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Reproduction of saguiru Steindachnerina elegans (Steindachner, 1874) (Pisces: Curimatidae) in the São Francisco River, downstream from a large reservoir in south-eastern Brazil

Abstract

The gametogenesis and reproduction of S. elegans from the São Francisco River at Três Marias, Minas Gerais, were analyzed in this study. Steindachrina elegans is a species abundant in the São Francisco River basin and an important fish in the food chain. The size at first gonadal maturation (indicated by the total length of the shortest spermatid male and spawned female) was 10.5 cm and 15.0 cm, respectively. Reproduction occurred more frequently from September to April. This period had high water temperature values. A high frequency of females was observed at the mature and spawned stages and height gonadosomatic index (GSI). Meanwhile, in males, the reproductive peak was from November to February. The long spawning period and the histological characteristics of the spawned ovaries that contained oocytes at different stages of development along with post-ovulatory and atretic oocytes indicates that the spawning of S. elegans is of the partial type.

Key words
ovary; testes; spawner; gonadal maturation; fecundity; follicles

INTRODUCTION

The saguiru S. elegans is abundant in the Pardo and Jequitinhonha Rivers in Bahia and Minas Gerais, as São Francisco River basin and has a wide geographic distribution (Fowler 1951FOWLER HW. 1951. Os peixes de água doce do Brasil. Arq Zool Est São Paulo 6: 205-404.). They habit in several Brazilian hydrographic basins and belong to the Curimatidae family of the Characiforms order (Buckup et al. 2007BUCKUP PA, MENEZES NA & GHAZZI MS’A. 2007. Catálogo das espécies de Peixes de água doce do Brasil. Rio de Janeiro: Museu Nacional, p. 195.). Fish from the Curimatidae family inhabit the bottom of rivers or lentic environments. They feed mainly on debris and decomposing organic matter, being considered important forage species (Sato et al. 1997SATO Y, VIEIRA SAMPAIO E, GODINHO HP, FENERICH-VERANI N & VERANI JR. 1997. Biologia reprodutiva do saguiru Steindachnerina elegans (= Curimata elegans Steindachner, 1875) (Pisces: Curimatidae) submetido à hipofisação. Bios 55: 37-41.). The S. insculpta, small detritivorous fish species in Furnas reservoir, upper rio Paraná basin, Minas Gerais, Brazil, has a prolonged period of reproductive activity that extends from September to March, with partial spawning (Ribeiro et al. 2007RIBEIRO VMA, SANTOS GB & BAZZOLI N. 2007. Reproductive biology of Stendachnerina insculpta, (Teleostei, Curimatidae) in Furnas reservoir, Minas Gerais, Brazil. Rev Bras Zool 24: 71-76.). The S. elegans does not exhibit migratory reproductive behavior and has a large number of oocytes per gram of ovaries with the oocytes showing little adhesiveness (Sato et al. 1997SATO Y, VIEIRA SAMPAIO E, GODINHO HP, FENERICH-VERANI N & VERANI JR. 1997. Biologia reprodutiva do saguiru Steindachnerina elegans (= Curimata elegans Steindachner, 1875) (Pisces: Curimatidae) submetido à hipofisação. Bios 55: 37-41.).

Studies on fish breeding provide essential information for the conservation of biodiversity (Rizzo & Bazzoli 2020RIZZO E & BAZZOLI N. 2020. Reproduction and Embryogenesis. ‘Biology and Physiology of Freshwater Neotropical fish’. (Eds B Baldisserotto, EC Urbinati and J Cyrino) p. 287-313. (Academic Press, Elsevier: London).). The present study analyzes the main parameters of the reproductive biology of the species from the São Francisco River downstream of the Três Marias dam in Minas Gerais, Brazil. There are no known studies on the reproduction of S. elegans in lotic environments.

MATERIALS AND METHODS

Samples of S. elegans were previously collected between January and December 2012 from the São Francisco River (SFR) in an area that was 34 to 54 km downstream of the Três Marias dam, after the confluence with the Abaeté River (18°00’49” S, 45°10’51” W), Minas Gerais, Brazil (Figure 1). The fish were captured using gill nets, with mesh sizes of 3.0 cm between opposing nodes. The fish, when alive, were sacrificed through the cross-section of their cervical spine, following the ethical principles of animal manipulation established by the Brazilian College of Animal Experimentation (COBEA). This study was submitted to and approved by the Ethics Committee on Animal Use (Protocol n°. 071/2008 - UFMG). The sex proportion was determined as the ratio of the absolute frequency of females to that of males.

