Bacteriophage Ecology Group
Reference Abstracts (1963)
Dedicated to the ecology and evolutionary biology of the parasites of unicellular organisms (UOPs)
© Stephen T. Abedon
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© Phage et al. last updated on Wednesday, December 26, 2001
  1. Phage isolated from lysogenic Bacillus anthracis. Buck, C.A., Anacker, R.L., Newman, F.S., Eisenstark, A. (1963). J. Bacteriol. 85:1423-1430. [TOP OF PAGE]

  2. On the sanitary significance of detecting bacteriophage producing lysis of dysenteri bacilli in the water of open reservoirs. Feigin, T.S. (1963). Zh. Mikrobiol. Epidemol. Immunobiol. 40:132-137. [TOP OF PAGE]

  3. The conditions which govern the adsorption of a tryptophan-dependent bacteriophage to kaolin and bacteria. Fildes, P., Kay, D. (1963). J. Gen. Microbiol. 30:183-191. [TOP OF PAGE]

  4. Models for a bacterial growth process with removals. Gani, J. (1963). Journal of the Royal Statistical Society. Series B (Statistical Methodology) 25:140-149. The paper considers the extinction of a bacterial colony subject to phage infection. A description of the biological process leads to the construction of a simplified model from which it is possible to derive the probability generation function (p.g.f.) for surviving bacteria in terms of repeated contour integrals. The distribution of phage offspring released by a single bacterium, and of bacterial infections due to these phages, are discussed. For bacterial birth and birth-death processes, it is possible to express the p.g.f. for surviving bacteria explicitly; this is done by first obtaining the p.g.f. conditional on numbers of bacterial infections, and then summing over all such possible infections. [TOP OF PAGE]

  5. Host-induced modification of T-even phages due to defective glucosylation of their DNA. Hattmann, S., Fukasawa, T. (1963). Proc. Natl. Acad. Sci. USA 50:297-??? "…5-hydroxymethylcytosine in the DNA of T-even phages (reference), a pyrimidine whose existance would indeed be difficult to explain by invoking chemical evolution based on structural chemical characteristics (cf. Hattmann and Fukasawa, 1963) made it evident, however, that it was what we would call 'social' incompatibilities betweeen phage and host which may have governed the evolutionary history of hydroxymethylcytosine and its glucosylated DNA derivatives." [quoted from p. 47 of Kalckar, H. M. (1992), High energy phosphate bonds: Optional or obligatory? in Cairns, J., Stent, G. S., Watson, J. D. (eds.) Phage and the Origins of Molecular Biology, Cold Spring Harbor Press, Cold Spring Harbor, New York, pp. 43-49]. [TOP OF PAGE]

  6. Tentative de traitement des hamsters inoculés avec le BCG par un bactériophage. Hauduroy, P., Rosset, W. (1963). Annales de l'Institut Pasteur 104:419-420. [TOP OF PAGE]

  7. ??? Hoffmann-Berling, H., Marvin, D.A., Duerald, H. (1963). Z. Naturforsch. 18B:893-??? [TOP OF PAGE]

  8. ??? Lindenmann, J., Gifford, G.E. (1963). Virology 19:283-??? [TOP OF PAGE]

  9. The role of mycobacteriophages and of cortisome in experimental tuberculosis and sarcoidosis. Mankiewicz, E., Beland, J. (1963). Am. Rev. Respir. Dis. 89:707-720. [TOP OF PAGE]

  10. Studies on the lytic interaction and cell transformation with a large and a small-plaque mutant of polyoma virus. Medina, D., Sachs, L. (1963). Virology 19:127-139. [TOP OF PAGE]

  11. On uncertainties inherent in the determination of the efficiency of collision between virus particle and cells. Ogston, A.G. (1963). Biochim. Biophys. Acta 66:279-281. Several authors (VALENTINE AND ALLISON, TOLMACH AND STENT AND WOLLMAN) have recently concluded, or regarded it as established, that the efficiency of collision of virus particles with cells is near unity. In fact the methods used can only give meaningful values for the collision efficiency if this is less than 10-3-10-6, and are insensitive to higher values. Apart from this limitation, uncertainties in the kinetic theory of liquids prevents the exact measurement of collision efficiency under any conditions... One must conclude, therefore, that even in the most favourable case of collision with small spherical objects, the collision efficiency can be measured only if it is considerably less than 10-3. Even so, the value would be subject to a considerable uncertainty because of our prsent lack of exact knowledge of such microscopic quantities as the jump-length and the jump-frequency. [TOP OF PAGE]

  12. Further models for phage reproduction. Ohlsen, S. (1963). Cold Spring Harbor Symp. Quant. Biol. 19:441-449. [TOP OF PAGE]

  13. Bacteriophages of plant pathogens. Okabe, N., Goto, M. (1963). Ann. Rev. Phytopathol. 1:397-418. [TOP OF PAGE]

  14. Algal virus: isolation. Safferman, R.S., Morris, M.E. (1963). Science 140:679-680. [TOP OF PAGE]

  15. ??? Salmon, G., Symonds, M. (1963). J. Med. Soc. 60:188-193. [TOP OF PAGE]

  16. Treatment and prophylaxis of cholera with bacteriophage. Sayamov, R.M. (1963). Bull. W. H. O. 28:361-??? [TOP OF PAGE]

  17. Bacterial viruses in the sea. Spencer, R. (1963). pp. 350-365. In In Oppenheimer, C.H. (ed.), Symposium on Marine Microbiology. Charles C. Thomas, Publisher, Springfield, IL. [TOP OF PAGE]

  18. Molecular Biology of Bacterial Viruses. Stent, G. (1963). WH Freeman and Co., San Francisco, CA.[TOP OF PAGE]

  19. Two-dimensional immunodiffusion. Stollar, D., Levine, L. (1963). Methods in Enzymology VI:848-854. [TOP OF PAGE]

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