Introduction
It is well-established that human activities are having a negative, sometimes catastrophic, impact on biodiversity and ecosystem functioning (Barnosky et al., 2011; Pimm et al., 2014). Aquatic ecosystems, for example, provide important ecosystem services that are closely tied to human well-being (Constanza et al., 2014; Geist, 2011), but are also exposed to a variety of humaninduced changes, including the impacts of invasive species (Gozlan et al., 2010), pollution (Conkle et al., 2018) or ocean acidification (Sunday et al., 2017). This is having a drastic impact on aquatic biodiversity (Janse et al., 2015). However, in order to devise and employ proper conservation and species management plans, we first need to have a good understanding of the basic biology of the focal species, which, unfortunately, is often lacking (Stroud & Thompson, 2019).
While there are many different biological traits that can be investigated to gain a better understanding of the basic biology of a species under threat of extinction, life histories are of particular relevance in this regard (Stearns, 1992). For example, they tell us how organisms invest their acquired resources into growth, maintenance, and reproduction, but the specific life-history strategies employed by a species can also help us understand how they might interact with other syntopic species (Stearns, 1992). This makes life-history traits ideal for advancing our species-specific biological knowledge, because they help provide essential demographic data relating to fertility and population growth. This type of data can, for example, be used to gauge a species’ competitive ability (Bashey, 2008).
The Tamesí molly, Poecilia latipunctata, is a small livebearing fish of the family Poeciliidae, is critically endangered, and native to headwaters of the Río Tamesí in northeastern Mexico (Contreras-Balderas & AlmadaVillela, 1996; Tobler & Schlupp, 2009). The species has a relatively small range, which makes P. latipunctata especially vulnerable to habitat changes (Miller et al., 2005). The most important threats to the survival of this species stem from invasive species as well as fragmentation and deterioration of suitable habitat as a result of local agricultural practices (Tobler & Schlupp, 2009). Biologically, this species is of special interest for at least 3 reasons. First, despite the fact that it looks like a short-fin molly (Fig. 1A-E), it actually belongs to the long-fin mollies (Ptacek & Breden, 1998; Schartl et al, 1995). Second, it is sympatric with 2 other mollies, the Atlantic molly (Poecilia mexicana) and the Amazon molly (Poecilia formosa), and has been reported to be one of the few natural sperm donors for P. formosa (Niemeitz et al., 2002), an all-female hybrid species that reproduces via gynogenesis (i.e., sperm-dependent parthenogenesis; Schlupp & Riesch, 2011). This role is critical as P. latipunctata is a sperm donor species that was not involved in the hybridization event that led to Amazon mollies, and the mating system in the area of Ciudad Mante is one of very few described to have more than 1 sperm donor species (Joachim & Schlupp, 2012; Schlupp, 2009). Third, it is also invasive in at least 1 habitat outside its natural range. While it seems that an introduction into Florida, USA, has failed (there are no confirmed observations since 1971; Neilson, 2019), it has established a thriving population in La Media Luna, San Luis Potosí, México (Miller et al., 2005; Palacio-Núñez et al., 2015).
Nonetheless, very little is currently known about the basic biology of P. latipunctata, and how it might interact with syntopic P. formosa and P. mexicana. Here, we therefore report on basic life histories for 2 natural populations of P. latipunctata. Moreover, we compare aspects of male and female life histories of P. latipunctata to those of syntopic P. mexicana and P. formosa. With regards to the latter, we address 2 different questions: 1) What are some of the life-history differences between the 3 species? 2) Are these life-history differences similar or different between the 2 different population?
Material and methods
We collected fishes from 2 different localities in northern México, near Ciudad Mante in May 2010, and preserved all specimens in 10% formaldehyde under the guidelines granted in the collection permit from the Mexican government (SEMARNAT=SGPA/DGVS/02221/10). Due to the endangered species status of P. latipunctata we were only able to collect a small number of fishes. Furthermore, P. latipunctata has a small geographic range with low abundance and thus, the number of sites we could use for comparison was limited in our study (García-De León et al., 2018; Tobler & Schlupp, 2009). We therefore focused on 2 sites: one was located in the canalized headwaters of the Río Mante (Mante Canal or MC hereonafter: 22°42’54.79” N, 99°1’18.83” W; Río Guayalejo/Pánuco drainage). This is a wide channel that takes water a short distance from the spring to provide water for agriculture. The second was a small ditch in between sugarcane fields within the same river drainage north of Ciudad Mante called El Limón (EL: 22°48’44.57” N, 99°0’44.55” W; Río Guayalejo/Pánuco drainage). At MC, we collected P. latipunctata and P. mexicana, while at EL, we collected all 3 species: P. latipunctata, P. mexicana, and P. formosa. Using a Hydrolab© Multisonde, we also measured several physicochemical characteristics: water temperature, pH, turbidity, oxygen content, salinity, chlorophyll and specific conductance. Our qualitative measurements included: the presence of a current, agriculture, predators, the type of substrate, contact vegetation, if the water level was managed, and the level of abundance of water plants (Table 1). All preserved specimens were then transferred to the University of Oklahoma in Norman, Oklahoma (USA) for further analyses.
