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Neotropical Ichthyology

versão impressa ISSN 1679-6225versão On-line ISSN 1982-0224

Neotrop. ichthyol. v.5 n.2 Porto Alegre  2007

https://doi.org/10.1590/S1679-62252007000200007 

Swimming performance of the migratory Neotropical fish Leporinus reinhardti (Characiformes: Anostomidae)

 

 

Hersília de Andrade e SantosI; Paulo dos Santos PompeuII and Carlos Barreira MartinezI

ICentro Federal de Educação Tecnológica de Minas Gerais, Campus II, Av. Amazonas, 7675, Nova Gameleira, 305000–000 Belo Horizonte. MG. Brazil. hersilias@yahoo.com.br
IIUniversidade Federal de Lavras, Departamento de Biologia, Ecologia. 37200–000 Lavras, MG, Brazil

 

 


ABSTRACT

The fishways built in Latin America were mainly based on those used in the northern hemisphere for passing salmonids upstream. However, the swimming capacity in terms of speed and endurance is a major factor concerning the design of a fishway, and this information is not available for migratory neotropical fish species. Therefore, studies on swimming performance of neotropical species is fundamental. The aim of this study was to estimate the critical, sustained and prolonged speeds for the piau–três–pintas Leporinus reinhardti, and to evaluate the influence of water temperature on the swimming performance of the species. Variable (increasing) and fixed velocity tests were performed in a respirometer. When compared to other species whose critical speed data are available, the piau showed higher speeds, for a given total length. Fatigue times per prolonged speed class were estimated as well as prolonged speed per fatigue time class. The changing point from sustained to prolonged swimming was estimated to occur approximately at a speed of seven body–lengths per second (1.12 m/s for an individual with 16 cm total length: the first maturation length). In spite of the great swimming performance of piau, the adoption of efficient directives in fishway projects to allow the passage of neotropical ichthyofauna, will depend on a more detailed analysis of the swimming capacity of different species.

Key words: Prolonged speed, Critical speed, Sustained speed, Fishway.


RESUMO

As passagens para peixes construídas na América Latina são principalmente baseadas nos dispositivos existentes no hemisfério norte que, por sua vez, foram dimensionados para salmonídeos. Entretanto, a capacidade natatória das espécies migradoras, em termos de resistência e velocidade, é o principal fator a ser considerado no dimensionamento de uma passagem para peixes e estas informações ainda não são conhecidas para as espécies migradoras neotropicais. Dessa forma, o estudo da capacidade natatória das espécies neotropicais tornou–se uma necessidade. Este estudo tem como objetivo estimar as velocidades crítica, sustentável e prolongada do piau–três–pintas, Leporinus reinhardti, bem como avaliar a influência da temperatura da água na capacidade natatória. Testes de velocidade variável e fixa foram desenvolvidos em um aparato experimental do tipo respirômetro. Quando comparado a outras espécies, cujos dados de velocidade crítica são disponíveis, observa–se que o piau apresenta velocidades superiores para um mesmo comprimento total. Tempo de fadiga por classe de velocidade prolongada foram obtidos bem como a velocidade prolongada por classes de tempo de fadiga. O ponto de mudança do modo sustentável para o modo prolongado de natação foi estimado ocorrer em, aproximadamente, sete comprimentos por segundo (1.12 m/s para indivíduos com 16 cm de comprimento total: comprimento de primeira maturação). Apesar da grande capacidade natatória do piau, a adoção de critérios eficientes para o projeto de mecanismos de transposição para peixes neotropicais dependerá de análise detalhada da capacidade natatória de diferentes espécies.


 

 

Introduction

The blockage of rivers causes intense modifications in aquatic environments and related communities (Sale, 1985). Dams built for the purpose of hydroelectric power are the main reason for such impacts. The new environment formed presents distinct characteristics compared to the original river, and communities undergo significant changes. An unavoidable result is the alteration in abundance and richness of species, with proliferation of some and reduction of others or even elimination of certain species (Agostinho, 1994). Among the aquatic communities, the impacts on fish should be carefully considered because they are easily observed in the environment and they have economic value (fisheries), in addition to their vulnerability to changes in other components of the aquatic system.

Dams represent obstacles to fish species that need to migrate to complete their life cycle, altering recruitment in their populations. However, only a fraction of neotropical species is in fact migratory (Petrere Jr., 1985; Godinho & Godinho, 1994), but they are the most important for professional (Goulding, 1979; Bittencourt & Cox–Fernandes, 1990; Godinho, 1993) and sport fisheries in South America, due to their larger sizes and abundance (Northcote, 1978).

