Activity and habitat use of two species of stingrays (Myliobatiformes: Potamotrygonidae) in the upper Paraná River basin, Southeastern Brazil

Garrone Neto, Domingos; Uieda, Virgínia Sanches

doi:10.1590/S1679-62252012000100008

Abstracts

The life history of freshwater stingrays (Potamotrygonidae) under natural conditions has been poorly documented. In this study, we investigated theperiod of activity and the habitat use of two species of the genus Potamotrygon in the upper Paraná River basin, Southeastern Brazil. Potamotrygon falkneri and P. motoro are similar to each other as far as the analyzed behavior is concerned. Individuals of both species segregate according to their size, and in function of the depth and period of the day. Younger individuals inhabit mostly sandy beaches and places that are no deeper than four meters throughout the whole day. Bigger stingrays realize bathymetric migrations, alternating their position between places deeper than eight meters during the day, and shallow areas at night. Individuals of intermediate size inhabit transition environments that have greater habitat diversity. Both species presented mostly nocturnal habits, especially regarding their feeding behavior. The behavioral patterns observed seem to go through ontogenetic variations and probably change throughout the year, between dry and wet seasons.

Bathymetric migration; Dial movements; Potamotrygon; Scientific diving; Spatial ecology

Informações sobre o modo de vida das raias de água doce (Potamotrygonidae) sob condições naturais são escassas. Neste trabalho, estudamos o período de atividade e as formas de uso do habitat de duas espécies do gênero Potamotrygon na bacia do alto rio Paraná, no Sudeste do Brasil. Potamotrygon falkneri e P. motoro apresentaram comportamento muito semelhante, com nítida segregação espacial dos indivíduos em função do seu tamanho, da profundidade e do período do dia. Juvenis estiveram associados a praias arenosas e locais com profundidades abaixo de quatro metros ao longo de todo o dia. Raias de grande porte realizaram migrações batimétricas, alternando sua posição entre locais com profundidade superior a oito metros durante o dia e áreas mais rasas à noite. Indivíduos com tamanho intermediário ocuparam ambientes de transição, com maior heterogeneidade ambiental. Ambas as espécies apresentaram atividade, especialmente alimentar, predominantemente noturna. Os padrões comportamentais estudados parecem sofrer variações ontogenéticas e é provável que se alterem ao longo do ano, entre períodos de seca e cheia.

Activity and habitat use of two species of stingrays (Myliobatiformes: Potamotrygonidae) in the upper Paraná River basin, Southeastern Brazil

Domingos Garrone Neto^I; Virgínia Sanches Uieda^II

^IUniversidade Estadual Paulista (UNESP), Laboratório de Pesquisa de Elasmobrânquios, Praça Infante Dom Henrique s/nº, 11330-900 São Vicente, São Paulo, Brazil. garroneneto@yahoo.com

^IIUniversidade Estadual Paulista (UNESP), Departamento de Zoologia, Instituto de Biociências, Distrito de Rubião Jr. s/nº, 18618-970 Botucatu, SP, Brazil. vsuieda@ibb.unesp.br

ABSTRACT

The life history of freshwater stingrays (Potamotrygonidae) under natural conditions has been poorly documented. In this study, we investigated theperiod of activity and the habitat use of two species of the genus Potamotrygon in the upper Paraná River basin, Southeastern Brazil. Potamotrygon falkneri and P. motoro are similar to each other as far as the analyzed behavior is concerned. Individuals of both species segregate according to their size, and in function of the depth and period of the day. Younger individuals inhabit mostly sandy beaches and places that are no deeper than four meters throughout the whole day. Bigger stingrays realize bathymetric migrations, alternating their position between places deeper than eight meters during the day, and shallow areas at night. Individuals of intermediate size inhabit transition environments that have greater habitat diversity. Both species presented mostly nocturnal habits, especially regarding their feeding behavior. The behavioral patterns observed seem to go through ontogenetic variations and probably change throughout the year, between dry and wet seasons.

Key words: Bathymetric migration, Dial movements, Potamotrygon, Scientific diving, Spatial ecology.

RESUMO

Informações sobre o modo de vida das raias de água doce (Potamotrygonidae) sob condições naturais são escassas. Neste trabalho, estudamos o período de atividade e as formas de uso do habitat de duas espécies do gênero Potamotrygon na bacia do alto rio Paraná, no Sudeste do Brasil. Potamotrygon falkneri e P. motoro apresentaram comportamento muito semelhante, com nítida segregação espacial dos indivíduos em função do seu tamanho, da profundidade e do período do dia. Juvenis estiveram associados a praias arenosas e locais com profundidades abaixo de quatro metros ao longo de todo o dia. Raias de grande porte realizaram migrações batimétricas, alternando sua posição entre locais com profundidade superior a oito metros durante o dia e áreas mais rasas à noite. Indivíduos com tamanho intermediário ocuparam ambientes de transição, com maior heterogeneidade ambiental. Ambas as espécies apresentaram atividade, especialmente alimentar, predominantemente noturna. Os padrões comportamentais estudados parecem sofrer variações ontogenéticas e é provável que se alterem ao longo do ano, entre períodos de seca e cheia.

Introduction

Studies on patterns of movement, spatial distribution, activity and habitat use of fishes, associated with the description of the characteristics of the occupied areas, have been used as central topics of ecological research, including resources sharing, organization of communities, ecomorphology, and optimum foraging (Anderson et al., 1989; Rincón, 1999). Knowledge of fishes' way of life in nature and their preference for particular types of environments have also been used to identify and protect specific habitats and to support actions of management and conservation of species in different parts of the world (Steimle & Zetlin, 2000; Simpfendorfer & Heupel, 2004; Aguiar et al., 2009).