Figure 1
Study area: São Francisco River (SFR) 34 (*) to 54 km (*) downstream of the Três Marias dam after the confluence of the SFR with the Abaeté River.

For histological analyses, all fragments of ovaries and testes were previously fixed in Bouin’s fluid for 12 hours, embedded in paraffin, cut to a 5 μm thickness, and, finally, stained with hematoxylin-eosin (HE). The gonadal maturation stages were established based on the microscopic and macro (such as size, staining, and vascularization of the ovaries and tests) (Weber et al. 2013WEBER AA, NUNES DMF, GOMES RZ, RIZZO E, SANTIAGO KB & BAZZOLI N. 2013. Downstream impacts of a dam and influence of a tributary on the reproductive success of Leporinus reinhardti in São Francisco River. Aquat Biol 19: 195-200., Brandão et al. 2017BRANDÃO DEL, VIRTUDE AN, MARCON L, SANTOS JE, SANTIAGO KB, RIZZO E & BAZZOLI N. 2017. Comparative analyses of reproductive activity in Schizodon knerii (Steindachner, 1875) (Characiformes: Anostomidae) in three sections of the São Francisco River basin. J Appl Ichthyol 33: 1118-1124., Bazzoli et al. 2019BAZZOLI N, SILVA VES, MARCON L, SANTIAGO KB, SANTOS JE & RIZZO E. 2019. The influence of a large reservoir on the reproductive activity of the white piranha, Serrasalmus brandtii (Lütken, 1875) in Southeast Brazil. Biota Neotrop 19: e20180580.). The gonadosomatic index (GSI = GW X 100 / BW) and the Fulton (K) factor (K = BW × 100 / TL3) per bimester were calculated from the biometric data obtained. The size at the first gonadal maturation was indicated by the total length of the shortest spermatid male and spawned female (Boncompagni-Júnior et al. 2013BONCOMPAGNI-JÚNIOR O, NORMANDO FT, BRITO MFG & BAZZOLI N. 2013. Reproductive biology of Prochilodus argenteus Agassiz, 1829 (Pisces: Prochilodontidae) in São Francisco River, Brazil. J Appl Ichthyol 29: 132-138.). The diameter of 50 follicles of each maturation stage and 50 nuclei from cells spermatogenic lineages were measured using the Olympus Cell software from images captured by an Olympus SC30 camera that was connected to an Olympus-BX50 microscope (Santos et al. 2019SANTOS JE, MARCON L, BRITO MFG, SALES NG, RIZZO E & BAZZOLI N. 2019. Reproductive biology of the Neotropical catfish Iheringichthys labrosus (Siluriformes: Pimelodidae), with anatomical and morphometric analysis of gonadal tissues. Anim Reprod Sci 209: 106173.). The physiochemical variables of the water were temperature, pH, electrical conductivity, dissolved oxygen, and transparency. Each of which was obtained downstream from the Abaeté River, using the Horiba device model U-10.

Statistical analysis

The average values of the biological indices and water parameters for each bimester were assessed by using the Statistica 7.0 software and analysis of variance. After a normal distribution test, the data were compared using a one-way ANOVA analysis of variance followed by a Duncan test. A t-test was used to compare the total length (TL), body weight (BW), gonadosomatic index (GSI), and Fulton condition factor (K) of the males and females. The level of significance was p < 0.05. The chi-square test (x2; p <0.05) was applied to detect possible differences in the proportions between the sexes.

RESULTS

The water parameters for the São Francisco River (SFR) downstream of the Três Marias dam showed in November, December, January, and February high values ​​of temperature and dissolved oxygen and low values ​​of transparency (Table I).

Table I
The bimester values of Temperature (T), dissolved oxygen (DO), pH, electrical conductivity (CE) and transparency (T) between January and December 2012 in the São Francisco River, after the confluence with the Abaeté River, Minas Brazil.

The ovaries and testes of the S. elegans were paired, and elongated organs located in the coelomic cavity were attached to the gaseous bladder by a peritoneal fold. Variations in the volume, vascularization, and color of the gonads were observed in all stages of the gonadal maturation.

A total of 224 specimens were collected: 71 males and 153 females. The mean values ​​of the total length, K (p > 0.05), body weight and GSI (p < 0.05) of the females were higher than that of the males (Table II). The female reproductive peak occurred from September to April, while, for males, it was from November to February, when the GSI and K had the highest values (Table III). There were more females than males in the study area (2:1), with differences in proportions between the sexes (x2=30.02).

