Рузин И. М.
Рузин
Игорь Мартынович
к.ф.-м.н.
Моделирование эволюции и иммунологии патогенов
Некоторые патогены быстро эволюционируют и так вырабатывают сопротивление лекарствам и иммунной системе хозяина. Высокое генетическое разнообразие патогенов осложняет изучение их эволюции. Эволюционные факторы включают в себя естественный отбор, случайный генетический дрейф, рекомбинацию. Кроме того, геном популяции имеет большое количество связанных локусов. Эволюционные динамика на разных локусах не является независимой из-за эффектов эпистаза, т.е., биохимического взаимодействия между белками и их доменами, а также их филогенетической связки (общих предков). Наши исследования сосредоточены на разработке математических и вычислительных методов для предсказания эволюции патогенов с сильными эффектами связки, эпистазом, и рекомбинацией, и для оценок эволюционных параметров из образцов ДНК.
Мотивация
В последнее десятилетие произошел значительный прогресс в высокоточном дешевом секвенировании. Были разработаны новые математические методов эволюционного моделирования. На основе собственных предыдущих математических и программных разработок, Игорь и его коллеги будут моделировать эволюцию вирусов ВИЧ, гриппa, полиомиелитa, и SARS CoV-2. Проект важен с медицинской точки зрения, так как будет стимулирования исследований новых классов лекарств для контроля скорости вирусной адаптации. Новое программное обеспечение поможет созданию персонализированной терапии и вакцин против патогенов сопротивляющихся за счет своей быстрой эволюции.
Пример недавней работы
High-fidelity detection method of epistasis from DNA sequence samples
Pedruzzi & Rouzine, PLOS Pathogens 2021
A. The computer model of asexual evolution includes the factors of random mutation, selection, epistasis, and random genetic drift. Pairwise haplotype frequencies are averaged over an ensemble of independent simulation runs (populations). The strength of interactions, UFEij0, is calculated. The indirect links and the residual stochastic linkage disequilibrium are excluded by using triple-site haplotype frequencies, UFEij0.
B. Pre-set epistatic network for 50 sites. Real epistatic links are shown by green lines. The resulting indirect links are red lines. Some examples of stochastic linkage bonds are shown by blue lines. C-D. The network of strong ( UFE > 0.5 ) candidate epistatic interactions predicted (C) from a single population and (D) after averaging over 200 populations.
E. Scatter plot of 3-locus haplotype min(UFEij0) shown against UFEij for the pairs identified in (D). Dashed sector (green): Predicted direct interactions.
F. Predicted network accurately recapitulates the pre-set epistatic network.
Parameters:
- initial allele frequency 0.45,
- mutation rate per genome Ub = 0.07,
- fixed selection coefficient s = 0.1,
- epistatic strength E = 0.75.
Биография
До 1995 года, Игорь Рузин работал в теоретической физике конденсированного состояния. Затем он ушел в биологию и занялся общей теорией эволюции, вирусной эволюцией, и моделями адаптивного иммунного отклика. Комбинируя методы теоретической физики, популяционной генетики, иммунологии, и эпидемиологии, он моделирует эволюцию и динамику вирусов на уровне хозяина и популяции. Цель это понять и предсказать, с математической точностью, системное взаимодействие между факторами, формирующими эволюцию и динамику патогена. Этот стиль моделирования, называемый у математиков «восходящим», предназначен для ответа на вопросы «почему», «как» и «сколько», а не только для описания данных. Игорю приходилось работать с разными патогенами, включая ВИЧ, вирусы гриппа, полиомелита, везикулярного стоматита, и лимфатического хореоменингита, и малярийный плазмодий. Игорь сотрудничал с вирусологическими и иммунологическими лабораториями Джона Коффина из Университета Тафтса в Бостоне, Рафи Ахмеда из Университета штата Джорджия в Атланте, Леора Вайнбергера из Института Вирусологии и Иммунологии Гладстона в Сан-Франциско, и Рауля Андино из Калифорнийского университета в Сан-Франциско.
