Gail L. Williamson scite author profile

Gail L. Williamson

3Publications

3Citation Statements Received

63Citation Statements Given

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Mount Holyoke College

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Life‐cycles of lotic populations of Spongilla lacustris and Eunapius fragilis (Porifera: Spongillidae)

Williamson

1979

Freshwater Biology

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The life-cycles of green and white morphs of the freshwater sponge Spongilla lacustris were examined in the light of past evidence that zoochlorellae may augment their sponge host's nutrition. Field collections from a lotic population of S. lacustris were supplemented by laboratory experiments on gemmule hatching and gemmule size. Both white and green S. lacustris produced sperm for a 6-week period in 1976 starting in the middle of May. Out of thirty white and thirty green sponges examined during this period, twenty white and ten green sponges contained sperm. Sperm production in both morphs was limited primarily to the basal 3.18 mm of sponge tissue, and the density of sperm packets in the two morphs was the same. Out of 180 white and green sponges examined in 1976, only four eggs, no embryos, and no larvae were observed. White sponges gemmulated a week or two earlier, and produced smaller gemmules which were more uniform in size than those of green sponges. White and green gemmules hatched synchronously in the spring. In 1977 one female and numerous male specimens of S. lacustris, and numerous females but no males of another sponge, Eunapius fragilis, were found. The life-cycles are discussed in the hght of other recent studies on freshwater sponges.

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Compositional Changes of the Corticopapillary Osmotic Gradient during Dehydration in the Absence of Vasopressin

Williamson¹,

Edwards²

1984

Kidney Blood Press Res

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Despite the absence of vasopressin, Brattleboro homozygous (DI) rats concentrate their urine to hypertonic levels when deprived of drinking water. Ultimately this rise in urine osmolality must follow from increased osmolality of the corticopapillary gradient and/or increased osmotic equilibration across the collecting ducts. In this study we examined the concentrations and contents of total solute, urea, and nonurea solute in tissue from cortex to papillary tip of DI rats before and after dehydration for 12, 24, and 48 h. The greatest increase in osmolality occurred during the first 12 h; both urea and nonurea solute concentrations increased, but urea preferentially. From 12 to 48 h there were only small further increases in these concentrations, largely as a result of decreased tissue water content. Osmotic equilibration (reflected by urine/papillary tip osmolality) increased dramatically during dehydration, presumably because of decreased flow rate, attaining full equilibration by 48 h. The rise in urine osmolality during the first 12 h of dehydration was due to increased osmotic equilibration and to the enhanced corticopapillary gradient; urine became more concentrated from 12 to 48 h largely as a result of increased osmotic equilibration.

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Changes in the Corticopapillary Osmotic Gradient During Prolonged Dehydration of the Brattleboro Rat*

Williamson¹,

Edwards²

1982

Annals of the New York Academy of Sciences

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