In vitro correction of antigen-induced immune suppression: effects of poly(A) poly(U) and prostaglandin E

Incubation of SJL or DBA/1 mouse spleen cells with poly(lTyr, lGlu)-polylPro—polylLys, (T, G)-Pro—L in vitro reduced the immune response potential of the cells to this immunogen as tested by adoptive transfer into irradiated, syngeneic recipients, followed by immunization with (T, G)-Pro—L in complete Freund's adjuvant. This reduction in immunocompetence was antigen-specific, since incubation with another antigen (rabbit immunoglobulin G) did not result in a suppression of responsiveness of the cells to subsequent in vivo immunization with (T, G)-Pro—L. Incubation of the spleen cell-(T, G)-Pro—L mixture in the presence of either prostaglandin E₁(PGE₁) or polyadenylic-polyuridylic acid (poly(A)·poly (U)) restored the immune response potential to the normal level. Incubation of (T, G)-Pro—L with spleen cells had no effect on cyclic AMP accumulation, whereas incubation of PGE₁ with the cells stimulated cyclic AMP production, irrespective of the presence of antigens. In contrast, the level of cyclic AMP was not affected by poly(A) · poly(U). The difference in cyclic AMP accumulation suggests that PGE₁ and poly(A) · poly(A) modify immune responsiveness by different mechanisms. The above observations were verified both in SJL and DBA/1 mice, which are the respective genetic high and low responders to (T, G) -Pro—L. This implies that the modifications of responsiveness described are not related to the genetic control of immune response to this immunogen.     

Histochemical detection of l-gulonolactone: phenazine methosulfate oxidoreductase activity in several mammals with special reference to synthesis of vitamin C in primates

Summary An improved detection of activity of l-gulonolactone oxidase, which is responsible for the final oxidative step in the synthetic process of l-ascorbate from glucose in animals, was achieved using phenazine methosulfate and cyanide. Cold acetone fixation eliminated non-specific deposition of formazan on lipid droplets. The specificity of the method was tested and proven by a biological control, histochemical controls, inhibitors and activators. By application of the method, strong reactivity was found in the cytoplasm of centrilobular parenchymal cells of livers of the opossum, rat, ground squirrel and flying squirrel. Staining of dog liver was moderate and centrilobular. Prosimians were strongly positive: The centrilobular localization was found in the tree shrew and galago; slow lorises and some pottos showed strong reactivity in centrilobular cells and some peripheral cells as well. These prosimians seem to be able to synthesize l-ascorbate as many lower mammals are. On the contrary, true simians (i.e. the squirrel monkey, spider monkey, rhesus monkey and chimpanzee) were negative as guinea pigs were, suggesting their probable inability for l-ascorbate synthesis.Visiting scientist from the Department of Anatomy, Tokyo Medical and Dental University, Tokyo, Japan. T. R. Shanthaveerappa in previous publications, also fellow, Department of Anesthesiology, Emory University.     

Histochemical studies on urate oxidase in several mammals with special reference to uricolytic ability of primates

Summary Strong reactivity for urate oxidase was found in the liver parenchymal cells of the prosimians (i.e. the tree shrew, slow loris, potto and galago) as well as those of lower mammals. The liver parenchymal cells of the platyrrhine monkeys (i.e. the marmoset, owl monkey, squirrel monkey, capuchin monkey and spider monkey) were moderately positive. There was no preferential distribution of granular reaction products in zones of liver lobules of these species. The prosimians and platyrrhine monkeys seem to be uricolytic as lower mammals are. On the other hand, the old world monkeys (i.e. Java monkey and rhesus monkey) and the apes (i.e. the orang-utan and chimpanzee) were histochemically negative.     

Studies on the distribution of phosphorylase in eyes of the rabbit and the squirrel monkey

Summary Detailed studies on phosphorylase localization in various components of the eyeball of rabbit and squirrel monkey have been made. Corneal epithelium, endothelium, and stromal cells, extrinsic and intrinsic muscles of the eyeball, ciliary process, endothelial cells of the anterior chamber angle, vitreal cells, lens epithelium, inner segment of cones; plexiform layer, ganglion cell layer, internal and external limiting membrane and Muller cells show high phosphorylase activity. Surprisingly, we observed phosphorylase activity inside the nucleus in the posterior 2 to 3 layers of corneal epithelium. The significance of phosphorylase localization in relation to glycogen distribution in various components of the eyeball and their energy requirements is stressed.     

Histochemical studies on the distribution of some enzymes of the glycolytic pathways in the olfactory bulb of the squirrel monkey (Saimiri sciureus)

Summary Detailed histochemical studies on the distribution of glycolytic enzymes have been made in the olfactory bulb of the Squirrel Monkey. The olfactory glomeruli, mitral cells, tufted cells, glial cells and nerve fibers are well equipped with the enzymes of the glycolytic pathways. Granule cells do not have the ability to synthesize or breakdown glycogen, but they have the Embden-Meyerhof-Parnas pathway and the Warburg-Dickens pathway. The synapses of the olfactory glomeruli may have the ability to break-down glycogen for an energy source. Small glial cells found in the olfactory glomeruli may be a special type of oligodendrocyte. Glial cells found abundantly in and around the olfactory glomeruli may be energy donators to the synapses of the olfactory glomeruli. It is suggested that oligodendrocytes and astrocytes of the olfactory bulb may have different branching enzymes.Visiting scientist from Anatomy Department, Tokyo Medical and Dental University, Tokyo, Japan. T. R. Shanthaveerappa in previous publications.     

Localization of GABA-like immunoreactivity in the ectostriatum of domestic chicks: GABA immunocytochemistry combined with Golgi impregnation

Brain Cell Biology - The distribution of GABA-like immunoreactivity (GABA-LI) in the ectostriatal core (Ec) of domestic chicks (one to two days old) was investigated using (1) preembedding GABA...     

Performance of a cell recycle bubble column fermentor with a membrane filter module for continuous vinegar production

The steady-state performance of a bubble column combined with a membrane filter module for cell separation and recycle is investigated numerically in the case of vinegar fermentation. The one-dimensional dispersion model for describing the longitudinal mixing of the liquid phase is employed. Kinetic expressions and their parameter values are taken from the available literature. Several characteristics of this fermentor system namely the concentration profiles of cells, substrate and product, the viability of viable cells relative to total cells, the washout condition for cells and the productivity of acetic acid are discussed. The average cell viability in the whole column and the critical dilution rate for washout are presented as equations. Low levels of the axial mixing are found to enhance the vinegar productivity. The optimum dilution rate giving the maximum productivity is determined and both are shown as figures with the Peclet number, the recycle ratio and the bleed ratio as parameters.