In Brazil, research into the behavior of fish in the natural environment is recent but has been steadily growing from year to year, normally focusing on species of teleostean fish (Sazima, 1986; Casatti & Castro, 1998; Sabino, 1999; Teresa et al., 2011). Information of this kind is scarce when dealing with elasmobranchs, particularly with stingrays of the family Potamotrygonidae (Castex, 1963; Achenbach & Achenbach, 1976; Rosa, 1985). Only in recent years, the surveys of Brazilian fish species, and particularly of freshwater stingrays, were intensified. In the last years, the potamotrygonids have rekindled the interest of researchers, enabling the generation of data on the biology, ecology, taxonomy, and toxicology of some species (see Garrone Neto & Haddad Jr., 2010; Rosa et al., 2010; Carvalho & Lovejoy, 2011 and references therein).

However, the life history of the family Potamotrygonidae under natural conditions has been poorly studied (Garrone Neto & Sazima, 2009a, b), since the majority of existing data are based on indirect observations, with this methodology's inherent limitations. In this sense, we have aimed to present information on patterns of activity and forms of habitat use by two co-occurring species of potamotrygonids, thereby contributing to the better understanding of the way of life of these animals in their natural environment.

Material and Methods

Study area. The present study was carried out in the upper course of the Paraná River, Southeastern Brazil, between 2005 and 2008. The investigations were concentrated in the municipalities of Castilho, SP and Três Lagoas, MS (about 20°47'S 51°37'W), on the border of the states of São Paulo and Mato Grosso do Sul. Additional information was obtained from expeditions conducted in the municipality of Panorama, SP (21°22'S 51°54'W), in the region comprising the lower reaches of the Tietê (20°40'S 51°25'W) and Paranapanema (22°39'S 53°05'W) rivers, and in the Ilha Grande National Park (24°00'S 54°07'W). These expeditions comprised a stretch of approximately 350 kilometers which are under the influence of two hydroelectric dams: Engenheiro Sérgio Motta (Porto Primavera) and Engenheiro Souza Dias (Jupiá) (Fig. 1).

According to the Köppen-Geiger classification (Peel et al., 2007), the region has a Cfa or humid sub-tropical climate, comprising two clearly defined seasons: one hot and rainy, which runs from the beginning of November through April, and the other dry and cooler, beginning in May and ending around October. In the dry period, when the underwater observations were concentrated, the water from the rivers and marginal lakes has excellent transparency, which may reach depths of 6 to 8 meters, mainly in October.

The region comprising the upper Paraná River has a long history of human occupation, with the deployment of large hydroelectric projects and few locations which have maintained the original environmental characteristics (e. g. rapids and waterfalls). The substrate and the composition of the banks range from muddy bottom with pasture present at the water's edge, to sandy substrate with the presence of rocks, aquatic macrophytes and riparian vegetation. In order to represent a large number of these features, different locations for observational studies were explored, with depths ranging from 0.5 to 18 meters.

Potamotrygonids species in the studied area. Of the three species of stingrays recorded in the upper Paraná River basin (Garrone Neto & Haddad Jr., 2010), two were selected for this study: Potamotrygon falkneri Castex & Maciel, 1963 and P. motoro (Müller & Henle, 1841) (Fig. 2). Potamotrygon falkneri is endemic to the Paraná-Paraguay River basin and its specific identity is well corroborated (Rosa, 1985; Silva & Carvalho, 2011). Potamotrygon motoro integrate a set of morphotypes widely distributed through the rivers of South America and at least one new form was identified in the Paraná River basin, requiring further investigation for its determination (Rosa, 1985; Loboda, 2010). Therefore, two specimens of each studied species were collected and stored in the fish collection of the Museu de Zoologia Prof. Dr. Adão José Cardoso - ZUEC/UNICAMP (voucher-specimens: ZUEC 6331 - P. falkneri, and ZUEC 6332 - P. motoro), in a way to enable future verification and the potential revision of their identification.

Underwater observations. Data concerning activity and habitat use were obtained during 112 hours of underwater observations, comprised through random transects with the use of self-contained diving technique (scuba diving) and free diving (snorkeling) (Sabino, 1999). In order to detect possible temporal variations, we divided the daily cycle into three time periods: day - from the total sunrise to the beginning of sunset; dusk - from the period in which the sun is near to and below the horizon; night - from the total sunset until the beginning of sunrise. Data on the water temperature and depth of the observation sites were obtained during the dives using mercury thermometer and a graduate lead line, respectively, in order to verify possible correlations of these environmental variables with the behavior of the rays. In addition, data on the habitats occupied by the animals at the time of the sightings were collected, aiming to investigate the use of the different types of environments (beach, flooded forest, stone, or grass), substrate type (sand, muddy, or gravel), and places with presence or absence of horizontal and/or vertical restrictions (i.e. structures used as shelters, like rocks, trunks, and macrophyte banks).