В 1999-2001 годах, Игорь предсказал что быстрая эволюция ВИЧ в пациентах, не принимающих антивирусные лекарства, связана с вторичными мутациями, которые компенсируют ранние мутации в эпитопах клеток ЦТЛ. Этот эффект был позже обнаружен и исследован. Игорь также выяснил какую роль стохастические эффекты и естественный отбор играют в эволюции ВИЧ и оценил эффективный размер популяции в типичных пациентах, что было позже подтверждено другими методами. Позже он разработал первую точную теорию бесполой эволюции с большим числом эволюционирующих локусов испытывающими сильные эффекты взаимной интерференции. Позже он показал, что даже очень редкая рекомбинация (например, ВИЧ) может во много раз ослабить эти эффекты и, соответственно, ускорить эволюцию. Затем он оценил параметры эволюции ВИЧ в пациентах, такие как средний коэффициент отбора, эффективный размер популяции, и частоту рекомбинации.
Игорь также предложил модель ВИЧ-инфекции, которая обьяснила ранее неизвестную эволюционную роль того что ВИЧ может пребывать в латентном состоянии. Стабильность и эволюция вируса в присутствии дефектных интерференционных частиц была исследована в сотрудничестве с лабораториями Леора Вайнбергера и Рауля Андино. С последним соавтором, Игорь также показал существование оптимальной вероятности мутации, как экспериментально, так и теоретически. Работая в Сорбонне, Игорь опубликовал статью, в которой скорость эволюции гриппа в человеческой популяции была выражена через иммунологические и эпидемиологические параметры, и вся задача была сведена к его предыдущей работе по бесполовой эволюции. Его группа также разработали высокоточный метод измерения адаптивного ландшафта на основе данных вирусной последовательности, что является наиболее важным параметром для прогнозирования вирусной адаптации.
Образование
1985 — Магистр, Санкт-Петербургский Электротехнический Университет (ЛЭТИ), Санкт-Петербург
1988 — Кандидат физико-математических наук, теоретическая физика полупроводников, Физико-Технический Институт имени Иоффе, Санкт-Петербург
Научные должности
2017-2021 — Group Leader, Sorbonne Université (Pierre et Marie Curie), Laboratory of Computational and Quantitative Biology, Paris
2015-2017 — Specialist, Microbiology, University of California, San Francisco
2012-2015 — Staff Scientist, The Gladstone Institute of Virology and Immunology, San Francisco
2007-2011 — Research Associate Professor, Department of Molecular Biology and Microbiology, Tufts University, Boston
2001-2007 — Research Assistant Professor, Department of Molecular Biology and Microbiology, Tufts University, Boston
1996-2000 — Research Associate, Department of Molecular Biology and Microbiology, Tufts University, Boston
1993-1995 — Postdoctoral (Research) Associate, Department of Physics, University of California, Los Angeles
1990-1993 — Postdoctoral (Research) Associate, Theoretical Physics Institute, University of Minnesota, Minneapolis
1985-1990 — Researcher, Theoretical Department, A.F. Ioffe Physical Technical Institute, St. Petersburg, Russia
Языки
- Английский свободный
- Русский родной
- Французский продвинутый
- Немецкий промежуточный
- Итальянский элементарный
Визиты
May 2016 — Pekin University, Center for Quantitative Biology, Bejing, China.