Biotic/abiotic variable | Field sites | |
El Limón | Mante Canal | |
Water temperature (oC) | 28.45 | 27.26 |
SpC (mS/cm) | 1.479 | 1.008 |
pH | 7.84 | 7.48 |
DO (% Saturation) | 35.65 | 59.55 |
DO (mg/l) | 2.60 | 4.77 |
Chloro (ug/l) | 1.28 | 3.30 |
Salinity (0/00) | 0.79 | 0.53 |
Current present | Yes | Yes |
Agriculture present | Yes | Yes |
Fish predators | Mexican tetra | Cichlids |
Substrate type | Sand | Sand, silt |
Contact vegetation | Herbs, shrubs, trees | Herbs |
Water level managed | Yes | Yes |
Water plant abundance | Low | High |
To quantify selected life-history traits, fishes were dissected following well-established protocols (Riesch et al., 2015, 2016). In short, we first measured fish standard length (SL), and then removed testes for males and ovaries with (if present) developing embryos for females. Fishes and dissected reproductive tissues were then dried for 24 hrs at 55 ºC, after which they were weighed to establish dry weights. Soluble fats were extracted with a petroleum ether bath, then we weighed all fish and tissues again to establish lean weights. Thus, we quantified the following traits: male and female SL (mm), male and female dry and lean weights (g), male and female fat content (%; relative to dry weight), fecundity (number of fertilized and developing oocytes), offspring dry and lean weight (mg), and offspring fat content (%; relative to embryo dry weight). We further calculated the gonadosomatic index (GSI) for males [testis dry weight / (testis dry weight + somatic dry weight)] and reproductive allocation (RA) for females [total offspring dry weight / (total offspring dry weight + somatic dry weight)]. Finally, we evaluated the reproductive mode (i.e., if these poeciliids are capable of superfetation, which is the existence of more than a single brood at the same time; Pires et al., 2011).
For females, we further calculated the matrotrophy index [MI] to indirectly evaluate rates of post-fertilization maternal provisioning. The MI equals the estimated dry weight of the embryo at birth divided by the estimated dry weight of the oocyte at fertilization (Pollux et al., 2009). Thus, if the eggs were fully provisioned by yolk prior to fertilization (lecithotrophy), we would expect the embryos to lose 30-40% of their dry weight during development (MI ≤ 0.75). On the other hand, in the case of continuous maternal provisioning even after fertilization (matrotrophy), one would expect the embryos to lose less weight (MI between 0.75 and 1.00) or even to gain weight during development (MI ≥ 1.00; Pollux et al., 2009). Due to a low sample size, we did not calculate MI for P. mexicana females from MC nor for P. formosa from EL.
In preparation for additional subsequent analyses, we then log-transformed (SL and all lean weights), squareroot transformed (fecundity) and arcsine-transformed (all fat contents, GSI and RA) all variables, and subsequently z-transformed them to meet model assumptions and to remove scaling effects.
For statistical analyses, we conducted 2 sex-specific univariate general linear models (ANOVA) on SL. For the male model, the factors were population (EL or MC) and species (P. latipunctata or P. mexicana). Since we did not have any life-history data for P. mexicana from MC, we did not include the species-by-population interaction effect. For the female model, we included the factors population (EL or MC), species (P. latipunctata, P. mexicana, and P. formosa), and the species-by-population interaction.
In a second step, we then ran 2 sex-specific multivariate general linear models (MANCOVA) on the remaining life histories. For the male model, we included the traits lean weight, fat content and GSI as dependent variables, species and population were again the factors, and SL now served as a covariate. We further included the interactions between SL and the 2 factors in the initial model but removed any nonsignificant interactions with p > 0.1 from the final model. For the female model, we included the traits lean weight, fat content, fecundity, offspring lean weight, offspring fat content, and RA as dependent variables, species and population were the factors, with SL and offspring stage of development now served as covariates. We further included all possible two-way interactions between the factors and covariates in the initial model, but again removed any nonsignificant interactions (p > 0.1) from the final model.