Table II
The amplitude, mean, and standard deviation (SD) of the total length (TL) in centimeters, body weight (BW) in grams, gonadosomatic index (GSI), and Fulton condition factor (K) of S. elegans females and males captured in the São Francisco River between January and December 2012.
Table III
The average values per bimester of gonadosomatic índice (GSI) and condition factor (K) of S. elegans females and males captured in the São Francisco River between January and December 2012.

Histologically, folliculogenesis was classified as the initial perinucleolar, advanced perinucleolar, previtellogenic, and vitellogenic oocytes, and the stages were characterized by changes in the ooplasm, follicular cells, and zona radiata (Figure 2). In spermatogenesis, cells of the spermatogenic lineage were also observed. The cells were classified as primary spermatogonia, secondary spermatogonia, primary spermatocyte, secondary spermatocyte, spermatid, and spermatozoa (Figure 3). The following stages of gonadal maturation were determined for females based on the macro and microscopic characteristics of the gonads. (Figure 2): F1 = rest, F2 = maturation/mature, and F3 = spawned and for males (Figure 3): M1 = rest, M2 = maturation/mature, and M3 = spent.

Figure 2
Histological sections of S. elegans ovaries in the different stages of the gonadal maturation are stained by HE. a) Stage F1 = rest with initial perinucleolar follicles (O1, diameter = 80.70 ± 12.43 µm). It’s with basophilic cytoplasm and vesiculous nucleus and advanced perinucleolar follicles (O2 = 149.66 ± 21.10 µm), as well as granular cytoplasm and nucleus with nucleoli attached to the nuclear envelope; b) Stage F2 = maturation with previtellogenic oocyte (O3 = 217.10 ± 36.05 µm), presenting characteristic cortical alveoli (arrow) and vitellogenic follicles (O4 = 442.01 ± 51.72 µm) with ooplasm full of yolk globules; c) Detail of O4 showing squamous follicular cells (FC), thin zona radiata (ZR) and spherical and acidophilus yolk globules (Y); d) Stage F3 = spawned with post-ovulatory follicles (POF) and follicles at all stages of development as well as atretic follicles (A) and previtellogenic follicles (O4i) with early of acidophilus yolk globules (arrow). Bars: a and b = 100 μm; c and d = 200 μm.
Figure 3
The histological sections of the testes of S. elegans are shown in different stages of the gonadal maturation stained by HE. a) Stage M1 = rest containing only spermatogonia (SPG) and lumen of the closed seminiferous tubules. b) The cells of the spermatogenic lineage are shown with primary spermatogonia (G1, diameter = 6.18 ± 1.01 µm). An abundant cytoplasm and a spherical central nucleus are displayed, as well as secondary spermatogonia (G2 = 5.19 ± 0.80 µm) with little cytoplasmic material and a spherical central nucleus. The primary spermatocyte (C1 = 3.95 ± 0.51 µm) is with spherical the central nucleus and granulated chromatin. The secondary spermatocyte (C2 = 2.93 ± 0.54 µm) is with the spherical central nucleus and fine chromatin. The spermatid (T = 1.32 ± 0.17 µm) with the dense spherical nucleus. The spermatozoa (SPZ = 0.95 ± 0.15) presents a spherical head and strongly condensed nucleus. c) Stage M2 = maturation with the lumen of the seminiferous tubules filled with spermatozoa. d) M3 = time spent with the lumen (L) of the seminiferous tubules open and the wall containing only spermatogonia. Bars: a, b, and d = 50 μm. Bar c = 200 μm.

The smallest male captured in the spent stage had a total length of 10.5 cm, while the shortest female in the spawning stage measured 15.0 cm in total length. In females, the period with reproductive activity (F2 and F3 stages) occurred from September to April (Figure 4a, Table IV). Whereas, in males, it was from November to February (Figure 4b, Table IV). The occurrence of the spawning females with follicles in all stages of development, as well as atretic and post-ovulatory follicles, confirms that S. elegans is a partial spawner.

Figure 4
The bi-monthly distribution of the gonadal maturation stages of S. elegans (a) females and (b) males caught in the São Francisco River downstream of the Três Marias dam between January and December 2012.
Table IV
The bi-monthly absolute distribution (n) of the gonadal maturation stages (GMS) of S. elegans females (F) and males (M) caught in the São Francisco River downstream of the Três Marias dam between January and December 2012.