Oct-Nov 2015 — UPMC, Laboratory of Computational and Quantitative Biology, UMR 7238
CNRS- UPM, Paris, France
Oct-Dec 2011 — University of Cologne, Department of Physics, Germany
Aug-Sep 2011 — The Gladstone Institute of Virology and Immunology, San Francisco
June-July, 2011 — University of California at San Diego, Department of Chemistry and Biochemistry, La Jolla, CA, USA
Feb 2011 — Workshop on Microbial Evolution, KITP, University of California at Barbara, CA, USA
Mar, Jun-Aug 1995 — Harvard University, Department of Physics, Boston, USA
Apr-May, 1995 — Leiden University, Department of Physics, Leiden, Netherlands
Области специализации
- Computational and theoretical biology
- Dynamics and evolution of viruses
- Semiconductor Physics
Членство, комитеты, панели
2021-2022 — Organization Committee «QLife WS Quantitative Viral Dynamics Across Scales, March 21-25, 2022»
2021-now — Topic Editorial Board of Microorganisms
2018-2019 — Guest Editor of Pathogens
2006-2009 — Associate Editor of the Journal of Mathematical Analysis and Applications
2015-2017 — Member of the Society for Mathematical Biology
2013-2016 — Member of the American Mathematical Society
1990-1995 — Member of the American Physical Society
Преподавательская работа
2017-2019 — Instructor in Evolution Modeling for third-year students of Sorbonne-Polytech, Paris
2013 — Adjunct Professor in Astronomy for business majors, University of San Francisco
1995 — Lecturer in Electricity and Magnetism for CS and EE majors, University of California at Los Angeles
2018-2020 — Public lectures at la Fête de la Science, Sorbonne Université Campus Pierre et Marie Curie, Paris, https://www.sorbonne-universite.fr/les-lois-de-la-selection-naturelle
Рецензент международных научных журналов
AIDS Research Retroviruses
American Naturalist
BMC Evolution
BMC Microbiology
Bulletin of Mathematical Biology
Cell
Critical Reviews of Microbiology
EMBO
Genetics
Genes
Evolutionary Applications
Frontiers of Immunology
Inter. Journal of Molecular Sciences
Journal of Statistical Mechanics
Journal of Virology
Lancet Microbe
Nucleic Acid Research
Pathogens
Proceed. of Nat. Acad. Sciences of USA
PLoS Computational Biology
PLoS Pathogens
PLoS Genetics
PLoS ONE
Physical Review Letters
Physical Review B
Theoretical Population Biology
Viruses
Рецензент грантов
| 2020: | Vici grant proposal, Hague, Netherlands |
| 2011: | NIH research grant proposal (R01) |
| 2012: | NIH research grant proposal (R01) |
| 2012: | Vienna Research Group grant proposal for Young Investigators |
Полученные гранты
| 2017-2021: |
ANR grant «Hosting high-level researchers», $600,000 direct expenses |
| 2016-2020: |
Grant DARPA-BAA-16-35—INTERCEPT, USA, $273 000 |
| 2014-2016: |
grant R21AI109611 from National Institutes of Health, $500,000 total |
| 2006-2010: |
grant R01AI063926 from National Institutes of Health, USA, $1000,000 total |
| 2001-2005: |
grant K25AI01811 from National Institutes of Health, USA, $600,000 total |
Приглашенные семинары и доклады на конференциях
(28 total)
| 2021: | Seminar «Progression to AIDS and HIV controllers», IAME, University de Paris, INSERM |
| 2021: | Seminar «Progression to AIDS and HIV controllers», University of Heidelberg, Germany |
| 2020: | Seminar «Progression to AIDS and HIV controllers», University of Montpelier, France |
| 2019: | Nordita workshop «From Molecular Basis to Predictability and Control of Evolution», Stockholm, Sweden. |
| 2018: | 3d IFOM Symposium «Evolution, Resistance, and Cancer», IFOM, Milan, Italy. |
| 2015: | 5th Interdisciplinary Symposium «Genomics and Microbial Communities», Institut de Biologie Paris-Seine, UPMC, Paris |
| 2015: | Two seminars on the evolutionary role of HIV latency: Groupe de Travail math / bio, UPMC, Paris; Biophysique, Institut Curie, Paris |
| 2015: | Seminar on the evolutionary role of HIV latency, IBM, Almaden Research Center, San Jose, CA |
| 2014: | Seminar on modeling HIV evolution caused by the host immune response, IBM, Almaden, CA |
| 2014: | Program «Evolution of Drug Resistance», Kavli Institute of Theoretical Physics, University of California at Santa Barbara, CA |