The scuba diving totaled 15 hours (day = 08 hours; night = 05 hours; dusk = 02 hours) and was performed in locations where the depth of the water was between eight and 18 meters. The free diving totaled 97 hours (day = 52 hours; night = 29 hours; dusk = 16 hours) and was carried out in locations with depth less than 12 meters. Observations were described according to a standard protocol built for this study and recorded using digital photography and video, and notes were made on PVC boards, based on methodology presented by Sazima (1986) and Sabino (1999). During the dives carried out at dusk and at night, we used indirect lighting and lamps with red cellophane filter in order to reduce the disturbance by the observer (Helfman, 1992; Sabino, 1999).

Species identification (based on the coloration of the animals' dorsum) and sex identification (based on the presence of claspers in the males - easily observed dorsally) were done in situ during the underwater observations, without the necessity of catching the animals. The size of the observed individuals was estimated using a hand net of known dimensions placed close to the animals in a way to determine the disc width (DW, i.e. the distance between the extremities of the stingray's pectoral fins). A similar method has been successfully used to estimate the disc length of marine rays (e.g. Aguiar et al., 2009).

Data analysis. To ascertain potential relationship between the observed individuals and environmental variables as time period, depth, type of environment, substrate, and local with presence or absent of horizontal and/or vertical restrictions, a Factorial Correspondence Analysis (FCA) was conducted using the software Statistica 7.0^®. Data about temperature were not included in this analysis, but were used to correlate this variable to the others analyzed. During underwater observations it was observed a similarity among species - but a difference between individuals of different sizes - in relation to distribution and habitat use. In function of these observations, the FCA analysis was applied to data grouped by size, without differentiation by species. According to disc width (DW) and sexual maturity (Garrone Neto, 2010), the individuals were divided into three size classes: f1 (DW 15-25 cm), f2 (DW 26-45 cm) and f3 (DW 46-65 cm).

The FCA is a graphical procedure which aims to represent the associations of a contingency table; therefore it does not take absolute values into consideration, but rather the correspondence between characters. This method analyses the data frequency table via the chi-square distance, thereby permitting the object of the study to be linked to different variables.

Results

In total, 132 animals were observed, 62 of which were identified as P. falkneri (males = 14; females = 48) and 70 as P. motoro (males = 17; females = 51; unidentified = 02). Of these 132 sightings, 87 corresponded to daytime observations (65.9%), 34 at night time (25.8%), and 11 at dusk (8.3%). From the daytime observations, 42 were related to stationary animals (48.3%), 23 to roaming animals (26.4%), 18 foraging (20.7%), and four were buried (4.6%). At night, 24 stingrays were foraging (70.5%), five were roaming (14.7%), four were stationary (11.8%), and one was buried (3.0%). At dusk, eight individuals were involved in foraging activity (73%), two were roaming (18%), one was stationary (9%), and none was buried.

The two studied species presented very similar patterns of number of individuals observed per size class, sex and time of the day. They also presented very similar behavior. For both species there was a variation in the spatial distribution of the individuals and the ways in which they use the habitat related to the size (disc width, DW), as shown in a schematic diagram produced with the results of underwater observation (Fig. 3) and in the graphic representation of FCA analysis (Fig. 4).

In the main river channel, stingrays belonging to the smaller size class (f1) were associated with the riverbanks, at depths between zero and four meters, in waters with about 24°C (x = 23.8ºC; sd = 0.64) and over a predominantly sandy substrate, throughout the day cycle. For this size class, it was common to observe intra-specific aggregations of up to five stingrays resting, sometimes close to some kind of shelter, particularly tree trunks. Otherwise, in marginal lakes and in some stretches of the impoundment areas, these small stingrays showed behavioral variation related to time period, depth and temperature. In these lentic environments, where the temperature of the water approached 27°C in depths up to three meters (x = 26.5°C; sd = 0.53), the individuals remained in deeper places during the day, in waters of about 24ºC (x = 24.2°C; sd = 0.70) and over muddy substrate. However, these small-sized stingrays were more active at night and were observed approaching to shallow banks, when the temperature of the water was about 24ºC (x = 23.7ºC; sd = 0.48).

Intermediate-sized individuals (size class f2) were also found in the river channel and in marginal lakes, frequently between zero and four meters depth and temperatures near 23ºC (x = 23.3ºC; sd = 0.52), and showed greater activity during the night. These individuals were associated to different types of environments, which ranged from rocky banks and stony bottom to places with low-growing riverbank vegetation, sandy substrates, tree trunks and macrophyte banks. In this group, many individuals were observed moving or foraging and, in some cases (n = 07), interacting with species of Cichlidae during their feeding activity.

Large individuals (size class f3) were observed only in the river channel. These stingrays were usually solitary and were rarely seen totally or partially buried in the substrate. For this size class, the spatial distribution showed variation related to depth and time period, with individuals occurring in deeper locations (more than eight meters) during the day and in shallower sites (between 3-8 meters) during the night. During the day they were observed over muddy or sandy substrates at the bottom of the river channel, resting in deeper waters at temperatures around 22ºC (x = 21.6°C; sd = 0.74), sometimes near some type of vertical restriction (e. g. shelters like rocks and macrophyte banks). These large stingrays were more active at night, when they forage in shallow marginal places and temperatures near 24ºC (x = 24.2°C; sd = 0.70).

Discussion

The use of underwater observation was shown to be of great relevance for the study of freshwater stingrays in their natural environment, enabling the pioneering collection of data related to their way of life. Excepting for difficulties during the peak of the wet period (December to March), when there is a natural tendency for river visibility to be drastically reduced, the use of scuba and free diving techniques provided valuable information about the periods of activity and the ways of habitat use of P. falkneri and P. motoro, and made possible a preliminary understanding of their spatial distribution in lentic and lotic environments.

