Induction of the Synthesis of Melanin and Pteridine in Cells Isolated from the Axolotl Embryo: induction/melanin/pteridine/embryonic cells/axolotl

It has previously been reported that when LiCl and tyrosine is added to ectodermal cells isolated from the blastula of Ambystoma mexicanum, then the synthesis of melanin is initiated in cells not normally engaged in this activity (mesenchyme cells, nerve cells and undifferentiated animal cells). In the present paper it has been shown that to obtain this effect tyrosine (0.02 mM) has to be present in the culture medium during at least one of the first seven days of culture, thus several days before melanin is produced. It is concluded that the added tyrosine is acting as an inductor of, and not as a substrate for the synthesis of melanin. In the normal cultures it is possible to observe the spontaneous formation of yellow cells, indicating that they have produced pteridine. These cells are spherical, suggesting that they are undifferentiated embryonic cells. GTP is a precursor in the synthesis of pteridine, and in analogy with the observations made with tyrosine it was found that in the presence of LiCl a number of different cell types elaborate pteridine when GTP (0.1 mM) is added to the medium. Also in this case was it possible to show that GTP acts as an inductor, not as a substrate. Copyright © 1984, Wiley Blackwell. All rights reserve

Comparison of Area 17 Cellular Composition in Laboratory and Wild-Caught Rats Including Diurnal and Nocturnal Species

In this study we examine the size of primary sensory areas in the neocortex and the cellular composition of area 17/V1 in three rodent groups: laboratory nocturnal Norway rats (Long-Evans; Rattus norvegicus), wild-caught nocturnal Norway rats (R. norvegicus), and laboratory diurnal Nile grass rats (Arvicanthis niloticus). Specifically, we used areal measures of myeloarchitecture of the primary sensory areas to compare area size and the isotropic fractionator method to estimate the number of neurons and nonneurons in area 17 in each species. Our results demonstrate that the percentage of cortex devoted to area 17 is significantly greater and the percentage of cortex devoted to S1 is significantly smaller in the diurnal Nile grass rat compared with the nocturnal Norway rat groups. Further, the laboratory rodent groups have a greater percentage of cortex devoted to auditory cortex compared with the wild-caught group. We also demonstrate that wild-caught rats have a greater density of neurons in area 17 compared to laboratory-reared animals. However, there were no other clear cellular composition differences in area 17 or differences in the percentage of brain weight devoted to area 17 between nocturnal and diurnal rats. Thus, there are differences in primary sensory area size between diurnal versus nocturnal and laboratory versus wild-caught rat groups and cellular density between wild-caught and laboratory rat groups. Our results demonstrate that the differences in the size and cellular composition of cortical areas do not fit with what would be expected based on brain scaling differences alone, and have a consistent relationship with lifestyle and sensory morphology