Toxicity of low and moderate multiplicities of Chlamydia psittaci for mouse fibroblasts (L cells).

When mouse fibroblasts (L cells) were infected in suspension or in monolayer with 10 to 100 50% infectious doses (ID(50)) of Chlamydia psittaci (6BC) per host cell, they showed signs of damage 24 to 48 h later. Host-cell injuries were termed multiplication dependent when both the ingestion and subsequent reproduction of C. psittaci were required; when only ingestion but not replication was needed, the injuries were considered to be multiplication independent. The time that the injury was first apparent, as well as its final magnitude, was proportional to the multiplicity of infection. When L cells ingested infectious or ultraviolet-inactivated C. psittaci, damage was manifested by failure to exclude trypan blue, by leakage of lactic dehydrogenase, by inhibition of reproduction as measured by ability to form colonies, by inhibition of protein and deoxyribonucleic acid synthesis, and eventually by cell disintegration. Infectious, but not ultraviolet-killed, chlamydiae stimulated host-cell glycolysis. Heat-killed chlamydiae were without measurable toxicity. The time of appearance of host-cell injury was always earlier, and its terminal magnitude always greater, with infectious inocula than with ultraviolet-inactivated ones. The multiplication-independent toxicity of ultraviolet-killed C. psittaci disappeared with inocula of less than 10 ID(50) per L cell, but an inoculum of only a single ID(50) of infectious chlamydiae per host cell injured most of the cells it infected, as evidenced by increased trypan blue staining and decreased efficiency of colony formation. The toxicity of multiplicities of infection between 10 and 100 ID(50) of infectious C. psittaci per host cell was the sum of both multiplication-dependent and -independent components. The effects of chloramphenicol and isoleucine deficiency on the ability of C. psittaci to injure L cells suggested that some synthesis of protein by both parasite and host may be essential for expression of multiplication-independent chlamydial toxicity. The failure of infectious chlamydiae to stimulate host-cell glycolysis in the presence of cycloheximide suggested that this multiplication-dependent consequence of chlamydial infection was also dependent on protein synthesis by the host.

Immediate toxicity of high multiplicities of Chlamydia psittaci for mouse fibroblasts (L cells).

One hour after suspensions of mouse fibroblasts (L cells) were exposed to 500 to 1,000 L-cell 50% infectious doses of Chlamydia psittaci (6BC), the L cells failed to attach to and spread out on solid substrates, phagocytosed polystyrene latex spheres at reduced rates, incorporated less [14C]isoleucine into protein, and had smaller soluble pools of nucleoside triphosphates. The infected L cells began to die at 8 h and were all dead by 20 h. Lower multiplicities of infection took correspondingly longer to kill the L cells. These effects of high multiplicities of C. psittaci on L cells will be referred to collectively as immediate toxicity. Similar effects were obtained with other strains of C. psittaci and C. trachomatis and with other cell lines. Ultraviolet-inactivated C. psittaci retained the ability to cause immediate toxicity, but heat-inactivated chlamydiae did not. C.psittaci cells had to be ingested by L cells before they were immediately toxic but, once they were phagocytosed, they did not need to multiply or to synthesize macromolecules in order to cause immediate injury to their hosts. Immediate toxicity was not the result of depression of energy metabolism, changes in the levels of intracellular cyclic nucleotides, or release of hydrolases from lysosomes. It was suggested that a lesion is produced in the plasma membrane of the L cell every time it ingests a chlamydial cell, that each act of ingestion produces an independent lesion, and that their injurious effects are additive. Thus, the more ingestion lesions there are, the faster the host cell dies. It was also suggested that induced phagocytosis, inhibition of lysosomal fusion, and death of mice and of cells in culture may all depend on a single activity of C. psittaci.