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Chromosomes of Asian cyprinid fishes: Variable karyotype patterns and evolutionary trends in the genus Osteochilus (Cyprinidae, Labeoninae, “Osteochilini”)

Abstract

The Cyprinidae family is a highly diversified but demonstrably monophyletic lineage of cypriniform fishes. Among them, the genus Osteochilus contains 35 recognized valid species distributed from India, throughout Myanmar, Laos, Thailand, Malaysia, Indonesian archipelago to southern China. In this study, karyotypes and other chromosomal characteristics of five Osteochilus species occurring in Thailand, namely O. lini, O. melanopleura, O. microcephalus, O. vittatus and O. waandersii were examined using conventional and molecular cytogenetic protocols. Our results showed they possessed diploid chromosome number (2n) invariably 2n = 50, but the ratio of uni- and bi-armed chromosomes was highly variable among their karyotypes, indicating extensive chromosomal rearrangements. Only one chromosome pair bearing 5S rDNA sites occurred in most species, except O. melanopleura, where two sites were detected. In contrast, only one chromosomal pair bearing 18S rDNA sites were observed among their karyotypes, but in different positions. These cytogenetic patterns indicated that the cytogenomic divergence patterns of these Osteochilus species were largely corresponding to the inferred phylogenetic tree. Similarly, different patterns of the distributions of rDNAs and microsatellites across genomes of examined species as well as their different karyotype structures indicated significant evolutionary differentiation of Osteochilus genomes.

Keywords:
Fish cytogenetics; karyotype evolution; repetitive DNAs; Thai ichthyofauna

Introduction

The Cyprinidae family (sensu Tan and Ambruster, 2018Tan M and Armbruster JW (2018) Phylogenetic classification of extant genera of fishes of the order Cypriniformes (Teleostei. Ostariophysi). Zootaxa 4476:6-39.), i.e. sensu stricto, is now restricted to phylogenetically and taxonomically highly diversified but a demonstrably monophyletic lineage of cypriniform fishes (Yang et al., 2015Yang L, Sado T, Hirt MV, Pasco-Viel E, Arunachalam M, Li J, Wang X, Freyhof J, Saitoh K, Simons AM et al. (2015) Phylogeny and polyploidy: Resolving the classification of cyprinine fishes (Teleostei: Cypriniformes). Mol Phylogenet Evol 85:97-116. ) which itself encompasses eleven intra-clade monophyletic lineages taxonomically recently recognized as subfamilies by Tan and Ambruster (2018Tan M and Armbruster JW (2018) Phylogenetic classification of extant genera of fishes of the order Cypriniformes (Teleostei. Ostariophysi). Zootaxa 4476:6-39.). One of these lineages, Labeoninae, was demonstrated as sister basal lineage of all remaining cyprinid subfamilies (Conway, 2011Conway KW (2011) Osteology of the South Asian Genus Psilorhynchus McClelland, 1839 (Teleostei: Ostariophysi: Psilorhynchidae), with investigation of its phylogenetic relationships within the order Cypriniformes. Zool J Linnean Soc 163:50-154.; Yang et al., 2015Yang L, Sado T, Hirt MV, Pasco-Viel E, Arunachalam M, Li J, Wang X, Freyhof J, Saitoh K, Simons AM et al. (2015) Phylogeny and polyploidy: Resolving the classification of cyprinine fishes (Teleostei: Cypriniformes). Mol Phylogenet Evol 85:97-116. ; Stout et al., 2016Stout CC, Tan M, Lemmon AR, Lemmon EM and Armbruster JW (2016) Resolving Cypriniformes relationships using an anchored enrichment approach. BMC Evol Biol 16:1-13.). Moreover, the lineage monophyly of labeonine cyprinids was supported by both morphological and molecular studies (see review by Yang et al., 2012Yang L, Arunachalam M, Sado T, Levin BA, Golubtsov AS, Freyhof J, Friel JP, Chen WJ, Hirt MV, Manickam R et al. (2012) Molecular phylogeny of the cyprinid tribe Labeonini (Teleostei: Cypriniformes). Mol Phylogenet Evol 65:362-379. ). These authors also identified four monophyletic intra-lineage groups within Labeoninae, taxonomically recognized (Tan and Ambruster, 2018Tan M and Armbruster JW (2018) Phylogenetic classification of extant genera of fishes of the order Cypriniformes (Teleostei. Ostariophysi). Zootaxa 4476:6-39.) as tribes Garrini, Labeonini and taxonomically informal “Osteochilini” and “Semilabeonini”: Labeonine cyprinids are highly morphologically diversified and include altogether around 50 genera with more than 500 species (Eschmeyer Catalog of Fishes, 2020Eschmeyer’s Catalog of Fishes, Eschmeyer’s Catalog of Fishes, http://researcharchive.calacademy.org/research/ichthyology/catalog/SpeciesByFamily.asp (accessed 12 January 2020).
http://researcharchive.calacademy.org/re...
), “Osteochilini” itself contains eight genera with close to 100 recently recognized species.

