Bacteriophage Ecology Group
Reference Abstracts (1969)
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. Bactériophages--propriétes et premières étapes d'une classification. Ackermann, H.-W. (1969). Path. -Biol. 17:1003-1024. [TOP OF PAGE]

  2. 5-hydroxymethylcytosine-containing Klebsiella bacteriophage. Anisymova, N.I., Gabrilovich, I.M., Soshina, N.V., Cherenkevich, S.N. (1969). Biochim. Biophys. Acta 190:225-227. [TOP OF PAGE]

  3. DNA modification and restriction. Arber, W., Linn, S. (1969). Annual Review of Biochemistry 38:467-500. [TOP OF PAGE]

  4. Geographic distribution of bacteriophage types of Mycobacterium tuberculosis. Bates, J.H., Mitchison, D.A. (1969). Am. Rev. Respir. Dis. 100:189-193. [TOP OF PAGE]

  5. Isolation, growth and preservation of bacteriophages. Billings, E. (1969). pp. 315-329. In In Norris, J.R. and Robbins, D.W. (eds.), Methods in Microbiology. Academic Press, London. [TOP OF PAGE]

  6. [Isolation and study of Bdellovibrio bacteriovorus]. Catteau, M., Petitprez, A., Leclerc, H., Vivier, E. (1969). ANNALES DE L INSTITUT PASTEUR DE LILLE 20:141-154. [TOP OF PAGE]

  7. Direct solution of Markovian phage attachment to bacteria in suspension. Chang, M.L., Chang, T.S. (1969). Math. Biosci. 5:9-18. A Markov process of phage attachment to bacteria in suspension is considered. For such a stochastic process, the probabilities P(n0, n1, . . . , nr; v0; t) of n0, n1, . . . , nr bacteria having 0, 1, . . . , r phages attached to them (where r is the maximum number of phages that can be attached to a bacterium) and v0 unattached phages at t >= 0 are related by a rather complicated differential-difference equation. This article presents a direct solution of such a stochastic process with contrained random variables. [TOP OF PAGE]

  8. Inhibition of bacterial spot of peach foliage by Xanthomonas pruni bacteriophage. Civerolo, E.L., Kiel, H.L. (1969). Phytopathology 59:1966-1977. [TOP OF PAGE]

  9. Association of microcyst formation in Spirillum itersonii with the spontaneous induction of a defective bacteriophage. Clark-Walter, G.D. (1969). J. Bacteriol. 97:885-??? [TOP OF PAGE]

  10. Bacteriophages of psychophilic pseudomonads. I. Host range of phage pools active against fish spoilage and fish-pathogenic pseudomonads. Delisle, A.L., Levin, R.E. (1969). Antonie van Leeuwenhoek J. Microbiol. 35:307-317. [TOP OF PAGE]

  11. ??? Drake, J.W. (1969). Nature 221:1128-??? [TOP OF PAGE]

  12. Bacteriophages of Clostridium botulinum. Types A, B, E, and F and nontoxigenic strains resembling Type E. Eckland, M.W., Poysky, F.T., Boatman, E.S. (1969). J. Virol. 3:270-274. [TOP OF PAGE]

  13. Thermophilic bacteria and bacteriophages. Farrell, J., Campbell, L.L. (1969). Adv. Microbial Physiol. 3:83-109. [TOP OF PAGE]

  14. Comparative characterization of choleraphages by serology, pH stability, and thermal stability methods. Guice, M.B., Newman, F.S. (1969). J. Infect. Dis. 119:2-??? [TOP OF PAGE]

  15. Detection of Salmonella carriers and Vi-phage typing of the isolates. Ha, T.Y. (1969). Journal of the Korean Medical Association 12:836-??? [TOP OF PAGE]

  16. Transformation of phage resistance. Horvath, S. (1969). Acta Microbiologica Academiae Scientiarum Hungaricae 16:77-83. [TOP OF PAGE]

  17. Transformation of phage-resistance in Bacillus subtilis. Horvath, S. (1969). Experientia 25:312 [TOP OF PAGE]

  18. The immunogenicity of phagocytosed T4 bacteriophage: Cell replacement studies with splenectomized and irradiated mice. Inchley, C.J., Howard, J.G. (1969). Clin. Exp. Immunol. 5:189-198. [TOP OF PAGE]

  19. The activity of mouse Kuppfer cells following intravenous injection of T4 bacteriophage. Inchley, C.J. (1969). Clin. Exp. Immunol. 5:173-187. [TOP OF PAGE]

  20. Lysogenic conversion in Bacillus amyloliquefaciens H affecting viral adsorption. Jonasson, J., Rutberg, L., Young, F.E. (1969). J. Virol. 4:309-??? [TOP OF PAGE]