All tests were conducted in IBM® SPSS® Version 21 (IBM Corp. 2012). Assumptions of normality of residuals and homocedasticity were met for all models.
Results
Descriptive statistics for life histories of males and females can be found in Table 2. Poecilia latipunctata and P. mexicana were characterized by a pronounced sexual size dimorphism, with males being smaller than females.
Species | Population | Sex | N | SL [mm] | Lean weight [g] |
Fat content [%] |
Fecundity | Embryo lean weight [mg] |
Embryo fat content [%] |
GSI/RA [%] |
P. formosa | EL | ♀ | 5 | 46.40 ± 8.65 |
0.500 ± 0.255 |
2.26 ± 2.03 |
22.20 ± 14.31 |
3.20 ± 0.42 |
17.47 ± 2.61 |
14.37 ± 4.63 |
P. latipunctata | EL | ♂ | 15 | 33.80 ± 5.56 |
0.187 ± 0.094 |
0.90 ± 1.34 |
- | - | - | 0.85 ± 0.27 |
♀ | 11 | 38.09 ± 3.42 |
0.280 ± 0.087 |
1.37 ± 1.43 |
9.18 ± 2.27 |
5.00 ± 1.04 |
17.24 ± 2.00 |
16.51 ± 2.80 |
||
MC | ♂ | 14 | 30.29 ± 5.93 |
0.145 ± 0.112 |
5.30 ± 3.23 |
- | - | - | 1.10 ± 0.49 |
|
♀ | 9 | 45.33 ± 2.45 |
0.445 ± 0.088 |
6.90 ± 6.26 |
21.89 ± 10.99 |
4.81 ± 0.93 |
17.42 ± 2.58 |
19.64 ± 6.76 |
||
P. mexicana | EL | ♂ | 10 | 39.30 ± 5.62 |
0.299 ± 0.132 |
5.37 ± 4.62 |
- | - | - | 0.92 ± 0.25 |
♀ | 15 | 45.07 ± 6.88 |
0.444 ± 0.213 |
3.23 ± 3.58 |
23.93 ± 15.73 |
3.10 ± 0.56 |
16.16 ± 5.87 |
15.18 ± 5.29 |
||
MC | ♀ | 7 | 43.43 ± 8.26 |
0.401 ± 0.244 |
9.07 ± 3.99 |
30.71 ± 20.89 |
2.89 ± 0.94 |
20.99 ± 6.42 |
19.20 ± 5.60 |
Males. Male size distribution in P. latipunctata from EL and MC and in P. mexicana from EL did not deviate from normal distributions (Shapiro-Wilk test, P. latipunctata, EL: W 15 = 0.951, p = 0.536; MC: W 14 = 0.892, p = 0.087; P. mexicana, EL: W 10 = 0.968, p = 0.876; Fig. 2A-C).). Our ANOVA on male SL uncovered a significant species effect, because P. mexicana males were larger than P. latipunctata males (Tables 2, 3). Our multivariate analysis of male lean weight, fat content and GSI revealed a significant effect of the covariate SL, but the species -and population- factors were also significant (Table 3). Post-hoc ANCOVA revealed that SL had a significant effect on lean weight (F 1,35 = 1663.629, p < 0.001) and GSI (F 1,35 = 16.441, p < 0.001), which both increased with increasing SL. Significant species -and populations- factors were only uncovered for fat content (F 1,35 = 13.191, p = 0.001 and F 1,35 = 20.028, p < 0.001, respectively). At EL, P. mexicana had more body fat than P. latipunctata, and P. latipunctata from MC had more body fat than conspecifics from EL (Table 2). GSI further exhibited a non-significant trend between species (F 1,35 = 4.061, p = 0.052), with P. latipunctata showing a trend for a lower investment into reproduction (estimated marginal means of GSI corrected for SL = 33.33 mm, P. latipunctata, EL: 0.83%; MC: 0.91%; P. mexicana, EL: 1.10%).