The genus Osteochilus (Günther, 1868) contains 35 recognized valid species distributed from India, throughout Myanmar, Laos, Thailand, Malaysia, Indonesian archipelago to southern China (Karnasuta, 1993Karnasuta J (1993) Systematic revision of Southeastern Asiatic cyprinid fish genus Osteochilus with a description of two new species and a new subspecies. J Fish Env 19:1-105.). Although three major systematic revisions have been performed for this genus (Karnasuta, 1993Karnasuta J (1993) Systematic revision of Southeastern Asiatic cyprinid fish genus Osteochilus with a description of two new species and a new subspecies. J Fish Env 19:1-105.), just eight species were included in detailed molecular phylogenetic analyses performed by Yang et al. (2012Yang L, Arunachalam M, Sado T, Levin BA, Golubtsov AS, Freyhof J, Friel JP, Chen WJ, Hirt MV, Manickam R et al. (2012) Molecular phylogeny of the cyprinid tribe Labeonini (Teleostei: Cypriniformes). Mol Phylogenet Evol 65:362-379. ). Although the cytogenetic analysis are restricted, up to now, to only three species, the results point for a quite large karyotype differentiation inside Osteochilus (Table 1).

Table 1 -
Available cytogenetic data for Osteochilus species.

Cypriniform cytotaxonomy documents a great 2n variation, ranging from 42 in Acheilognathus gracilis (Acheilognathidae) (Hong and Zhou, 1985Hong Y and Zhou T (1985) Studies on the karyotype and C-banding patterns in Acheilognathus gracilis with a discussion on the evolution of acheilognathid fishes. Acta Gen Sinica 12:143-148.) to 446 in Diptychus dipogon (Cyprinidae) (Yu and Yu, 1990Yu XY and Yu XJ (1990) A schizothoracine fish species, Diptychus dipogon, with a very high number of chromosomes. Chromosome Inform Serv 48:17-18.). However, 2n = 50 is the most frequent chromosome number, which represents a basal pattern for the whole group (Wolf et al., 1969Wolf U, Ritter H, Atkin NB and Ohno S (1969) Polyploidization in the fish family Cyprinidae, order Cypriniformes. Humangenetik 7:240-244.; Sola and Gornung, 2001Sola L and Gornung E (2001) Classical and molecular cytogenetics of the zebrafish, Danio rerio (Cyprinidae, Cypriniformes): An overview. Genetica 111:397-412.). Moreover, several polyploidization events have taken an important role in 2n variation for cyprinids and differentiated sex chromosomes seem rare (Buth et al., 1991Buth DG, Dowling TE and Gold JR (1991) Molecular and cytological investigations. In: Nelson JS and Winfield IJ (eds) Cyprinid fishes: Systematics, biology and exploitation. Chapman and Hall, London, pp 83-126.; Rab and Collares-Pereira, 1995Ráb P and Collares-Pereira MJ (1995) Chromosomes of European cyprinid fishes (Cyprinidae, Cypriniformes). Folia Zool Brno 44:193-214.; Yang et al., 2015Yang L, Sado T, Hirt MV, Pasco-Viel E, Arunachalam M, Li J, Wang X, Freyhof J, Saitoh K, Simons AM et al. (2015) Phylogeny and polyploidy: Resolving the classification of cyprinine fishes (Teleostei: Cypriniformes). Mol Phylogenet Evol 85:97-116. ).