Many alternatives considered to minimize the adverse effects of barriers on fish migration have been proposed and implemented, such as the construction of fishways. These are basically water conduits (open or closed), where the hydraulic energy is dissipated by internal obstacles, to facilitate fish moving through it without excessive stress. The first fishways built in Latin America followed the design used in the northern hemisphere for passing salmonids upstream (Quirós, 1989). However, neotropical fish are different from those found in the northern hemisphere (Clay, 1995), considering migratory strategies and the swimming behavior. Since the swimming capacity in terms of speed and endurance is a major factor concerning the design of a fishway (Beach, 1984), it is possible to determine whether it has a negative influence on the efficiency of the fishways already built in South America. Consequently, studies of the swimming performance of the main neotropical species are mandatory for the improvement of neotropical fish passage design, and this represents a great challenge, because South America species richness encompasses approximately 4,500 fish species (Reis et al., 2003).

Usually, fish swimming can be divided into three categories: sustained, burst and prolonged speeds (Beamish, 1978). Sustained swimming contains a spectrum of swimming speeds that can be maintained for an indefinite period of time, longer than 200 min, and fatigue is not involved. Burst swimming involves rapid movements of short duration, less than 15–20 min, and high speeds. This kind of swimming uses anaerobic processes. Prolonged swimming covers a spectrum of speeds between burst and sustained and have more often been measured in the laboratory. The main subcategory is the critical speed, which was first defined and employed by Brett (1964). Critical swimming speed is a common measure of the relationship between exercise intensity and duration within the prolonged performance envelope (Peake, 2004).

In Latin America, fish communities in large rivers comprise mainly siluroids and characins (Quirós, 1989). Piaus (Anostomidae) are some of the main representatives of the order Characiformes. Their distribution is wide on the continent, inhabiting large river basins (main channel and tributaries), including the Magdalena and Atrato rivers in Colombia, Orinoco River and the Maracaibo lake system in Venezuela and the drainage systems of Brazil, from Amazon to the south of Buenos Aires in Argentina. Some members of the genera Leporinus perform spawning migrations in the Paraná–Paraguay system (Godoy, 1967), São Francisco River basin (Sato et al., 1987), and in the Amazon and Orinoco basins (Goulding, 1979). These migratory species are exploited in commercial and subsistence fisheries as an important food item for people (Goulding, 1979; Bittencourt & Cox–Fernandes, 1990; Godinho, 1993). The piau–três–pintas (Leporinus reinhardti) is a middle–sized migratory species, abundant along the entire São Francisco River basin, including tributaries (Alves & Pompeu, 2005). Therefore, aim of this study was to estimate the critical, sustained and prolonged speeds for the piau–três–pintas L. reinhardti, and to evaluate the influence of water temperature on the swimming performance of the species.

 

Materials and Methods

Individuals of piau–três–pintas (L. reinhardti) were captured during 2005, in the São Francisco River near Três Marias Dam, Minas Gerais State, Brazil. In the laboratory, the fish remained for at least 24h in the maintenance system before tests. Two types of swimming performance tests were carried out: variable (increasing) and fixed velocities. The first gives critical speed whereas the second gives prolonged and sustained speeds.

To determine critical speed, 40 tests were performed between February and April of 2005, among which 25 were considered for statistical analysis. Tests were discarded when fish either refused to swim or fatigued immediately after tests started. For these tests, the fish sizes were selected to provide different size classes (Fig.1).

 

 

To measure prolonged and sustained speeds, we conducted 30 tests, between October and December of 2005, among which 27 were considered for statistical analysis. Considering the purpose of the study, we selected individuals with total length over 16 cm (Fig. 2), because this is the size of first maturation (according to Rizzo et al. (1996); 12.9 and 14.0 cm standard length for males and females, respectively) estimated for the Três Marias region.

 

 

Each individual was tested once and after the test it was measured, weighed and the condition factor calculated according the equation 1. After seven days in the laboratory, the fish that had already been tested were returned to the river where they were captured.

 

 

The experimental apparatus used to measure swimming capacity of the piau–três–pintas was constructed based on the respirometer developed by Brett (1964). It is a hydrodynamic tube with 150 mm nominal diameter. Its central part is a chamber made of plexiglas which allows visualization of the fish. The flow is driven by two centrifugal pumps with water taken from a reservoir (Santos et al., in press).

