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Chromosomal Radiation: A model to explain karyotypic diversity in cryptic species

Abstract

We present a concept that explains the pattern of occurrence of widely distributed organisms with large chromosomal diversity, large or small molecular divergence, and the insufficiency or absence of morphological identity. Our model is based on cytogenetic studies associated with molecular and biological data and can be applied to any lineage of sister species, chronospecies, or cryptic species. Through the evaluation of the karyotypic macrostructure, as the physical location of genes e satellites DNAs, in addition to phylogenetic reconstructions from mitochondrial and nuclear genes, per example, we have observed morphologically indistinguishable individuals presenting different locally fixed karyomorphs with phylogeographic discontinuity. The biological process behind this pattern is seen in many groups of cryptic species, in which variation lies mainly in the organization of their genomes but not necessarily in the ecosystems they inhabit or in their external morphology. It’s similar to the processes behind other events observed in the distribution of lineages. In this work, we explore the hypothesis of a process analogous to ecological-evolutionary radiation, which we called Chromosomal Radiation. Chromosomal Radiation can be adaptive or non-adaptive and applied to different groups of organisms.

Keywords
Stasipatric speciation; chromosomal rearrangements; karyotypic polymorphisms; genomic plasticity; adaptive radiation

Stasipatric speciation and other models of chromosomal speciation

Since the 60’ the presence of chromosomal rearrangements in populations has been correlated with the origin of new species, mainly in organisms with restricted vagility. White et al. (1967White M, Blackith R, Blackith R and Cheney J (1967) Cytogenetics of the viatica group morabine grasshoppers. I. The coastal species. Aust J Zool 15:263-302.) published the idea of a mechanism of chromosomal change acting on the emergence of species which was followed by many biologists. Over the years, besides the criticism, several authors claim that a range of organisms presenting different “chromosomal races” could evolve by the process proposed by White (1968White MJD (1968) Models of Speciation. Science 159:1065-1070. ), the Stasipatric Speciation (Shaw and Wilkinson, 1980Shaw DD and Wilkinson P (1980) Chromosome differentiation, hybrid breakdown and the maintenance of a narrow hybrid zone in Caledia. Chromosoma 80:1-31. ; Watanabe and Kawanishi, 1983Watanabe TK and Kawanishi M (1983) Stasipatric speciation in Drosophila. Jpn J Genet 58:269-274. ; Michailova, 1992Michailova P (1992) Endochironomus tendens (F.) (Chironomidae, Diptera) an example of stasipatric speciation. Neth J Aquat Ecol 26:173-180. ; Frisman et al., 2009Frisman LV, Korobitsyna KV, Kartavtseva IV, Sheremetyeva IN and Vouta LL (2009) Voles (Microtus Schrank 1798) of the Russian Far East: Allozymic and karyological divergence. Russ J Genet 45:707-714. ; Ruiz-García et al., 2011Ruiz-García M, Vásquez C, Camargo E, Leguizamón N, Gálvez H, Vallejo A, Pinedo M, Castellanos-Mora L, Shostell J and Alvarez D (2011) Molecular Phylogenetics of Aotus (Platyrrhini, Cebidae). Int J Primatol 32:1218-1241. ; López-López et al., 2021López-López A, Acosta V, Rataj L and Galián J (2021) Evolution and diversification of the Southern Chilean genus Ceroglossus (Coleoptera, Carabidae) during the Pleistocene glaciations. Syst Entomol 46:856-869. ; Zamudio et al., 2023Zamudio S, Mata-Rosas M, Salinas-Rodríguez MM and Hernández-Rendón J (2023) Pinguicula warijia sp. nov. (Lentibulariaceae), a newly rediscovered species from the Sierra Obscura, northern Mexico. Phytotaxa 578:219-227. ; among others). Stasipatric speciation is a model of non-allopatric speciation in which a chromosome rearrangement that reduces fitness when heterozygous is taken to be the post-mating isolating mechanism that confers species status on a population. Above all, the critics’ arguments have changed very little during this time.

Probably, almost all cytogeneticists working with organisms with a high number of chromosomal karyomorphs faced a similar discussion that was pointed out primarily by Key (1968Key KHL (1968) The concept of stasipatric speciation. Syst Biol 17:14-22. ) in response to White et al. (1967White M, Blackith R, Blackith R and Cheney J (1967) Cytogenetics of the viatica group morabine grasshoppers. I. The coastal species. Aust J Zool 15:263-302.). Key (1968Key KHL (1968) The concept of stasipatric speciation. Syst Biol 17:14-22. ) first argues that there was no evidence that speciation “sensu stricto” has occurred in Vandiemenella, a group of grasshoppers from Australia used as a model by White et al. (1967White M, Blackith R, Blackith R and Cheney J (1967) Cytogenetics of the viatica group morabine grasshoppers. I. The coastal species. Aust J Zool 15:263-302.). In sequence, other authors also criticized the stasipatric model of speciation in Vandiemenella (Hewitt, 1979Hewitt GM (1979) Orthoptera: Grasshoppers and crickets. In: Jolui B (ed) Animal Cytogenetics 3. Insecta I. Gebrüder-Borntraeger, Berlin-Stuttgart, pp 170.; Futuyma and Mayer, 1980Futuyma DJ and Mayer GC (1980) Non-allopatric speciation in animals. Syst Biol 29:254-271. ). They have centered their criticisms on the difficulty of chromosomal mutants reaching fixation and the plausibility of simpler, allopatric models, once White et al. (1967White M, Blackith R, Blackith R and Cheney J (1967) Cytogenetics of the viatica group morabine grasshoppers. I. The coastal species. Aust J Zool 15:263-302.) invoked meiotic drive. In addition, Futuyma and Mayer (1980Futuyma DJ and Mayer GC (1980) Non-allopatric speciation in animals. Syst Biol 29:254-271. ) argued that stasipatric speciation is unlikely under population genetic theory because it requires the evolution of a new species within the range of an existing one without geographic isolation, once the gene flow between populations would normally prevent the accumulation of genetic differences that could lead to speciation. Furthermore, the observed distribution of chromosome forms does not necessarily imply fixation without the influence of a geographic barrier (Futuyma and Mayer, 1980Futuyma DJ and Mayer GC (1980) Non-allopatric speciation in animals. Syst Biol 29:254-271. ).

