Abstract

The present study aims to describe the population structure of the freshwater prawn Macrobrachium brasiliense and to analyze whether it varies seasonally, with emphasis on abundance variation by demographic category, sex ratio, size, and morphotypes, in addition to analyzing the recruitment period and its relationship with rainfall. The collections of M. brasiliense were carried out in a Cerrado region, in the southeastern region of Brazil. The population structure was analyzed according to the size, sex, and life stage. The density of morphotypes was calculated by the proportion of each morphotype in the population. Male and female prawns were more abundant in the largest and smallest size classes, respectively. The juvenile morphotype was the most abundant among males (45.9 %), while the “Mirim” and “Açu” morphotypes occurred in a similar proportion (27.87 % and 26.23 %, respectively). The population structure varied significantly between seasons (dry and rainy). A relationship of juvenile abundance with rainfall was recorded. The recruitment period was observed between the end of the rainy season and the beginning of the dry season, while adults were more abundant at the end of the dry season and the beginning of the rainy season. The information in this study contributes to the knowledge of the influence of seasonality and rainfall on populations of aquatic organisms in the Cerrado region, such as the prawn M. brasiliense. Rainfall seasonality affects the population structure of these organisms between seasons, possibly due to the top-down and bottom-up effects caused by different rates of nutrient input in such aquatic systems.

Keywords
Bottom-up; Caridea; recruitment; seasonality; top-down

INTRODUCTION

The American neotropical region is characterized by a wide area that stretches between Central and South America (Morrone, 2014Morrone, J.J. 2014. Biogeographical regionalisation of the Neotropical region. Zootaxa, 3782: 1-110.). In this region, the Caatinga, Cerrado and Chaco biomes constitute an area known as the “dry diagonal”, which extends from the northeast of Brazil to the northwest of Argentina (Ab'Sáber, 1977Ab'Sáber, A.N. 1977. Os domínios morfoclimáticos na América do Sul: primeira aproximação. Geomorfologia, 52: 1-22.; Silva, 1995Silva, J.M.C. 1995. Biogeographic analysis of the South American Cerrado avifauna. Steenstrupia, 21: 49-67.; Zanella, 2011Zanella, F.C.V. 2011. Evolução da biota da diagonal de formações abertas secas da América do Sul. p. 198-220. In: C.J.B. Carvalho and E.A.B. Almeida (eds), Biogeografia da América do Sul: padrões e processos. São Paulo, Editora Roca.). Such biomes share among their main characteristics a relevant seasonality in relation to rainfall (Pinheiro et al., 2002Pinheiro, F.; Diniz, I.R.; Coelho, D. and Bandeira, M.P.S. 2002. Seasonal pattern of insect abundance in the Brazilian cerrado. Austral Ecology, 27: 132-136.; Monteiro et al., 2006Monteiro, J.M.; Albuquerque, U.P.; Lins-Neto, E.M.; Araújo, E.L.; Albuquerque M.M. and Amorim, E.L. 2006. The effects of seasonal climate changes in the Caatinga on tannin levels in Myracrodruon urundeuva (Engl.) Fr. All. and Anadenanthera colubrina (Vell.) Brenan. Revista Brasileira de Farmacognosia, 16: 338-344.; González et al., 2012González, M.H.; Cariaga, M.L. and Skansi, M.D.L.M. 2012. Some factors that influence seasonal precipitation in Argentinean Chaco. Advances in Meteorology, 2012: 359164.).

For the aquatic systems present in these regions (e.g., rivers, streams and lakes), rains play an extremely important ecological role; for example, they transport into these systems important organic matter and nutrients, which play a fundamental role in the food chain (Chaves et al., 2013Chaves, F.Í.B.; Freitas-Lima, P.; Leitão, R.C.; Paulino, W.D. and Santaella, S.T. 2013. Influence of rainfall on the trophic status of a Brazilian semiarid reservoir. Acta Scientiarum Biological Sciences, 35: 505-511.; Fong et al., 2020Fong, C.R.; Gaynus, C.J. and Carpenter, R.C. 2020. Extreme rainfall events pulse substantial nutrients and sediments from terrestrial to nearshore coastal communities: a case study from French Polynesia. Scientific Reports, 10: 1-8.). These organic fragments and nutrients are ingested by invertebrates (i.e., mollusks, insects and crustaceans), and subsequently these animals can be preyed upon by larger organisms, such as fish, reptiles and birds (Suberkroop, 1992Suberkropp, K. 1992. Interactions with invertebrates. p. 118-134. In: F. Bärlocher (ed), The ecology of aquatic hyphomycetes. Heidelberg, Springer.; Post et al., 2000Post, D.M.; Pace, M.L. and Hairston, N.G. 2000. Ecosystem size determines food-chain length in lakes. Nature, 405(6790): 1047-1049.; McHugh et al., 2010McHugh, P.A.; McIntosh, A.R. and Jellyman, P.G. 2010. Dual influences of ecosystem size and disturbance on food chain length in streams. Ecological Letters, 13: 881-890.). Among these invertebrates that inhabit rivers, and are fundamental in the food chain, are the palaemonid prawns, which are widely abundant in these environments (Coelho and Ramos-Porto, 1984Coelho, P.A. and Ramos-Porto, M. 1984. Camarões de água doce do Brasil: distribuição geográfica. Revista Brasileira de Zoologia, 2: 405-410.; Mantel and Dudgeon, 2004Mantel, S.K. and Dudgeon, D. 2004. Effects of Macrobrachium hainanense predation on benthic community functioning in tropical Asian streams. Freshwater Biology, 49: 1306-1319.).

