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Искусственные генетические системы. Том 1 - Патрушев Л.И.

Патрушев Л.И. Искусственные генетические системы. Том 1 — М.: Наука, 2004. — 256 c.
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87. Sieber V., Martinez С A., Arnold F.H. Libraries of hybrid proteins from distantly related sequences // Ibid. 2001. Vol. 19. P. 456-460.
88. Smith G.P. Filamentous fusion phage: Novel expression vectors that display cloned antigens on the virion surface I I Science. 1985. Vol. 228, N 4705. P. 1315-1317.
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92. Rakonjac J., Feng J.N., Model P. Filamentous phage are released from the bacterial membrane by a two-step mechanism involving a short C-terminal fragment of pill // Ibid. 1999. Vol. 289, N 5. P. 1253-1265.
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95. Efimov V.P., Nepluev I.V., Mesyanzhinov V.V. Bacteriophage-T4 as a surface display vector // Virus Genes. 1995. Vol. 10, N 2. P. 173-177. (a) Scott J.K. Discovering peptide ligands using epitope libraries // Trends Biochem. Sci. 1992. Vol. 17. P. 241-245.
96. Roberts R.W., Ja W.W. In vitro selection of nucleic acids and proteins: What are we learning? I I Curr. Opin. Struct. Biol. 1999. Vol. 9. P. 521-529.
97. Soumillion P., Fastrez J. Investigation of phage display for the directed evolution of enzymes // Directed evolution of proteins, or how to improve enzymes for biocatalysis / Ed. S. Brakmann, K. Johnsson. N.Y.: Wiley, 2002. P. 79-110.
98. Light J., Lerner R.A. Random mutagenesis of staphylococcal nuclease and phage display selection // Bioorg. Med. Chem. 1995. Vol. 3, N 7. P. 955-967.
99. Pauling L. Chemical achievement and hope for the future // Amer. Sci. 1948. Vol. 36. P. 51-58.
100. Pasqualini R., Ruoslahti E. Organ targeting in vivo using phage display peptide libraries // Nature. 1996. Vol. 380, N 3572. P. 364-366.
101. George A.J.T., Lee L., Pitzalis C. Isolating ligands specific for.human vasculature using in vivo phage selection I I Trends Biotechnol. 2003. Vol. 21. P. 199-203.
102. Samoylova T.I., Smith B.F. Elucidation of muscle-binding peptides by phage display screening // Muscle Nerve. 1999. Vol. 22. P. 460-466.
103. Arap W„ Haedicke W., Bernasconi M. et al. Targeting the prostate for destruction through a vascular address // Proc. Nat. Acad. Sci. USA. 2002. Vol. 99, N3. P. 1527-1531.
104. Essler М., Ruoslahti E. Molecular specialization of breast vasculature: A breast-homing phage-displayed peptide binds to aminopeptidase P in breast vasculature // Ibid. P. 2252-2257.
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106. Michon I.N., Hauer A.D., Von der Thusen J.H. et al. Targeting of peptides to restenotic vascular smooth muscle cells using phage display in vitro and in vivo // Biochim. biophys. acta. 2002. Vol. 1591, N 1/3. P. 87-97.
107. Houston P., Goodman J., Lewis A. et al. Homing markers for atheroscle-
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108. Lee L., Buckley C., Blades M.C. et al. Identification of synovium-specific homing peptides by in vivo phage display selection // Arthritis Rheum.
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111. Wittrup K.D. Directed evolution of binding proteins by cell surface display: Analysis of the screening process I I Directed evolution of proteins, or how to improve enzymes for biocatalysis / Ed. S. Brakmann, K. Johnsson. N.Y.: Wiley, 2002. P. 111-126.
112. Mattheakis L.C., BhattR.R., Dower W.J. An in vitro polysome display system for identifying ligands from very large peptide libraries // Proc. Nat. Acad. Sci. USA. 1994. Vol. 91, N 19. P. 9022-9026.
113. Hanes J., Pliickthun A. In vitro selection and evolution of functional proteins by using ribosome display // Ibid. 1997. Vol. 94. P. 4937-4942.
114. Roberts R.W., Szostak J.W. RNA-peptide fusions for the in vitro selection peptides and proteins // Ibid. 1997. Vol. 94. P. 12297-12302.
115. Schqffitzel C., Pliickthun A. Protein-fold evolution in the test tube // Trends Biochem. Sci. 2001. Vol. 26. P. 577-579.
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