The second critique was the lack of evidence that the chromosomal rearrangements principally distinguish the chromosomal races that arose within the area of distribution of the parental race in any effective sense. However, the chromosomal, biochemical, mitochondrial, and nuclear molecular data from the Vandiemenella populations have shown chromosomal variants in geographic regions, followed by secondary contact, resulting in the presence of a parapatric distribution of chromosomal races (Kawakami et al., 2007aKawakami T, Butlin RK, Adams M, Saint KM, Paull DJ and Cooper SJB (2007a) Differential gene flow of mitochondrial and nuclear DNA markers among chromosomal races of Australian morabine grasshoppers (Vandiemenella viatica species group). Mol Ecol 16:5044-5056. , bKawakami T, Butlin RK, Paull DJ and Cooper SJB (2007b) Polymorphic microsatellite markers for chromosomal races of Australian morabine grasshoppers (Vandiemenella viatica species group). Mol Ecol Notes 7:1181-1184. , 2009aKawakami T, Butlin RK, Adams M, Paull DJ and Cooper SJB (2009a) Genetic analysis of a chromosomal hybrid zone in the Australian morabine grasshoppers (Vandiemenella viatica species group). Evolution 63:139-152., bKawakami T, Butlin RK, Adams M, Saint KM, Paull DJ and Cooper SJB (2009b) Re-examination of a proposed case of stasipatric speciation: Phylogeography of the Australian morabine grasshoppers (Vandiemenella viatica species group). Mol Ecol 18:3429-3442. , 2011Kawakami T, Butlin RK and Cooper SJB (2011) Chromosomal speciation revisited: Modes of diversification in Australian Morabine Grasshoppers (Vandiemenella viatica species group). Insects 2:49-61. ). Although many authors still consider this dataset more consistent to corroborate allopatric speciation after population fragmentation (Kearney and Hewitt, 2009Kearney M and Hewitt G (2009) Stasipatric speciation: Resurrecting a system to bury a hypothesis? Mol Ecol 18:3331-3333. ), there is no way to rule out the reproductive isolation in sympatry generated by chromosomal rearrangements as a primary source of the speciation process.

Recently, genomic analysis bring new clues to this discussion, since the role of transposable elements on chromosomal rearrangements is well known (Klein and O’Neill, 2018Klein SJ and O’Neill RJ (2018) Transposable elements: Genome innovation, chromosome diversity, and centromere conflict. Chromosome Res 26:5-23. ), and the species/chromosomal races/cytotypes of Vandiemenella viatica analyzed so far indicate tendencies of accumulation of a specific type of repetitive DNA, satellite DNA (Palacios-Gimenez et al., 2020aPalacios-Gimenez OM, Koelman J, Palmada-Flores M, Bradford TM, Jones KK, Cooper SJB, Kawakami T and Suh A (2020a) Comparative analysis of morabine grasshopper genomes reveals highly abundant transposable elements and rapidly proliferating satellite DNA repeats. BMC Biol 18:199. ). Moreover, satellite DNA has been shown to be a good marker of chromosomal evolution among grasshoppers, as seen in the Schistocerca genus (Palacios-Gimenez et al., 2020bPalacios-Gimenez OM, Milani D, Song H, Marti DA, López-Léon MD, Ruiz-Ruano FJ, Camacho JPM and Cabral-de-Mello DC (2020b) Eight Million Years of Satellite DNA Evolution in Grasshoppers of the Genus Schistocerca Illuminate the Ins and Outs of the Library Hypothesis. Genome Biol Evol 12:88-102. ), and could represent an important tool to understand the chromosomal evolution of V. viatica. In fact, in virtually all groups of organisms, repetitive DNA plays some role in genomic changes and therefore, karyotypic evolution (Schrader and Schmitz, 2019Schrader L and Schmitz J (2019) The impact of transposable elements in adaptive evolution. Mol Ecol 28:1537-1549. ).

Several models have been proposed to explain the relationship between chromosome evolution and speciation, particularly regarding the mechanisms of fixation of polymorphisms (for a review see Rieseberg, 2001Rieseberg LH (2001) Chromosomal rearrangements and speciation. Trends Ecol Evol 16:351-358. ; Navarro and Barton 2003Navarro A and Barton NH (2003) Chromosomal Speciation and Molecular Divergence-Accelerated Evolution in Rearranged Chromosomes. Science 300:321-324. ; Hoffmann and Rieseberg, 2008Hoffmann AA and Rieseberg LH (2008) Revisiting the impact of inversions in evolution: From population genetic markers to drivers of adaptive shifts and speciation? Annu Rev Ecol Evol Syst 39:21-42. ; Faria and Navarro, 2010Faria R and Navarro A (2010) Chromosomal speciation revisited: Rearranging theory with pieces of evidence. Trends Ecol Evol 25:660-669.; Jackson et al., 2016Jackson B, Butlin R, Navarro A and Faria R (2016) Speciation, chromosomal rearrangements and. Enc Evol Biol 4:149-158. ). However, these models still need to address a practical problem arising from chromosomal speciation: the formation of groups of cryptic species, usually with an intense karyotypic variation. Genomic polymorphisms from hybridisms and events of haploid genome changes may lead to the reorganization of karyotypes, culminating in speciation. In the absence of these events (hybridization and euploidy), the existence of sizable genomic diversity and karyotype plasticity in the ancestral lineage, for example, could explain the emergence of different karyomorphs. These karyomorphs, in turn, can be fixed by evolutionary processes or demographic events, contributing to the formation of new evolutionary significant units (ESUs).

Groups with independent evolutionary units with wide geographic distribution usually constitute informative examples of radiation, since adaptive radiation refers to those evolutionary groups that exhibit an exceptional extension of adaptive diversification in a variety of ecological niches (Schluter, 2000Schluter D (2000) Ecological Character Displacement in Adaptive Radiation. Am Nat 156:4-16. ), and non-adaptive radiation can be described as an evolutionary diversification from a common ancestor not accompanied by relevant niche differentiation but by isolation for competition (Gittenberger, 1991Gittenberger E (1991) What about non-adaptive radiation? Biol J Linn Soc 43:263-272. ). Basically, only mutation and selection processes were sufficient to promote the rapid proliferation of new forms, which supports the theory that compensations in the competitive capacity drive adaptive radiation (Gavrilets and Vose, 2005Gavrilets S and Vose A (2005) Dynamic patterns of adaptive radiation. Proc Natl Acad Sci U S A 102:18040-18045. ). On the contrary, niche conservatism can contribute to the rapid accumulation of lineages by promoting the isolation of derived forms and the multiplication of species through a spatially and temporally floating environment (Kozak et al., 2005Kozak KH, Weisrock DW and Larson A (2005) Rapid lineage accumulation in a non-adaptive radiation: Phylogenetic analysis of diversification rates in eastern North American woodland salamanders (Plethodontidae: Plethodon). Proc Biol Sci 273:539-546. ).

