Relative contributions of ruminal bacteria and protozoa to the degradation of protein in vitro.

Mixed ruminal microorganisms from a cow fed timothy hay and concentrate supplement (50:50) were incubated with various protein sources for 15 h (no carbohydrates or growth), and deamination was studied under enzyme-limiting substrate-excess conditions (n = 3). Addition of amphotericin (10 micrograms/ml) killed protozoa and decreased (P less than .05) ammonia production from killed bacteria but it had no effect (P greater than .05) on casein deamination. Monensin (5 micrograms/ml) also killed protozoa; however, it decreased (P less than .05) casein deamination to a much greater extent than amphotericin. Antibacterial antibiotics (penicillin G, polymixin B, cephalosporin C and streptomycin) greatly reduced (P less than .05) ammonia formation from casein. Isolated bacteria always produced more ammonia than isolated protozoa, but the difference was less with heat-treated, particulate proteins. Heated soybean protein was as soluble as heated casein but it was deaminated (P less than .05) at a faster rate by bacteria. Nonammonia-nonprotein N accumulation was greater (P less than .05) with the protozoa than bacteria. When incubations containing bacteria or protozoa were compared with combinations of protozoa and bacteria, the combinations always caused a synergistic increase in ammonia and decrease (P less than .05) in nonammonia-nonprotein N. These results suggest: soluble proteins were primarily degraded by bacteria; protozoa could contribute to the degradation of insoluble, particulate proteins; protozoa were limited in their ability to assimilate peptides (or amino acids); low molecular weight products could be fermented more readily by bacteria and monensin was toxic to protozoa, but decreases in ammonia were primarily due to action of monensin on bacteria.