| 2014: | «Workshop on From Within-Host Dynamics to the Epidemiology of Infectious Disease», Institute of Mathematical Biosciences, Columbus, Ohio |
| 2014: | Seminar on therapeutic inteference particles, Institute of Biology, Paris Seine, UPMC, 2012: Workshop on Discrete and Topological Models in Molecular Biology and AMS special session on Discrete Models in Molecular Biology, University of Florida, Tampa, FL, USA |
| 2011: | Seminar on modeling immune response against influenza, Department of Physics, University of Exeter, Exeter, UK |
| 2011: | Workshop on Microbial Evolution, Kavli Institute for Theoretical Physics, University of California at Santa Barbara, Santa Barbara, CA, USA |
| 2010: | Seminar on evolution theory, The National Evolutionary Synthesis Center, Duke University, Durham, NC, USA |
| 2009: | International 3rd Eastern European and Central Asia AIDS Conference, Moscow, Russia |
| 2007: | Workshop on Theoretical Immunology, University of Leuven, Belgium |
| 2006: | Workshop on Mathematical Population Genetics, Edinburgh, UK |
| 2006: | Seminar on evolution theory, Department of Evolution and Ecology, University of California at Davis, CA, USA |
| 2006: | Two seminars on evolution theory and modeling HIV immunology, Department of Physics, University of California at San Diego, CA, USA |
| 2005: | Seminar on modeling HIV immunology, Centre for Non-Linear Dynamics, Department of Physiology, McGill University, Montreal, Canada |
| 2004: | Seminar on asexual evolution, Department of Biostatistics, University of California at Los Angeles, CA, USA |
| 2004: | Seminar on evolution and dynamics of HIV at A.F. Ioffe Physical Technical Institute, St. Petersburg, Russia |
| 2003: | Seminar in Genomics Center, Harvard University, Cambridge, MA, USA |
| 2002: | Seminar on evolution theory of asexual populations, Department of Applied Mathematics, Massachusetts Technological Institute, Cambridge, MA, USA |
| 2002: | Seminar on evolution theory of asexual populations, Department of Physics, Harvard University, Cambridge, MA, USA |
| 1998: | Meeting on HIV Dynamics and Evolution, organized by University of California at San Diego |
| 1995: | Seminar on antigenic escape of HIV from the immune response, Department of Microbiology, University of California, CA, USA |
Другие доклады на конференциях
| 2021: | EEID Agropolis International (Université de Montpelier) |
| 2021: | WIP ANRS AC41 (ANRS, Paris) |
| 2021: | Alphy: Genomique evolutive (Université de Montpelier, Lyon, Grenoble) |
| 2020: | Approche Interdisciplinaire de l’Evolution Moleculaire, Annual Meeting (CNRS INEE ) |
| 2012-2013: | 4 informal seminars and 6 talks at the University of California at San Francisco |
| 1996-2012: | 20+ conferences including annual series: Meeting on HIV evolution and dynamics (organized by UCSD, La Jolla, CA, USA) Retroviruses (Cold Spring Harbor, NY) Conference on Retroviruses and Opportunistic Infections Keystone meetings at Keystone, Colorado, and Banff, Alberta, Canada |
| 1990-1995: | 8-9 conferences including annual series: Meeting of American Physical Society Aspen Workshop on Condensed Matter Theory, Aspen, Colorado |
Обучение аспирантов и ведение после защиты диссертации
| 2020: | Luis Pereira, postdoctoral associate, Sorbonne Université Campus Pierre et Marie Curie, Paris |
| 2018: | Ayuna Barlukova, postdoctoral associate, Sorbonne Université Campus Pierre et Marie Curie, Paris |
| 2017-2019: | Gabriele Pedruzzi, postdoctoral associate, Sorbonne Université Campus Pierre et Marie Curie, Paris |
| 2014-2015: | Ariel Weinberger, collaborator and postdoctoral fellow at Harvard University |
| 2013-2015: | Luke Rast, intern, Gladstone Institute of Virology and Immunology, University of California, San Francisco |
| 2012: | Lisa Bishop, postdoctoral associate, Gladstone Institute of Virology and Immunology, University of California at San Francisco |
| 2008-2012: | Rebecca Batorsky, graduate student, Department of Physics at Tufts University, Boston. |