Here, we propose a concept based on the idea of radiation of the karyomorphs to explain the existence of cryptic species karyotypically differentiated, with or without the presence of clines, common in several megadiverse groups of animals and plants.

The concept of Chromosomal Radiation

We herein introduce the concept of “Chromosomal Radiation,” which explains the diversity patterns observed for many years in the chromosomal studies of various diploid organisms. This concept can be applied to studying any group of cryptic species, chronospecies, or sister species, which display lower or higher molecular and usually low morphological divergence, associated with large karyotype diversity, i.e., a rapid chromosome evolution.

We believe, therefore, that chromosomal radiation consists of a pattern in which the common ancestor of the group has the potential for karyotype plasticity. Just as phenotypic plasticity refers to the ability of the same genotype to express different phenotypic characteristics in different environments (West-Eberhard, 1989West-Eberhard MJ (1989) Phenotypic Plasticity and the Origins of Diversity. Annu Rev Ecol Evol Syst 20:249-278.; Whitman and Agrawal, 2009Whitman D and Agrawal A (2009) What is Phenotypic Plasticity and Why is it Important? Phen Plast Insec. DOI: 10.1201/b10201-2.
https://doi.org/10.1201/b10201-2...
; Secer et al., 2022Secer B, Mouludi-Saleh A, Eagderi S, Poorbagher H, Cicek E and Sungur S (2022) Phenotypic Plasticity of Angora Loach, Oxynoemacheilus angorae (Steindachner, 1897) in Inland Waters of Turkey. Iran J Sci Technol Trans Sci 46:1317-1326.), karyotype or chromosomal plasticity represents the capacity of the same (or near same) phenotype to exhibit different chromosomal characteristics in different environments and/or populations. In Leishmania, for instance, the tolerance of natural populations to different types of aneuploidies appears to be crucial for the homozygosity (monozygosity) of distinct genes, thereby constituting a significant tool for investigations concerning gene function and regulatory mechanisms (Cruz et al., 1993Cruz AK, Titus R and Beverley SM (1993) Plasticity in chromosome number and testing of essential genes in Leishmania by targeting. Proc Natl Acad Sci U S A 90:1599-1603.; Dujardin et al., 1995Dujardin JC, Dujardin JP, Tibayrenc M, Timperman G, Doncker SD, Jacquet D, Arevalo J, Llanos-Cuentas A, Guerra H, Bermudez H et al. (1995) Karyotype plasticity in Neotropical Leishmania: An index for measuring genomic distance among L. (V.) peruviana and L. (V.) braziliensis populations. Parasitology 110:21-30.). With over 70 chromosomal races (Wójcik et al., 2003Wójcik JM, Borodin PM, Fedyk S, Fredga K, Hausser J, Mishta A and Orlov VN (2003) The list of the chromosome races of the common shrew Sorex araneus (updated 2002). Mammalia 67:169-178.), Sorex araneus stands as a significant example of how a species can modify its chromosomes without substantial phenotypic manifestations, although certain correlations between morphometrics and karyotypes can be observed in specific groups (Polly, 2007Polly PD (2007) Phylogeographic differentiation in Sorex araneus: Morphology in relation to geography and karyotype. Russ J Theriol 6:73-84.). Furthermore, processes of chromosome gain and loss associated with equid evolution underscore the importance of karyotypic plasticity in evolution (Jónsson et al., 2014Jónsson H, Schubert M, Seguin-Orlando A, Ginolhac A, Petersen L, Fumagalli M, Albrechtsen A, Petersen B, Korneliussen TS, Vilstrup JT et al. (2014) Speciation with gene flow in equids despite extensive chromosomal plasticity. Proc Natl Acad Sci U S A 111:18655-18660. ). Such karyotype plasticity enables the expansion of forms, with new populations presenting different karyotypes, which can be set independently by evolutionary and/or demographic processes. Under this explanation, chromosomal differentiation currently found in populations that do not always show signs of homology would be the result of two main processes: (i) the emergence of rearrangements that generate intrapopulation genetic variability in different lineages, without affecting the reproductive performance of individuals (Figure 1a); and (ii) the spread and fixation of different rearrangements independently in different populations over time, leading to the interpopulation variability observed (Figure 1b).

Figure 1 -
The schema delineates the process of chromosomal radiation through two sequential stages. Firstly, Stage a) involves the emergence of populations presenting rearrangements from an ancestor karyotype exhibiting karyotypic plasticity, resulting in intrapopulation genetic variability. These rearrangements include both major structural alterations and minor polymorphisms such as heterochromatin or ribosomal sites (not shown in the schema). Subsequently, Stage b) encompasses the independent spread and fixation of various rearrangements in distinct populations over time, concomitant with the extinction of other rearrangements. This stage culminates in interpopulation variability. Since not all possible polymorphisms are generated or fixed, and other subsequent rearrangements may arise and reorganize the genome of mutant individuals, several variant forms are observed in natural populations.

Thus, cryptic species complexes where there are a large diversity of karyomorphs with autapomorphies must have originated due to plasticity in the ancestral karyomorph. The multiple karyotypic forms found in cryptic species could constitute, therefore, important examples of non-adaptive or adaptive chromosomal radiation, depending on the relation of the character with the environment.

Despite the debates about the role of chromosomal rearrangements in the diversification of species, there is evidence that unbalanced rearrangements can interfere in gametogenesis, reinforcing the reproductive isolation of karyomorphs by reduction of gene flow, as some species have increased tolerance to chromosomal rearrangements, maintaining polymorphic populations or possessing large karyotype plasticity (Pazza et al., 2018Pazza R, Dergam JA and Kavalco KF (2018) Trends in Karyotype Evolution in Astyanax (Teleostei, Characiformes, Characidae): Insights From Molecular Data. Front Genet 9:31. ). Regardless of the explanations for the appearance and fixation of the existing variation, there is a consensus that chromosomes play an important role in the speciation of several groups of organisms.

In theory, although frequently a causal factor of differentiation, the accumulation of chromosomal rearrangements can also be the result of evolutionary processes in natural populations. In groups where gene flow persists for a long time between different forms of a lineage, it is very difficult to assign reproductive isolation to chromosomal rearrangements. In species with large karyotype plasticity, for example, equids (Jónsson et al., 2014Jónsson H, Schubert M, Seguin-Orlando A, Ginolhac A, Petersen L, Fumagalli M, Albrechtsen A, Petersen B, Korneliussen TS, Vilstrup JT et al. (2014) Speciation with gene flow in equids despite extensive chromosomal plasticity. Proc Natl Acad Sci U S A 111:18655-18660. ), the maintenance of gene flow between different karyomorphs appears to be possible, at least for some time. This may occur more often than we estimate, explaining the discontinuity between molecular and karyotypic evolution seen in some groups with significant chromosomal diversity (Kavalco et al., 2016Kavalco KF, Pazza R, de Oliveira Brandão K, Garcia C, Bertollo LAC and de Almeida-Toledo LF (2016) Chromosomal diversification higher than molecular variation in Astyanax aff. fasciatus (Teleostei, Characidae). Zebrafish 13:345-353. ).