The family Palaemonidae is considered a primary taxon in the infraorder Caridea, and aggregates several genera of marine, estuarine and freshwater prawns, including those belonging to the genus Macrobrachium Spence Bate, 1868. Some representatives of this genus, such as Macrobrachium amazonicum (Heller, 1862), Macrobrachium rosenbergii (De Man, 1879), and Macrobrachium jelskii (Miers, 1877) have been extensively studied because of their extensive geographical distribution and/or economic importance in the Brazilian territory (Melo, 2003Melo, G.A.S. 2003. Manual de identificação dos Crustacea Decapoda de água doce do Brasil. São Paulo, Edições Loyola, 429p.; Magalhães et al., 2005Magalhães, C.; Bueno, S.L.S.; Bond-Buckup, G.; Valenti, W.C.; Silva, H.L.M.; Kiyohara, F.; Mossolin, E.C. and Rocha, S.S. 2005. Exotic species of freshwater decapod crustaceans in the state of São Paulo, Brazil: records and possible causes of their introduction. Biodiversity and Conservation, 14: 1929-1945.; Pileggi and Mantelatto, 2012Pileggi, L.G. and Mantelatto, F.L. 2012. Taxonomic revision of doubtful Brazilian freshwater shrimp species of genus Macrobrachium (Decapoda, Palaemonidae). Iheringia, Série Zoologia, 102: 426-437. ).

Studies show that the distribution and population structure of freshwater prawns can vary between different locations, with the main factor being the physical and chemical conditions of the environment, which can be influenced by seasonality (Brooks et al., 2005Brooks, A.J.; Haeusler, T.I.M.; Reinfelds, I. and Williams, S. 2005. Hydraulic microhabitats and the distribution of macroinvertebrate assemblages in riffles. Freshwater Biology, 50: 331-344.; Barros-Alves et al., 2012Barros-Alves, S.D.P.; Almeida, A.C.; Fransozo, V.; Alves, D.F.R.; Silva, J.C.D. and Cobo, V.J. 2012. Population biology of shrimp Macrobrachium jelskii (Miers, 1778) (Decapoda, Palaemonoidea) at the Grande River at northwest of the state of Minas Gerais, Brazil. Acta Limnologica Brasiliensia, 24: 266-275.; Paschoal et al., 2019Paschoal, L.R.; Oliveira, L.J.F.; Andrioli, G.C. and Zara, F.J. 2019. Reproductive biology of Macrobrachium amazonicum (Heller, 1862) populations with distinct phenotypes in neotropical reservoirs during the ‘El Niño’ event. Marine and Freshwater Research, 70: 1465-1479.; Silva et al., 2020Silva, G.M.; Andrade, M.C.; Silva, B.R.; Palheta, I.S.; Gonçalves, L.B.; Rocha, R.M. and Ferreira, M.A. 2020. Has a river dam affected the life-history traits of a freshwater prawn? Ecology and Evolution, 10: 6536-6548.; Macedo et al., 2021Macêdo, R.S.D.; Martins, C.A.M.; Nascimento, W.M. and Pinheiro, A.P. 2021. Population structure and fecundity of Macrobrachium jelskii (Miers, 1877) (Decapoda, Palaemonidae) on the Batateiras River, sub-basin of the Salgado River, in southern Ceará, Brazil. Nauplius, 29: e2021033.; Perroca et al., 2021Perroca, J.F.; Nogueira, C.S.; Carvalho-Batista, A. and Costa, R.C. 2021. Population dynamics of a hololimnetic population of the freshwater prawn Macrobrachium amazonicum (Heller, 1862) (Decapoda, Palaemonidae) in southeastern Brazil. Aquatic Ecology, 1-14. doi: 10.1007/s10452-021-09889-8
https://doi.org/10.1007/s10452-021-09889... ). Thus, it is essential that studies on the seasonal variation in population structure of different organisms are carried out, in order to understand the effects of climate on such populations, considering that we are living in a time of great climatic changes on a global scale (Jourdan et al., 2018Jourdan, J.; O'Hara, R.B.; Bottarin, R.; Huttunen, K.L.; Kuemmerlen, M.; Monteith, D.; Muotka, T.; Ozoliņš, D.; Paavola, R.; Pilotto, F.; Springe, G.; Skuja, A.; Sundermann, A.; Tonkin, J.D. and Haase, P. 2018. Effects of changing climate on European stream invertebrate communities: A long-term data analysis. Science of The Total Environment, 621: 588-599.; Souza-Dias et al., 2018Souza-Dias, V.; Pereira-Luz, M.; Medero, G.M. and Nascimento, D.T.F. 2018. An overview of hydropower reservoirs in Brazil: Current situation, future perspectives and impacts of climate change. Water, 10: 592.).

