Muscle growth in yolk‐sac larvae of the Atlantic halibut as influenced by temperature in the egg and yolk‐sac stage

Atlantic halibut eggs and yolk‐sac larvae were incubated at 1, 5 and 8° C. Eggs incubated at 8° C gave slightly shorter larvae at hatching with a significantly smaller total cross‐sectional area of white muscle fibres than eggs incubated at 5° C. Transport of eggs 2 days prior to hatching gave significantly longer larvae at hatching with a significantly larger red fibre cross‐sectional area than when eggs were transported shortly after the blastopore closure. A higher survival until 230 degree days after hatching was also observed in the former group. All eggs incubated at 1° C died before hatching and all larvae incubated at 1° C died before 45 degree days after hatching. From hatching until 230 degree days the total white cross‐sectional area increased threefold in all temperature groups. The increase in white cross‐sectional area was entirely due to hypertrophy between hatching and 150 degree days (10 mm L S ). Recruitment of new white fibres increased in germinal zones at the dorsal, ventral and lateral borders of the myotome from 150 degree days onwards, but at 230 degree days (12–13 mm L S ) the recruitment fibre zone constituted <10% of the total white cross‐sectional area. Larval incubation at 8° C gave slightly longer larvae with a significantly larger cross‐sectional area of recruitment fibres at 230 degree days than incubation at 5° C. The larval group incubated at 8° C also had a significantly lower survival until 230 degree days than did the 5° C group. Incubation temperature regimes did not affect the volume density of myofibrils in the axial muscle fibres at 230 degree days. Thus hypertrophy is the predominant mechanism of axial white muscle growth in Atlantic halibut yolk‐sac larvae and an increased rearing temperature during the yolk‐sac stage increases white muscle fibre hyperplasia.