Leptysma argentina

The aim of the present cytological research in L. argentina consisted in testing the operation of natural selection, chiefly on the centric fusion (F) and the large supernumerary segment (S) polymorphisms, and to a lesser extent on the B-chromosome. Having analysed 11 populations over a span of 7 degrees of latitude (between 27°S and 34°S) (table 1, fig. 1) a latitudinal cline for F and another for B (which forms a reverse slope) were detected. Data come mostly from already published material (Colombo, Reference Colombo1987, Reference Colombo1989, Reference Colombo1990, Reference Colombo1993, Reference Colombo1997, Reference Colombo2000; Norry and Colombo, Reference Norry and Colombo1999; Colombo et al., Reference Colombo, Pensel and Remis2001, Reference Colombo, Pensel and Remis2004); data from the Tucumán (T) population remained unpublished until now.

Table 1. Leptysma argentina: geographic and climatic variables associated with the populations studied here

Lat, South latitude; MinT, mean annual minimum temperature; MaxT, mean annual maximum temperature (in °C); Monthly rainfall, average yearly rainfall (in mm); Etp/yr, mean yearly evapotranspiration (in mm/year). Frequencies of chromosome polymorphisms for F, S and B (see text) are also indicated. N = sample size. Abbreviations of grasshopper populations are given in fig. 1.

^a Previously unpublished data.

Figure 1. Sampling area and Leptysma argentina populations included in this study: Tucumán (T), Santa Fe (SF), Los Loros (LL), Yarará Guazú (YG), El Palmar (EP), Zárate (ZA), Puerto Talavera (PT), Isla Talavera (IL), Río Luján (RL) and Pilar (P). Pie diagrams indicate the frequencies of the centric fusion 3/6 (F), the segment S and the B-chromosome (B) in dark grey. Data from T were unpublished so far.

Latitudinal clines are compatible with (but not conclusive of) the operation of natural selection (Endler, Reference Endler1977). Endler (Reference Endler1986) listed ten criteria to detect the operation of natural selection in the wild, as follows:

1. I) Correlations of the polymorphisms with environmental (climatic) variables;

2. II) Comparison between closely related species;

3. III) Comparison between unrelated species living in similar habitats;

4. IV) Deviation from formal null-models, such as Hardy–Weinberg or gametic phase (linkage) equilibria;

5. V) Long-term study of trait frequency distribution, such as (a) long-term stability or (b) regular directional change;

6. VI) Perturbation of natural populations such as: (a) predictable seasonal changes and (b) introduction into new equivalent and non-equivalent habitats;

7. VII) Genetic demography or cohort analysis;

8. VIII) Comparisons among age-classes or life-history classes such as (a) comparison of breeding and non-breeding adults or (b) comparison of juveniles and adults and (c) fitness component analysis such as mating ability, mating preference, fecundity, viability, age of reproduction, etc.

9. IX) Non-equilibrium predictions of changes in trait distributions; and

10. X) Equilibrium predictions about trait frequency distribution.

Criteria II, III, VII, IX and X would not (likely) apply for the purposes of the present research and they were not discussed.

As for (I), besides the latitudinal clinal variation, the statistical analysis showed that:

1. i) F correlates negatively with average and maximum temperature (P = 0.0001 and 0.0002), positively with latitude (P = 0.0005) and negatively with yearly evapotranspiration (Etp yr^–1) (P = 0.0111) and rainfall (P = 0.0189). A stepwise regression analysis showed a positive regression on latitude (P = 0.00063) and a negative one on Etp yr^–1 (P < 0.00181).

2. ii) B correlates negatively with latitude (P = 0.0001) and positively with average and maximum temperature (P = 0.0002 and P = 0.0076 respectively). As for the stepwise regression analysis, B displays an inverted pattern with respect to F, with a highly significant negative selection on latitude (P = 0.0063) and a positive significant one on average temperature (P 0.0142),

3. iii) All 11 populations considered, S showed a significant negative regression against rainfall (P = 0.0189) despite the absence of any obvious geographic pattern (table 1, fig. 1). However, the IT population is very much of an outlier. A small sample from an extremely small population, in an area of intense human perturbation, it was suppressed from a second statistical analysis. As supposed, negative correlation with rainfall became highly significant (P = 0.0009).