Therefore, we will investigate a population of M. brasiliense located in the Cerrado region in southeastern Brazil, with marked seasonality in terms of rainfall. The hypothesis that rainfall seasonality should affect population structure and reproduction leading to peak recruitment in the dry season was tested. This hypothesis is supported by the theory of upward (bottom-up) and downward (top-down) regulatory processes of population and community dynamics (Collar et al., 2017Collar, S.; Roby, D.D. and Lyons, D.E. 2017. Top-down and bottom-up interactions influence fledging success at North America’s largest colony of Caspian terns (Hydroprogne caspia). Estuaries and Coasts, 40: 1808-1818.; Benke, 2018Benke, A.C. 2018. River food webs: an integrative approach to bottom-up flow webs, top-down impact webs, and trophic position. Ecology, 99: 1370-1381.) and by several empirical studies that found a relationship between the reproductive period/recruitment with periods of greatest rainfall (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Nogueira et al., 2019Nogueira, C.S.; Perroca, J.F.; Piantkoski, E.L.; Costa, R.C.; Taddei, F.G. and Fransozo, A. 2019b. Relative growth and population dynamics of Macrobrachium iheringi (Decapoda, Palaemonidae). Papéis Avulsos de Zoologia, 59: e20195908.b; Oliveira et al., 2019Oliveira, L.J.F.; Sant’Anna, B.S. and Hattori, G.Y. 2019. Population biology of the freshwater prawn Macrobrachium brasiliense (Heller, 1862) in the Middle Amazon Region, Brazil. Tropical Zoology, 32: 19-36.). The hypothesis proposes that: [1] different population structures occur between seasons (dry and rainy), i.e., immature and small individuals predominating in the dry season and a predominance of adult individuals and larger size classes in the rainy season; and [2] a significant relationship will occur between juvenile abundance and rainfall.

MATERIAL AND METHODS

Study area and sampling methods

The Água Limpa stream (19º05’38”S 48º22’47”W) is located in the municipality of Uberlândia, state of Minas Gerais, a Cerrado region in southeastern Brazil (Fig. 1). The stream where the sampling was carried out consists of a stretch with a maximum of 2.0 m in width between the margins and with sandy sediments. The marginal vegetation of this stream consists of plants (i.e., grasses, shrubs, and trees) characteristic of the Cerrado biome. This region has a large seasonal variation in rainfall levels (ANA, 2014ANA (Agência Nacional de Águas). 2014-2021. Hidroweb - Sistema de informações hidrológicas. Avaible at Avaible at http://www.snirh.gov.br/hidroweb/apresentacao . Accessed on 21 April 2021.
http://www.snirh.gov.br/hidroweb/apresen... ), with two well-defined seasons: a rainy season during spring and summer in the southern hemisphere (from October to March), with monthly average rainfall of a minimum of 113 and a maximum of 301 mm³ per month (mean ± SD = 217.83 ± 71.61 mm³); and a dry period during autumn and winter (from April to September), with much lower monthly accumulated precipitation averages, with a minimum of 11 and a maximum of 86 mm³ per month (mean ± SD = 36.33 ± 28.53 mm³).

The specimens were sampled monthly by two collectors who used circular sieves (50.0 cm in diameter; 2.0 mm mesh), from July 2012 to June 2013. The sieves were deployed in the submerged marginal vegetation, between depths of 15 to 120 cm, for a period of 90 minutes. In the field, the collected animals were kept in ice boxes and then transported to the laboratory. The specimens were preserved in 70 % alcohol and kept for later species identification, sexing and measurements.

Laboratory procedure

Prawns were identified to species level according to Melo (2003Melo, G.A.S. 2003. Manual de identificação dos Crustacea Decapoda de água doce do Brasil. São Paulo, Edições Loyola, 429p.). The sex of each individual was identified by the presence (males) or absence (females) of the appendix masculina on the second pair of pleopods (Bauer, 2004Bauer, R.T. 2004. Remarkable shrimps: adaptations and natural history of the carideans. Norman, University of Oklahoma Press, 326p.). Individuals smaller than the smallest identified male were considered as undifferentiated juveniles. After these procedures, the prawns were measured with a caliper (0.1 mm precision), for the length of the carapace (CL, mm) and the total length of the second pair of chelipeds (left and right). The CL comprises the distance between the anterior post-orbital margin and the posterior margin of the carapace. The total length of the second pair of chelipeds is equivalent to the sum of the individual size of the ischium, merus, carpus, and propodus. Only individuals who presented both chelipeds with all the articles were used in the analysis.

Individuals of both sexes were classified into adults and juveniles according to the size of morphological sexual maturity proposed by Nogueira et al. (2019aNogueira, C.S.; Oliveira, M.S.; Jacobucci, G.B. and Almeida, A.C. 2019a. Relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) and its implications for reproduction. Iheringia, Série Zoologia, 109: e2019005.), 8.64 mm and 8.03 mm CL for males and females, respectively. The male morphotypes of M. brasiliense were identified according to Nogueira et al. (2020Nogueira, C.S.; Pantaleão, J.A.F.; Almeida, A.C. and Costa, R.C. 2020. Male morphotypes of the freshwater prawn Macrobrachium brasiliense (Decapoda: Caridea: Palaemonidae). Invertebrate Biology, 139: e12279.), using the major cheliped length (MCL), which was defined by comparing the length between the left and the right chelipeds. Male morphotypes are constituted by dominant and submissive individuals of the same population, in the case of M. brasiliense there are two types of morphotypes, one submissive (“Mirim” morphotype) and one dominant (“Açu” morphotype) (for more details on male morphotypes in Macrobrachium species, see Karplus and Barki, 2019Karplus, I. and Barki, A. 2019. Male morphotypes and alternative mating tactics in freshwater prawns of the genus Macrobrachium: a review. Reviews in Aquaculture, 11: 925-940.; Nogueira et al., 2020Nogueira, C.S.; Pantaleão, J.A.F.; Almeida, A.C. and Costa, R.C. 2020. Male morphotypes of the freshwater prawn Macrobrachium brasiliense (Decapoda: Caridea: Palaemonidae). Invertebrate Biology, 139: e12279.). Monthly rainfall data were obtained from the digital platform “HidroWeb” of the National System on Water Resources (SNIRH).