Effect | F | df | p | Partial variance |
(a) SL (ANOVA) | ||||
Species | 5.015 | 1, 36 | 0.031 | |
Population | 3.273 | 1, 36 | 0.079 | |
(b) Male life histories (MANCOVA) | ||||
SL | 555.316 | 3, 33 | < 0.001 | 0.981 |
Species | 4.872 | 3, 33 | 0.006 | 0.307 |
Population | 6.466 | 3, 33 | 0.001 | 0.370 |
(SL × species) | 0.327 | 3, 31 | 0.806 | |
(SL × population) | 1.700 | 3, 32 | 0.187 |
Females. The ANOVA on female SL only found a significant effect of the interaction species-by-population, because P. latipunctata females were smaller than P. mexicana females in EL, but this pattern was reversed in MC (Table 4). In the MANCOVA on the remaining female life-history traits, we uncovered significant effects of the covariate SL as well as the factors species and population, while embryonic stage of development was not significant (Table 4). Post-hoc ANCOVA revealed that SL had a significant effect on female lean weight, fecundity, and embryo lean weight (all 3 traits increased with increasing SL). Species differed significantly only in embryo lean weight (F2,41 = 32.350, p < 0.001) with P. latipunctata producing the largest offspring (EMMs of embryo lean weight at SL = 42.91 mm, P. formosa: 3.11 mg, P. latipunctata: 4.86 mg, P. mexicana: 2.88 mg), while lean weight and fecundity only exhibited non-significant trends (F2,41 = 2.896, p = 0.067 and F2,41 = 3.054, p = 0.058, respectively). Populations differed significantly only in fat content (F1,41 = 13.621, p = 0.001), but there were also non-significant trends for fecundity (F1,41 = 3.781, p = 0.059), embryo fat (F1,41 = 3.188, p = 0.082), and RA (F1,41 = 3.071, p = 0.087; Table 2).
Effect | F | df | p | Partial variance |
(a) SL (ANOVA) | ||||
Species | 1.909 | 2, 42 | 0.161 | 0.083 |
Population | 2.371 | 1, 42 | 0.131 | 0.053 |
Species × population | 6.242 | 1, 42 | 0.016 | 0.129 |
(b) Female life histories (MANCOVA) | ||||
SL | 170.052 | 6, 36 | < 0.001 | 0.966 |
Stage of development | 1.288 | 6, 36 | 0.287 | 0.177 |
Species | 4.982 | 12, 72 | < 0.001 | 0.454 |
Population | 4.051 | 6, 36 | 0.003 | 0.403 |
(SL × species) | 1.473 | 12, 68 | 0.156 | |
(Stage × species) | 1.632 | 12, 64 | 0.106 | |
(SL × population) | 1.783 | 6, 31 | 0.135 | |
(Species × population) | 1.539 | 6, 30 | 0.200 | |
(Stage × population) | 0.524 | 6, 29 | 0.785 |
Embryo dry weight either remained more or less constant or decreased strongly with developmental stage, which is congruent with a predominantly lecithotrophic provisioning strategy (MI, P. latipunctata, EL = 0.73; MC = 1.01; P. mexicana, EL = 0.90; Fig. 2D-F). This confirmed the pattern we found for embryo lean weight (see above), because based on this, P. latipunctata produced larger neonates than P. mexicana (estimated dry weight at birth, P. latipunctata, EL = 4.00 mg, MC = 5.82 mg; P. mexicana, EL = 3.33 mg). We did not find any evidence for superfetation in P. latipunctata, P. mexicana, and P. formosa, as all developing embryos per female were always of approximately the same developmental stage.
Discussion
As is typical for most poeciliids, P. latipunctata was characterized by strong sexual size dimorphism, with males being smaller than females (Pires et al., 2011). Moreover, size distributions for P. latipunctata did not deviate significantly from a normal distribution. At present it is too early to conclusively determine whether male size in P. latipunctata is genetically determined or not. However, bimodal size distributions in this family are usually strong evidence for size at maturity being genetically determined (Kallman, 1989), so this would suggest that size at maturity in P. latipunctata is not genetically determined. On the other hand, while males of some poeciliids exhibit a bimodal size distribution, the interpopulation variation in male size distributions is common, and environmental effects are known to sometimes supersede genetic determination (Kallman, 1989; Kolluru & Reznick, 1996; Reznick et al., 2007).