It may seem odd that some of the polymorphisms show better regressions on latitude than on the environmental variable they ought to be related with, presumably temperature (but also rainfall in this region of South America). However, this seems to be a frequent feature of chromosomal clines of other organisms such as Drosophila (see Kapun et al., Reference Kapun, Fabian, Goudet and Flatt2016 and references therein). Apparently this may indicate that the underlying factor of clinal variation is related with temperature, but not temperature as such (Krimbas, Reference Krimbas, Krimbas and Powell1992).

(II) Two areas were sampled with special intensity: the northeast of Buenos Aires province (RL, O, Z, IT, PT) (lat. 34°S) and a protected area 300 km further north (‘El Palmar’, LL, EP, YG) (lat. 31.8°S). The karyotypes always adjusted to the Hardy–Weinberg expectations everywhere, but preliminary analyses in the first area suggested that

1. (i) there was a non-significant excess for S heterozygotes (BS) at the onset of the breeding season (spring), and a non-significant defect at the end (summer); the X² comparison between both samples was significant, although the frequency of S did not change.

2. (ii) By contrast, the F frequency showed a consistent increase between spring and summer samples everywhere. The following year, however, the population had the same F frequency as the precedent. The polymorphism was apparently stable, but the frequencies changed along the year. (i) and (ii) turned out to be the first evidences of seasonal selection for F and S (Endler's VI a) (Colombo, Reference Colombo1989).

This evidence of cyclical change was constant for over 20 years, between, 1983 and 2004 and was replicated elsewhere, i.e. in the ‘El Palmar’ area, which was geographically distant and with different karyotypic frequencies when compared to the previous one.

Gametic phase (linkage) equilibrium analyses were carried out between F and S, both in early and late spring in both populations, taking advantage of the fact that L. argentina has synchronous and non-overlapping generations (Aquino and Turk, Reference Aquino and Turk1997). In the El Palmar population, young individuals (spring sample) were in equilibrium; in aged ones (summer sample) gametic phase disequilibrium was significant instead, with a prevalence – according to the simulation – of FB (fused and without S) and US (unfused and with the segment) gametes (Colombo, Reference Colombo1993). The same result was replicated further south, with a much higher F frequency, only that linkage disequilibrium D was non-significant (Colombo, Reference Colombo2000). This is yet another evidence (Endler's IV), albeit indirect, of the operation of natural selection (Endler, Reference Endler1986). Therefore, gametic phase equilibrium is a null model this species does not fit into.

As generations were synchronous and non-overlapping in this species (Aquino and Turk, Reference Aquino and Turk1997), age-class comparisons in both areas were possible. We compared the frequencies of all nine karyotypes (for F and S) at spring (young males) and summer (aged males) in both sampling regions. In the young male sample from El Palmar, karyotypes for both polymorphisms distributed independently; in aged ones the FF individuals tended to be unsegmented (BB), and the segmented (SS) ones tended to be unfused (UU); furthermore, there was always a clear excess of double heterozygotes (Colombo, Reference Colombo1993). The same result was obtained further south, where F displays a much higher frequency in both places, only with a different frequency (Colombo, Reference Colombo1993; Colombo et al., Reference Colombo, Pensel and Remis2001). All individuals are already adult by the onset of October (spring), and at this latitude there is just one generation a year (personal observation); therefore, the change of frequency must be due to differential survival alone. According to Endler (Reference Endler1986), comparison between age classes, in this case juveniles and adults (Endler's VIIIb), is a fairly direct evidence of natural selection for both polymorphisms, and it may come to explain the gametic disequilibrium described above.