Both species presented very similar patterns of spatial distribution and of ways in which they use the habitat. Potamotrygon falkneri and P. motoro were considered predominantly nocturnal animals, particularly regarding feeding activity. Studies suggested that various species of elasmobranchs are active during different periods of the day, notably at night (Ackerman et al., 2000; Simpfendorfer & Heupel, 2004). In many cases, this pattern of movement seems to be associated with different factors, such as foraging, thermoregulation, and anti-predation strategies (Silliman & Gruber, 1999; Matern et al., 2000; Aguiar et al., 2009), or having a close relationship with environmental factors, such as the lunar phases or tide movements (Smith & Merriner, 1985; Cartamil et al., 2003; Simpfendorfer & Heupel, 2004).

The behavior of P. falkneri and P. motoro showed ontogenetic differences and a clear spatial segregation of individuals, mainly in relation to water depth and period of day. The spatial distribution and period of activity of the stingrays also presented an interesting relationship with the diet and the hunting tactics employed by P. falkneri and P. motoro in the study area. Class f1 stingrays are mainly insectivorous (Silva & Uieda, 2007) and use the hunting tactic namely "undulate disc and stir substrate" to uncover hidden prey in unconsolidated substrata (Garrone-Neto & Sazima, 2009a), both in lentic and lotic environments. As a result, these individuals probably prefer to inhabit the riverbanks and shallow areas with predominantly sandy or muddy substrate due to their feeding behavior during this stage of maturity.

Aguiar (2005) and Aguiar et al. (2009), studying the behavior of the ray Dasyatis americana (Dasyatidae) on an oceanic island in Northeastern Brazil, observed that the spatial distribution of young individuals (disc length < 35 cm) was closely related to sandy beaches and shallow waters, and that this size class was commonly observed in aggregations in these sites. These authors assigned this fact primarily to anti-predatory strategies and secondarily to feeding strategies, and suggested the use of sandy beaches by young individuals as nursery areas (Aguiar, 2005; Aguiar et al., 2009). Despite P. falkneri and P. motoro not being native to the upper Paraná River basin and possessing a relatively recent history of occurrence in the study area (Vazzoler et al., 1997; Garrone Neto et al., 2007), it is possible that this behavior is also recurrent in these taxa and among other species of potamotrygonids, with f1 individuals normally forming aggregations or looking for shelter in shallow waters in lotic environments, associated with sandy beaches, or in deeper waters in lentic environments, associated with muddy substrates.

The large stingrays realized daily bathymetric migrations, occupying locations with different depths during the day and at night, especially for feeding purposes. At night, they were observed searching for preys in shallow waters, mainly freshwater shrimps (Palaemonidae) and small fishes (mostly Characiformes), using predominantly the hunting tactic known as "charging in the shallows" (Garrone Neto & Sazima, 2009a). During the day, those individuals were observed resting in deeper places, eventually moving and using the hunting tactic known as "undulate disc and stir substrate" to prey upon aquatic insects and mollusks (Ampullariidae) (Garrone Neto & Sazima, 2009a).

Matern et al. (2000), in a study of movement patterns of the bat ray Myliobatis californica (Myliobatidae) in Tomales Bay (California/USA), based on information obtained by means of ultrasonic telemetry, suggested that the individuals of this species carried out daily movements with the aim of making the capture and digestion of food more efficient. In this case, one of the factors which apparently exert a strong influence on the animals' patterns of movement is the water temperature, with stingrays alternating their behavior between foraging in shallow warmer waters, located in the bay, and digestion in the open sea, with greater depth and colder waters (Matern et al., 2000). This search for optimum feeding temperatures seems to fit the model originally described by McLaren (1963), where the post-foraging relocation to cooler places reduces the energy demands of the metabolism, by providing additional energy on account of the reduction in the rate of gastric evacuation (Parrish & Margraf, 1990; Cortes & Gruber, 1992), while food assimilation efficiency is maintained (Brett, 1971) or possibly intensified (Wetherbee & Gruber, 1990). To the size class f3 the temperature variation was not significant in this study, although large individuals of P. falkneri and P. motoro showed a strong association of feeding activity with depths under four meters and at temperatures close to 24°C at night, and resting activity with places where the depth is over eight meters and the temperatures are near 22°C at day.

The intermediate-sized stingrays (class f2) occupied a great diversity of environments and comprised the most active of the three studied size classes. Individuals of this size class are known to eat a wide variety of items in the study area, including aquatic insects, mollusks, crustaceans, small fishes, and even residues of artisanal and sport fisheries (Silva & Uieda, 2007; Garrone Neto & Uieda, 2009), using the two hunting tactics mentioned previously and another one, least common, known as "picking up prey on vertical and inclined substrata above water surface" (Garrone Neto & Sazima, 2009a). Those behaviors demonstrated the great flexibility of these individuals in the exploitation of resources (habitat and food), while f1 individuals were basically restricted to shallow areas and to a diet composed mainly of insects, and f3 individuals consumed snails, shrimps and small fishes. The versatility of the hunting behavior of Potamotrygon spp. (Garrone Neto & Sazima, 2009a) also contributed to the interspecific interactions observed between P. falkneri and P. motoro and some species of cichlids (Garrone Neto & Sazima, 2009b), and to their recent and successful colonization of new areas and habitats in the upper Paraná River basin (Garrone Neto et al., 2007; Garrone Neto & Haddad Jr., 2010).