This study aimed to analyze karyotypes and other chromosomal characteristics as revealed by conventional (Giemsa-staining and C-banding) and molecular (rDNA and microsatellite FISH) protocols in five species of the genus Osteocheilus occurring in Thailand, namely O. lini, O. melanoptera, O. microcephalus, O. vittatus, and O. waandersii together with a brief overlook of cytotaxonomy of “osteochiline” cyprinids. The results added new informative characters useful in comparative genomics at the chromosomal level and highlighted extensive diversity among the analyzed species.

Material and Methods

Individuals, mitotic chromosome preparation and C-banding

Representatives of five Osteochilus species were collected from distinct natural ecosystems of wild regions in Thailand (Figure 1). The numbers and sexes of the individuals under study were presented in Table 2. The specimens were deposited in the fish collections of the Cytogenetic Laboratory, Department of Biology, Faculty of Science (KhonKaen University). Mitotic chromosomes were obtained from anterior kidney, by the conventional air-drying method (Bertollo et al., 2015Bertollo LAC, Cioffi MB and Moreira-Filho O (2015) Direct chromosome preparation from freshwater teleost fishes. In: Ozouf-Costaz C, Pisano E, Foresti F and Toledo LFA (eds) Fish cytogenetic techniques: Ray-fin fishes and chondrichthyans. 1st edition. RC Press, Boca Raton, pp 21-26.). The distribution of C-positive heterochromatin blocks was visualized according to Sumner (1972Sumner AT (1972) A simple technique for demonstrating centromeric heterochromatin. Exp Cell Res 75:304-306.). All the experiments followed ethical protocols, and anesthesia was conducted with clove oil before the sacrifice of the animals. The process was approved by the Animal Ethics Committee of KhonKaen University based on the Ethics of Animal Experimentation of the National Research Council of Thailand AEKKU23/2558.

Figure 1 -
Thailand map showing the collection sites of the five species studied. 1. Osteochilus lini (blue circles); 2. Osteochilus melanopleura (red circles); 3. Osteochilus microcephalus (green circles); 4. Osteochilus vittatus (pink circles); 5. Osteochilus waandersii (black circles). The maps were created using the following softwares: QGis 3.4.3, Inkscape 0.92 and Photoshop 7.0.

Table 2 -
Species analyzed, collection sites and number of analyzed individuals (n).

Fluorescence in situ hybridization (FISH)

Fluorescence in situ hybridization experiments were performed under high stringency conditions (Yano et al., 2017Yano CF, Bertollo LAC and Cioffi MB (2017) Fish-FISH: Molecular cytogenetics in fish species. In: Liehr T (ed) Fluorescence In Situ Hybridization (FISH). Springer, Berlin, pp 429-443.) to identify both classes of ribosomal DNA and microsatellites (CA)15, (GA)15, (GC)15, (A)30, (CAC)10 and (CGG)10 sequences. Two tandemly-arrayed DNA sequences isolated from the genome of Hoplias malabaricus, previously cloned into plasmid vectors and propagated in competent cells of Escherichia coli DH5α (Invitrogen, San Diego, CA, USA), were used. The first probe contained a 5S rDNA repeat copy and included 120 base pairs (bp) of the 5S rRNA transcribing gene and 200 bp of the non-transcribed spacer (NTS) (Martins et al., 2006Martins C, Ferreira IA, Oliveira C, Foresti F and Galetti PM (2006) A tandemly repetitive centromeric DNA sequence of the fish Hoplias malabaricus (Characiformes: Erythrinidae) is derived from 5S rDNA. Genetica 127:133-141.). The second probe corresponded to the 1400 bp segment of the 18S rRNA gene obtained via PCR from the nuclear DNA (Cioffi et al., 2009Cioffi MB, Martins C, Centofante L, Jacobina U and Bertollo LAC (2009) Chromosomal variability among allopatric populations of Erythrinidae fish Hoplias malabaricus: Mapping of three classes of repetitive DNAs. Cytogenet Genome Res 125:132-141.). Both probes were directly labeled with the Nick-Translation mix kit (Roche, Manheim, Germany). The 5S rDNA was labeled with Spectrum Orange-dUTP, and the 18S rDNA was labeled with Spectrum Green-dUTP(Vysis, Downers Grove, IL, USA), according to the manufacturer’s manual. The microsatellite sequences were directly labeled with Cy-3 during the synthesis, as described by Kubat et al. (2008Kubat Z, Hobza R, Vyskot B and Kejnovsky E (2008) Microsatellite accumulation on the Y chromosome in Silene latifolia. Genome 51:350-356.).