  21. The fate of viruses in a marine environment. Kott, Y., Ari, B., Buras, N. (1969). p. ???-??? AnonymousProceedings of the Fourth International Conference on Water Pollution Research. Prague. [TOP OF PAGE]

  22. Propagation of mammalian viruses in protista. IV. Experimental infection of C. albicans and S. cerevisiae with polyoma virus. Kovacs, E., Bucz, B., Kolompar, G. (1969). Proc. Soc. Exp. Biol. Med. 132:971-977. [TOP OF PAGE]

  23. Biological effects of substituting cytosine for 5-hydroxymethylcytosine in the deoxyribonucleic acid of bacteriophage T4. Kutter, E.M., Wiberg, J.S. (1969). J. Virol. 4:439-453. [TOP OF PAGE]

  24. Filamentous bacterial viruses. Marvin, D.A., Hohn, B. (1969). Bacteriol. Rev. 33:172-209. [TOP OF PAGE]

  25. Die bakteriophagie in der Therapie und Prophylaxe der Infektionskranheiten. Mazácek, M., Petera, A., Mach, J. (1969). Zentralbl. Bakteriol. Parasienkd. Infektionskr. Hyg. Abt. 1 Orig. Reihe A 211:385-??? [TOP OF PAGE]

  26. Processes controlling virus inactivation in seawater. Mitchell, R., Jannasch, H.W. (1969). Environ. Sci. Technol. 3:941-??? [TOP OF PAGE]

  27. Isolation and properties of two new RNA phages SP and FI. Miyake, T., Shiba, T., Sakurai, T., Watanabe, I. (1969). Jpn. J. Microbiol. 13:375-382. [TOP OF PAGE]

  28. Electron microscopy of bacteriophages of tgwo polylysogenic Rhizobium phaseoli cultures. Moskalenko, L.N., Rautenstein, Ya.I. (1969). Mikrobiologiya 38:489-491. [TOP OF PAGE]

  29. Bacteriophage of photosynthetic bacterium (Rhodopseudomonas capsulatus) and phytopathogenic bacterium (Pseudomonas glycinea). Numic, R., Kobayashi, M., Akai, S., Takahashi, E. (1969). Soil Sci. Plant Nutr. 15:11-??? [TOP OF PAGE]

  30. Physical stability and biological and physiochemical properties of twelve Pseudomonas aeruginosa bacteriophages. O'Callaghan, R.J., O'Mara, W., Grogan, J.B. (1969). Virology 37:642-648. [TOP OF PAGE]

  31. Distribution of cyanophages in natural habitats. Padan, E., Shilo, M. (1969). Int. Soc. Appl. Theor. Limnol. Verh. Int. Ver. Limnol. 17:747-751. [TOP OF PAGE]

  32. Isolation and preliminary characterization of some Aeromonas salmonicida bacteriophages. Paterson, W.D., Douglas, R.L., Grinyer, I., McDermott, L.A. (1969). J. Fisheries Res. Board Canada 26:629-632. [TOP OF PAGE]

  33. Some morphological types of bacteriophages in bovine rumen contents. Paynter, M.J.B., Ewert, D.L., Chalupa, W. (1969). Appl. Microbiol. 18:942-943. [TOP OF PAGE]

  34. Dynamics of coliphage infections. Paynter, M.J.B., Bungay III, H.R. (1969). pp. 323-335. In In Perlman, D. (ed.), Fermentation Advances. Academic Press, New York. [TOP OF PAGE]

  35. Felix d'Herelle and bacteriophage therapy. Peitzman, S.J. (1969). Transactions and Studies of the College of Physicians of Philadelphia 37:115-123. [TOP OF PAGE]

  36. [Assumptions for successful therapy using staphylococcal phage lysates]. [German]. Pillich, J., Vymola, F., Buda, J. (1969). Zentralblatt Fur Bakteriologie, Parasitenkunde, Infektionskrankheiten Und Hygiene - 1 - Abt - Medizinisch-Hygienische Bakteriologie, Virusforschung Und Parasitologie - Originale 210:377-381. [TOP OF PAGE]