Ontogenetic variations in diet and in feeding behavior are known for some species of elasmobranchs (e.g. Ebert, 2002; Sisneros & Tricas, 2002; Wetherbee & Cortés, 2004). The distribution of individuals in the environment may also have a close relationship with their stage of development, as indicated by the data obtained for P. falkneri and P. motoro in this study. The field observations and the FCA analysis (see Fig. 4) showed that f3 individuals alternate their position throughout the day cycle (bathymetric migration), approaching the banks during the night, whereas f1 stingrays are strongly associated with beach and sandy substrate environments, and the f2 class is present in different environments and depths, associated with rocks and vegetation. Seasonal variations in activity, spatial distribution and habitat use of the species of stingrays here studied may likely occur, but as the peak of the rainy period impairs the use of underwater observations in the upper Paraná River basin, only the use of biotelemetry or other similar technology (see Simpfendorfer & Heupel, 2004 for overviews) may enable the acquisition of these information and expand our knowledge of the behavior of potamotrygonids in their natural environment.

Acknowledgements

The gathering of data would not have been possible without the exceptional collaboration of Cláudia E. Yoshida, Paulo J. P. Cicchi, Ottilie C. Forster, Maria J. A. Vilela, Laura F. Luvisotto, and Marcos T. da Silveira. Aline A. Aguiar made significant comments on the manuscript and made possible the production of the FCA. Cristina Sazima, Otto B. F. Gadig, and Domingo R. Fernandez provided valuable suggestions to the text. The Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) provided financial support for DGN.