Karyotyping and image processing

To confirm the 2n and the results of hybridization experiments, at least 30 metaphase spreads were analyzed per individual. Images were captured with an Axioplan II microscope (Carl Zeiss Jena GmbH, Germany) with CoolSNAP, and processed using an Image-Pro Plus 4.1 software (Media Cybernetics, Silver Spring, MD, USA). Chromosomes were classified according to their arm ratios as metacentric (m), submetacentric (sm), subtelocentric (st), and acrocentric (a) (Levan et al., 1964Levan A, Fredga K and Sandberg AA (1964) Nomenclature for centromeric position on chromosomes. Hereditas 52:201-220.).

Results

All five examined species possessed invariably, for both females and males, 2n = 50, but a different composition of their karyotypes: 12m+34sm+4st in Osteochilus lini, 22m+24sm+2st+2a in O. melanopleura, 14m+32sm+4st in O. microcephalus, 16m+30sm+4st in O. vittatus and 16m+26sm+8st in O. waandersi (Figure 2). The constitutive heterochromatin was always located at the pericentromeric region of all chromosomes. Additionally, the short (p) arms of some pairs also contained heterochromatic blocks, i.e., the 12th in the karyotype of O. lini, 14th of O. melanopleura, 11th of O. microcephalus, 12th of O. vittatus and the 15th of O. waandersi (Figure 2).

Figure 2 -
Karyotypes of the Osteochilus species examined arranged from Giemsa- stained, C-banded chromosomes and chromosomes after FISH with 5S (red) and 18S (green) rDNA probes. A= O. lini; B=O. melanopleura; C= O. microcephalus; D= O. vittatus; E= O. waandersi. Chromosomes were counterstained with DAPI (blue). Scale bar = 5 μm.

FISH experiments documented a single pair bearing 5S and 18S rDNA sites in karyotypes of Osteochilus lini (pairs Nos. 08 and 12 respectively), O. microcephalus (Nos. 11 and 03), O. vittatus (Nos. 10 and 12) and in O. waandersi (Nos. 22 and 15), while in that of O. melanopleura 5S rDNA signals were situated on two chromosome pairs (Nos. 12 and 14) and only one pair with the 18S rDNA signal (No 02) (Figure 2).

In general, a spreading pattern was a frequent feature for the microsatellites analyzed. However, some specific features could also be highlighted among species (Figures 3- 7). In this sense, O. waandersi had small spread (GC)n signals in all chromosomes but a strong hybridization pattern in the pericentromeric region of a single pair. For (A)30, O. melanopleura showed the pericentromeric region of 46 chromosomes hybridized, while all the other species had scattered signals in all 50 chromosomes. Concerning (CA)n, while O. microcephalus and O. waandersi had a scattered distribution in all chromosomes, O. lini and O. vittatus presented small telomeric signals and O. melanopleura had scattered signals except in the centromeric regions. Spreading signals were also observed for the (GA)n, (CAC)n, and (CGG)n probes in all chromosomes of all species. Additionally, O. melanopleura and O. vittatus had a strong (CGG)n signal in the telomeric region of a single chromosome pair.

