Abstract
WE reported recently on the properties of the deoxyribonucleic acids isolated from the egg, sperm and adult diploid tissues of the American sea urchin, Arbacia punctulata1. It was found that the DNA isolated from the two haploid cells had similar buoyant densities of 1.700 g/cm3. This can be taken to mean that the DNAs from these sources have identical base compositions2. On the other hand, the DNA derived from adult diploid cells exhibited a buoyant density of 1.702 g/cm3. If this difference in the density values of the haploid and adult diploid cells reflects a real shift in base composition, it is indeed a most unexpected finding. The current ideas concerning cellular development and differentiation are based on the belief that just as the adult diploid cells derive from the original zygote by orderly mitotic division, so the DNA from the adult cell is derived from the fertilized egg by exact replicative cycles. Because the DNAs of sperm and egg have identical base compositions, this belief would lead to the prediction that a diploid cell resulting from this union would contain DNA with a correspondingly identical base composition. Implied in this concept is the hypothesis that cellular differentiation is not the result of changes in the DNA but rather that it is controlled by histone-masking and/or “cytoplasmic regulators” which have now been equated with messenger RNA.
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ROSENKRANZ, H., CARDEN, G. DNA during the Development of the American Sea Urchin. Nature 213, 1024–1025 (1967). https://doi.org/10.1038/2131024a0
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DOI: https://doi.org/10.1038/2131024a0
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