Literature Cited

Submitted May 24, 2011

Accepted December 11, 2011

Published March 30, 2012

Achenbach, G. M. & S. V. M. Achenbach. 1976. Notas acerca de algunas especies de raya fluvial (Batoidei, Potamotrygonidae) que frecuentan el sistema hidrografico del rio Paraná medio en El Departamento La Capital (Santa Fé - Argentina). Comunicaciones del Museo Provincial de Ciencias Naturales Florentino Ameghino, 8: 1-34.
Ackerman, J. T., M. C. Kondratieff, S. A. Matern & J. J. Cech Jr. 2000. Tidal influence on spatial dynamics of leopard sharks, Triakis semifasciata, in Tomales Bay, California. Environmental Biology of Fishes, 58: 33-43.
Aguiar, A. A. 2005. Estrutura e densidade populacional e uso de hábitat por Dasyatis americana Hildebrand e Schroeder, 1928 (Chondrichthyes; Dasyatidae) no Arquipélago de Fernando de Noronha, Brasil. Unpublished Ph.D. Dissertation, Universidade Federal da Paraíba, João Pessoa, 74p.
Aguiar, A. A., J. L. Valentin & R. S. Rosa. 2009. Habitat use by Dasyatis americana in a south-western Atlantic oceanic island. Journal of the Marine Biological Association of the United Kingdom, 89: 1147-1152.
Anderson, T. W., E. E. Demartini & D. A. Roberts. 1989. The relationship between habitat structure, body size and distribution of fishes at a temperate artificial reef. Bulletin of Marine Science, 44: 681-697.
Brett, J. R. 1971. Energetic responses of salmon to temperature. A study of some thermal relations in the physiology and freshwater ecology of sockeye salmon (Oncorhynchus nerka). American Zoologist, 11: 99-113.
Cartamil, D. P., J. J. Vaudo, C. G. Lowe, B. M. Wetherbee & K. N. Holland. 2003. Diel movement patterns of the Hawaiian stingray, Dasyatis lata: implications for ecological interactions between sympatric elasmobranch species. Marine Biology, 142: 1-13.
Carvalho, M. R. & N. R. Lovejoy. 2011. Morphology and phylogenetic relationships of a remarkable new genus and two new species of Neotropical freshwater stingrays from the Amazon basin (Chondrichthyes: Potamotrygonidae). Zootaxa, 2776: 13-48.
Casatti, L. & R. M. C. Castro. 1998. A fish community of São Francisco River headwaters riffles, southeastern Brazil. Ichthyological Exploration of Freshwaters, 9: 229-242.
Castex, M. N. 1963. La Raya Fluvial - Notas Histórico-Geográficas. Santa Fé, Librería y Editorial Castellví S.A., 119p.
Cortes, E. & S. H. Gruber. 1992. Gastric evacuation in the young lemon shark, Negaprion brevirostris, under field conditions. Environmental Biology of Fishes, 35: 205-212.
Ebert, D. A. 2002. Ontogenetic changes in the diet of the sevengill shark (Notorynchus cepedianus). Marine & Freshwater Research, 53: 517-523.
Garrone Neto, D. 2010. Considerações sobre a reprodução de duas espécies de potamotrigonídeos (Myliobatiformes, Potamotrygonidae) na região do Alto Rio Paraná, Sudeste do Brasil. Pan-American Journal of Aquatic Sciences, 5: 101-111.
Garrone Neto, D., V. Haddad Jr., M. J. A. Vilela & V. S. Uieda. 2007. Registro de ocorrência de duas espécies de potamotrigonídeos na região do Alto Rio Paraná e algumas considerações sobre sua biologia. Biota Neotropica, 7: 1-4.
Garrone Neto, D. & I. Sazima. 2009a. Stirring, charging, and picking: hunting tactics of potamotrygonid rays in the upper Paraná River. Neotropical Ichthyology, 7: 113-116.
Garrone Neto, D. & I. Sazima. 2009b. The more stirring the better: cichlid fishes associate with foraging potamotrygonid rays. Neotropical Ichthyology, 7: 499-501.
Garrone Neto, D. & V. S. Uieda. 2009. Ingestion of catfish by freshwater stingray: possible mistake or inexperience. Biota Neotropica, 9: 1-3.
Garrone Neto, D. & V. Haddad Jr. 2010. Arraias em rios da região Sudeste do Brasil: locais de ocorrência e impactos sobre a população. Revista da Sociedade Brasileira de Medicina Tropical, 43: 82-88.
Helfman, G. S. 1992. Underwater methods. Pp. 349-369. In: Nielsen, L. A. & D. L. Johnson (Eds.). Fisheries Techniques. Blacksburg, American Fisheries Society, 468p.
Loboda, T. S. 2010. Revisão taxonômica e morfológica de Potamotrygon motoro (Müller & Henle, 1841) na bacia Amazônica (Chondrichthyes: Myliobatiformes: Potamotrygonidae). Unpublished M.Sc. Dissertation, Universidade de São Paulo, São Paulo, 306p.
Matern, S. A., J. J. Cech & T. E. Hopkins. 2000. Diel movements of bat rays, Myliobatis californica, in Tomales Bay, California: evidence for behavioral thermoregulation? Environmental Biology of Fishes, 58: 173-182.
McLaren, I. A. 1963. Effects of temperature on growth of zooplankton, and the adaptive value of vertical migration. Journal of the Fisheries Research Board of Canada, 20: 685-727.
Parrish, D. L. & F. J. Margraf. 1990. Gastric evacuation rates of white perch, Morone americana, determined from laboratory and field data. Environmental Biology of Fishes, 29: 155-158.
Peel, M. C., B. L. Finlayson & T. A. McMahon. 2007. Updated world map of the Köppen-Geiger climate classification. Hydrology and Earth System Sciences, 11: 1633-1644.
Rincón, P. A. 1999. Uso do micro-hábitat em peixes de riachos: métodos e perspectivas. Pp. 23-90. In: Caramaschi, E. P., R. Mazzoni & P. R. Peres-Neto (Eds.). Ecologia de Peixes de Riachos. Rio de Janeiro, PPGE-UFRJ, 260p.
Rosa, R. S. 1985. A systematic revision of the South American freshwater stingrays (Chondrichthyes: Potamotrygonidae). Unpublished Ph.D. Dissertation, School of Marine Sciences, Virginia, 523p.
Rosa, R. S., P. Charvet-Almeida & C. C. D. Quijada. 2010. Biology of the South American Potamotrygonid Stingrays. Pp. 241-281. In: Carrier, J. C., J. A. Musick & M. R. Heithaus (Eds.). Sharks and their relatives II: biodiversity, adaptive physiology, and conservation. Boca Raton, CRC Press, 616p.
Sabino, J. 1999. Comportamento de peixes em riachos: uma abordagem naturalística. Pp. 183-208. In: Caramaschi, E. P., R. Mazzoni & P. R. Peres-Neto (Eds.). Ecologia de Peixes de Riachos. Rio de Janeiro, PPGE-UFRJ, 260p.
Sazima, I. 1986. Similarities in feeding behaviour between some marine and freshwater fishes in two tropical communities. Journal of Fish Biology, 29: 53-65.
Silliman, W. R. & S. H. Gruber. 1999. Behavior biology of the spotted eagle ray, Aetobatus narinari (Euphrasen, 1790) in Bimini, Bahamas; an interim report. Bahamas Journal of Science, 7: 13-20.
Silva, T. B. & V. S. Uieda. 2007. Preliminary data on the feeding habits of the freshwater stingrays Potamotrygon falkneri and Potamotrygon motoro (Potamotrygonidae) from the Upper Paraná River basin, Brazil. Biota Neotropica, 7: 183-188.
Silva, J. P. C. B. & M. R. de Carvalho. 2011. A taxonomic and morphological redescription of Potamotrygon falkneri Castex & Maciel, 1963 (Chondrichthyes: Myliobatiformes: Potamotrygonidae). Neotropical Ichthyology, 9: 209-232.
Simpfendorfer, C. A. & M. R. Heupel. 2004. Assessing habitat use and movement. Pp. 553-572. In: Carrier, J. C., J. A. Musick & M. R. Heithaus (Eds.). Biology of Sharks and their Relatives. Boca Raton, CRC Press, 596p.
Sisneros, J. A. & T. C. Tricas. 2002. Ontogenetic changes in the response properties of the peripheral electrosensory system in the Atlantic stingray (Dasyatis sabina). Brain, Behavior and Evolution, 59: 130-140.
Smith, J. W. & J. V. Merriner. 1985. Food habits and feeding behavior of the cownose ray, Rhinoptera bonasus, in lower Chesapeake Bay. Estuaries, 8: 305-310.
Steimle, F. W. & C. Zetlin. 2000. Reef habitats in the Middle Atlantic Bight: abundance, distribution, associated biological communities, and fishery resource use. Marine Fisheries Review, 62: 24-42.
Teresa, F. B., R. M. Romero, L. Casatti & J. Sabino. 2011. Habitat simplification affects nuclear-follower foraging association among stream fishes. Neotropical Ichthyology, 9: 121-126.
Vazzoler, A. E. A. M., A. A. Agostinho & N. S. Hahn. 1997. A planície de inundação do Alto Rio Paraná: aspectos físicos, biológicos e socioeconômicos. Maringá, EDUEM, 460p.
Wetherbee, B. M. & S. H. Gruber. 1990. The effects of ration level on food retention time in juvenile lemon sharks, Negaprion brevirostris Environmental Biology of Fishes, 29: 59-65.
Wetherbee, B. M. & E. Cortés. 2004. Food Consumption and Feeding Habits. Pp. 225-246. In: Carrier, J. C., J. A. Musick & M. R. Heithaus (Eds.). Biology of Sharks and their Relatives. Boca Raton, CRC Press, 596p.