Population structure and dynamics

For the characterization of the population structure, the prawns were distributed in nine size classes established by the method proposed by Sturges (1926Sturges, H.A. 1926. The choice of a class interval. Journal of the American Statistical Association, 21(153): 65-66.). The size frequency distribution of undifferentiated juveniles, males and females, adults and juveniles, was assessed according to the standard of normality by the Shapiro-Wilk test (α = 0.05). The overall sex ratio in all size classes was assessed using a binomial test (α = 0.05) (Wilson and Hardy, 2002Wilson, K. and Hardy, I.C.W. 2002. Statistical analysis of sex ratios: an introduction. p. 48-92. In: I.C.W. Hardy (ed), Sex ratios: concepts and research methods. Cambridge, Cambridge University Press.). After identifying the morphotypes present in the population, the proportion of each group was calculated. The comparison between the size (CL) of males and females was assessed using the Mann-Whitney test (α = 0.05).

Considering the difference in rainfall patterns, the seasonal changes in population were tested, i.e., if the abundance of prawns in each demographic category varied over the two seasons. For this, a multidimensional scaling (nMDS) was carried out considering two seasons (rainy vs. dry), based on Bray-Curtis similarity matrices (Clarke, 1993Clarke, K.R. 1993. Non-parametric multivariate analyses of changes in community structure. Austral Ecology, 18: 117-143.; Clarke and Warwick, 2001Clarke, K.R. and Warwick, R.M. 2001. Change in Marine Communities: an approach to statistical analysis and interpretation. Plymouth, Primer-E, 262p. ). This separation enables testing the hypothesis that the population structure of M. brasiliense is modified seasonally. One-way cross-analyses of similarity (ANOSIM R) were later used to test for significant differences in population structure between seasons (α < 0.05) (Clarke, 1993Clarke, K.R. 1993. Non-parametric multivariate analyses of changes in community structure. Austral Ecology, 18: 117-143.). In addition, correspondence analysis (CA) was used to evaluate the relationship between the sampling month and the number of prawns by demographic classes and/or by size classes (Lepš and Šmilauer, 2003Lepš, J. and Šmilauer, P. 2003. Multivariate analysis of ecological data using CANOCO. Cambridge, Cambridge University Press, 362p.). In this analysis, absolute abundance values were used, considering the number of prawns in each month, demographic classes and size class. The analyzes mentioned in this paragraph were used because they are adequate to analyze a dataset with a low number of samples or absent data, not influencing the final results (Forcino et al., 2015Forcino, F.L.; Leighton, L.R.; Twerdy, P. and Cahill, J.F. 2015. Reexamining sample size requirements for multivariate, abundance-based community research: when resources are limited, the research does not have to be. PLoS One, 10(6): e0128379.). Finally, we tested the relationship between undifferentiated juvenile abundance and rainfall using linear regression (α = 0.05).

RESULTS

Population structure and density of morphotypes

A total of 253 individuals were collected during the sampling period, with 54 undifferentiated juveniles (UJ), 44 adult males, 53 juvenile males, 27 adult females and 75 juvenile females. The mean CL of UJ was 3.87 ± 0.70 mm (2.3-4.7 mm), 13.36 ± 3.46 mm (8.7-20.5 mm) in adult males, 6.57 ± 0.95 mm (4.8-8.5 mm) in juvenile males, 12.59 ± 3.05 mm (8.2-20.1 mm) in adult females, and 5.95 ± 0.77 mm (4.8-7.9 mm) in juvenile females. The distribution of data from all demographic categories differed significantly from a normality pattern (undifferentiated juveniles: W = 0.93, p = 0.02; adult and juvenile males: W = 0.87, p < 0.001; adult and juvenile females: W = 0.75, p < 0.001), and the mean CL was significantly different between males and females (Mann-Whitney, U = 3,176, p < 0.05).

The individuals were distributed in nine size classes with an interval of 2 mm. In general, females were more abundant in the smaller size classes, while a greater number of male individuals was observed in the larger classes (Fig. 2).

Juvenile males were observed only in classes 4.3 -| 6.3, 6.3 -| 8.3 and 8.3 -| 10.4, with greatest abundance in the second class mentioned, while adult males were more abundant in classes 8.3 -| 10.4, 10.4 -| 12.4, 16.5 -| 18.5 and 18.5 -| 20.5 mm CL (Fig. 2). Juvenile females are distributed in classes 4.3 -| 6.3 and 6.3 -| 8.3, with the greatest abundance in the first class mentioned, while adult females were more abundant in class 12.4 -| 14.4 mm CL (Fig. 2). UJ were only categorized into the two smallest size classes between 2.3 to 6.3 mm CL (Fig. 2).

