosomes of Tityus (Archaeotityus) scorpions.

Mattos VF , Carvalho LS , Carvalho MA , Schneider MC .

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Scorpions represent an intriguing group of animals characterized by a high incidence of heterozygous chromosomal rearrangements. In this work, we examined six species of Tityus (Archaeotityus) from Brazilian fauna with a particular focus on elucidating the rearrangements responsible for the intraspecific variability of diploid number and the presence of long chromosomal chains in meiosis. To access any interpopulation diversity, we also studied individuals from four species representing distinct localities. Most species demonstrated intraspecific polymorphism in diploid number (2n = 19 and 2n = 20 in T. clathratus, T. mattogrossensis, and T. pusillus, 2n = 16, 2n = 17 and 2n = 18 in T. paraguayensis, and 2n = 16 and 2n = 24 in T. silvestris) and multi-chromosomal associations during meiosis I, which differed even among individuals with the same chromosome number. In some species, the heterozygous rearrangements were not fixed, resulting such as in Tityus clathatrus, in 11 different chromosomal configurations recognized within a same population. Based on meiotic chromosome behaviour, we suggested that independent rearrangements (fusion/fission and reciprocal translocations), occurring in different combinations, originated the multi-chromosomal chains. To evaluate the effects of these chromosome chains on meiotic segregation, we applied the chi-square test in metaphase II cells. The non-significant occurrence of aneuploid nuclei indicated that non-disjunction was negligible in specimens bearing heterozygous rearrangements. Finally, based on our analysis of many chromosome characteristics, e.g., holocentricity, achiasmate meiosis, endopolyploidy, ability to segregate heterosynaptic or unsynapsed chromosomes, (TTAGG)n sequence located in terminal regions of rearranged chromosomes, we suggest that the maintenance of multi-chromosomal associations may be evolutionarily advantageous for these species.

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Genes referenced: LOC115925415

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	Fig 1. Distribution and collection localities in Brazil of the scorpion species analyzed in this work.Species distribution was based on Lourenço [55–60] and Lourenço et al. [61].
	Fig 2. Mitotic metaphase cells of Tityus species after Giemsa staining (A, C, E, F, H, I, J, K, M, N, P, R, S) and silver impregnation (B, D, G, L, O, Q, T). (A-D) Tityus clathratus, 2n♂ = 19 (A-B) and 2n♂ = 20 (C-D). (E-H) Tityus mattogrossensis, 2n♂ = 19 (E) and 2n♂ = 20 (F-H). (i-l) Tityus paraguayensis, 2n♂ = 16 (I), 2n♂ = 17 (J) and 2n♂ = 18 (K-L). (M-O) Tityus pusillus, 2n♂ = 19 (M) and 2n♀ = 20 (N-O). (P-T) Tityus silvestris, 2n♂ = 16 (P-Q) and 2n♂ = 24 (R-T). In all species, the NORs (arrows) localized on the subterminal or terminal regions of two chromosomes. L = large chromosome size. S = small chromosome size. Arrowhead = constriction. Scale bar = 10μm.
	Fig 3. Postpachytene cells of Tityus stained with Giemsa.(A-L). Tityus clathratus with 10II (A), 4II+IX (B), 5II+IX (C), 3II+X (D), 4II+X (E), 5II+X (F), 2II+XI (G), 3II+XI (H), 4II+XI (I), 5II+XI (J), 1II+XIII (K), 3II+XIII (L). (M-R). Tityus mattogrossensis with 10II (M), 6II+III+IV (N), 8II+III (O), 8II+VI (P), and a quadrivalent association (Q, R). II = bivalent. The Roman numeral indicates the number of chromosomes in the chain. Scale bar = 10μm.
	Fig 4. Analysis of length of the quadrivalent association of Tityus mattogrossensis from Alto Araguaia (black), Chapada dos Guimarães (red) and Januária (green).The chain of specimen from Januária differs from other two populations (scree plot 82.8%).
	Fig 5. Meiotic cells of Tityus stained with Giemsa.(A-E, G-O) Postpachytene. (F, P) Anaphase I. (A-F) Tityus paraguayensis with 8II (A), 9II (B-C), 5II+VII (D), 5II+VIII (E). The detail in (E) highlights the chain of eight chromosomes. (G-M) Tityus pusillus with 10II (G), 8II+III (H), 7II+IV (I), 7II+V (J), 7II+VI (K), variable numbers of bivalents and chromosome chains, generally consisting of four chromosomes (L-M). (N-P) Tityus silvestris with 12II (N), 2II+XII (O), and the zigzag disposition of the chromosome chain (P). Arrow = gap or subterminal constriction. II = bivalent. The Roman numeral indicates the number of chromosomes in the chain. Scale bar = 10μm.
	Fig 6. Metaphase II cells of Tityus stained with Giemsa.(A-B) Tityus clathratus with n = 9 (A) and n = 10 (B). (C-D) Tityus mattogrossensis with n = 9 (C) and n = 10 (D). (E-F) Tityus paraguayensis with n = 8 (E) and n = 9 (F). (G-H) Tityus pusillus with n = 9 (G) and n = 10 (H). (I-J) Tityus silvestris with n = 8 (I) and n = 12 (J). Scale bar = 10μm.
	Fig 7. Localization of the 28S rDNA cistrons (green signal = arrow) in postpachytene chromosomes of Tityus species.(A) Tityus clathratus with 10II. (B) Tityus maranhensis 10II. (C-D) Tityus mattogrossensis with 10II (C) and 8II+IV (D). (E-F) Tityus paraguayensis with 8II (E) and 5II+VII (F). (G-H) Tityus pusillus with 10II (G) and 7II+IV (H). (I) Tityus silvestris with 2II+XII. II = bivalent. The Roman numeral indicates the number of chromosomes in the chain. Scale bar = 10μm.
	Fig 8. Localization of the (TTAGG)n telomeric region (green signal) in chromosomes of Tityus species.(A, B, D, F) Postpachytene cells. (C, E) Pachytene cells. XII = multivalent association of 12 chromosomes. Scale bar = 10μm.

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