Establishment and Characterization of Cell Lines from Homozygous Brachyury (T/T) Embryos of the Mouse

Lethal mutations in the T/t complex cause stage-specific morphologic abnormalities during early embryogenesis of mice. Although mutant embryos are lethal at the early stages of development, we have succeeded in establishing several cell lines from one of these mutants ( T/T ). Mutant-specific abnormality was not observed in gross morphology and growth patterns of cells. They, however, retained the characters of freshly dissociated embryonic cells to form smaller aggregates than the wild-type in rotation-mediated aggregation.
One of the T/T cell lines (T-1) formed tumors when injected into one-day-old syngeneic and allogeneic host, Expression of H-2 antigens was serologically studied with H-2 specificity 5 as a marker antigen. All lines except T-1 were shown to have this specificity.     

Protein Synthesis Initiated by Cell Fusion in Dictyostelium discoideum

D. discoideum has two alternative developmental pathways. If cells of two complement mating-type strains, NC4 and HM1, fuse sexually, a giant cell is produced which subsequently develops into a macrocyst, the sexual structure of this organism. However, if fusion fails to occur and cells are starved, a fruiting-body is produced instead of a macrocyst. In this paper, a two-dimensional polypeptide gel electrophoresis study showed that giant cells produce specific polypeptides which may possibly be involved in macrocyst development. Out of total 497 polypeptides which appeared in a giant cell during an incubation period of 13 hr, 92 were the specific for giant cells. Four of these polypeptides were appeared within only 1 hr after the cell fusion. The other 405 were non-specific polypeptides which appeared in both giant cells and NC4 or/and HM1 cells. However, the patterns and the rates of production of each polypeptide during the incubation period were different between these cells.     

STUDIES ON THE POLYSACCHARIDE-SULFATING SYSTEM IN SEA URCHIN EMBRYOS

The sulfating system in sea urchin embryos was examined, using the labeled precursor inorganic [³⁵S]sulfate in vivo and [³⁵S]3'-phosphoadenosine 5'-phosphosulfate ([³⁵S]PAPS) in a cell-free system. In vivo incorporation of [³⁵pS]sulfate into the trichloroacetic acid (TCA)-insolubte fraction increased gradually during sea urchin development, whereas radioactivity of [³⁵S]sulfate contained in the TCA-soluble fraction showed a conspicuous peak at the late gastrula stage.
In a cell-free system, the particulate fraction showed marked incorporation of [³⁵pS]JPAPS. This sulfating activity was highest at pH 6.4 to 7.2 and at 27°C, and it was strongly inhibited by Hg ²⁺and p-chloromercuribenzoic acid.
The sulfating activity was quite low in fertilized eggs, but then increased rapidly up to the swimming blastula stage. The activity in the particulate fraction precipitated at 10,000 xg increased gradually and that in the particulate fraction precipitated at 100,000 xg was almost constant from the swimming blastula stage to the pluteus stage.