Despite the deviation in the general sex ratio in favor of females (1:1.25), there was no significant difference in relation to the proportion of males (Binomial test, p > 0.05). Among the eight largest size classes, the sex ratio was inclined towards females in three classes (4.3 -| 6.3, 6.3 -| 8.3 and 12.4 -| 14.4 mm; Fig. 3), while for males it was inclined towards them in four classes (8.3 -| 10.4, 10.4 -| 12.4, 16.5 -| 18.5 and 18.5 -| 20.5 mm; Fig. 3), and, in class 14.4 -| 16.5 mm, the sex ratio was 1:1. However, significant differences in sex ratio were observed in only three classes, 4.3 -| 6.3 for females and 8.3 -| 10.4 and 16.5 -| 18.5 mm for males (Binomial test, p < 0.05).

Among the 97 males collected, only 61 individuals were identified as to their morphotype. Among the three existing morphotypes (Juveniles, “Mirim” and “Açu”), individuals were classified into 28 juveniles, 17 “Mirim” and 16 “Açu”. The average CL among the juvenile morphotypes, “Mirim” and “Açu” was 7.01 ± 1.03 mm, 10.45 ± 1.37 mm and 16.46 ± 2.56 mm, respectively (Tab. 1). The average major cheliped length (MCL) among juveniles, “Mirim” and “Açu” morphotypes was 13.97 ± 2.06 mm, 22.55 ± 2.73 mm and 41.19 ± 9.44 mm, respectively (Tab. 1). The proportion of male morphotypes in the population was juveniles (45.9 %), “Mirim” (27.87 %) and “Açu” (26.23 %) (Tab. 1).

Seasonal variation in population structure and recruitment

During the sampling period, the highest rainfall was recorded in January (363.3 mm) and November (201.1 mm), while the lowest rainfall was observed in June (4.5 mm), July (13.9 mm), and August, when no rainfall was recorded (Fig. 4).

The nMDS ordination derived from the abundance of prawns in each demographic category recorded two groups for population structure (Fig. 5A). ANOSIM indicated a significant difference in the composition of the population in each season (rainy vs. dry) (ANOSIM; R = 0.320; p = 0.007; Fig. 5A). Composition varied across seasons (rainy vs. dry), and this variation was observed in CA (Fig. 5B, C). UJ (representatives of the first size class; SC 1) were more frequent in the months at the end of the rainy season and the beginning of the dry season (March, April, and May) (Fig. 5B, C). There was a correlation between the occurrence of UJ and rainfall (Linear regression, t = -3.63; p = 0.001). The recruitment period was verified by the occurrence of UJ between the months of March and May, with a prominent peak in March and April. On the other hand, adults (AF and AM) and representatives of the last size classes (SC 8) were more frequent at the end of the dry season and the beginning of the rainy season (August, September, and October) (Fig. 5B, C).

DISCUSSION

Our results show differences in the composition of the population structure between the dry and rainy seasons. The proposed predictions were confirmed, considering that the population structure differed between the dry and rainy seasons, and the abundance of juveniles was affected by rainfall; as recruits were observed at the end of the rainy season and the beginning of the dry season (predominant in the latter). The general characteristics of the population biology observed were similar in comparison with other populations of M. brasiliense investigated in the states of São Paulo and Mato Grosso do Sul (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Pereira and Chacur, 2009Pereira, M.G.C. and Chacur, M.M. 2009. Estrutura populacional de Macrobrachium brasiliense (Crustacea, Palaemonidae) do Córrego Escondido, Batayporã, Mato Grosso do Sul, Brasil. Revista de Biologia Neotropical, 6: 75-82.), mainly in relation to the population structure and the period of recruitment. In addition, this is the first population study that provides information on the occurrence and density of morphotypes within an M. brasiliense population.

Throughout the sampling period, individuals of both sexes were registered, except for the category of undifferentiated juveniles (UJ) that were collected at specific times. The frequency distribution of males and females of M. brasiliense between the size classes followed a pattern, with a greater number of females in the smallest size classes and a greater number of males in the largest classes, which may be a reflection of the reproductive strategy called “temporary female guarding” (Bauer, 2004Bauer, R.T. 2004. Remarkable shrimps: adaptations and natural history of the carideans. Norman, University of Oklahoma Press, 326p.), with dominant males that court and protect females during copulation. This model of population structure seems to be a pattern in M. brasiliense, considering all the populations studied so far (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Pereira and Chacur, 2009Pereira, M.G.C. and Chacur, M.M. 2009. Estrutura populacional de Macrobrachium brasiliense (Crustacea, Palaemonidae) do Córrego Escondido, Batayporã, Mato Grosso do Sul, Brasil. Revista de Biologia Neotropical, 6: 75-82.; Oliveira et al., 2019Oliveira, L.J.F.; Sant’Anna, B.S. and Hattori, G.Y. 2019. Population biology of the freshwater prawn Macrobrachium brasiliense (Heller, 1862) in the Middle Amazon Region, Brazil. Tropical Zoology, 32: 19-36.), as well as for other Macrobrachium species (Mattos and Oshiro, 2009Mattos, L.A. and Oshiro, L.M.Y. 2009. Population structure of Macrobrachium potiuna (Crustacea, Palaemonidae) in the Moinho's River, Mangaratiba, Rio de Janeiro, Brazil. Biota Neotropica, 9: 81-86.; Gualberto et al., 2012Gualberto, T.L.; Almeida, L.O. and Menin, M. 2012. Population structure, fecundity and ecological aspects of freshwater shrimp species (Decapoda, Palaemonidae) of an urban forest fragment in central Amazonia, Brazil. Crustaceana, 85: 1205-1219.; Nogueira et al., 2019Nogueira, C.S.; Perroca, J.F.; Piantkoski, E.L.; Costa, R.C.; Taddei, F.G. and Fransozo, A. 2019b. Relative growth and population dynamics of Macrobrachium iheringi (Decapoda, Palaemonidae). Papéis Avulsos de Zoologia, 59: e20195908.b; Perroca et al., 2021Perroca, J.F.; Nogueira, C.S.; Carvalho-Batista, A. and Costa, R.C. 2021. Population dynamics of a hololimnetic population of the freshwater prawn Macrobrachium amazonicum (Heller, 1862) (Decapoda, Palaemonidae) in southeastern Brazil. Aquatic Ecology, 1-14. doi: 10.1007/s10452-021-09889-8
https://doi.org/10.1007/s10452-021-09889... ). Therefore, this type of sexual system appears to be common within the genus, since most populations are characterized by males being larger than females, with males showing aggressive behavior during social interactions (Fielder and Lee, 1983Fielder, D.R. and Lee, C.L. 1983. Agonistic behaviour and the development of dominance hierarchies in the freshwater prawn, Macrobrachium australiense Holthuis, 1950 (Crustacea: Palaemonidae). Behaviour, 83: 1-16.; Karplus et al., 1992Karplus, I.; Hulata, G. and Zafrir, S. 1992. Social control of growth in Macrobrachium rosenbergii. IV. The mechanism of growth suppression in runts. Aquaculture, 106: 275-283.; Karplus and Barki, 2019Karplus, I. and Barki, A. 2019. Male morphotypes and alternative mating tactics in freshwater prawns of the genus Macrobrachium: a review. Reviews in Aquaculture, 11: 925-940.).

