Niacin requirement for growth of axenic Entamoeba histolytica.

Niacin (nicotinic acid) was found to be essential for the cultivation of axenic Entamoeba histolytica. This vitamin requirement was also satisfied by nicotinamide. Panmede liver digest, a source of vitamins in the axenic medium was replaced with a dialyzed hot water extract of homogenized whole liver, supplemented with various growth factors. Cultured medium made with the liver extract and not supplemented with niacin failed to support continued multiplication of E. histolytica, but did support serial subculture when niacin was added. The concentration of added niacin required to achieve maximum growth was about 1 microgram per ml of medium. This is the first demonstration of a niacin requirement by the organism.

Concanavalin A-induced agglutination of Naegleria.

Concanavalin A (Con A) agglutinated all Naegleria gruberi strains tested but did not agglutinate any N. fowleri strains tested. Agglutination was time and temperature dependent and Con A concentration and ameba concentration dependent over certain ranges. Agglutination increased to maximum up to 1 h incubation with Con A. At least 1 X 10(6) amebae/ml were needed for maximum agglutination, and Con A concentrations higher than 100 microgram/ml did not appreciably increase agglutination. Incubation of 4 degrees C or with 10 mM alpha-methyl-D-mannoside inhibited agglutination of N. gruberi. These data indicate a difference in polysaccharide structure of cell membranes of N. fowleri and N. gruberi.

Immunization of mice against Naegleria fowleri infection.

Naegleria fowleri produces fatal meningoencephalitis in humans and in experimentally infected laboratory animals. The course of the disease in mice is dependent upon the infecting dose of amoebae, route of inoculation, and prior exposure to Naegleria antigens. DUB/ICR mice were immunized by various routes and antigen preparations, held for 21 days, and, together with noninfected control mice, challenged intravenously (i.v.) or intranasally (i.n.) with 10(7) or 10(6) N. fowleri per mouse, respectively. Mice immunized with liver or formalinized N. fowleri or live N. gruberi subcutaneously, intraperitoneally, i.v., or i.n. were significantly protected against a subsequent lethal challenge with N. fowleri i.v. or i.n. In general, i.v. inoculation afforded greated protection than other routes of immunization, intact cells immunized mice better than did cell fragments, and N. gruberi appeared to be a better immunogen than N. fowleri.

Cell size, macromolecular composition, and O2 consumption during agitated cultivation of Naegleria gruberi.

Cell size, macromolecular composition, carbohydrate utilization patterns, and O2 concentrations were measured throughout the growth stages of Naegleria gruberi in agitated culture in a complex medium. Biphasic logarithmic growth occurred during the intial 83 hr of growth and the mean generation time was 7.0 hr and 19 hr during initial and secondary log growth stages, respectively. The maximum yield was 5 X 10(6) amebae/ml. The pH rose rapidly (1 pH unit) during the secondary log growth phase (52-83 hr) and continued into the stationary growth phase (83-120 hr). Dry weight, total protein, carbohydrate, and RNA per ameba increased just before the secondary log growth phase. RNA increase 31% to 35% per ameba at the end of each phase of log growth. DNA increased approximately 2-fold throughout the different growth phases. Average cell size increased 90% during biphasic log growth then decreased during stationary phase. O2 tension decreased from 100% to 18% of saturation during the biphasic growth phase, then increased during stationary growth to near 100% saturation. Glucose and total carbohydrate assays showed little utilization of those substrates throughout the growth stages. Naegleria gruberi presumably has a predominantly aerobic metabolism, also its metabolism may change during the different growth phases.