(IV) Coincidental correlations between environmental variables both between and within populations along the year: the evidence here is contradictory and spotty. F is inversely correlated with temperature. However, it always increases its frequency from spring to summer; F showed a positive regression on Tmax along a series of seven (not strictly consecutive) years; the regression on rainfall changes its sign in El Palmar with respect to Buenos Aires' NE. Segment S does not change its frequency along the season, it is just the heterozygotes BS who decrease among the aged males. No attempt to perform these studies on the B-chromosome was done.

(V) Selection component analyses (Endler's VIIIc) confirmed that the F dosage was correlated with adult male longevity (Norry and Colombo, Reference Norry and Colombo1999). The selective male longevity value of F is clearer since its frequency has always increased along the breeding season, i.e. from October to December (spring to summer) (Colombo, Reference Colombo1993; Colombo et al., Reference Colombo, Pensel and Remis2001).

Moreover, a unisexual approach revealed that the F carriers had an advantage in mating selection (Colombo et al., Reference Colombo, Pensel and Remis2001). Furthermore, F dosage also increased female mating success (Colombo et al., Reference Colombo, Pensel and Remis2004). No effect on either phenotype or mating success was detected for segment S.

The quest for the selection target

At the time these studies were undertaken for the first time, except for a few cases (White and Andrew, Reference White and Andrew1960; Butlin et al., Reference Butlin, Read and Day1982) chromosomal change was generally deemed to be neutral for the external phenotype (Lande, Reference Lande1979; John, Reference John, Sharma and Sharma1983) and it was believed that only the internal phenotype (i.e. meiosis) was affected by them (John, Reference John, Sharma and Sharma1983). The study of body size in all three karyotypes of F on most body size-related traits in two populations of L. argentina (Colombo, Reference Colombo1989, Reference Colombo1997) revealed that F carriers were significantly larger, and that there is a good correlation between its frequency, latitude and body size-related traits. The populations of ‘El Palmar’ (lat. 31.8°) had smaller individuals and a lower F frequency; those of Buenos Aires (lat. 34°C) have a larger body size, and a higher F frequency (Colombo, Reference Colombo1989, Reference Colombo1997). The karyotype–body size correlation was consistent and highly significant. Santa Fe individuals, one degree of latitude further north, have no F and are smaller than the others; finally, males from the norther monomorphic population of Tucumán (27°S) are tiny (data unpublished).

The selection component analyses mentioned above (Endler's VIIIc criteria) showed that F is positively selected for longevity from spring to summer, i.e. with increasing temperature; aged males are larger than young ones, the direct target of selection being thorax height (Norry and Colombo, Reference Norry and Colombo1999). Additionally, when mating choice was studied it was found that sexual male selection advantage is associated with a larger third femur length in males, and total body length (TL) as well as third femur length (FL) in females. However, these variables are not the actual selection targets (Colombo et al., Reference Colombo, Pensel and Remis2001, Reference Colombo, Pensel and Remis2004).

To summarise:

1. i) Along the latitudinal cline, F correlates negatively with temperature but positively with size.

2. ii) Within a population, at a given time, F correlates positively with body size.

3. iii) Within a population, F increases from spring to summer (i.e. its frequency correlates positively with temperature) and, as always, keeps correlating positively with body size.

This supposed fit to the ‘Bergmann rule’ would rather reflect the case of a change of voltinism along a latitudinal transect (Shelomi, Reference Shelomi2012). There is evidence of this in Aquino and Turk (Reference Aquino and Turk1997). Further analysis is needed to shed light on the other two phenomena.

Both longevity and mating choice would lead to an increase of F; however, along the more than 20 years of monitoring these frequencies did not modify.

No phenotypic effect could be attributed on a consistent basis to segment S, nor was it revealed to be associated to mating success. It is certainly correlated against rainfall but no geographic pattern was observed. The target of selection on S (detected through gametic phase disequilibrium and joint age class comparison with F) remains unidentified.

Effects of centric fusions on recombination

In addition to the effects of F on phenotype, there were more evident outcomes on cytological features that led to a significant reduction of recombination in F carriers, especially heterozygotes (Colombo, Reference Colombo1987, Reference Colombo1989, Reference Colombo1990):

1. 1) Formation of a new linkage group from the two erstwhile independently segregating chromosome pairs.