In the studies by Mantelatto and Barbosa (2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.), Pereira and Chacur (2009Pereira, M.G.C. and Chacur, M.M. 2009. Estrutura populacional de Macrobrachium brasiliense (Crustacea, Palaemonidae) do Córrego Escondido, Batayporã, Mato Grosso do Sul, Brasil. Revista de Biologia Neotropical, 6: 75-82.), and Oliveira et al. (2019Oliveira, L.J.F.; Sant’Anna, B.S. and Hattori, G.Y. 2019. Population biology of the freshwater prawn Macrobrachium brasiliense (Heller, 1862) in the Middle Amazon Region, Brazil. Tropical Zoology, 32: 19-36.) there is no information on morphotypes. In this sense, considering the density observed in the present study and the density of morphotypes in populations of similar species, it is important to note that the density of morphotypes in M. brasiliense males did not follow the patterns observed in M. amazonicum and M. rosenbergii (Cohen et al., 1981Cohen, D.; Raanan, Z. and Brody, T. 1981. Population profile development and morphotypic differentiation in the giant freshwater prawn Macrobrachium rosenbergii (de Man). Journal of the World Aquaculture Society, 12: 231-243.; Santos et al., 2006Santos, J.A.; Sampaio, C.M. and Soares-Filho, A.A. 2006. Male population structure of the Amazon River prawn (Macrobrachium amazonicum) in a natural environment. Nauplius, 14: 55-63.), since the density of the morphotypes “Açu” (dominant) and “Mirim” (submissive) were similar within the population.

It was observed that the juvenile morphotype (group with the smallest males) was the most abundant, similar to the “Small Male” morphotype in M. rosenbergii (Cohen et al., 1981Cohen, D.; Raanan, Z. and Brody, T. 1981. Population profile development and morphotypic differentiation in the giant freshwater prawn Macrobrachium rosenbergii (de Man). Journal of the World Aquaculture Society, 12: 231-243.). However, the morphotypes “Mirim” and “Açu” showed a similar proportion within the population, while the morphotypes of M. rosenbergii (Orange claw and Blue claw) and M. amazonicum (Cinnamon claw and Green claw) differ in proportion within their populations, with the dominant morphotype (Blue claw and Green claw, respectively) always being less abundant (Cohen et al., 1981Cohen, D.; Raanan, Z. and Brody, T. 1981. Population profile development and morphotypic differentiation in the giant freshwater prawn Macrobrachium rosenbergii (de Man). Journal of the World Aquaculture Society, 12: 231-243.; Santos et al., 2006Santos, J.A.; Sampaio, C.M. and Soares-Filho, A.A. 2006. Male population structure of the Amazon River prawn (Macrobrachium amazonicum) in a natural environment. Nauplius, 14: 55-63.). Many factors can influence the morphotype density of a population, such as habitat, availability, and competition for food, early sexual maturation, social hierarchy, and aggression (Karplus et al., 1986Karplus, I.; Hulata, G.; Wohlfarth, G.W. and Halevy, A. 1986. The effect of density of Macrobrachium rosenbergii raised in earthen ponds on their population structure and weight distribution. Aquaculture, 52: 307-320.). Possibly, M. brasiliense may present lower levels of aggressiveness in relation to M. rosenbergii and M. amazonicum, with less agonistic confrontations between males, and therefore maintaining similar levels of abundance in the population. However, further studies addressing this theme are essential for understanding this behavior and its influence on the population dynamics of M. brasiliense.

