Normoxia exposure reduces hemoglobin concentration and gill size in a hypoxia-tolerant tropical freshwater fish

Abstract

Hypoxia is a widespread environmental stressor that shapes fish physiology and morphology. Plasticity in traits that improve oxygen uptake and delivery or reduce oxygen requirements may be critical for fish to cope with fluctuating dissolved oxygen (DO) conditions in their natural habitat or adapt to new environments. In this study, we characterized a suite of morpho-physiological respiratory traits of a naturally hypoxia-acclimated weakly electric mormyrid fish, Petrocephalus degeni, and quantified their plasticity in response to long-term normoxia exposure. We captured P. degeni from a hypoxic swamp habitat (PO2 = 2.43 ± 1.85 kPa) surrounding Lake Nabugabo, Uganda, and acclimated them to normoxia (PO2 > 16 kPa) for up to 75 days. At various time points throughout normoxia exposure, we measured blood hemoglobin and lactate concentration, gill size, routine metabolic rate (RMR), regulation index (RI), and critical oxygen tension (P crit). We found that 62–75 days of normoxia exposure significantly reduced blood hemoglobin concentration (− 17%), gill filament length (− 14%), and hemibranch area (− 18%), whereas RMR, RI, P crit, and blood lactate showed no significant change. Our results support earlier findings that swamp-dwelling P. degeni are well adapted to life in chronic and severe hypoxia and indicate that they possess a limited capacity for phenotypic plasticity in response to a change in their DO environment.