The pattern observed among populations originating from chromosomal radiation would be similar to that seen in a wide range of species. Almost all living organisms possess some level of karyotype plasticity, although, in certain groups, large plasticity can be considered a characteristic biological trait. This is the case in several groups of fish, for example.

Chromosomal radiation in fish

Chromosomal data had long supported the idea that the genus Astyanax (Teleostei, Characiformes) was polyphyletic, as noted by Weitzman and Malabarba (1998Weitzman SH and Malabarba LR (1998) Perspectives about the phylogeny and classification of the Characidae (Teleostei: Characiformes). In: Malabarba LR, Reis RE, Vari RP, Lucena ZMS and Lucena CAS (eds) Phylogeny and Classification of Neotropical Fishes. EDIPUCRS, Porto Alegre, pp 161-170.), and had even revealed the existence of several cryptic species within the group, as summarized by Pasa and Kavalco (2007Pasa R and Kavalco K (2007) Chromosomal evolution in the neotropical characin Astyanax (Teleostei, Characidae). Nucleus 50:519-543.). More recently, molecular studies have provided further evidence for the formation of structured clades within Astyanax (Mello et al., 2015Mello R, Maniglia TC, Prioli SMAP and Prioli AJ (2015) Genetic and biogeographical relationships among species of Astyanax (Teleostei, Characidae) in Brazilian river basins. Genet Mol Res 14:15356-15364. ; Rossini et al., 2016Rossini BC, Oliveira CAM, Melo FAG, Bertaco VA, Astarloa RND, Rosso JJ, Foresti F and Oliveira C (2016) Highlighting Astyanax species diversity through DNA Barcoding. PLoS One 11:e0167203. ; Pazza et al., 2018Pazza R, Dergam JA and Kavalco KF (2018) Trends in Karyotype Evolution in Astyanax (Teleostei, Characiformes, Characidae): Insights From Molecular Data. Front Genet 9:31. ; Pasa et al., 2021Pasa R, Menegídio FB, Rodrigues-Oliveira IH, Silva IB, Campos MLCB, Rocha-Reis DA, Heslop-Harrison JS, Schwarzacher T and Kavalco KF (2021) Ten Complete Mitochondrial Genomes of Gymnocharacini (Stethaprioninae, Characiformes). Insights Into Evolutionary Relationships and a Repetitive Element in the Control Region (D-loop). Front Ecol Evol 9:650783.), and it has become clear that chromosomal features are linked to these clades, especially with regard to the origin and spread of the As51 satellite DNA (Mestriner et al., 2000Mestriner CA, Galetti PM, Valentini SR, Ruiz IRG, Abel LDS, Moreira-Filho O and Camacho JPM (2000) Structural and functional evidence that a B chromosome in the characid fish Astyanax scabripinnis is an isochromosome. Heredity (Edinb) 85:1-9. ) and the localization of the 5S ribosomal gene. Additionally, Pazza et al. (2018Pazza R, Dergam JA and Kavalco KF (2018) Trends in Karyotype Evolution in Astyanax (Teleostei, Characiformes, Characidae): Insights From Molecular Data. Front Genet 9:31. ) highlighted the association between these chromosomal features and the species’ phylogeny. This was reflected in a revision by Terán et al. (2020Terán GE, Benitez MF and Mirande JM (2020) Opening the Trojan horse: Phylogeny of Astyanax, two new genera and resurrection of Psalidodon (Teleostei: Characidae). Zool J Linn Soc 190:1217-1234.), which involved the reassignment of some Astyanax species to six different genera, reverberating the molecular phylogenies and the chromosomal features described. For instance, Astyanax species from coastal river basins of Brazil were now assigned to the genus Deuterodon (such as D. hastatus, D. giton and D. intermedius), which lacks the As51 satellite DNA and in which the rDNA 5S is located only on distal position on ST/A chromosomes (Kavalco et al., 2004Kavalco KF, Pazza R, Bertollo LAC and Moreira-Filho O (2004) Gene mapping of 5S rDNA sites in eight fish species from the Paraíba do Sul river basin, Brazil. Cytogenet Genome Res 106:107-110. , 2009Kavalco KF, Brandão K de O, Pazza R and Almeida-Toledo LF de (2009) Astyanax hastatus Myers, 1928 (Teleostei, Characidae): A new species complex within the genus Astyanax? Genet Mol Biol 32:477-483. ; Rodrigues-Oliveira et al., 2023Rodrigues-Oliveira IH, Penteado PR, Pasa R, Menegídio FB and Kavalco KF (2023) Phylogeography and karyotypic evolution in some Deuterodon species from southeastern Brazil (Characiformes, Characidae, Stethaprioninae). Genet Mol Biol 46:e20230044.). Meanwhile, traditional species complexes such as Astyanax fasciatus and Astyanax scabripinnis were moved to the genus Psalidodon, which has high levels of karyotypic diversity and chromosomal rearrangements, where the As51 satellite DNA plays an important role (Kavalco et al., 2013Kavalco KF, Pazza R, de Oliveira Brandão K and de Almeida-Toledo LF (2013) Biogeographic patterns in the chromosomal distribution of a satellite DNA in the banded tetra Astyanax fasciatus (Teleostei: Characiformes). Org Divers Evol 13:67-76. ). So, we have the emergence of a motor for karyotype plasticity, and the spread of a high diversity of karyotypes of low genetic distance in a short time (Pazza et al., 2018Pazza R, Dergam JA and Kavalco KF (2018) Trends in Karyotype Evolution in Astyanax (Teleostei, Characiformes, Characidae): Insights From Molecular Data. Front Genet 9:31. ), i.e., chromosomal radiation.