In general, the sex ratio was inclined towards females in the population. This trend occurs frequently within the genus Macrobrachium (Garcia-Davila et al., 2000García-Davílla, C.R.; Alcantara, F.B.; Vasquez, E.R. and Chujandama, M.S. 2000. Biologia reprodutiva do camarão Macrobrachium brasiliense (Heller, 1862) (Crustacea: Decapoda: Palaemonidae) em igarapés da terra firme da Amazônia Peruana. Acta Amazonica, 30: 653-664.; Montoya, 2003Montoya, J.V. 2003. Freshwater shrimps of the genus Macrobrachium associated with roots of Eichhornia crassipes (Water Hyacinth) in the Orinoco Delta (Venezuela). Caribbean Journal of Science, 39: 155-159.; Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Mattos and Oshiro, 2009Mattos, L.A. and Oshiro, L.M.Y. 2009. Population structure of Macrobrachium potiuna (Crustacea, Palaemonidae) in the Moinho's River, Mangaratiba, Rio de Janeiro, Brazil. Biota Neotropica, 9: 81-86.; Tamburus et al., 2012Tamburus, A.F.; Mossolin, E.C. and Mantelatto, F.L. 2012. Populational and reproductive aspects of Macrobrachium acanthurus (Wiegmann, 1836) (Crustacea: Palaemonidae) from north coast of São Paulo state, Brazil. Brazilian Journal of Aquatic Science and Technology, 16: 9-18.; Pescinelli et al., 2016Pescinelli, R.A.; Carosia, M.F.; Pantaleão, J.A.F.; Simões, S.M. and Costa, R.C. 2016. Population biology and size at the onset of sexual maturity of the amphidromous prawn Macrobrachium olfersii (Decapoda, Palaemonidae) in an urban river in southeastern Brazil. Invertebrate Reproduction and Development, 60: 254-262.; Nogueira et al., 2019bNogueira, C.S.; Perroca, J.F.; Piantkoski, E.L.; Costa, R.C.; Taddei, F.G. and Fransozo, A. 2019b. Relative growth and population dynamics of Macrobrachium iheringi (Decapoda, Palaemonidae). Papéis Avulsos de Zoologia, 59: e20195908.), mainly in species in which males reach larger sizes compared to females. Many factors can influence sex ratio within the population, such as aggressiveness, migration, reproductive strategies, differential selection of microhabitats, and longevity (Karplus et al., 1991Karplus, I.; Barki, A. and Goren, M. 1991. The agonistic behaviour of the three male morphotypes of the freshwater prawn Macrobrachium rosenbergii (Crustacea, Palaemonidae). Behaviour, 116: 252-276.; Bauer, 2004Bauer, R.T. 2004. Remarkable shrimps: adaptations and natural history of the carideans. Norman, University of Oklahoma Press, 326p.; Karplus and Barki, 2019Karplus, I. and Barki, A. 2019. Male morphotypes and alternative mating tactics in freshwater prawns of the genus Macrobrachium: a review. Reviews in Aquaculture, 11: 925-940.). Possibly, for M. brasiliense, the greater abundance of females in the population may be related to the reproductive strategy characterized by a series of agonistic behaviors, including aggression among males, which certainly can increase the mortality rates of this demographic category, influencing the sex ratio of the population.

The seasonal variation in the population structure is the result, at least in part, of the relationship between rainfall and the recruitment of UJ. Recruitment increases at the end of the rainy season, with the period with the highest recruitment intensity observed from March to July, a period similar to that recorded for populations in the states of São Paulo and Mato Grosso do Sul (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Pereira and Chacur, 2009Pereira, M.G.C. and Chacur, M.M. 2009. Estrutura populacional de Macrobrachium brasiliense (Crustacea, Palaemonidae) do Córrego Escondido, Batayporã, Mato Grosso do Sul, Brasil. Revista de Biologia Neotropical, 6: 75-82.), but different from the populations of the Amazon regions of Brazil and Peru (García-Davila et al., 2000García-Davílla, C.R.; Alcantara, F.B.; Vasquez, E.R. and Chujandama, M.S. 2000. Biologia reprodutiva do camarão Macrobrachium brasiliense (Heller, 1862) (Crustacea: Decapoda: Palaemonidae) em igarapés da terra firme da Amazônia Peruana. Acta Amazonica, 30: 653-664.; Oliveira et al., 2019Oliveira, L.J.F.; Sant’Anna, B.S. and Hattori, G.Y. 2019. Population biology of the freshwater prawn Macrobrachium brasiliense (Heller, 1862) in the Middle Amazon Region, Brazil. Tropical Zoology, 32: 19-36.). This difference between the recruitment periods may be related to local environmental factors, such as seasonal rainfall, food resources and predators (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Bittencourt and Armadio, 2007Bittencourt, M.M. and Amadio, S.A. 2007. Proposta para identificação rápida dos períodos hidrológicos em áreas de várzea do rio Solimões-Amazonas nas proximidades de Manaus. Acta Amazonica, 37: 303-308.; Oliveira et al., 2019Oliveira, L.J.F.; Sant’Anna, B.S. and Hattori, G.Y. 2019. Population biology of the freshwater prawn Macrobrachium brasiliense (Heller, 1862) in the Middle Amazon Region, Brazil. Tropical Zoology, 32: 19-36.). Comparing previous studies, the rainy season and the hydrological cycle are the main factors that modulate these differences in population aspects between the southeast/central-west regions and the Amazon region.

