Abstract

AbstractThree red cell populations have been distinguished in genotypically low potassium (LK) newborn sheep by an improved electrical sizing method and were best approximated by a logarithmic normal distribution. Labeling studies with 51Cr and 59Fe exclude transformation of the three red cell populations into each other. Population I, consisting of large red cells (mean volume 36 μm3), with a comparatively slow electrophoretic mobility is present at birth and disappears within three to four weeks from circulation. These cells possess a high potassium (HK) steady state concentration, a K+ pump influx activity at least 5‐fold greater than observed in adult LK red cells, very low amounts of the L antigens generally associated with the LK property, and do not respond to the stimulatory action of the L antibody. The first population is gradually replaced by population II comprising small red cells (mean volume 28 μm3) of intermediate electrophoretic mobility and with a peak production around day 20 after birth. The potassium concentration, [K+]c, in these cells appears to be lower than in the cells of population I but the L antigen content is increased. Formation of population III (mean volume 30 μm3 and comparatively fast electrophoretic mobility) follows closely that of population II and is preceded by a sharp increase in reticulocytosis. The red cells of population III exhibit parameters characteristic for adult LK cells: low [K+]c and K+ pump activity, fully developed L antigen content, and an almost maximal response to the K+ pump stimulating effect of anti‐L. In L and M antigen positive LK red cells of newborn sheep, the development of the M antigen parallels that of the L antigen. The data are consistent with the hypothesis that cellular replacement and not maturation is the major factor in controlling the HK‐LK transition in newborn sheep.

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