2. 2) Reduction of proximal (P) and interstitial (I) chiasma formation in the fusion trivalent, which elicits an abrupt decrease of chiasma frequency, and a strict distal (D) localisation in these elements (intrachromosomal effects) (P, I and D with respect to the centromere) (Colombo, Reference Colombo1990).

3. 3) Decrease in the frequency of total (T), proximal (P) and interstitial (I) chiasmata, and a slight increase in the frequency of distal chiasma frequency (D) in the fusion bivalent (but not so marked as that in the fusion trivalent). The rise in D takes place at the expense of I (both are negatively correlated) and the decrease of T is explained by a reduction of P (both are positively correlated, Colombo, Reference Colombo1990).

4. 4) These within-population results were mirrored by the comparison among populations that display different F frequencies (Colombo, Reference Colombo1989).

These results (Colombo, Reference Colombo1987, Reference Colombo1989, Reference Colombo1990) along with those of Bidau and Mirol (Reference Bidau and Mirol1988), Bidau (Reference Bidau1990), Remis (Reference Remis1990), Colombo (Reference Colombo2007, Reference Colombo2008), Taffarel et al. (Reference Taffarel, Bidau and Martí2015), Martí et al. (Reference Marti, Castillo, Marti and Taffarel2017) and Castillo et al. (Reference Castillo, Taffarel, Maronna, Cigliano, Palacios-Gimenez, Cabral-de-Mello and Martí2018) corroborated that this feature of Robertsonian polymorphisms is consistent among grasshoppers (Colombo, Reference Colombo2013) and beyond. Suppression of recombination in trivalents of heterozygotes and chiasma reduction in fusion bivalents of fusion homozygotes has been reported in house mice (Davisson and Akeson, Reference Davisson and Akeson1993; Bidau et al., Reference Bidau, Gimenez, Palmer and Searle2001; Dumas and Britton-Davidian, Reference Dumas and Britton-Davidian2002; Merico et al., Reference Merico, Giménez, Vasco, Zuccotti, Searle, Hauffe and Garagna2013; Förster et al., Reference Förster, Jones, Jóhannesdóttir, Gabriel, Giménez, Panithanarak, Hauffe and Searle2016), and plants (Rieseberg, Reference Rieseberg2001). Moreover, recombination is shifted towards distal parts of heterozygous metacentrics in the shrew S. araneus (Borodin et al., Reference Borodin, Karamysheva, Belonogova, Torgasheva, Rubtsov and Searle2008).

Comparison between a spontaneous and a stable polymorphic centric fusion

A spontaneous fusion between pairs 5 and 7 (fusion 5/7) was found in a double heterozygote male that also conveyed the 3-3/6-6 trivalent. The number and position of chiasmata in both trivalents were compared, the 5/7 trivalent did not show any change of proximal (to the centromere) chiasma number or position, whereas the effect of the 3/6 centric fusion was conspicuous (Colombo, Reference Colombo1987). The higher frequency of proximal chiasmata in 5/7 trivalent when compared with the 3/6 one was associated with an increased proportion of linear orientation, thus conducing to the formation of unbalanced gametes. As both trivalents occurred in the same individual, it can be assumed that the genetic background was the same.

Hence, it was concluded that the 3/6 fusion triggered a shift of chiasma position towards the distal extremes – not so the 5/7 – and this may have been crucial in the maintenance of the polymorphism. Furthermore, the reduction of recombination between the arms of the newly arisen metacentric and its acrocentric homologues would have entailed a genetic differentiation – above all close to the centromere – between them. Rieseberg and Burke (Reference Rieseberg and Burke2001) stated that rearrangements reduce recombination in the vicinity of the rupture points; in this case, this point is the centromere, where two linkage groups no longer segregate independently. This linkage disequilibrium (LD) may have encompassed genes for local adaptation that would explain the creation of a chromosomal cline such as that exposed here. Wellerenreuther et al. (Reference Wellerenreuther, Rosenquist, Jaksons and Larson2017) demonstrated the existence of such genes within the inversions of the dipteran Coelopa frigida, which shows clines for inversions in the North and Baltic Seas correlated with temperature.