The phenomenon of dispersion of repetitive sequences within chromosomes is often attributed to the activity of transposable elements (TE) present in the genomes (Silva-Neto et al., 2015Silva-Neto LC, Bernardino ACS, Loreto V and Moura RC (2015) Physical mapping of 18S and 5S rDNA loci and histone H3 gene in grasshopper species of the subfamily Gomphocerinae (Acrididae). Genet Mol Res 14:15008-15015. ). Such activity may explain the heterogeneous patterns observed in the distribution of heterochromatin blocks and rDNAs 5S cistrons across different pairs of chromosomes. Evidence from rDNA sequence analyses indicates the presence of these elements within spacer regions, facilitating the dissemination of gene families across functional copies or pseudogenes (Drouin and de Sá, 1995Drouin G and de Sá MM (1995) The concerted evolution of 5S ribosomal genes linked to the repeat units of other multigene families. Mol Biol Evol 12:481-493. ; 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. ; Symonová et al., 2013Symonová R, Majtánová Z, Sember A, Staaks GBO, Bohlen J, Freyhof J, Rábová M and Ráb P (2013) Genome differentiation in a species pair of coregonine fishes: An extremely rapid speciation driven by stress-activated retrotransposons mediating extensive ribosomal DNA multiplications. BMC Evol Biol 13:42. ). The dispersion of TEs (and consequently of ribosomal DNA, for example) could then affect the rate of recombination in the genomes and lead to rapid divergence of the karyotype/genome, as observed in the salmonids Coregonus albula and Coregonus fontanae (Symonová et al., 2013Symonová R, Majtánová Z, Sember A, Staaks GBO, Bohlen J, Freyhof J, Rábová M and Ráb P (2013) Genome differentiation in a species pair of coregonine fishes: An extremely rapid speciation driven by stress-activated retrotransposons mediating extensive ribosomal DNA multiplications. BMC Evol Biol 13:42. ). TEs have faced strong selection against them due to unequal homologous recombination, which can lead to their elimination from a genome or the production of inviable chromosomal aberrations (Schrader and Schmitz, 2019Schrader L and Schmitz J (2019) The impact of transposable elements in adaptive evolution. Mol Ecol 28:1537-1549. ). Despite this, TEs have accumulated in most eukaryotic genomes. This raises the question of whether the evolution of epigenetic silencing mechanisms controlling recombination played a crucial role in enabling the invasion of TEs into eukaryotic genomes, as suggested by Fedoroff (2012Fedoroff NV (2012) Transposable elements, epigenetics, and genome evolution. Science 338:758-767. ).

In turn, the species H. ancistroides (Siluriformes) has an extensive diversity of karyomorphs with markers showing homoplastic phenotypes, without clina across geographic distribution, and between haplogroups. One explanation for this pattern is that the period of diversification and the time spent during population divergence was so brief that some karyomorphs and haplotypes may have been lost (Rocha-Reis et al., 2021Rocha-Reis DA, Pasa R and Kavalco KF (2021) High congruence of karyotypic and molecular data on Hypostomus species from Brazilian southeast. Org Divers Evol 21:135-143. ). Such losses difficult the understanding the entire evolutionary landscape of the group, mainly due to the lack of intermediate forms. However, the 19 karyomorphs of H. ancistroides are so exclusive that each population has a particular cytotype (Rocha-Reis et al., 2018Rocha-Reis DA, de Oliveira Brandão K, de Almeida-Toledo LF, Pazza R and Kavalco KF (2018) The Persevering Cytotaxonomy: Discovery of a Unique XX/XY Sex Chromosome System in Catfishes Suggests the Existence of a New, Endemic and Rare Species. Cytogenet Genome Res 156:45-55.) and two populations have shown different Sexual Chromosome Systems, with male (Rocha-Reis et al., 2018Rocha-Reis DA, de Oliveira Brandão K, de Almeida-Toledo LF, Pazza R and Kavalco KF (2018) The Persevering Cytotaxonomy: Discovery of a Unique XX/XY Sex Chromosome System in Catfishes Suggests the Existence of a New, Endemic and Rare Species. Cytogenet Genome Res 156:45-55.) and female (Lara Kamei et al., 2017Lara Kamei MCS, Baumgärtner L, Paiva S, Zawadzki CH, Martins-Santos IC and Portela-Castro ALB (2017) Chromosomal Diversity of Three Species of Hypostomus Lacépède, 1803 (Siluriformes, Loricariidae), from the Paraná River Basin, Brazil: A Species Complex in Hypostomus ancistroides Reinforced by a ZZ/ZW Sex Chromosome System. Zebrafish 14:357-363.) heterogamety. Comparing the data from the morphology, chromosome macrostructure, genetic and genomic markers, plus the mitochondrial differences, Rocha-Reis et al. (2020Rocha-Reis DA, Pasa R, Menegidio FB, Heslop-Harrison JS, Schwarzacher T and Kavalco KF (2020) The Complete Mitochondrial Genome of Two Armored Catfish Populations of the Genus Hypostomus (Siluriformes, Loricariidae, Hypostominae). Front Ecol Evol 8:579965. ) argue that H. aff. ancistroides with XX/XY and 2n=66 need to be formally described and named as a taxonomically valid species.

This was also observed in species of Chromaphyosemion (Cyprinodontiformes), especially in C. riggenbachi (Völker et al., 2006Völker M, Sonnenberg R, Ráb P and Kullmann H (2006) Karyotype differentiation in Chromaphyosemion killifishes (Cyprinodontiformes, Nothobranchiidae) II: Cytogenetic and mitochondrial DNA analyses demonstrate karyotype differentiation and its evolutionary direction in C. riggenbachi. Cytogenet Genome Res 115:70-83. ). The authors emphasize that karyotypic and haplotypic differentiation suggests speciation in its initial stages and that the karyotype differentiation in C. riggenbachi is an ongoing process, in which the rearrangements may be fixed by several processes such as natural selection, genetic drift, or meiotic impulse. According to Völker et al. (2008Völker M, Ráb P and Kullmann H (2008) Karyotype differentiation in Chromaphyosemion killifishes (Cyprinodontiformes, Nothobranchiidae): Patterns, mechanisms, and evolutionary implications. Biol J Linn Soc 94:143-153. ), various factors, such as the accumulation of chromosomal and genetic incompatibilities, as well as sexual selection, are responsible for driving speciation in Chromaphyosemion. It is not necessary that the relative potency of these factors remains constant in all speciation processes within the group, and in some instances, interactions among them, such as reinforcement, may take place (Völker et al., 2008Völker M, Ráb P and Kullmann H (2008) Karyotype differentiation in Chromaphyosemion killifishes (Cyprinodontiformes, Nothobranchiidae): Patterns, mechanisms, and evolutionary implications. Biol J Linn Soc 94:143-153. ).

