ABSTRACT
Understanding the effects of environmental factors on sperm motility characteristics can increase artificial reproduction efficiency in species that do not spawn naturally in captivity, such as Megaleporinus obtusidens. This study evaluated the effects of the osmolality (25, 85, 145, 205, 265, and 325â¯mOsmâ¯kg-1) and composition of activating solutions (NaCl, KCl, or fructose) on the percentage of motile sperm, and the swimming velocity and path straightness of M. obtusidens spermatozoa. The concentrations of major ions in the seminal fluid were also assessed and Na+ (74.46â¯mmolâ¯L-1), K+ (37.24â¯mmolâ¯L-1), and Cl- (114.29â¯mmolâ¯L-1) were the most abundant. When the activating solution was hypertonic (325â¯mOsmâ¯kg-1) compared to the seminal fluid (293â¯mOsmâ¯kg-1), sperm motility was completely inhibited. A wide range of osmolalities that initiated sperm motility were identified for all three solutions. Both, the percentage of motile sperm and the motility duration were reduced (Pâ¯<â¯.05) at extreme osmolalities. At 145â¯mOsmâ¯kg-1, the percentage of motile sperm remained high (>50%) up to 40â¯s after activation and the motile phase lasted for >50â¯s, regardless of the activating solution composition. Over the postactivation time, the curvilinear velocity and straightness were similar (Pâ¯>â¯.05) for fructose and NaCl solutions, whereas KCl solutions induced a higher (Pâ¯<â¯.05) curvilinear velocity, lower (Pâ¯<â¯.05) straight-line velocity, and a circular swimming motion in spermatozoa. Our results suggest that a reduction in osmolality, using both non-electrolyte and electrolyte solutions, is the main trigger for the onset of spermatic movement in M. obtusidens sperm.