Figure 3 -
Hybridization patterns with microsatellites probes (red signals) on metaphase plates of Osteochilus lini. Chromosomes were counterstained with DAPI (blue). Scale bar = 5 μm.

Figure 4 -
Hybridization patterns with microsatellites probes (red signals) on metaphase plates of the Osteochilus melanopleura. Chromosomes were counterstained with DAPI (blue). Scale bar = 5 μm.

Figure 5 -
Hybridization patterns with microsatellites probes (red signals) on metaphase plates of the Osteochilus microcephalus. Chromosomes were counterstained with DAPI (blue). Scale bar = 5 μm.

Figure 6 -
Hybridization patterns with microsatellites probes (red signals) on metaphase plates of the Osteochilus vittatus. Chromosomes were counterstained with DAPI (blue). Scale bar = 5 μm.

Figure 7 -
Hybridization patterns with microsatellites probes (red signals) on metaphase plates of the Osteochilus waandersii. Chromosomes were counterstained with DAPI (blue). Scale bar = 5 μm.

Discussion

“Osteochilini” species possess 2n = 50 (Arai, 2011), which is also considered a basal pattern for cypriniform fishes (Chaiyasan et al., 2018Chaiyasan P, Supiwong W, Saenjundaeng P, Seetapan K, Pinmongkhonkul S and Tanomtong A (2018) A Report on Classical Cytogenetics of Hihgfin Barb Fish, Cyclocheilichthys armatus (Cypriniformes, Cyprinidae). Cytologia 83:149-154.). Our results showed that 2n = 50 is also a demonstrably conserved pattern for all Osteochilus species karyotyped to date. However, despite the conservative 2n, significant differences in the karyotype structures in all five species examined were observed. Hence, this species also had multiple 5S rDNA sites and a different hybridization pattern for (A)30, (CA)15 and (CGG)10 microsatellites. According to the phylogeny of the Labeonini tribe proposed by Yang and Mayden (2010Yang L and Mayden RL (2010) Phylogenetic relationships, subdivision, and biogeography of the cyprinid tribe Labeonini (sensu) (Teleostei: Cypriniformes), with comments on the implications of lips and associated structures in the labeonin classification. Mol Phylogenet Evol 54:254-265.), Osteochilus was recovered as a monophyletic genus, with three Labiobarbus species forming a sister basal clade (Figure 8). O. melanopleura was recognized as the oldest derived species of the genus and Labiobarbus lineatus possessed 20 acrocentric chromosomes composing its karyotype (Magtoon and Arai, 1990Magtoon W and Arai R (1990) Karyotypes of three cyprinid fishes, Osteochilus hasselti, O. vittatus, and Labiobarbus lineatus, from Thailand. Jpn J Ichthyol 36:483-487.). This fact suggests that the acrocentric pair No. 25 of O. melanopleura could be a remnant of the common ancestor between both Osteochilus and Labiobarbus genera. Thus, the karyotype diversification in Osteochilus genus was probably accompanied by a series of structural chromosome rearrangements, with a special role of pericentric inversions or centromere reposition, as indicated by changes in karyotype structure and a constant 2n (Figure 8).

Figure 8 -
Adapted phylogenetic tree for the tribe Labeonini, based on the molecular-phylogenetic data generated by Yang et al. (2012Yang L, Arunachalam M, Sado T, Levin BA, Golubtsov AS, Freyhof J, Friel JP, Chen WJ, Hirt MV, Manickam R et al. (2012) Molecular phylogeny of the cyprinid tribe Labeonini (Teleostei: Cypriniformes). Mol Phylogenet Evol 65:362-379. ) indicating the main chromosomal data obtained in this paper with the superscript 1, and by Magtoon and Arai (1990Magtoon W and Arai R (1990) Karyotypes of three cyprinid fishes, Osteochilus hasselti, O. vittatus, and Labiobarbus lineatus, from Thailand. Jpn J Ichthyol 36:483-487., 1993Magtoon W and Arai R (1993) Karyotypes and distribution of nucleolus organizer regions in cyprinid fishes from Thailand. Jpn J Ichthyol 40:77-85.) with the superscript 2.