DISCUSSION

The macro- and microscopic morphology of ovaries and testes are similar to other Characiforms (Hojo et al. 2004HOJO RES, SANTOS GB & BAZZOLI N. 2004. Reproductive biology of Moenkhausia intermedia (Eigenmann) (Pisces, Characiformes) in Itumbiara Reservoir, Goiás, Brazil. Rev Bras de Zool 21: 519-524.).

For females, the mean values ​​of the total length, body weight, and GSI were higher than males. This demonstrates sexual dimorphism, a characteristic of fish of the order Characiforms (Hojo et al. 2004HOJO RES, SANTOS GB & BAZZOLI N. 2004. Reproductive biology of Moenkhausia intermedia (Eigenmann) (Pisces, Characiformes) in Itumbiara Reservoir, Goiás, Brazil. Rev Bras de Zool 21: 519-524., Thomé et al. 2005THOMÉ RG, BAZZOLI N, RIZZO E, SANTOS GB & RATTON TF. 2005. Reproductive biology of Leporinus taeniatus Lütken (Pisces, Anostomidae) in Juramento Reservoir, São Franscisco River basin, Minas Gerais, Brazil. Rev Bras Zool 3: 565-570., Abdo et al. 2018ABDO TF, MARCON L & BAZZOLI N. 2018. Downstream effects of a large reservoir on the reproductive activity of Prochilodus hartii (Pisces: Prochilodontidae). Anim Reprod Sci 190: 102-107.). During the reproductive peak, high values of the gonadosomatic index and Fulton condition were observed in S. elegans females and males, indicating that reproduction did not interfere with the fish’s physiological condition or health (Froese 2006FROESE R. 2006. Cube law, condition factor and weight–length relationships: History,meta- analysis and recommendations. J Appl Ichthyol 22: 241-253., Roriz Lemes et al. 2016RORIZ LEMES DM, VIZIOLI B, MARCON L & BAZZOLI N. 2016. Reproduction of the internal inseminator (Linnaeus, 1766) (Siluriformes: Auchenipteridae). J Appl Ichthyol 32: 115-125.). In the present study, we observed a predominance of females, similar to that in other studies (Hojo et al. 2004HOJO RES, SANTOS GB & BAZZOLI N. 2004. Reproductive biology of Moenkhausia intermedia (Eigenmann) (Pisces, Characiformes) in Itumbiara Reservoir, Goiás, Brazil. Rev Bras de Zool 21: 519-524., Bazzoli et al. 2019BAZZOLI N, SILVA VES, MARCON L, SANTIAGO KB, SANTOS JE & RIZZO E. 2019. The influence of a large reservoir on the reproductive activity of the white piranha, Serrasalmus brandtii (Lütken, 1875) in Southeast Brazil. Biota Neotrop 19: e20180580.). However, the sex ratio may be related to differences between the sexes, the selectivity of the sampling apparatus, the amount of available food, and population stratification (Carvalho et al. 2009CARVALHO PA, PASCHOALINI AL, SANTOS GB, RIZZO E & BAZZOLI N. 2009. Reproductive biology of Astyanax fasciatus (Pisces: Characiformes) in a reservoir in southeastern Brazil. J Appl Ichthyol 25: 306-313.).

The follicular development of S. elegans is similar to the descriptions of other fish (Grier et al. 2017GRIER HJ, NEIDIG CL & QUAGIO-GRASSIOTTO I. 2017. Development and fate of the postovulatory follicle complex, postovulatory follicle, and observations on folliculogenesis and oocyte atresia in ovulated common snook, Centropomus undecimalis (Bloch, 1792). J Morphol 278: 547-562.). It is comprised of the perinucleolar, vitellogenic, and final maturation stages. These phases occur inside follicles, whose walls consist of zona radiata, the follicular cell, basement membrane, and theca. They play an important role during folliculogenesis and fertilization. The mature ovaries of S. elegans exhibit asynchronous development with oocytes in different growth stages, as has been reported for other fish, (i.e., perinucleolar, previtellogenic, and vitellogenic oocytes) (Honorato-Samapio et al. 2009HONORATO-SAMPAIO K, PRADO PS, SATO Y & BAZZOLI N. 2015. Comparative morphology of the oocyte surface and early development in four characiformes from the São Francisco River, Brazil. J Morphol 276: 1258-1278., Marcon et al. 2017MARCON L, THOMÉ RG, MOUNTEER AH, BAZZOLI N, RIZZO E & BENJAMIN LA. 2017. Immunohistochemical, morphological and histometrical analyses of follicular development in Astyanax bimaculatus (Teleostei: Characidae) exposed to an organochlorine insecticide. Ecotox Environ Safe 143: 249-258.). Spermatogenesis consists of a sequence of morphological changes that occur in germ cells while differentiating from spermatogonia to spermatozoa. In S. elegans, the cells of the spermatogenic lineage were observed in the germinal epithelium, similarly observed in other fish (Grier & Uribe-Aranzábal 2009GRIER HJ & URIBE-ARANZÁBAL MC. 2009. The testis and spermatogenesis in teleosts. In: Jamieson BGM (Ed). Reproductive biology and phylogeny of fishes (Agnathans and Bony fishes). Endfield: Science Publishers, p. 119-142.).