Publication Dates

Publication in this collection
18 Apr 2012
Date of issue
2012

History

Received
24 May 2011
Accepted
11 Dec 2011

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Achenbach, G. M. & S. V. M. Achenbach. 1976. Notas acerca de algunas especies de raya fluvial (Batoidei, Potamotrygonidae) que frecuentan el sistema hidrografico del rio Paraná medio en El Departamento La Capital (Santa Fé - Argentina). Comunicaciones del Museo Provincial de Ciencias Naturales Florentino Ameghino, 8: 1-34.

[2] Ackerman, J. T., M. C. Kondratieff, S. A. Matern & J. J. Cech Jr. 2000. Tidal influence on spatial dynamics of leopard sharks, Triakis semifasciata, in Tomales Bay, California. Environmental Biology of Fishes, 58: 33-43.

[3] Aguiar, A. A. 2005. Estrutura e densidade populacional e uso de hábitat por Dasyatis americana Hildebrand e Schroeder, 1928 (Chondrichthyes; Dasyatidae) no Arquipélago de Fernando de Noronha, Brasil. Unpublished Ph.D. Dissertation, Universidade Federal da Paraíba, João Pessoa, 74p.

[4] Aguiar, A. A., J. L. Valentin & R. S. Rosa. 2009. Habitat use by Dasyatis americana in a south-western Atlantic oceanic island. Journal of the Marine Biological Association of the United Kingdom, 89: 1147-1152.

[5] Anderson, T. W., E. E. Demartini & D. A. Roberts. 1989. The relationship between habitat structure, body size and distribution of fishes at a temperate artificial reef. Bulletin of Marine Science, 44: 681-697.

[6] Brett, J. R. 1971. Energetic responses of salmon to temperature. A study of some thermal relations in the physiology and freshwater ecology of sockeye salmon (Oncorhynchus nerka). American Zoologist, 11: 99-113.

[7] Cartamil, D. P., J. J. Vaudo, C. G. Lowe, B. M. Wetherbee & K. N. Holland. 2003. Diel movement patterns of the Hawaiian stingray, Dasyatis lata: implications for ecological interactions between sympatric elasmobranch species. Marine Biology, 142: 1-13.

[8] Carvalho, M. R. & N. R. Lovejoy. 2011. Morphology and phylogenetic relationships of a remarkable new genus and two new species of Neotropical freshwater stingrays from the Amazon basin (Chondrichthyes: Potamotrygonidae). Zootaxa, 2776: 13-48.

[9] Casatti, L. & R. M. C. Castro. 1998. A fish community of São Francisco River headwaters riffles, southeastern Brazil. Ichthyological Exploration of Freshwaters, 9: 229-242.

[10] Castex, M. N. 1963. La Raya Fluvial - Notas Histórico-Geográficas. Santa Fé, Librería y Editorial Castellví S.A., 119p.

[11] Cortes, E. & S. H. Gruber. 1992. Gastric evacuation in the young lemon shark, Negaprion brevirostris, under field conditions. Environmental Biology of Fishes, 35: 205-212.

[12] Ebert, D. A. 2002. Ontogenetic changes in the diet of the sevengill shark (Notorynchus cepedianus). Marine & Freshwater Research, 53: 517-523.

[13] Garrone Neto, D. 2010. Considerações sobre a reprodução de duas espécies de potamotrigonídeos (Myliobatiformes, Potamotrygonidae) na região do Alto Rio Paraná, Sudeste do Brasil. Pan-American Journal of Aquatic Sciences, 5: 101-111.

[14] Garrone Neto, D., V. Haddad Jr., M. J. A. Vilela & V. S. Uieda. 2007. Registro de ocorrência de duas espécies de potamotrigonídeos na região do Alto Rio Paraná e algumas considerações sobre sua biologia. Biota Neotropica, 7: 1-4.

[15] Garrone Neto, D. & I. Sazima. 2009a. Stirring, charging, and picking: hunting tactics of potamotrygonid rays in the upper Paraná River. Neotropical Ichthyology, 7: 113-116.

[16] Garrone Neto, D. & I. Sazima. 2009b. The more stirring the better: cichlid fishes associate with foraging potamotrygonid rays. Neotropical Ichthyology, 7: 499-501.

[17] Garrone Neto, D. & V. S. Uieda. 2009. Ingestion of catfish by freshwater stingray: possible mistake or inexperience. Biota Neotropica, 9: 1-3.

[18] Garrone Neto, D. & V. Haddad Jr. 2010. Arraias em rios da região Sudeste do Brasil: locais de ocorrência e impactos sobre a população. Revista da Sociedade Brasileira de Medicina Tropical, 43: 82-88.

[19] Helfman, G. S. 1992. Underwater methods. Pp. 349-369. In: Nielsen, L. A. & D. L. Johnson (Eds.). Fisheries Techniques. Blacksburg, American Fisheries Society, 468p.