Many representatives of several fish orders, such as Characiformes, Cypriniformes, Siluriformes, and Gymnotiformes have karyotypes dominated by bi-armed chromosomes (Molina et al., 2014Molina WF, Martinez PA, Bertollo LAC and Bidau CJ (2014) Evidence for meiotic drive as an explanation for karyotype changes in fishes. Mar Genom 15:29-34.). Our data also demonstrated that Osteochilus species have more bi-armed elements in their karyotypes, suggesting that orthoselection and meiotic drift (White, 1973White MJD (1973) Animal cytology and evolution. 3rd edition. Cambridge University Press, Cambridge, 468 p.; Molina et al., 2014Molina WF, Martinez PA, Bertollo LAC and Bidau CJ (2014) Evidence for meiotic drive as an explanation for karyotype changes in fishes. Mar Genom 15:29-34.) could be strong evolutionary drivers for this group. Noteworthy, the karyotype now reported for O. waandersi was different from that reported by Magtoon and Arai (1993Magtoon W and Arai R (1993) Karyotypes and distribution of nucleolus organizer regions in cyprinid fishes from Thailand. Jpn J Ichthyol 40:77-85.).Cypriniform chromosomes have notable small sizes (Sember et al., 2015Sember A, Bohlen J, Šlechtová V, Altmanova M, Symonová R and Rab P (2015) Karyotype differentiation in 19 species of river loach fishes (Nemacheilidae, Teleostei): Extensive variability associated with rDNA and heterochromatin distribution and its phylogenetic and ecological interpretation. BMC Evol Biol 15:251.; Saenjundaeng et al., 2018Saenjundaeng P, Kaewmad P, Supiwong W, Pinthong K, Pengseng P and Tanomtong A (2018) Karyotype and characteristics of nucleolar organizer regions in longfin carp, Labiobarbus leptocheilus (Cypriniformes, Cyprinidae). Cytologia 83:265-269.) and this feature can make it difficult to visualize the correct centromere position (Ráb and Collares-Pereira, 1995Ráb P and Collares-Pereira MJ (1995) Chromosomes of European cyprinid fishes (Cyprinidae, Cypriniformes). Folia Zool Brno 44:193-214.; Spoz et al., 2014Spoz A, Boron A, Porycka K, Karolewska M, Ito D, Abe S, Kirtiklis L and Juchno D (2014) Molecular cytogenetic analysis of the crucian carp, Carassius carassius (Linnaeus, 1758) (Teleostei, Cyprinidae), using chromosome staining and fluorescence in situ hybridisation with rDNA probes. Comp Cytogenet 8:233-248.; Knytl et al., 2018Knytl M, Kalous L, Rylková K, Choleva L, Merilä J and Ráb P (2018) Morphologically indistinguishable hybrid Carassius female with 156 chromosomes: A threat for the threatened crucian carp, C. carassius, L. PLoS One 13:e0190924.), thus impairing the identification of the chromosomal morphology.

Microsatellite motifs had a preferential accumulation in heterochromatic regions (reviewed in Cioffi and Bertollo, 2012Cioffi MB and Bertollo LAC (2012) Chromosomal distribution and evolution of repetitive DNAs in fish. In: Garrido-Ramos MA (ed) Repetitive DNA. Karger Publishers, Basel, pp 197-221.). However, the majority of the microsatellite sequences in Osteochilus showed a scattered pattern on chromosomes, without a specific relation with heterochromatic regions. Nevertheless, the (A)30 motif presented a strong accumulation pattern in the pericentromeric regions of O. melanopleura, a species in which this same chromosomal region appeared strongly C-banded, i.e., with C-positive heterochromatin. Also, microsatellites are often embedded within rDNA clusters (Piscor and Parise-Maltempi, 2016Piscor D and Parise-Maltempi PP (2016) Microsatellite organization in the B chromosome and A chromosome complement in Astyanax (Characiformes, Characidae) species. Cytogenet Genome Res 148:44-51.), which can also explain the strong labeling in the (CGG)n motifs found in chromosomes of O. vittatus and O. melanopleura.