Three gonadal maturation stages for females and males were established, similar to the studies of Brandão et al. (2017)BRANDÃO DEL, VIRTUDE AN, MARCON L, SANTOS JE, SANTIAGO KB, RIZZO E & BAZZOLI N. 2017. Comparative analyses of reproductive activity in Schizodon knerii (Steindachner, 1875) (Characiformes: Anostomidae) in three sections of the São Francisco River basin. J Appl Ichthyol 33: 1118-1124. and Bazzoli et al. (2019)BAZZOLI N, SILVA VES, MARCON L, SANTIAGO KB, SANTOS JE & RIZZO E. 2019. The influence of a large reservoir on the reproductive activity of the white piranha, Serrasalmus brandtii (Lütken, 1875) in Southeast Brazil. Biota Neotrop 19: e20180580.. The long spawning period and histological characteristics of spawned ovaries containing oocytes at all stages of development, in addition to post-ovulatory oocytes and atretic oocytes, indicate that S. elegans presents partial spawning, similar to other Characiforms of the Curimatidae family (Schifino et al. 1998SCHIFINO LC, FIALHO CB & VERANI JR. 1998. Reproductive aspects of Cyphocharax voga (Hensel) from Custódias Lagoon, Rio Grande do Sul, Brazil (Characiformes, Curimatidae) Rev Bras Zool 15: 757-766., Ribeiro et al. 2007RIBEIRO VMA, SANTOS GB & BAZZOLI N. 2007. Reproductive biology of Stendachnerina insculpta, (Teleostei, Curimatidae) in Furnas reservoir, Minas Gerais, Brazil. Rev Bras Zool 24: 71-76.). Asynchronous folliculogenesis is characteristic of species with long reproductive periods and multiple or partial spawning (Bazzoli et al. 2019BAZZOLI N, SILVA VES, MARCON L, SANTIAGO KB, SANTOS JE & RIZZO E. 2019. The influence of a large reservoir on the reproductive activity of the white piranha, Serrasalmus brandtii (Lütken, 1875) in Southeast Brazil. Biota Neotrop 19: e20180580.), as is the case for S. elegans of the present study. Partial spawning is a strategy that allows several spawns in the same reproductive cycle, the asynchronous development of larvae, and, consequently, the occupancy of distinct niches (Ratton et al. 2003RATTON FT, BAZZOLI N & BASTOS SANTOS G. 2003. Reproductive biology of Apareiodon affinis (Pisces: Parodontidae) in the Furnas Reservoir, Minas Gerais, Brazil. J Appl Ichthyol 19: 387-390.).

Larger size at the first gonadal maturation was observed for females, which may be related to differences in environmental conditions and food availability (Nikolsky 1963NIKOLSKY GV. 1963. The ecology of fishes. London, Academic Press, p. 351., Pawson et al. 2000PAWSON MG, PICKETT GD & WITTHAMES PR. 2000. The influence of temperature onset of first maturity in sea bass. J Fish Biol 56: 319-327.). Another explanation could be related to the production of sex hormones (such as 17-β oestradiol), which is responsible for both the somatic growth and gonadal development in females (Arantes et al. 2010ARANTES F, SANTOS HB, RIZZO E, SATO Y & BAZZOLI N. 2010. Profiles of sex steroids, fecundity, and spawning of, the curimatã-pacu Prochilodus argenteus in the São Francisco River, downstream from the Três Marias Dam, Southeastern Brazil. Anim Reprod Sci 118: 330-336.).