Overall, adult male and female life histories, as well as most offspring life histories were quite similar to those of other long-fin (e.g., P. latipinna: Martin et al., 2009; Riesch et al., 2012) and short-fin (e.g., P. mexicana: Riesch et al., 2010, 2011; this study) mollies (including the lack of superfetation; Pires et al., 2011). However, P. latipunctata was notably different from most other nonsuperfetating poeciliids from regular (i.e., non-extreme) aquatic habitats, in that they produced very large offspring. This is not fitting the general pattern within poeciliids well, whereby smaller species usually produce smaller offspring and larger species larger offspring (Pires et al., 2011). In fact, the offspring sizes we uncovered here for both populations, are much more similar to those found in non-superfetating poeciliids inhabiting toxic sulfide springs or dark caves (Riesch et al., 2010, 2011, 2016).
With respect to maternal provisioning, P. latipunctata was characterized by a largely lecithotrophic provisioning strategy (i.e., resources needed for embryo development are almost exclusively stored in the yolk prior to fertilization; Marsh-Matthews, 2011; Pires et al., 2011). However, similar to some previous studies in other poeciliids (Trexler, 1985; reviewed by Pires et al., 2011), we found inter-population variation in the extent of maternal provisioning as quantified via the MI (we have to point out, though, that sample sizes for estimating MI were quite low and late-stage embryos were largely missing). Overall, this is also congruent with the fact that some of the other male and female life histories differed to varying degree between these 2 populations. This suggests potential differences in resource availability between EL and MC but could also result from genetic differences or other selective forces that differ between these 2 populations (Johnson & Bagley, 2011). Based on the abiotic parameters we measured at the time of sampling (Table 1), some of these differences could, for example, be based on the observed differences between habitats in conductivity, oxygen content, and chlorophyll a (a proxy for productivity) content. However, we do not know if these single point measurements represent more permanent differences between habitats. Moreover, both habitats are exposed to different levels of human disturbance, which could also have a measurable impact here. EL is a small drainage ditch in the midst of surrounding agriculture, mainly sugarcane fields, while MC is a fairly large irrigation channel in the midst of agricultural fields. We have observed EL to change over time due to removal of silt from the ditch, which temporarily turned the ditch into a relatively fast flowing habitat (which is not ideal habitat for poeciliids; Meffe & Snelson, 1989), but siltation and regrowth of plants returned the ditch quickly to a state that seemed more suitable for mollies.
Our sampling scheme allowed us to directly compare aspects of life histories between 3 different species (with respect to females) of poeciliid fishes that are all syntopic in the same 2 habitats in northeastern Mexico. For males, we could unfortunately only compare P. mexicana with P. latipunctata from EL due to sampling constraints (nonetheless, it is important to note that all 3 species did occur in both habitats). Here, male P. mexicana were significantly larger and also had significantly more body fat, suggesting that P. mexicana males might, at least at EL, have a competitive advantage over P. latipunctata males.
For females, we were able to compare all 3 species for EL, and P. mexicana and P. latipunctata at MC. At EL, P. formosa and P. mexicana were of roughly similar size, and also had very similar fecundities, RA, and produced offspring of roughly similar size. Given that P. formosa is a hybrid species originating from hybridization between P. mexicana and P. latipinna, this similarity is not necessarily surprising (Schlupp & Riesch, 2011). However, it is interesting to note that P. latipunctata females at EL were considerably smaller, and produced significantly larger but fewer offspring, resulting in a somewhat similar investment into reproduction (RA). We largely found the same similarities and differences when comparing P. mexicana and P. latipunctata females at MC, but in this population, P. latipunctata females were actually larger than P. mexicana females. The significantly larger offspring of P. latipunctata compared to the syntopic P. mexicana and P. formosa, suggest strong selection on offspring’s competitive ability, as larger offspring have been demonstrated to have better competitive abilities in poeciliid fishes (Bashey, 2008). Future experiments should investigate directly the relative competitive ability of the offspring of these 3 different species in these habitats.
The present study represents the first characterization of important life-history traits of the critically endangered P. latipunctata. While it already provides us with relevant insights into their life histories and reveals some similarities and differences relative to life histories of other mollies, more research into their basic biology is needed. One interesting aspect of P. latipunctata life histories was the large offspring size. If, as we speculate above, there is indeed strong competition between the 3 species (given their relatively similar niches, this is not necessarily surprising), this could be an additional factor on top of anthropogenic disturbance that might help explain why the species seems to be doing poorly in its native range. Additional studies from the area where P. latipunctata is invasive (La Media Luna), would be important in this context. We therefore call on more research into this species; without this it will be extremely difficult to plan and implement meaningful conservation efforts to save this charismatic little fish from extinction within its native range.