Usually, the 18S rDNA occupies a terminal position in chromosomes, in contrast to the more frequent interstitial position of the 5S rDNA (Sochorová et al., 2018Sochorová J, Garcia S, Gálvez F, Symonová R and Kovařík A (2018) Evolutionary trends in animal ribosomal DNA loci: Introduction to a new online database. Chromosoma 127:141-150.). All the Osteochilus species under study had both ribosomal classes located in a terminal position in association with heterochromatin, suggesting that these regions were recombination hotspots (Salvadori et al., 1997Salvadori S, Deiana AM, Coluccia E, Cannas R, Cau A and Milia A (1997) Heterochromatin distribution and structure in Gymnothorax unicolor (Anguilliformes, Muraenidae). Ital J Zool 64:125-129.; Sola et al., 2003Sola L, Rossi AR, Annesi F and Gornung E (2003) Cytogenetic studies in Sparus auratus (Pisces, Perciformes): Molecular organization of 5S rDNA and chromosomal mapping of 5S and 45S ribosomal genes and of telomeric repeats. Hereditas 139:232-236.; Gornung, 2013Gornung E (2013) Twenty years of physical mapping of major ribosomal RNA genes across the teleosts: A review of research. Cytogenet Genome Res 141:90-102.). Their terminal position may also facilitate the dispersion of these sequences to other chromosomes, according to Rabl’s model, since higher recombination rates were found near the telomeric region (reviewed in Foster and Bridger, 2005Foster HA and Bridger JM (2005) The genome and the nucleus: A marriage made by evolution. Chromosoma 114:212-229.). Besides that, the heterochromatinization of ribosomal loci was suggested to facilitate chromosomal heteromorphisms, by unequal crossing over between homologs and/or amplification of the heterochromatin between sister chromatids (Collares-Pereira and Ráb, 1999Collares-Pereira MJ and Ráb P (1999) NOR polymorphism in the Iberian species Chondrostoma lusitanicum (Pisces: Cyprinidae) - re-examination by FISH. Genetica 105:301-303.; Sola and Gornung, 2001Sola L and Gornung E (2001) Classical and molecular cytogenetics of the zebrafish, Danio rerio (Cyprinidae, Cypriniformes): An overview. Genetica 111:397-412.; Gromicho et al., 2006Gromicho M, Coutanceau JP, Ozouf-Costaz C and Collares-Pereira MJ (2006) Contrast between extensive variation of 28S rDNA and stability of 5S rDNA and telomeric repeats in the diploid-polyploid Squalius alburnoides complex and in its maternal ancestor Squalius pyrenaicus (Teleostei, Cyprinidae). Chromosome Res 14:297-306.). The presence of both rDNAs in different chromosomal pairs is a usual condition in fish species (Sochorová et al., 2018Sochorová J, Garcia S, Gálvez F, Symonová R and Kovařík A (2018) Evolutionary trends in animal ribosomal DNA loci: Introduction to a new online database. Chromosoma 127:141-150.), as also observable for cyprinids in our study. Besides, it is noteworthy that O. melanopleura was recognized as a basal one in the genus (Karnasuta, 1993Karnasuta J (1993) Systematic revision of Southeastern Asiatic cyprinid fish genus Osteochilus with a description of two new species and a new subspecies. J Fish Env 19:1-105.; Yang and Mayden, 2010Yang L and Mayden RL (2010) Phylogenetic relationships, subdivision, and biogeography of the cyprinid tribe Labeonini (sensu) (Teleostei: Cypriniformes), with comments on the implications of lips and associated structures in the labeonin classification. Mol Phylogenet Evol 54:254-265.; Figure 8), and this species had two chromosome pairs with 5S rDNA sites. In this sense, this could suggest that a single pair bearing such sites in the karyotypes of other Osteochilus species could be a derived pattern. However, this second pair with 5S sites in O. melanopleura was likely a particular pattern due to spreading events (Figure 8). Ribosomal clusters are characterized by its dynamism promoting significant intragenomic diversification (Gornung, 2013Gornung E (2013) Twenty years of physical mapping of major ribosomal RNA genes across the teleosts: A review of research. Cytogenet Genome Res 141:90-102.; Rebordinos et al., 2013Rebordinos L, Cross I and Merlo A (2013) High evolutionary dynamism in 5S rDNA of fish: state of the art. Cytogenet Genome Res 141:103-113.; Cioffi et al., 2015Cioffi MB, Bertollo LAC, Villa MA, de Oliveira EA, Tanomtong A, Yano CF, Supiwong W and Chaveerach A (2015) Genomic organization of repetitive DNA elements and its implications for the chromosomal evolution of channid fishes (Actinopterygii, Perciformes). PLoS One 10:e0130199.; Sember et al., 2015Sember A, Bohlen J, Šlechtová V, Altmanova M, Symonová R and Rab P (2015) Karyotype differentiation in 19 species of river loach fishes (Nemacheilidae, Teleostei): Extensive variability associated with rDNA and heterochromatin distribution and its phylogenetic and ecological interpretation. BMC Evol Biol 15:251.; Symonová and Howell, 2018Symonová R and Howell WM (2018) Vertebrate genome evolution in the light of fish cytogenomics and rDNAomics. Genes (Basel) 9:96.).

