Abstract
Animals inhabiting extreme environments allow the powerful opportunity to examine adaptive evolution in response to diverse pressures. One such pressure is reduced oxygen, commonly present at high-altitude and subterranean environments. Cave-dwelling animals must also deal with darkness and starvation, both of which have been rigorously studied as key forces driving the evolution of cave-associated traits. Interestingly, hypoxia as an environmental pressure has received less attention. Here we examined putatively adaptive phenotypes evolving in a freshwater teleost fish, Astyanax mexicanus, which includes both surface- and cave-dwelling forms. This model system also provides the opportunity to identify convergent responses to hypoxia, owing to the presence of numerous natural and independently-colonised cave populations, alongside closely-related surface conspecifics. The focus of this study is hemoglobin, an essential molecule for oxygen transport and delivery. We found that multiple cave populations harbor a higher concentration of hemoglobin in their blood, which is coincident with an increase in cave morph erythrocyte size compared to surface fish. Interestingly, both cave and surface morphs have comparable numbers of erythrocytes per unit of blood, suggesting elevated hemoglobin is not due to overproduction of red blood cells. Alternatively, owing to an increased cell area of erythrocytes in cavefish, we reason that they contain more hemoglobin per erythrocyte. These findings support the notion that cavefish have adapted to hypoxia in caves through modulation of both hemoglobin production and erythrocyte size. This work reveals an additional adaptive feature of Astyanax cavefish, and demonstrates that coordinated changes between cellular architecture and molecular changes are necessary for organisms evolving under intense environmental pressure.
Highlights
Animals inhabiting extreme environments allow the powerful opportunity to examine adaptive evolution in response to diverse pressures
Diverse cellular features could conceivably contribute to increased hemoglobin concentration, so we examined cellular features of erythrocytes
Erythrocyte area demonstrated a strong positive correlation with hematocrit (r = 0.869, Fig. 5b), suggesting that variation in elevated hematocrit across Astyanax cavefish populations is a function of erythrocyte size. We evaluated this further by calculating mean corpuscular hemoglobin (MCH, “Material and methods”), a metric that integrates hemoglobin concentration with erythrocyte density to estimate the mass of hemoglobin in a single red blood cell
Summary
Animals inhabiting extreme environments allow the powerful opportunity to examine adaptive evolution in response to diverse pressures. We examined putatively adaptive phenotypes evolving in a freshwater teleost fish, Astyanax mexicanus, which includes both surface- and cave-dwelling forms This model system provides the opportunity to identify convergent responses to hypoxia, owing to the presence of numerous natural and independently-colonised cave populations, alongside closely-related surface conspecifics. A powerful natural model to study adaptation in extreme environments is the blind Mexican cavefish, Astyanax mexicanus (Fig. 1a) This species allows for direct comparisons of two extant morphotypes, a river-dwelling ‘surface’ morph and obligate subterranean ‘cave’ morphs. Empirical measurements of dissolved oxygen have been conducted in two El Abra caves, Pachón and Tinaja, which demonstrate significantly lower oxygen levels in cave pools compared to surrounding surface waters (DO = 2.97 mg/L in the Pachón cave compared to 8.20 mg/L in the surface environment (Rascón); 59% saturation in the Tinaja cave compared to 80% saturation in the surface environment (Nacimiento del Río Choy)[8,9] This environmental feature has most likely impacted. Complex responses to hypoxia include behavioral changes (decreased predator avoidance in grey mullets16), morphological changes (gill remodeling in crucian carp17) and molecular changes (increased expression of the oxygen sensing gene HIF-1 in zebrafish[18])
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