[20] Loboda, T. S. 2010. Revisão taxonômica e morfológica de Potamotrygon motoro (Müller & Henle, 1841) na bacia Amazônica (Chondrichthyes: Myliobatiformes: Potamotrygonidae). Unpublished M.Sc. Dissertation, Universidade de São Paulo, São Paulo, 306p.

[21] Matern, S. A., J. J. Cech & T. E. Hopkins. 2000. Diel movements of bat rays, Myliobatis californica, in Tomales Bay, California: evidence for behavioral thermoregulation? Environmental Biology of Fishes, 58: 173-182.

[22] McLaren, I. A. 1963. Effects of temperature on growth of zooplankton, and the adaptive value of vertical migration. Journal of the Fisheries Research Board of Canada, 20: 685-727.

[23] Parrish, D. L. & F. J. Margraf. 1990. Gastric evacuation rates of white perch, Morone americana, determined from laboratory and field data. Environmental Biology of Fishes, 29: 155-158.

[24] Peel, M. C., B. L. Finlayson & T. A. McMahon. 2007. Updated world map of the Köppen-Geiger climate classification. Hydrology and Earth System Sciences, 11: 1633-1644.

[25] Rincón, P. A. 1999. Uso do micro-hábitat em peixes de riachos: métodos e perspectivas. Pp. 23-90. In: Caramaschi, E. P., R. Mazzoni & P. R. Peres-Neto (Eds.). Ecologia de Peixes de Riachos. Rio de Janeiro, PPGE-UFRJ, 260p.

[26] Rosa, R. S. 1985. A systematic revision of the South American freshwater stingrays (Chondrichthyes: Potamotrygonidae). Unpublished Ph.D. Dissertation, School of Marine Sciences, Virginia, 523p.

[27] Rosa, R. S., P. Charvet-Almeida & C. C. D. Quijada. 2010. Biology of the South American Potamotrygonid Stingrays. Pp. 241-281. In: Carrier, J. C., J. A. Musick & M. R. Heithaus (Eds.). Sharks and their relatives II: biodiversity, adaptive physiology, and conservation. Boca Raton, CRC Press, 616p.

[28] Sabino, J. 1999. Comportamento de peixes em riachos: uma abordagem naturalística. Pp. 183-208. In: Caramaschi, E. P., R. Mazzoni & P. R. Peres-Neto (Eds.). Ecologia de Peixes de Riachos. Rio de Janeiro, PPGE-UFRJ, 260p.

[29] Sazima, I. 1986. Similarities in feeding behaviour between some marine and freshwater fishes in two tropical communities. Journal of Fish Biology, 29: 53-65.

[30] Silliman, W. R. & S. H. Gruber. 1999. Behavior biology of the spotted eagle ray, Aetobatus narinari (Euphrasen, 1790) in Bimini, Bahamas; an interim report. Bahamas Journal of Science, 7: 13-20.

[31] Silva, T. B. & V. S. Uieda. 2007. Preliminary data on the feeding habits of the freshwater stingrays Potamotrygon falkneri and Potamotrygon motoro (Potamotrygonidae) from the Upper Paraná River basin, Brazil. Biota Neotropica, 7: 183-188.

[32] Silva, J. P. C. B. & M. R. de Carvalho. 2011. A taxonomic and morphological redescription of Potamotrygon falkneri Castex & Maciel, 1963 (Chondrichthyes: Myliobatiformes: Potamotrygonidae). Neotropical Ichthyology, 9: 209-232.

[33] Simpfendorfer, C. A. & M. R. Heupel. 2004. Assessing habitat use and movement. Pp. 553-572. In: Carrier, J. C., J. A. Musick & M. R. Heithaus (Eds.). Biology of Sharks and their Relatives. Boca Raton, CRC Press, 596p.

[34] Sisneros, J. A. & T. C. Tricas. 2002. Ontogenetic changes in the response properties of the peripheral electrosensory system in the Atlantic stingray (Dasyatis sabina). Brain, Behavior and Evolution, 59: 130-140.

[35] Smith, J. W. & J. V. Merriner. 1985. Food habits and feeding behavior of the cownose ray, Rhinoptera bonasus, in lower Chesapeake Bay. Estuaries, 8: 305-310.

[36] Steimle, F. W. & C. Zetlin. 2000. Reef habitats in the Middle Atlantic Bight: abundance, distribution, associated biological communities, and fishery resource use. Marine Fisheries Review, 62: 24-42.

[37] Teresa, F. B., R. M. Romero, L. Casatti & J. Sabino. 2011. Habitat simplification affects nuclear-follower foraging association among stream fishes. Neotropical Ichthyology, 9: 121-126.

[38] Vazzoler, A. E. A. M., A. A. Agostinho & N. S. Hahn. 1997. A planície de inundação do Alto Rio Paraná: aspectos físicos, biológicos e socioeconômicos. Maringá, EDUEM, 460p.

[39] Wetherbee, B. M. & S. H. Gruber. 1990. The effects of ration level on food retention time in juvenile lemon sharks, Negaprion brevirostris Environmental Biology of Fishes, 29: 59-65.

[40] Wetherbee, B. M. & E. Cortés. 2004. Food Consumption and Feeding Habits. Pp. 225-246. In: Carrier, J. C., J. A. Musick & M. R. Heithaus (Eds.). Biology of Sharks and their Relatives. Boca Raton, CRC Press, 596p.