Metabolism of Rickettsia Typhi and Rickettsia Akari in Irradiated L Cells

Overview

Journal Infect Immun

Publisher American Society for Microbiology

Specialty Allergy & Immunology

Date 1972 Jul 1

PMID 4628863

Citations 20

Authors

E Weiss

L W Newman

R Grays

A E Green

Affiliations

Soon will be listed here.

Abstract

L cells that had been exposed to 3,000 r of (60)Co the previous day were used to study the growth and metabolism of Rickettsia typhi and R. akari. Viable (unirradiated) L cells were used to study the effect of rickettsial infection on host-cell metabolism. Monolayers were infected with a rickettsial multiplicity of 1.2 and given Eagle's minimal essential medium containing 25 mmN-2-hydroxyethylpiperazine-N'-2'-ethanesulfonic acid buffer and 10% calf serum. At various intervals, cycloheximide (2 mug/ml) was added to one set of cultures, to inhibit eukaryotic protein and deoxyribonucleic acid (DNA) metabolism; phosphate-buffered saline (PBS) was added to another set. After 1 hr, the cultures received a mixture of 15 (14)C-labeled amino acids or adenine-8-(14)C. The cultures were harvested 16 hr later and were tested for incorporation of labeled carbon into the fraction precipitated by cold trichloroacetic acid. Viable cells were exposed to thymidine-2-(14)C for 2-hr periods. Infectivity of R. typhi increased to a peak of 150 to 400 hemolytic units/culture on day 4; the titer remained approximately the same on days 5 and 6, and declined rapidly on day 7. Total amino acid incorporation was about the same in infected and uninfected cultures up to day 6, but metabolic activity was reduced to a negligible level on day 7 in infected cells. Cycloheximide-resistant activity was higher in the infected cultures, with a peak equivalent to one-half the total activity at day 4 to 5. Total as well as cycloheximide-resistant adenine incorporation was higher in the infected cells between days 3 and 5 after infection, with a peak at day 3 to 4. Somewhat similar results were obtained with R. akari, except that the cycle of infection and of cycloheximide-resistant activity proceeded and was completed more rapidly. (14)C-DNA of both rickettsiae was isolated from infected cultures that had received labeled adenine. With labeled thymidine, which was not incorporated by the rickettsiae, it was shown that R. typhi and R. akari differ considerably in their effects on the host cell. R. typhi elicited moderate inhibition, whereas R. akari infection led to a complete inhibition of thymidine incorporation by the third day, at the time of highest rickettsial activity. It is concluded that rickettsiae have the necessary enzymes for protein and nucleic acid synthesis, but, thus far, these enzymes have been activated or induced only in an intracellular environment.

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References

McDade J, Stakebake J, Gerone P . Plaque assay system for several species of Rickettsia. J Bacteriol. 1969; 99(3):910-2. PMC: 250118. DOI: 10.1128/jb.99.3.910-912.1969. View

Lin H . Inhibition of thymidine kinase activity and deoxyribonucleic acid synthesis in L cells infected with the meningopneumonitis agent. J Bacteriol. 1968; 96(6):2054-65. PMC: 252558. DOI: 10.1128/jb.96.6.2054-2065.1968. View

Snyder J, BOVARNICK M, Miller J, CHANG R . Observations on the hemolytic properties of typhus rickettsiae. J Bacteriol. 1954; 67(6):724-30. PMC: 357312. DOI: 10.1128/jb.67.6.724-730.1954. View

Weiss E, DRESSLER H . Growth of Rickettsia prowazeki in irradiated monolayer cultures of chick embryo entodermal cells. J Bacteriol. 1958; 75(5):544-52. PMC: 290108. DOI: 10.1128/jb.75.5.544-552.1958. View

PUCK T, Marcus P . Action of x-rays on mammalian cells. J Exp Med. 1956; 103(5):653-66. PMC: 2136626. DOI: 10.1084/jem.103.5.653. View

Pestka S . Inhibitors of ribosome functions. Annu Rev Microbiol. 1971; 25:487-562. DOI: 10.1146/annurev.mi.25.100171.002415. View

Schaechter M, BOZEMAN F, SMADEL J . Study on the growth of Rickettsiae. II. Morphologic observations of living Rickettsiae in tissue culture cells. Virology. 1957; 3(1):160-72. DOI: 10.1016/0042-6822(57)90030-2. View

STOENNER H, LACKMAN D, Bell E . Factors affecting the growth of rickettsias of the spotted fever group in fertile hens' eggs. J Infect Dis. 1962; 110:121-8. DOI: 10.1093/infdis/110.2.121. View

Kazar J, Krautwurst P, GORDON F . Effect of Interferon and Interferon Inducers on Infections with a Nonviral Intracellular Microorganism, Rickettsia akari. Infect Immun. 1971; 3(6):819-24. PMC: 416244. DOI: 10.1128/iai.3.6.819-824.1971. View

10.

GORDON F, DRESSLER H, QUAN A, McQUILKIN W, THOMAS J . Effect of ionizing irradiation on susceptibility of McCoy cell cultures to Chlamydia trachomatis. Appl Microbiol. 1972; 23(1):123-9. PMC: 380289. DOI: 10.1128/am.23.1.123-129.1972. View

11.

Barker L, Patt J . Production of rickettsial complement-fixing antigens in tissue culture. J Immunol. 1968; 100(4):821-4. View

12.

Anderson D, HOPPS H, Barile M, BERNHEIM B . Comparison of the ultrastructure of several rickettsiae, ornithosis virus, and Mycoplasma in tissue culture. J Bacteriol. 1965; 90(5):1387-404. PMC: 315827. DOI: 10.1128/jb.90.5.1387-1404.1965. View

13.

Alexander J . Separation of protein synthesis in meningopneumonitisgent from that in L cells by differential susceptibility to cycloheximide. J Bacteriol. 1968; 95(2):327-32. PMC: 252021. DOI: 10.1128/jb.95.2.327-332.1968. View

14.

Alexander J . Effect of infection with the meningopneumonitis agent on deoxyribonucleic acid and protein synthesis by its L-cell host. J Bacteriol. 1969; 97(2):653-7. PMC: 249741. DOI: 10.1128/jb.97.2.653-657.1969. View

15.

Ennis H, Lubin M . CYCLOHEXIMIDE: ASPECTS OF INHIBITION OF PROTEIN SYNTHESIS IN MAMMALIAN CELLS. Science. 1964; 146(3650):1474-6. DOI: 10.1126/science.146.3650.1474. View

16.

Weinberg E, Stakebake J, Gerone P . Plaque assay for Rickettsia rickettsii. J Bacteriol. 1969; 98(2):398-402. PMC: 284828. DOI: 10.1128/jb.98.2.398-402.1969. View

17.

BOVARNICK M, Schneider L . The incorporation of glycine-1-C14 by typhus rickettsiae. J Biol Chem. 1960; 235:1727-31. View

18.

Kenyon R, Acree W, Wright G, Melchior Jr F . Preparation of vaccines for Rocky Mountain spotted fever from rickettsiae propagated in cell culture. J Infect Dis. 1972; 125(2):146-52. DOI: 10.1093/infdis/125.2.146. View