181
Beckage N. E. Games parasites play: the dynamic roles of proteins and peptides in the relationship between parasite and host // Parasites and Pathogens of Insects: Parasites. Academic Press, 1993, 25–57.
182
Whitfield J. B., Asgari S. Virus or not? Phylogenetics of polydnaviruses and their wasp carriers // Journal of Insect Physiology, 2003, V. 49, №5, 397–405.
183
Whitfield J. B. Molecular and morphological data suggest a single origin of the polydnaviruses among braconid wasps // Naturwissenschaften, 1997, V. 84, №11, 502–507.
184
Bezier A. et al. Polydnaviruses of braconid wasps derive from an ancestral nudivirus // Science, 2009, V. 323, №5916, 926–930.
185
Volkoff A. N. et al. Analysis of virion structural components reveals vestiges of the ancestral ichnovirus genome // PLoS Pathogens, 2010, V. 6, №5, e1000923.
186
Strand M. R., Burke G. R. Polydnaviruses: nature’s genetic engineers // Annual Review of Virology, 2014, V. 1, 333–354.
187
Strand M. R., Burke G. R. Polydnaviruses: from discovery to current insights // Virology, 2015, V. 479, 393–402.
188
Villarreal L. P. Can viruses make us human? // Proceedings of the American Philosophical Society, 2004, V. 148, №3, 296–323.
189
Roossinck M. J. The good viruses: viral mutualistic symbioses // Nature Reviews. Microbiology, 2011, V. 9, №2, 99–108.
190
Thurber R. V. et al. Virus-host interactions and their roles in coral reef health and disease // Nature Reviews Microbiology, 2017, V. 15, №4, 205–216.
191
Oldstone M. B. A. Prevention of type I diabetes in nonobese diabetic mice by virus infection // Science, 1988, V. 239, №4839, 500–503.
192
Stoye J. P. Studies of endogenous retroviruses reveal a continuing evolutionary saga // Nature reviews. Microbiology, 2012, V. 10, №6, 395–406.
193
Villarreal L. P. et al. Virus-host symbiosis mediated by persistence // Symbiosis (Rehovot), 2007, V. 44, №1/3, 1–9.
194
Gregory T. R. Synergy between sequence and size in large-scale genomics // Nature Reviews. Genetics, 2005, V. 6, 699–708.
195
Stoye, 2012.
196
Li W. et al. Human endogenous retrovirus-K contributes to motor neuron disease // Science Translational Medicine, 2015, V. 7, №307, 307ra153-307ra153.
197
Lager S., Powell T. L. Regulation of nutrient transport across the placenta // Journal of Pregnancy, 2012, V. 2012.
198
Mess A., Carter A. M. Evolutionary transformations of fetal membrane characters in Eutheria with special reference to Afrotheria // Journal of Experimental Zoology, Part B: Molecular and Developmental Evolution, 2006, V. 306, №2, 140–163.
199
Dupressoir A., Lavialle C., Heidmann T. From ancestral infectious retroviruses to bona fide cellular genes: role of the captured syncytins in placentation // Placenta, 2012, Volume 33, Issue 9, 663–671.
200
Magiorkinis G., Blanco-Melo D., Belshaw R. The decline of human endogenous retroviruses: extinction and survival // Retrovirology, 2015, V. 12, №1, 8.
201
Manghera M., Ferguson J., Douville R. Endogenous retrovirus-K and nervous system diseases // Current Neurology and Neuroscience Reports, 2014, V. 14, №10, 488.
202
Fisher R. A. The genetical theory of natural selection. Oxford University, 1930.
203
Bouvier A., Wadhwa M. The age of the Solar System redefined by the oldest Pb–Pb age of a meteoritic inclusion // Nature Geoscience, 2010, V. 3, 637–641.
204
Larson R. E., Bromm V. The first stars in the Universe // Scientific American, 2004, V. 14, №4, 4–11.
205
Glover S. The first stars // The First Galaxies. Springer Berlin Heidelberg, 2013, 103–174.
206
Cameron A. G. W., Truran J. W. The supernova trigger for formation of the solar system // Icarus, 1977, V. 30, №3, 447–461.
207
Hester J. J. et al. The cradle of the solar system // Science, 2004, V. 304, №5674, 1116–1117.
208
Tachibana S. et al. 60Fe in chondrites: Debris from a nearby supernova in the early Solar System? // The Astrophysical Journal Letters, 2006, V. 639, №2, L87–L90.
209
Leger A. et al. A new family of planets? “Ocean-Planets” // Icarus, 2004, V. 169, №2, 499–504.
210
Elkins-Tanton L. T. Uranus, Neptune, Pluto, and the Outer Solar System. Chelsea House Publishers, 2006.
211
Сорохтин О.Г., Ушаков С.А. Развитие Земли. — М.: Издательство МГУ, 2002.
212
Robert F. The origin of water on Earth // Science, 2001, V. 293, №5532, 1056–1058.
213
Robert F. The origin of water on Earth // Science, 2001, V. 293, №5532, 1056–1058.
214
Halliday A. N. The Origin of the Moon // Science, 2012, V. 338, №6110, 1040–1041.
215
Hartmann W. K. The giant impact hypothesis: past, present (and future?) // Philosophical Transactions of Royal Society, A: Mathematical, Physical and Engineering Sciences, 2014, V. 372, №2024, 2013.0249.
216
Di Achille G., Hynek B. M. Ancient ocean on Mars supported by global distribution of deltas and valleys // Nature Geoscience, 2010, V. 3, 459–463.
217
Huber C., Wachtershauser G. α-Hydroxy and α-amino acids under possible Hadean, volcanic origin-of-life conditions // Science, 2006, V. 314, №5799, 630–632.
218
Martin W., Russell M. J. On the origin of biochemistry at an alkaline hydrothermal vent // Philosophical Transactions of the Royal Society of London, B: Biological Sciences, 2007, V. 362, №1486, 1887–1926
219
Russell M. J. The alkaline solution to the emergence of life: energy, entropy and early evolution // Acta Biotheoretica, 2007, V. 55, №2, 133–179.
220
Mulkidjanian A. Y. On the origin of life in the zinc world: 1. Photosynthesizing, porous edifices built of hydrothermally precipitated zinc sulfide as cradles of life on Earth // Biology Direct, 2009, V. 4, №1, 26.
221
Mulkidjanian A. Y., Galperin M. Y. On the origin of life in the zinc world. 2. Validation of the hypothesis on the photosynthesizing zinc sulfide edifices as cradles of life on Earth // Biology Direct, 2009, V. 4, №1, 27.
222
Wachtershauser G. On the chemistry and evolution of the pioneer organism // Chemistry & Biodiversity, 2007, V. 4, №4, 584–602.
223
Руденко А.П. Теория развития открытых каталитических систем. — М.: Издательство МГУ, 1969.
224
Huber C., Eisenreich W., Wachtershäuser G. Synthesis of α-amino and α-hydroxy acids under volcanic conditions: implications for