Chromosomal radiation in other vertebrates

In other vertebrates, such as amphibians, reptiles, and mammals, large diversity associated with specious groups with wide distribution can also be observed. Rodents are known to constitute a group with a sizable chromosomal diversity and several polymorphisms. At least seven cryptic species are observed in the African gerbil Taterillus spp. (Dobigny et al., 2001Dobigny G, Moulin S, Cornette R and Gautun J (2001) Rodents from Adrar des Iforas, Mali. Chromosomal Data. Mammalia 65:215-220.), distinguishable only by their chromosomal characteristics, with karyotypes displaying extensive chromosomal rearrangements (Dobigny et al., 2002aDobigny G, Aniskin V and Volobouev V (2002a) Explosive chromosome evolution and speciation in the gerbil genus Taterillus (Rodentia, Gerbillinae): A case of two new cryptic species. Cytogenet Genome Res 96:117-124., bDobigny G, Baylac M and Denys C (2002b) Geometric morphometrics, neural networks and diagnosis of sibling Taterillus species (Rodentia, Gerbillinae). Biol J Linn Soc 77:319-327. ). Dobigny et al. (2005Dobigny G, Aniskin V, Granjon L, Cornette R and Volobouev V (2005) Recent radiation in West African Taterillus (Rodentia, Gerbillinae): The concerted role of chromosome and climatic changes. Heredity (Edinb) 95:358-368. ) have linked the observed rearrangements to the association between allopatry and bottlenecks due to drastic climate change, and they assume that the Taterillus genome is (or has recently been) particularly plastic and may consequently have a high probability of chromosomal mutation. Aniskin et al. (2005Aniskin VM, Benazzou T, Biltueva L, Dobigny G, Granjon L and Volobouev V (2005) Unusually extensive karyotype reorganization in four congeneric Gerbillus species (Muridae: Gerbillinae). Cytogenet Genome Res 112:131-140. ), in turn, quote as a remarkable feature of some gerbils’ genomes, is the accumulation of a high heterogeneous constitutive heterochromatin on lineages. In fact, the chromosomal changes and the amount of heterochromatin observed in species of the subgenus Gerbillus were highlighted through the utilization of a molecular phylogeny based on cyt b, where different cytotypes should be regarded as traits that have evolved over time, connecting the accumulation of heterochromatin with the presence of rearrangements (Abiadh et al., 2010Abiadh A, Chetoui M, Lamine-Cheniti T, Capanna E and Colangelo P (2010) Molecular phylogenetics of the genus Gerbillus (Rodentia, Gerbillinae): Implications for systematics, taxonomy and chromosomal evolution. Mol Phylogenet Evol 56:513-518. ).

In Neotropical Rodentia, extensive Robertsonian rearrangements, tandem fusions, fissions, and peri and paracentric inversions, besides heterochromatin polymorphisms, have been described. A review compiling data on the role of rearrangements in speciation and cytotaxonomy of South American species and demonstrating the richness of distinct chromosomal forms makes it possible to delimit cryptic species in Akodon, Calomys, Cerradomys, Euryoryzomys, Delomys, Hylaeamys, Juliomys, Neacomys, Oecomys, Oligoryzomys, Ctenomys, Thrichomys, and Trinomys was presented by Di-Nizo et al. (2017Di-Nizo CB, Banci KR, Sato-Kuwabara Y and Silva MJJ (2017) Advances in cytogenetics of Brazilian rodents: Cytotaxonomy, chromosome evolution and new karyotypic data. Comp Cytogenet 11:833-892. ).

Oliveira da Silva et al. (2019Oliveira da Silva W, Pieczarka JC, Rodrigues da Costa MJ, Ferguson-Smith MA, O’Brien PCM, Mendes-Oliveira AC, Rossi RV and Nagamachi CY (2019) Chromosomal phylogeny and comparative chromosome painting among Neacomys species (Rodentia, Sigmodontinae) from eastern Amazonia. BMC Evol Biol 19:184.) suggest that the process of chromosome evolution in Neacomys may be more intricate and involve more events than initially anticipated, based on the findings of phylogenetic relationships and chromosomal signatures. Their paper presents not only a populational phylogenetic tree with the variant karyotypes but a chromosomal painting showing the homologies among the chromosomes and rearrangements. Do Nascimento Moreira et al. (2022do Nascimento Moreira C, Percequillo AR, Ferguson-Smith MA, Yonenaga-Yassuda Y and Ventura K (2022) Chromosomal evolution of tribe Oryzomyini (Rodentia: Cricetidae: Sigmodontinae). Mamm Biol 102:441-464. ) suggest that genomic components, such as repetitive DNA, stimulate karyotype diversity in rodents belonging to the Oryzomyini tribe and contribute to their chromosomal variability.

In the case of Ctenomys, the most diverse mammals at the species level, the correlation between species diversity and chromosomal variability is not straightforward, as various chromosome sets have been documented within the same species, whereas different species may share similar forms of complex rearrangements (Buschiazzo et al., 2022Buschiazzo LM, Caraballo DA, Labaroni CA, Teta P, Rossi MS, Bidau CJ and Lanzone C (2022) Comprehensive cytogenetic analysis of the most chromosomally variable mammalian genus from South America: Ctenomys (Rodentia: Caviomorpha: Ctenomyidae). Mamm Biol 102:1963-1979. ). According to the authors, the diversity in chromosomes observed in Ctenomys and the variation in the prevalence of specific types of chromosome rearrangements among different groups of species suggest distinct patterns of diversification within each lineage. Therefore, to justify the significant differences in the structure of chromosomes, even within the same species, it is necessary to consider an increased rate of chromosome evolution (Buschiazzo et al., 2022Buschiazzo LM, Caraballo DA, Labaroni CA, Teta P, Rossi MS, Bidau CJ and Lanzone C (2022) Comprehensive cytogenetic analysis of the most chromosomally variable mammalian genus from South America: Ctenomys (Rodentia: Caviomorpha: Ctenomyidae). Mamm Biol 102:1963-1979. ).

It is undeniable that the ancestors of these rodents had the potential for karyotypic plasticity since so many different “types” arose from the preexisting chromosome variation of natural populations. Thus, we see clear radiation of karyomorphs, most probably due to the pre-zygotic isolation that the chromosomal alterations may have caused.

