Air-breathing and movement ecology of Arapaima sp. in the Amazon

Stokes, Gretchen Louise

30 January 2017

The annual hydrological cycle of floodplains supports fishes that are uniquely adapted to optimize resources throughout the year. Such adaptations to changing environments include air-breathing for seasonally hypoxic waters and directed movements to best utilize habitats as they become available. This study examined the environmental, temporal and body-size influences on air-breathing behavior and movement ecology of Arapaima sp., one of the most economically and ecologically significant species in the Amazon. Acoustic (n=15) and radio (n=12) telemetry was used to study the influences on air-breathing and movement ecology of arapaima in the Central Amazon. Generalized additive mixed models showed that temperature was the most influential predictor of air-breathing intervals, followed by body size. The shortest breathing intervals were associated with consecutive "aggressive" breaths while the longest breathing intervals had consecutive "calm" breaths. Generalized linear mixed models showed that flood stage was the most important predictor of residency time, directional movement, and rate of movement. Fish moved faster in the flood and dry stages than the rising and falling stages, and spent longer in one place in the rising and falling stages than the flood and dry stages. Findings of this study may be used to inform management decisions for arapaima conservation, such as protected habitat and population counts, with applications to fishes across river-floodplain ecosystems globally. / Master of Science / The annual hydrological cycle of floodplains supports fishes that are uniquely adapted to optimize resources throughout the year as their environment changes. Such adaptations include air-breathing for seasons with low oxygen levels and directed movements (i.e. upstream, downstream) to best utilize habitats as they become available during the year. This study examined the environmental, temporal and body-size influences on air-breathing behavior and movement ecology of <i>Arapaima</i> sp., one of the most economically and ecologically significant species in the Amazon. Acoustic and radio telemetry was used to study the influences on airbreathing and movement ecology of arapaima in the Central Amazon. Model results showed that temperature was the most influential predictor of air-breathing intervals, followed by body size. The shortest breathing intervals were associated with consecutive “aggressive” breaths while the longest breathing intervals had consecutive “calm” breaths. Generalized linear mixed models showed that flood stage was the most important predictor of how long a fish spent in a given area, the direction in which it travels and the rate at which it moved. Fish moved faster in the flood and dry stages, and spent longer without moving in the rising and falling stages. Findings of this study may be used to inform management decisions for arapaima conservation, such as protected habitat and population counts, with applications to fishes across river-floodplain ecosystems globally.

Air-breathing fishes

river-floodplains

Amazon

arapaima

movement ecology

telemetry

Environmental Modulation of the Onset of Air-breathing of the Siamese Fighting Fish and the Blue Gourami

Mendez Sanchez, Jose Fernando

12 1900

This study determined the effect of hypoxia on air-breathing onset and physiological and morphological characters in larvae of the air breathing fishes Trichopodus trichopterus and Betta splendens. Larvae were exposed intermittently (12/12 h daily) to 20, 17, and 14 kPa of PO2 from 1 to 40 days post-fertilization. Survival, onset of air breathing, wet body mass, O2, Pcrit were measured every 5 dpf. Hypoxia advanced by 4 days, and delayed by 9 days, the onset of air breathing in Betta and Trichopodus, respectively. Hypoxia increased larval body length, wet mass, and labyrinth organ respiratory surface of Betta, but did not affect these factors in Trichopodus. Hypoxic exposure increased O2 by 50-100% at each day throughout larval development in Betta, but had no effect on larval Trichopodus. Hypoxia decreased Pcrit in Betta by 37%, but increased Pcrit in Trichopodus by 70%. Larval Betta reared in hypoxia showed a modified heart rate:opercular rate ratio (3:1 to 2:1), but these changes did not occur in Trichopodus. Compared to Betta, the blood of Trichopodus had a higher P50 and much smaller Bohr and Root effects. These interspecific differences are likely due to ecophysiological differences: Betta is a non- obligatory air-breather after 36 dpf with a slow lifestyle reflected in its low metabolism, while Trichopodus is an obligatory air-breather past 32 dpf with an athletic fast lifestyle and accompanying high metabolism.

environmental modulation

air-breathing onset

Siamese fighting fish

blue gourami

Siamese fighting fish -- Larvae.

Gourami -- Larvae.

Siamese fighting fish -- Ecophysiology.

Gourami -- Ecophysiology.

Air-breathing fishes -- Larvae.

Air-breathing fishes -- Ecophysiology.

Hypoxia (Water)