Three parallel fusion clines: the case of C. aquaticum

Here we review the results of our previous work on newly collected populations of C. aquaticum on the abundant, southwardly flowing rivers Paraná and Uruguay (Colombo, Reference Colombo2007, Reference Colombo2008, Reference Colombo2009; Romero et al., Reference Romero, Colombo and Remis2014, Reference Romero, Colombo and Remis2017; Colombo and Remis, Reference Colombo and Remis2018; Colombo et al., Reference Colombo, Zelarayán, Franceschini and Remis2021, Reference Colombo, Bressa and Remis2023). Both large parallel rivers are born in the Brazilian rainforest and converge into the River Plate at latitude 34.5°S in the Paraná Delta, just north of Buenos Aires city. Seven populations from Argentina were sampled along the Paraná Basin since 2005, namely: Corrientes (LP, 27°S), Santa Fe (SF, 31.8°S), Rosario (RO, 33°S), San Nicolás (SN, 33.33°S), San Pedro (SP, 33.5°S), Zárate (ZA, 34°S) and Tigre (TI, 34.4°S). Three parallel fusion clines were found for fusions between L and M pairs, namely 2/5, 1/6 and 3/4. In fact, these fusions (the same ones reported by Mesa (Reference Mesa1956) and Mesa et al. (Reference Mesa, Ferreira and Carbonell1982)) were detected along the middle and lower course of the river; therefore, there are 3³ = 27 possible karyotypes. Fusion frequencies increase southward and downstream and the clines are steep: at the southernmost point they arrive to a frequency of 0.85 (they do not reach fixation) (Colombo, Reference Colombo2008). At this point the Paraná River flows into the River Plate, where there are no water-hyacinths, and consequently no C. aquaticum. In table 2a the frequencies for each fusion are shown, along with environmental variables they were correlated with, such as maximal, minimal and average temperature and yearly rainfall. Furthermore, the average fusion frequency per individual (fpi) is displayed for each population.

Table 2. Geographic and climatic variables associated with Cornops aquaticum populations from the Paraná (a) and Uruguay (b) River basins

Lat, South latitude; MinT, mean annual minimum temperature; MaxT, mean annual maximum temperature (in °C); AvgT, mean annual average temperature; Rainfall, average yearly rainfall (in mm); fusion 2/5, 1/6 and 3/4 frequencies are also indicated; fpi: average fusion number per population. Abbreviations of grasshopper populations are given in fig. 2.

^a In these populations fpi could be scored, but they were not identified due to poor fixation.

^b May also be regarded as part of the Uruguay Basin (see explanation in the text). All of the data were previously published (see quotations in the text).

Later, in co-operation with Dr M.I Remis and Lic. M.L. Romero, we set forth to sample six more populations on the parallel flowing Uruguay Basin, another oversized tributary of the River Plate, with an additional latitudinal cline, only steeper. This cline displays higher fusion frequencies when compared to the same latitude of the Paraná cline up to the GU population, which has an average number of fusions per individual (fpi) of 3.3 (table 2, fig. 2). For example, SN, on the Paraná basin, at the same latitude has an fpi of only 0.57.

Figure 2. Sampling area and Cornops aquaticum populations included in this study. Populations from the Paraná River Basin: Laguna Pampín (LP), Santa Fe (SF), Rosario (RO), San Nicolás (SN), San Pedro (SP), Villa Paranacito (VP), Zárate (ZA) and Tigre (TI). Populations from Uruguay River Basin: Monte Caseros (MC), Salto Grande (SG), Colón (CO), Concepción del Uruguay (CU) and Gualeguaychú (GU) Pie diagrams indicate the frequencies of the centric fusions 2/5, 1/6 and 3/4 in dark grey. All data were previously published elsewhere (see quotations in the text).