Chromosomal radiation in Drosophila

Another group with significant chromosomal diversity and where radiation probably played an important evolutionary role is the genus of arthropods Drosophila. Dobzhansky had already described polymorphisms in Drosophila chromosomes in the 1930s (Dobzhansky, 1947Dobzhansky T (1947) Adaptive Changes Induced by natural selection in wild populations of Drosophila. Evolution 1:1-16. ), since the first description of chromosome rearrangements, causing lack or recombination, by Sturtevant (1917Sturtevant AH (1917) Genetic Factors Affecting the Strength of Linkage in Drosophila. Proc Natl Acad Sci U S A 3:555-558.). In the 1960s more than 80 different karyomorphs were recognized as acting in the diversification of Hawaiian Drosophila spp., with phylogenies based on chromosomal rearrangements of the group since then (White, 1973White MJD (1973) Animal cytology and evolution. 3rd edition. Cambridge Univ. Press, Cambridge. ). It seems a lot, but this number may be several-fold higher since the adaptive radiation that led to the speciation in these islands has generated over 700 species and the main chromosomal markers emerged after the 1960s.

There are two mechanisms explaining the origin of inversions in Drosophila. The first and predominant mechanism is ectopic recombination between repetitive sequences in genomic regions prone to breakage, resulting in the inversion of the sequence. The second mechanism is based on two staggered double-strand breaks around the future inversion breakpoints, which leads to the reinsertion of the inverted segment and the generation of duplications around the breakpoints (Kapun and Flatt, 2019Kapun M and Flatt T (2019) The adaptive significance of chromosomal inversion polymorphisms in Drosophila melanogaster. Mol Ecol 28:1263-1282. ). It is worth noting that Drosophila species exhibit varying degrees of tolerance towards inversion polymorphisms. For instance, sister species of D. melanogaster, such as D. simulans, D. mauritiana, and D. sechellia, are virtually devoid of inversions, with only a few cases of unique inversion polymorphisms recorded at low frequencies in natural populations (see Kapun and Flatt, 2019Kapun M and Flatt T (2019) The adaptive significance of chromosomal inversion polymorphisms in Drosophila melanogaster. Mol Ecol 28:1263-1282. for a review). This lack of inversions in these species may be attributed to a lower number of transposable elements (TEs), which are known to play a crucial role in the generation of inversions, and/or larger population sizes as compared to D. melanogaster, leading to distinct patterns of genetic variation (Aquadro et al., 1988Aquadro CF, Lado KM and Noon WA (1988) The rosy region of Drosophila melanogaster and Drosophila simulans. I. Contrasting levels of naturally occurring DNA restriction map variation and divergence. Genetics 119:875-888. ). Similarly, the chromosomal variations described in groups of sister species or cryptic species of many other insects, including beetles, locusts, crickets, and mosquitoes are historically extensive.

Chromosomal radiation in plants

Chromosomal diversity is not exclusive to animals. In plants, besides hybridisms, numerical and structural polymorphisms, and polyploidy events are implicated in the rapid speciation of various groups. In Liliaceae, there is evidence of fusions, fissions, translocations, and inversions that generate a great diversity of karyomorphs in several genera, altering karyotypic symmetry (Peruzzi et al., 2009Peruzzi L, Leitch IJ and Caparelli KF (2009) Chromosome diversity and evolution in Liliaceae. Ann Bot 103:459-475. ). Karyomorph radiation from an ancestor of high intrinsic diversity, naturally selected or fixed by genetic drift, explains all these patterns.

Similarly, chromosomal diversity in the Asteraceae is substantial and seen in several genera, especially in the patterns of heterochromatin, where differences in the sizes and number of C+ bands appear to be related to the presence of rearrangements (see Marinho et al., 2017Marinho MAO, Sales-Melo MRC, Melo de Oliveira MB, Maciel VEO and Carvalho R (2017) Karyotype variation in 11 species of the Vernonieae Cass. tribe (Asteraceae Bercht. & J. Presl). Plant Biosyst 151:291-303. ). Repetitive DNA is generally the most variable and rapidly changing part of the genome, with significant differences in both the sequence and the number of individual motifs between species (Heslop-Harrison and Schwarzacher, 2007Heslop-Harrison JS and Schwarzacher T (2007) Domestication, genomics and the future for banana. Ann Bot 100:1073-1084. ). The idea that several derived karyomorphs can be produced from one pluripotent karyomorph as a result of the intrinsic karyotype plasticity of the species is more parsimonious, there being multiple possible forms for each character, and in the case of chromosomes carrying the sites of heterochromatin they are not necessarily homologous to the ancestral karyomorph. That is, each new arrangement could raise independently, creating several new lineages from the same direct ancestor. This would explain not only the distribution pattern of this type of DNA but also the existence of different karyotype formulas and heterochromatic blocks not shared between populations.

In Orchidaceae, one of the most numerous angiosperm families, groups of sister species and cryptic species feature a large number of karyomorphs, such as Epidendrum (Nóbrega et al., 2017Nóbrega SR, Coelho ALF, Verola CF, Costa IR, Vilaça R, Luz FJF and Araújo WF (2017) Research Article Chromosome variations and diversity of Epidendrum ibaguense Lindl. (Orchidaceae) on the Tepequém’s Tepuy, Roraima, Brazil. Genet Mol Res 16:gmr16039754.). The presence of repetitive elements such as transposable elements, satellites, and others, can result in variations in the distribution of heterochromatin and in the genome size, reflected in the phylogenetic lineages (Pessoa et al., 2021Pessoa EM, Cordeiro JMP, Felix LP, Almeida EM, Costa L, Nepomuceno A, Souza G, Chase MW, Alves M and van den Berg C (2021) Too many species: Morphometrics, molecular phylogenetics and genome structure of a Brazilian species complex in Epidendrum (Laeliinae; Orchidaceae) reveal fewer species than previously thought. Bot J Linn Soc 195:161-188. ). The absence of blocks in one of the homologs reveals the likely occurrence of unequal exchanges during cell division, where a part or the entire heterochromatin block is translocated to another chromosome. Interestingly, such polymorphisms are observed, especially in hetero-karyotypes, since the major part of the polymorphisms appears in heterozygosity in populations, and, depending on demographic events and evolutionary processes, can be fixed or eliminated over generations, usually after overcoming subdominance (Hoffmann and Rieseberg, 2008Hoffmann AA and Rieseberg LH (2008) Revisiting the impact of inversions in evolution: From population genetic markers to drivers of adaptive shifts and speciation? Annu Rev Ecol Evol Syst 39:21-42. ; Kirkpatrick, 2010Kirkpatrick M (2010) How and Why Chromosome Inversions Evolve. PLoS Biol 8:e1000501. ) or by selection or genetic drift in small populations (Spirito, 1998Spirito F (1998) The role of chromosomal change in speciation. In: Howard DJ and Berlocher SH (eds) Endless forms: Species and speciation. Oxford Univ. Press, Oxford, pp 320-329.). This indicates not only that there is variation in the population, but it is in the overt process of chromosome evolution.