After spawning, non-released structures of the follicle remain in the ovary, constituting the post-ovulatory follicle (Grier et al. 2017GRIER HJ, NEIDIG CL & QUAGIO-GRASSIOTTO I. 2017. Development and fate of the postovulatory follicle complex, postovulatory follicle, and observations on folliculogenesis and oocyte atresia in ovulated common snook, Centropomus undecimalis (Bloch, 1792). J Morphol 278: 547-562.), as seen in the present study. Follicular atresia is common in vertebrate ovaries. It can occur at any stage of folliculogenesis but is more frequent in vitellogenic oocytes (Santos et al. 2008SANTOS HB, THOMÉ RG, ARANTES FP, SATO Y, BAZZOLI N & RIZZO E. 2008. Ovarian follicular atresia is mediated by heterophagy, autophagy, and apoptosis in Prochilodus argenteus and Leporinus taeniatus (Teleostei: Characiformes). Theriogenology 70: 1449-1460.) with a low frequency, as observed in the present study. In this degenerative process, as reported by Marcon et al. (2017)MARCON L, THOMÉ RG, MOUNTEER AH, BAZZOLI N, RIZZO E & BENJAMIN LA. 2017. Immunohistochemical, morphological and histometrical analyses of follicular development in Astyanax bimaculatus (Teleostei: Characidae) exposed to an organochlorine insecticide. Ecotox Environ Safe 143: 249-258., morphophysiological events are essential in ovarian remodeling for the next reproductive cycle (Marcon et al. 2019MARCON L, FREITAS VR, BAZZOLI N, RIZZO E & BENJAMIN LA. 2019. Growth hormone on ovarian morphology of lambaris (Astyanax bimaculatus) after induced spawning. Cienc Rural 49: e20180478.).

The reproductive activity of both sexes of S. elegans in the São Francisco River was influenced by environmental factors, such as water temperature and rainfall in the region. This was observed in other studies, where the fish found favorable conditions for reproduction (Weber et al. 2013WEBER AA, NUNES DMF, GOMES RZ, RIZZO E, SANTIAGO KB & BAZZOLI N. 2013. Downstream impacts of a dam and influence of a tributary on the reproductive success of Leporinus reinhardti in São Francisco River. Aquat Biol 19: 195-200., Brandão et al. 2017BRANDÃO DEL, VIRTUDE AN, MARCON L, SANTOS JE, SANTIAGO KB, RIZZO E & BAZZOLI N. 2017. Comparative analyses of reproductive activity in Schizodon knerii (Steindachner, 1875) (Characiformes: Anostomidae) in three sections of the São Francisco River basin. J Appl Ichthyol 33: 1118-1124., Bazzoli et al. 2019BAZZOLI N, SILVA VES, MARCON L, SANTIAGO KB, SANTOS JE & RIZZO E. 2019. The influence of a large reservoir on the reproductive activity of the white piranha, Serrasalmus brandtii (Lütken, 1875) in Southeast Brazil. Biota Neotrop 19: e20180580.). These peaks occurred from September to February, coinciding with the greatest number of fish in the maturation stage and GSI, with the fish responding to water conditions in tropical environments (Lowe-McConnel 1987LOWE-MCCONNELL RH. 1987. Ecological studies in tropical fish communities (pp. 382). Cambridge: Cambridge University Press.), similar in S. insculpta that extends from September to March (Ribeiro et al. 2007RIBEIRO VMA, SANTOS GB & BAZZOLI N. 2007. Reproductive biology of Stendachnerina insculpta, (Teleostei, Curimatidae) in Furnas reservoir, Minas Gerais, Brazil. Rev Bras Zool 24: 71-76.). In Neotropical freshwater teleost, high rainfall triggers the final maturation of the gonads, and high-water temperatures are associated with spawning (Carvalho et al. 2009CARVALHO PA, PASCHOALINI AL, SANTOS GB, RIZZO E & BAZZOLI N. 2009. Reproductive biology of Astyanax fasciatus (Pisces: Characiformes) in a reservoir in southeastern Brazil. J Appl Ichthyol 25: 306-313.).

ACKNOWLEDGMENTS

The authors thank CODEVASF (Companhia de Desenvolvimento dos Vales do São Francisco e do Parnaíba), CNPq - Conselho Nacional de Desenvolvimento Científico e Tecnológico (306946/2016-5; 407719/2016-4 and 165119/2020-9), CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior) and FAPEMIG - Fundação de Amparo à Pesquisa do Estado de Minas Gerais (APQ 03232-15) for financial support.

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Publication Dates

  • Publication in this collection
    25 Mar 2022
  • Date of issue
    2022

History

  • Received
    10 Aug 2019
  • Accepted
    15 July 2020
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