However, further downstream from GU, Villa Paranacito (VP) has an fpi of only 1.65. A possible explanation for this anomaly may be that the Paranacito River, sited at the deltaic inundation zone of both convergent basins, is one of the many sprawling branches of the much mightier Paraná (hence its name), and flows into the final course of the Uruguay River. It communicates both basins: the stream (and the floods) of the Paraná basin would drag the floating mats of P. crassipes in which C. aquaticum lives into the smaller Uruguay. We think therefore that the fact that VP fusion frequencies fit closer to the Paraná than to the Uruguay cline is not a shocking anomaly. In fact, if we include it among the Paraná basin populations (to which it may arguably belong), VP fits neatly into this cline on account of its latitude (table 2b).

Correlation with environmental variables

The latitudinal, parallel clines between all three fusions and both rivers set the stage for level I in Endler's scale (Reference Endler1986): correlation between the trait (fusions in this case) and environmental variables. First a correlation was performed between individual fusions (and fpi) and climatic variables. All three fusions and fpi were positively correlated with latitude (cf. .L. argentina) and highly and negatively so with maximum temperature (P = 0.0036 for 2/5, P = 0.0017 for 1/6 and P = 0.0037 for 3/4; P = 0.0004 for fpi) (Colombo and Remis, Reference Colombo and Remis2018). None of the other variables analysed displayed any significant association with the fusions. As for stepwise correlations, there were no changes: all three fusions and fpi showed a negative regression on maximum temperature (2/5: P = 0.0076; 1/6: P = 0.0026; 3/4: P = 0.0040 and fpi: P = 0.0002). None of the other variables were even allowed into the analysis.

Phenotypic effects of C. aquaticum's fusions

Romero et al. (Reference Romero, Colombo and Remis2014) found an association between the fused 1/6 chromosome dosage and body size, which was significant for tegmina length, the provenance of the sample being the deltaic ZA and SP totalling 32 males. Colombo and Remis (Reference Colombo and Remis2018) analysed a more robust sample of 272 individuals, and the joint analysis revealed that fusions 2/5 and 3/4 are significantly associated with larger body size-related traits such as femur and tegmen length, fusion 1/6 not showing any significant effect. Therefore, the average fusion number per individual (fpi), which can take any number between zero and 6, is positively correlated with tegmen and femur length; otherwise stated, the regression of body size on fusion number is significant (Colombo and Remis, Reference Colombo and Remis2018).

As fusion frequency increases southwards, and fusion number (0–6) is correlated with body size, it could be expected that body size correlates with latitude as well. Indeed, it's the way round: body size decreases with latitude and increases correspondingly with temperature and rainfall (Colombo and Remis, Reference Colombo and Remis2018). In this case, the within-population effect is unlinked with the difference between populations.

This finding contradicts Adis et al. (Reference Adis, Sperber, Brede, Capello, Franceschini, Hill, Lhano, Marques, Nunes and Polar2008), who studied morphometrical variables of C. aquaticum all along a latitudinal transect between Trinidad (10°N) in the Caribbean and Punta del Este (35°S) on the River Plate's mouth. The insects were larger as the sampling site approached the Equator in this continent-wide study. The contradiction may lay on the scale of the survey. At Argentina's latitude C. aquaticum is bivoltine, but further north the number of generations a year increases, forming (seemingly) a seesaw effect. We failed to notice this effect in L. argentina because it does not occur much further north than Tucumán (27°S), where it is bivoltine and tiny, and further south is univoltine, with plenty of time for development.

We observed that, in C. aquaticum, there is a correlation between fusion dosage and body size (although fusion 1/6 does not affect body size related traits in C. aquaticum, Romero et al., Reference Romero, Colombo and Remis2014; Colombo and Remis, Reference Colombo and Remis2018).