The low abundance, or absence, of ovigerous females is common in populations of M. brasiliense, mainly in the populations of the central-west and southeast of Brazil (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Pereira and Chacur, 2009Pereira, M.G.C. and Chacur, M.M. 2009. Estrutura populacional de Macrobrachium brasiliense (Crustacea, Palaemonidae) do Córrego Escondido, Batayporã, Mato Grosso do Sul, Brasil. Revista de Biologia Neotropical, 6: 75-82.). In the present study, no ovigerous female was found; despite this fact, it is possible to estimate in which months the reproductive period of M. brasiliense occurs according to the delimitation of the recruitment period. It is known that M. brasiliense has abbreviated larval development (Pantaleão et al., 2011Pantaleão, J.A.F.; Gregati, R.A.; Taddei, F.G. and Costa, R.C. 2011. Morphology of the first larval stage of Macrobrachium brasiliense (Heller, 1868) (Caridea: Palaemonidae). Nauplius, 19: 79-85.); therefore, the embryo incubation period can take an average of 39 days (Lavarias et al., 2002Lavarias, S.; Heras, H.; Demichelis, S.; Portiansky, E. and Pollero, R.J. 2002. Morphometric study of embryonic development of Macrobrachium borellii (Arthropoda: Crustacea). Invertebrate Reproduction and Development, 41: 157-163.). In addition, the period between larval development into juveniles for Macrobrachium species with abbreviated development occurs on average from 5 to 11 days (Magalhães, 1989Magalhães, C. 1989. The larval development of palaemonid shrimps from the Amazon Region reared in the laboratory. VI. Abbreviated development of Macrobrachium nattereri (Heller, 1862) (Crustacea: Decapoda). Amazoniana, 10: 379-392.; 2016Magalhães, C. 2016. Abbreviated larval development of Macrobrachium inpa Kensley and Walker, 1982 (Crustacea: Decapoda: Palaemonidae) from an Amazon Basin Forest stream, Brazil, reared in the laboratory. Nauplius, 24: e2016009.; Rodrigues and Bueno, 1995Rodrigues, S.A. and Bueno, S.L.S. 1995. Abbreviated Larval development of the freshwater prawn, Macrobrachium iheringi (Ortmann, 1897) (Decapoda, Palaemonidae), reared in the laboratory. Crustaceana, 68: 665-686.; Mejía et al., 2003Mejía, L.; Alvarez, F. and Hartnoll, R. 2003. A new species of freshwater prawn, Macrobrachium totonacum (Decapoda, Palaemonidae), with abbreviated development from Mexico. Crustaceana, 76: 77-86.). In this way, the entire embryonic and larval development process would occur in approximately 50 days; therefore, the peak of the reproductive period of this M. brasiliense population possibly occurs between January and February; a similar period to species that have the same type of embryonic development, such as Macrobrachium iheringi (Ortmann, 1897) and M. potiuna (Müller, 1880) (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Mattos and Oshiro, 2009Mattos, L.A. and Oshiro, L.M.Y. 2009. Population structure of Macrobrachium potiuna (Crustacea, Palaemonidae) in the Moinho's River, Mangaratiba, Rio de Janeiro, Brazil. Biota Neotropica, 9: 81-86.; Nogueira et al., 2019Nogueira, C.S.; Perroca, J.F.; Piantkoski, E.L.; Costa, R.C.; Taddei, F.G. and Fransozo, A. 2019b. Relative growth and population dynamics of Macrobrachium iheringi (Decapoda, Palaemonidae). Papéis Avulsos de Zoologia, 59: e20195908.b).

Our results show that there was a (negative) correlation between the occurrence of undifferentiated juveniles and rainfall, and also that there was a differential composition of the population structure between the dry and rainy season; following the pattern observed in species with abbreviated larval development (Mantelatto and Barbosa, 2005Mantelatto, F.L.M. and Barbosa, L.R. 2005. Population structure and relative growth of freshwater prawn Macrobrachium brasiliense (Decapoda, Palaemonidae) from São Paulo State, Brazil. Acta Limnologica Brasiliensia, 17: 245-255.; Pereira and Chacur, 2009Pereira, M.G.C. and Chacur, M.M. 2009. Estrutura populacional de Macrobrachium brasiliense (Crustacea, Palaemonidae) do Córrego Escondido, Batayporã, Mato Grosso do Sul, Brasil. Revista de Biologia Neotropical, 6: 75-82.; Nogueira et al., 2019bNogueira, C.S.; Perroca, J.F.; Piantkoski, E.L.; Costa, R.C.; Taddei, F.G. and Fransozo, A. 2019b. Relative growth and population dynamics of Macrobrachium iheringi (Decapoda, Palaemonidae). Papéis Avulsos de Zoologia, 59: e20195908.). Such results are extremely relevant, as they reinforce the influence of environmental factors on these prawn populations, showing that rain and the entire regulation of population dynamics (bottom-up and top-down) plays a fundamental role in the development cycle of these animals.

ACKNOWLEDGMENTS

The authors are grateful to FAPEMIG (Fundação de Amparo à Pesquisa de Minas Gerais) and to the Instituto de Biologia of the Universidade Federal de Uberlândia for providing financial support. CSN thanks the doctoral scholarship provided by São Paulo State Research Support Foundation - FAPESP # 2019/00661-3. RCC thanks the National Council for Scientific and Technological Development, Brazil - CNPq (research scholarships PQ 306672/2018-9). All applicable international, national, and/or institutional guidelines for the care and use of animals were followed.

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