  37. Some new results in the mathematical theory of phage-reproduction. Puri, P.S., Prem, S. (1969). Journal of Applied Probability 6:493-504. In the theory of phage reproduction, the mathematical models considered thus far (see Gani [5]) assume that the bacterial burst occurs a fixed time after infection, after a fixed number of generations of phage multiplication, or when the number of mature bacteriophages has reached a fixed threshold. In the present paper, a more realistic assumption is considered: given that until time t the bacterial burst has not taken place, its occurrence between t and t + Dt is a random event with probability f(• | t)Dt + o(t), where f is a non-negative and non-decreasing function of the number X(t) of vegetative phages and of Z(t), the number of mature bacteriophages at time t. More specifically it is assumed that f = b(t)X(t) + c(t)Z(t) with b(t),c(t)>=0. Here X(t) denotes the survivors in a linear birth and death process and Z(t) the number of deaths until time t. The joint distribution of XT and ZT, the respective numbers of vegetative and mature bacteriophages at the burst time is considered. The distribution of ZT is then fitted to some observed data of Delbrück[2]. [TOP OF PAGE]

  38. Bacteriophages associated with turkey coecums in bluecomb-infected and healthy birds. Ritchie, A.E. (1969). p. 226-??? In Arcenaux, C.J. (ed.), 27th Annual Proceedings of the Electron Microscopy Society of America. Caytor's, Baton Rouge,LA. [TOP OF PAGE]

  39. Isolation of bacteriophages for Chlostridium tetani. Roseman, D., Richardson, R.L. (1969). J. Virol. 3:350-350. The purpose of this report is to note the isolation of a Chlostridium tetani phage from soil and to specify the produre used to obtain suitable lawns for plaque formation. [TOP OF PAGE]

  40. Phycovirus SM-1: a virus infecting unicellular blue-green algae. Safferman, R.S., Schneider, I.R., Steere, R.L., Morris, M.E., Diener, T.O. (1969). Virology 37:386-395. [TOP OF PAGE]

  41. Isolation and characterization of host-independent Bdellovibrios. Seidler, R.J., Starr, M.P. (1969). J. Bacteriol. 100:769-785. [TOP OF PAGE]

  42. Morphological and physiological aspects of the interaction of Bdellovibrio with host bacteria. Shilo, M. (1969). CURRENT TOPICS IN MICROBIOLOGY AND IMMUNOLOGY 50:174-204. [TOP OF PAGE]

  43. The inability to alter limited heterocatalytic expression in phage T4-infected Escherichia coli by growth of host cells under various physiological conditions. Snustad, D.P. (1969). Virology 38:361-364. no abstract. [TOP OF PAGE]

  44. The genetics and physiology of bacteriophage T7. Studier, F.W. (1969). Virology 39:562-574. [TOP OF PAGE]

  45. A protozoan virus. Terzakis, J.A. (1969). MILITARY MEDICINE 134:916-921. [TOP OF PAGE]

  46. ??? Valentine, R.C., Silverman, P.M., Ippen, K.A., Mobach, H. (1969). Adv. Microbiol. Physiol. 3:1-??? [TOP OF PAGE]

  47. Interaction of Bdellovibrio bacteriovorus and host bacteria. II. Intracellular growth and development of Bdellovibrio bacteriovorus in liquid cultures. Varon, M., Shilo, M. (1969). J. Bacteriol. 99:136-141. [TOP OF PAGE]

  48. Growth and transformation of phage T4 in Escherichia coli B/4, Salmonella, Aerobacter, Proteus, and Serratia. Wais, A.C., Goldberg, E.B. (1969). Virology 39:153-161. Spheroplasts of the genera Escherichia, Salmonella, Aerobacter, Proteus, and Serratia can be infected by T4 phage which have been exposed to 6 M urea. The interaction between the phage and the bacteria does not require either phage tail fibers or the specific tail fiber receptors of the bacteria. These findings imply two modes of infection, one of which may procede the other, in the normal phage infection process. ¶ Transformation of T4 phage by denatured DNA fragments has been demonstrated with Aerobacter as the host organism. In Aerobacter, transformation is more efficient than in Escherichia, and at low DNA concentrations Aerobacter yields 100-fold more transformed phage than Escherichia. [TOP OF PAGE]

  49. The distribution of inanimte marks over a non-homogeneous birth-death process. Williams, T. (1969). Biometrika 56:225-228. [TOP OF PAGE]

  50. Genetic evolution of bacteriophage. I. Hybrids between unrelated bacteriophage P22 and Fels 2. Yamamoto, N. (1969). Proc. Natl. Acad. Sci. USA 62:63-??? [TOP OF PAGE]

  51. [Further data on the association of bacteriophage with antibiotic therapy for the purpose of sterilizing carriers of dysentery bacilli]. [French]. Zilisteanu, C., Mintzer-Morgenstern, L., Ionesco, H., Ionesco-Dorohoi, T. (1969). Archives Roumaines de Pathologie Experimentales et de Microbiologie 28:1073-1080. [TOP OF PAGE]

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