The increasing velocity test was based on the experimental procedure of Brett (1964) and the values of critical speed were calculated according to the following expression:

 

 

where Vmax is the maximum speed, tmax the time during which the fish swam in the last time interval, Dt the time interval and DV the speed increment .

Tests started with the acclimation of fish to the water temperature of the respirometer and its introduction to the central chamber. Pumps were turned on and, after a period of 10 min, the water speed was increased in steps of 5 cm/s (DV), each lasting 5 min (Dt). These increments were based on the possibilities of speed control of the apparatus and the total time of the test. After successive speed increases, the fish would no longer resist the flow, due to fatigue, which was considered as the moment when the fish could no longer swim in the test chamber, after several burst attempts. We measured the time which the fish swam at such speed (Vmax) until its fatigue.

Fixed velocity tests were based on the method used by Brett (1967) and Jones et al. (1974). Chosen for these tests were percentage values of the estimated critical speed (1.32 m/s) for an individual with a total length of 16 cm (Table 1). For this analysis, the speed in meters per second (m/s) was transformed into length per second (length/s), dividing the velocity established in the apparatus by the total length of the fish.

 

 

Every parameter measured inside the hydrodynamic tube required corrections, because its walls cause effects on measurements (Webb, 1975). The solid blocking effect that occurs due to the obstruction of the flow by the body of the fish in the chamber was corrected for each test (performed in increasing and fixed velocity) according to the equation proposed by Rae & Pope (1966):

 

 

where K3 is the shape factor, t1the factor considering the layout of the cross–section of the chamber (circular sections t1 = 0.8), C the cross–sectional area of the chamber, e the maximum widthof the fish (the mean between the maximum width and height) and L the length of the fish.

During all tests, water quality inside the apparatus was continuously monitored (pH, dissolved oxygen and temperature). The relationships between the critical speed and the length (total and standard), weight and condition factor of the fish and water temperature were tested by linear regressions (variables were natural logarithm transformed). The same procedure was adopted for the relationships between prolonged speed and fatigue time as well as fatigue time and percentage of fatigued fish. Statistical significance was implied when P < 0.05. The coefficient of determination was used as a criterion to identify the best model. All analyses were performed using the software Statistica™.

From the relationships between critical speed, fish size and temperature, speed versus fish size curves for lower temperatures were estimated for L. reinhardti. The swimming performance of L. reinhardti was compared with the data from the temperate zone presented in the literature. For the species studied, we used the data obtained in the laboratory as well as the estimation for 20, 15 and 10 oC.

 

Results

In all tests performed, the water quality in the experimental apparatus was considered good for fish, with dissolved oxygen concentrations greater than 5 mg/l, temperatures ranging from 24 to 28 ºC and pH ranging from 6 to 9.

Increasing velocity tests

The results of the increasing velocity tests showed significant relationships between the critical speed, total and standard lengths and body weight. However, the total length was the variable with the greatest significance (greater value of the coefficient of determination) (Fig. 3). On the other hand, there was no relationship between condition factor and critical speed.

 

 

Temperature, when associated with the total length, despite its slight variation during the tests, also influenced the critical speed shown by the species (R2 = 0.48 and P–value < 0.001).

When compared to other species whose critical speed data are available, we observed that the piau shows superior speeds, for an equal total length (Fig. 4). Table 2 shows the experimental conditions in which such curves were obtained and their statistical parameters.

 

 

When we estimated the critical speeds that would be developed by this species for lower temperatures (20, 15 and 10ºC), we obtained speed curves close to those of the salmonids Salmo salar and Oncorhynchus nerka, for the same temperature range (Fig. 5).

 

 

Fixed Velocity Tests

Fatigue times per prolonged speed class (Fig.6) were estimated as well as prolonged speed per fatigue time class (Fig.7). It was possible to establish by these relationships the point of change from sustained to prolonged swimming. If, according to Brett (1967), a speed can be held by the fish for more than 200 min, it is accepted as continuous (sustained or aerobic endurance) swimming. This change was estimated to occur approximately at a speed of seven lengths per second for the piau (Fig. 6). For an individual of the first maturation size (16 cm), this speed would be approximately 1.12 m/s.

 

 

 

 

The percentage of fatigued fish for a given swimming time was also obtained for the speeds of 6.8, 9.2 and 10.7 lengths per second. For each of these speeds, the times in which 50% of the tested individuals fatigued were 155, 45 and 17 min, respectively (Fig. 8).