A general pattern on Osteochilus karyotypes with a fundamental number (NF) of 100 and a high variation on their karyotype macrostructure can generally be observed. This was somehow expected since Osteochilus is a specious genus, and it is known that the speciation process itself can be the result of high macrostructure karyotypic variation (White, 1973White MJD (1973) Animal cytology and evolution. 3rd edition. Cambridge University Press, Cambridge, 468 p.; Lowry and Willis, 2010Lowry DB and Willis JH (2010) A widespread chromosomal inversion polymorphism contributes to a major life-history transition, local adaptation, and reproductive isolation. PLoS Biol 8:e1000500.). However, we cannot disregard the variation found in O. melanopleura, the variation that was also probably extended to the sister species O. schlegelii, but more studies are required to confirm this assumption.

In conclusion, our data have improved the data about the karyotypes and chromosome characteristics in the genus Osteochilus. Its species presented a conservative 2n = 50 and NF = 100, but with differentiation of their karyotypes. Altogether these features indicate that chromosomal rearrangements, particularly the structural ones as centromere reposition and pericentric inversions, have taken place a major role during the evolutionary history of this cyprinid genus. The detailed cytogenetic survey indicated that the cytogenomic divergence patterns of these Osteochilus species were largely corresponding to the inferred phylogenetic tree. Also, repetitive DNAs, such as ribosomal and microsatellite ones, showed specificities in their distribution among species, thus being shown as good markers and promoters of specific genomic differentiation inside the genus.

Acknowledgments

This study was supported by The Faculty of Interdisciplinary Studies, Khon Kaen University, Nong Khai Campus, Research and Technology Transfer Affairs of Khon Kaen University and The Unit of Excellence 2020 on Biodiversity and Natural Resources Management, University of Phayao (UoE63005). ”. MBC was supported by Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) (Proc. Nos. 401962/2016-4 and 302449/2018-3), Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) (Proc. Nos. 2018/22033-1) and CAPES/Alexander von Humboldt (Proc. No. 88881.136128/2017-01). PR was supported by the project EXCELLENCE CZ.02.1.01/0.0/0.0/15_003/0000460 OP RDE.

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Internet resources

Publication Dates

  • Publication in this collection
    06 Nov 2020
  • Date of issue
    2020

History

  • Received
    16 June 2020
  • Accepted
    29 Sept 2020
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