Needless to say that the correlation of body size on fusion dosage does not mean necessarily that fusions are causing it: it is just a correlation. Secondly: if we do accept that some fusion is causing an effect, it would be too much of a leap of faith to assume that it is its function. However, it must be noted that the association between karyotype and phenotype is consistent in both species. This effect may be the target of selection (Norry and Colombo, Reference Norry and Colombo1999) or not (Colombo et al., Reference Colombo, Pensel and Remis2001, Reference Colombo, Pensel and Remis2004).

Did we demonstrate selection in these grasshoppers?

In the case of L. argentina there are many evidences of natural selection acting on the F and S polymorphisms (no matter how indirect this evidence may be) especially when we focus on the centric fusion: Endler's I, IV, V, VI and VIII criteria are comfortably met. In C. aquaticum we have three centric fusions, forming steep parallel clines, starting at the same point and always with the same frequency until they don't reach fixation because even the Paraná River was too short for them. To be sure, we have the Uruguay River besides, with a comparable cline. Too much of a coincidence. In addition, all three fusions correlate negatively and highly significantly with maximum temperature (same as L. argentina). But not much else.

Colombo (Reference Colombo2007) reported the recombination effects of all three fusions, which were coincidental in both species, i.e. (1) formation of a new linkage group from the two erstwhile independently segregating chromosome pairs, and (2) increase of distal (D) chiasma localisation, to the expense of proximal (P) and interstitial (I) chiasma formation in the chromosomes involved in the fusion, leading to a reduction of recombination in the fusion bivalent and an almost suppression in the trivalent.

A constant feature of large centric fusion polymorphisms is that recombination between the resulting metacentric and their acrocentric homologues is greatly reduced in the resulting trivalent of heterozygotes. The reason for this is that unrestricted chiasma formation in trivalents would lead to proximal and interstitial (with respect to the centromere) chiasmata. This would entail a rise of linear orientation of the trivalent due to spatial reasons to the expense of alternate orientation that renders V-shaped trivalents and balanced gametes (Bidau and Mirol, Reference Bidau and Mirol1988; Colombo, Reference Colombo2009, Reference Colombo2013). The ensuing reduction of recombination between the fused metacentric and the acrocentrics may provoke a partial genetic differentiation between both, especially in the regions close to the centromere, thus capturing locally adapted genes.

This differentiation between the rearranged and the non-rearranged homologue chromosomes of structural heterozygotes was often invoked as an explanation for inversion polymorphisms in Drosophila (Kirkpatrick, Reference Kirkpatrick2010), which capture advantageous haplotypes in linkage disequilibrium (Kirkpatrick and Barton, Reference Kirkpatrick and Barton2006; Charlesworth and Barton, Reference Charlesworth and Barton2018). According to this hypothesis the inversion is favoured because it prevents the breakdown of linkage disequilibrium caused by migration.

The parallel with C. aquaticum suggests an origin, somewhere in the Paraná middle course, of the Rb fusions and a local adaptation to it, and a southward migration helped by the current that drives the water-hyacinth floating meadows downstream. Upstream migration would be difficult for obvious reasons, although not impossible for a good flyer as C. aquaticum (Colombo et al., Reference Colombo, Zelarayán, Franceschini and Remis2021).

The hypothesis of the reduced recombination is endorsed by the fact that the most downstream populations, with high fusion frequencies, are both the most genetically disparate and most genetically impoverished when a microsatellite study was performed (Romero et al., Reference Romero, Colombo and Remis2017). The other populations could not be distinguished by the model and were lumped together under a Bayesian approach (Romero et al., Reference Romero, Colombo and Remis2017). When it came to population genetics, there were just three populations: the deltaic ZA and TI, and all the other lumped together.

Being neutral, these microsatellite distributions could be taken as null hypotheses when it came to compare the morphological distribution; in this case, the morphological Bayesian approach singled out just the northern, distant and subtropical LP and SF, pooling together all the others, deltaic or not, chromosomally polymorphic or not. Therefore, the morphological pattern must reflect season length and water availability and does not seem to reflect either genetic or chromosomal patterns (Colombo et al., Reference Colombo, Zelarayán, Franceschini and Remis2021).