 

 

Discussion

The results obtained in the present paper for the piau três–pintas, Leporinus reinhardti, were the first speeds measured in the laboratory for a species of such genus. So far, only some qualitative observations were known concerning Leporinus friderici, when passing by a rapid with flow speed of 13 m/s (Godoy, 1985). Despite the limitations of this finding, since there is no knowledge about the size of the fish and the type of speed performed to overcome such flow speed barrier, the value greatly differed from the values described in this study. According to Brett (1967), burst swimming can be held for 20 s. For piau, speed higher than 10.76 length/s was burst velocity, obtained from the prolonged speed curve to fatigued time of 20 s. The values of burst speed estimated from the maximum sizes of L. reinhardti (23 cm: Alves & Pompeu, 2004) and L. friderici (40 cm: Reis et al., 2003), correspond to 2.47 m/s and 4.30 m/s, respectively.

However, the speeds developed by fish inside the respirometer, such as Brett's, are lower than those determined in natural conditions of migration. This difference is due to the behavioral refusal of confined fish to swim to complete physiological exhaustion, and/or differences in the energetic costs associated with confined and unconfined swimming (Peake, 2004). Besides, at the end of the step tests, fishes swim rapidly and probably anaerobically, whereas during endurance tests, fishes swim relatively slowly and most of them probably swim aerobically (Kolok, 1992). Consequently, step tests tend to underestimate the endurance of fishes by pre–exhausting them at anaerobic levels. Another explanation for the observed difference lies in the fact that the point where Godoy (1985) determined the flow speed (13.8 m/s), probably does not correspond to the passing region of L. friderici. Facing speed barriers, fish negotiate their passage in a region of lower flow speeds, or a region where speeds are within their swimming capability.

The same behavior leads, several times, to a separation of species in the transversal speed profile of a water course. In Brazilian rivers, this separation is clear when we compare bottom dwelling species, such as the mandi–amarelo (Pimelodus maculatus), to those that prefer the water–column such as Leporinus reinhardti. The difference between the swimming capacities of these two species is significant. In the case of the mandi–amarelo, an individual with 15 cm total length swims at 1.10 m/s in critical prolonged mode (Santos et al., in press), whereas a piau with the same length swims at 1.28 m/s. However, despite the fact that the swimming speeds of bottom fishes are typically slower when compared to fish that swim in the middle of the water column, the migratory progress of both groups relative to the river banks is roughly equivalent (Pavlov, 1989), due to transversal speed profile differences.

Compared to other critical speed studies, the curves obtained for the piau showed higher R2 values, despite the low number of individuals tested. The strong relationship between critical speed and total length reflects the importance of the caudal fin, an important propulsion element in fish which has a subcarangiform type of locomotion pattern (Webb, 1994), such as in the case of the Anostomidae.

In the tests, the piau showed higher critical speeds when compared to several species from the temperate zone. The measurement of critical speed values depends on an array of factors, such as the experimental procedures and the water temperatures during the tests which mainly influence the process to attain this velocity. According to Hammer (1995), this dependence may make the comparisons between critical speeds among species susceptible to errors. Considering the procedures of our experiments, speed increments (DV) and time increments (Dt) significantly influenced the values of the critical speeds (Farlinger & Beamish, 1977). However, the differences between the experimental procedures could not explain the variations observed in the values of critical speed. According to Farlinger & Beamish (1977), if we adopted a Dt of 60 min and a DV of 10 cm/s, the outcome of the critical speed would be only 6% lower. If Dt was 10 min and DV was 10 cm/s, the critical speed would be greater than that obtained with Dt of 5 min and DV of 5 m/s. Therefore, the experimental procedures do not explain the differences observed between the piau and the species from the temperate zone.

Although there was a small variation in temperature, it explained 30% of the critical speed measured for the piau. Temperature is considered the main environmental factor related to the swimming performance of fish (Videler, 1993). Generally, within the thermal range of tolerance for a given species, prolonged speeds increase with temperature to a maximum (optimum temperature) and thereafter decline (Beamish, 1978).