Polyploidy is considered a paramount adaptive mechanism in chromosomal evolution and speciation. The analysis of meiotic chromosome pairing is a valuable tool in studying polyploids, but it is subject to the influence of genes that guarantee the exclusive pairing of homologous chromosomes (Heslop-Harrison et al., 2023Heslop-Harrison JS, Schwarzacher T and Liu Q (2023) Polyploidy: Its consequences and enabling role in plant diversification and evolution. Ann Bot 131:1-10. ). In order to prevent the occurrence of multivalents during meiosis, which can lead to non-disjunction of chromosomes and the production of infertile gametes, polyploids have evolved genetic mechanisms, such as the Ph-locus in wheat, that promote proper chromosome pairing during meiosis (Rawale et al., 2019Rawale KS, Khan MA and Gill KS (2019) The novel function of the Ph1 gene to differentiate homologs from homoeologs evolved in Triticum turgidum ssp. dicoccoides via a dramatic meiosis-specific increase in the expression of the 5B copy of the C-Ph1 gene. Chromosoma 128:561-570.). These mechanisms help to restore diploid behavior in the polyploid (Heslop-Harrison et al., 2023Heslop-Harrison JS, Schwarzacher T and Liu Q (2023) Polyploidy: Its consequences and enabling role in plant diversification and evolution. Ann Bot 131:1-10. ). Other means of dissemination, such as apomictic seed production or vegetative propagation, permit the propagation of species without the need for conventional meiosis. These mechanisms also enable the survival of taxa with an odd number of ancestral genomes, such as the triploid dessert banana Musa acuminata (Heslop-Harrison and Schwarzacher, 2007Heslop-Harrison JS and Schwarzacher T (2007) Domestication, genomics and the future for banana. Ann Bot 100:1073-1084. ), and can help the polymorphism to spread to surrounding populations and achieve fixation.

Adaptive and non-adaptive chromosomal radiation

Several diversifications may contain elements of both adaptive and non-adaptive radiation (Rundell and Price, 2009Rundell RJ and Price TD (2009) Adaptive radiation, nonadaptive radiation, ecological speciation and nonecological speciation. Trends Ecol Evol 24:394-399. ). Thus, it seems quite plausible that we can identify adaptive and non-adaptive traits in karyotypes of groups of sister species and accept that chromosomal radiation can cover both adaptive and non-adaptive characters, not being mutually exclusive. Chromosomal inversions have been shown to play a significant role in a local adaptation by capturing multiple linked variants that confer adaptive benefits within the specific environment. The heterozygosity of inverted regions suppresses recombination due to the production of unbalanced gametes or the inability of inverted regions to synapse (Hoffmann and Rieseberg, 2008Hoffmann AA and Rieseberg LH (2008) Revisiting the impact of inversions in evolution: From population genetic markers to drivers of adaptive shifts and speciation? Annu Rev Ecol Evol Syst 39:21-42. ; Kirkpatrick, 2010Kirkpatrick M (2010) How and Why Chromosome Inversions Evolve. PLoS Biol 8:e1000501. ). Consequently, inversions help maintain linkage disequilibrium among a group of locally adapted variants in the presence of gene flow and migration from populations without the inversion (Kirkpatrick and Barton, 2006Kirkpatrick M and Barton N (2006) Chromosome inversions, local adaptation and speciation. Genetics 173:419-434. ; Hoffmann and Rieseberg, 2008Hoffmann AA and Rieseberg LH (2008) Revisiting the impact of inversions in evolution: From population genetic markers to drivers of adaptive shifts and speciation? Annu Rev Ecol Evol Syst 39:21-42. ; Kirkpatrick, 2010Kirkpatrick M (2010) How and Why Chromosome Inversions Evolve. PLoS Biol 8:e1000501. ). The selective advantage of inversion is not dependent on epistatic interactions between adaptive variants, and their effects can be additive (Kirkpatrick and Barton, 2006Kirkpatrick M and Barton N (2006) Chromosome inversions, local adaptation and speciation. Genetics 173:419-434. ). Furthermore, it is possible that the breakpoints of inversions may have phenotypic effects and, therefore, be adaptive. Additional adaptive mutations may or may not occur within the inversion (Kirkpatrick and Barton, 2006Kirkpatrick M and Barton N (2006) Chromosome inversions, local adaptation and speciation. Genetics 173:419-434. ).

The disproportionate influence of sex chromosomes on the speciation process has been widely acknowledged. The fixation rate of X-linked inversions and their polymorphism levels are often observed to be higher compared to autosomal inversions in several insect species. Cheng and Kirkpatrick (2019Cheng C and Kirkpatrick M (2019) Inversions are bigger on the X chromosome. Mol Ecol 28:1238-1245.) report that X-linked inversions in Drosophila capture a significantly larger number of genes (67% more) compared to autosomal inversions. Similarly, the genetic differentiation between pairs of populations or species in birds is typically greater on the sex chromosomes when compared to the autosomes (Hooper et al., 2019Hooper DM, Griffith SC and Price TD (2019) Sex chromosome inversions enforce reproductive isolation across an avian hybrid zone. Mol Ecol 28:1246-1262. ).

Conclusion

The findings of this study provide substantial support for the notion that certain groups of organisms exhibit intrinsic genome-based karyotype plasticity. The observed widespread occurrence of cryptic evolutionary units correlates with a pattern akin to species radiation, termed here as “chromosomal radiation.” This phenomenon can manifest in both adaptive scenarios, wherein distinct karyotypes enable coping with selective environmental pressures, as well as non-adaptive scenarios, where karyomorphs are maintained in small populations through the process like genetic drift.

The recognition of the concept developed in our article may facilitate the discussion of topics related not only to evolution and karyotypic speciation among or within populations but also to chromosomal evolution itself, including the processes of emergence of variant karyomorphs and specialized chromosomes, such as sex chromosomes, in an eco-evolutionary context.

Acknowledgements

We are grateful to several institutions and colleagues that have contributed to our studies over several years, especially during our time in England. So, we must thank Pat and Trud (Heslop-Harisson and Schwarzacher) for all, and thank the staff of Pat’s lab for the excellent discussions during our lunchtimes at the University of Leicester. We are grateful to the UFV for allowing us to do a postdoctoral internship or sabbatical, even without a scholarship.

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  • Author Contributions

    KFK and RP conceived the idea; KFK and RP conducted the reference Search; KFK and RP wrote the manuscript; KFK and RP read and approved the final version.

Edited by

Associate Editor: Carlos F. M. Menck

Publication Dates

  • Publication in this collection
    25 Sept 2023
  • Date of issue
    2023

History

  • Received
    24 Apr 2023
  • Accepted
    22 Aug 2023
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