The effects of temperature on fish swimming can be divided into physical and physiological effects. The first is due to changes in water properties, such as specific mass and viscosity, capable of altering the swimming kinematics through drag forces (White, 2002). The physiological effects are generally attributed to differences in molecular kinetics and the rates of the biochemical reactions that convert chemical energy into propulsive thrust (Beamish, 1978). The relationship found between water temperature and speed of the piau is in accordance to the variations encountered for tests performed in species from the temperate region. In general, a decrease of approximately 10 oC in water temperature, promotes a decrease ranging from 24 to 37% in swimming capacity (Gibson & Fry, 1954; Brett, 1964; Otto & Rice, 1974; Glova & McInerney, 1977).

The physical effects will be stronger for fish swimming in a viscous hydrodynamic regime and will be negligible in an inertial regime (Fuiman & Batty, 1997). When the dimensionless Reynolds number (Re) is more than 1000, the viscous force can be ignored. Routine swimming speeds of most adult fishes, over a large range of sizes, are equivalent to the inertia hydrodynamic regime, with Re > 104 (Wu, 1977). Therefore, the physiological effects were probably the main cause for the significant differences between tests found for the speed of piau, which swims in higher temperatures than species from the temperate zone. Our results indicate too, that temperature changes, resulting from reservoir formation, may modify the piau speed during spawning migration.

Despite that the critical speed is a powerful tool to compare swimming capacity among species (Hammer, 1995), its use is limited, since this speed is lower than the speed developed in open channels (Peake, 2004), and it also has little biological significance. Endurance tests provide a more accurate measure of the swimming ability of a fish for a certain time span, for a given speed (Kolok, 1992). Thus, for the dimensioning of fish passage mechanisms, it is common to use prolonged speeds (Katopodis, 2005), which allows the acquisition of specific information on how long (endurance time) or how far (swimming distance) a particular fish can swim against a given water velocity (Katopodis, 1992). From the data obtained for Leporinus reinhardti, it is possible to estimate the mean velocity inside a fish ladder needed for a fish to ascend it, reaching the reservoir in a certain time. For example, the maximum flow speed inside a 100 m fish ladder should be 1.06 m/s, since a 16–cm long (total length) individual can swim 7 lengths per second (1.12 m/s – minimum value of prolonged speed) and the time limit to ascend the ladder would be 30 min.

Due to the lack of basic information on the biology of neotropical migratory species, important biological factors were not considered in fishway projects in South America. However, the high swimming capacity of the piau Leporinus reinhardti explained the success of genera in ascending fishways constructed in Brazil. Species of Leporinus are often abundant in fishways, sometimes with higher abundance than the large–sized migratory species, such as the dourado (Salminus spp.) and the curimatã (Prochilodus spp.) (Fernandez et al., 2004; Vono et al., 2004; Bizzoto, 2006; Pompeu, 2006). However, it is possible that the swimming capacity of this genus is greater than that of other migratory Characiformes. At Santa Clara Dam (in Mucuri River, Minas Gerais State), 16.1% of the individuals of Leporinus conirostris downstream from the dam passed through the fishway, against only 5.7 % of Prochilodus vimboides and 3.1 % of other species (Pompeu, 2005). These findings indicate the great capacity of the piau in overcoming the obstacles represented by a fishway.

It is also important to consider that the maximum flow speeds (2 m/s) established for South American fishways were based, mainly, on the swimming capacity of salmonids, which, despite having an inferior speed for a given size, can be faster due to their larger size as adults. The burst speed (1.72 m/s), maintained for 20 s by a piau of 16 cm is smaller than the guideline velocity used in fishway designs. Therefore, piau individuals will not be able to ascend passages using the 2 m/s criterion, in spite of its great swimming performance.

The adoption of efficient directives in fishway projects, to allow the passage of neotropical ichthyofauna, will depend on a more detailed analysis of the swimming capacity of different species. Similar studies for Prochilodus and Salminus species are necessary because they represent a great part of the biomass in rivers and are important for the fisheries in South American rivers (Welcomme, 1985).

However, the data obtained for Leporinus reinhardti represent an important contribution to the knowledge about the species, and they were added to the current "Ichthyomechanical Data Base." This database provides guidance and criteria for designing several structures, such as fishways, fish screens and other systems and provides estimates of the range of swimming performance for several fish species and sizes (Katopodis, 2005).

 

Acknowledgments

We are grateful to CEMIG for the logistics and financial support. Special thanks go to César Augusto Muniz Toledo and Lívia Duarte Ventura Melo, students who helped us in the experimental tests, and to Geraldo Garcia, Vicente Pimenta and Paulo Roberto, workers who helped us in the construction of experimental apparatus.

 

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Received January 2007
Accepted June 2007

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