| 2006-2009: | Rinat Sergeev, postdoctoral associate, Department of Molecular Biology and Microbiology, Tufts University. (Current employment: Institute for Quantitative Social Science, Harvard University) |
| 2007-2008: | Elena Gubankova, postdoctoral associate, Department of Molecular Biology and Microbiology, Tufts University |
| 2003-2005: | Speranta Gheorghiu, postdoctoral associate, Department of Molecular Biology and Microbiology, Tufts University |
Сотрудничество с экспериментальными группами
Raul Andino lab, Department of Microbiology and Immunology, University of California at San Francisco
Weinberger lab of Synthetic and Quantitative Virology, Gladstone Institute of Virology and Immunology, San Francisco
Coffin lab of Retrovirology, Department of Molecular Biology and Microbiology, Tufts University, Boston
John Coffin, Director (now Special Consultant), the HIV Drug Resistance Program at National Cancer Institute, NIH, Frederick, DC, USA
Novella lab of RNA virus evolution, College of Medicine, University of Toledo, Toledo, OH, USA
Rafi Ahmed, Director, Emory Vaccine Center, Atlanta, GA, USA
Список публикаций
Наиболее оригинальные работы
Rouzine* IM, Wakeley J, Coffin JM (2003) The solitary wave of asexual evolution. Proc Nat Acad Sci 100: 587-592
The first accurate mathematical analysis predicting the evolution rate of a population with a large number of linked loci in the absence of recombination.
Rouzine IM, Weinberger, AD, and Weinberger*, LS (2015) An evolutionary role for HIV latency in enhancing viral transmission. Cell 160, 1002–12
An evolutionary role for HIV latency is a Trojan horse effect during transmission.
Rouzine* IM, Coffin JM (2001) Transition between stochastic evolution and deterministic evolution in the presence of selection: general theory and application to virology [review]. Microbio Mol Bio Rev 65: 151-185
The classical stochastic theory of evolution 1930-1970 is reviewed and adapted for virology.
IM Rouzine (2020) An evolutionary model of progression to AIDS. Microorganisms 8, 1714
The first closed model of progression to AIDS is proposed based on gradual adaptation of HIV to a host is proposed.
Good BH, Rouzine IM, Balick DJ, Hallatschek O, and Desai* MM (2012) Distribution of fixed beneficial mutations and the rate of adaptation in asexual populations. Proc Natl Acad Sci U S A 109: 4950-4955
The traveling wave theory is generalized for the arbitrary distribution of mutational fitness effects.
Rouzine* IM and Rozhnova G (2018) Antigenic evolution of viruses in host populations. PLoS Pathogens 14, e1007291
A model of genetic evolution of a virus in a host population accumulating the immune memory connects epidemiology to immunology and the modern evolution theory. The predicted parameters are tested against data for influenza A.
Batorsky R, Kearney MF, Palmer SE, Maldarelli F, Rouzine* IM, Coffin JM (2011) Estimate of effective recombination rate and average selection coefficient for HIV in chronic infection. Proc Natl Acad Sci U S A 108: 5661
Rouzine* IM, Coffin JM (1999) Linkage disequilibrium test implies a large effective population number for HIV in vivo. Proc Nat Acad Sci 96: 10758-10763
The effective population size and the effective recombination rate of HIV are estimated correctly for the first time.
Rouzine* IM, Coffin JM (2005) Evolution of HIV under selection and weak recombination. Genetics 170: 7-18
Rouzine* IM, and Coffin, JM (2010) Many-site adaptation in the presence of infrequent recombination. Theor Pop Bio 77: 189-204
Recombination is incorporated in the modern multi-locus evolution theory
Rouzine* IM, Coffin JM (1999) Search for the mechanism of evolution in the pro gene of HIV in vivo. J Virol 73: 8167-8178.
The high diversity of HIV within and between infected individuals is explained as a result of compensatory mutations for the early escape mutations in CD8 T cell epitopes. The average value of the effective selection coefficient for HIV patient is estimated.
Rouzine* IM, McKenzie FE (2003) Link between immune response and parasite synchronization in malaria. Proc Nat Acad Sci 100: 3473-3478
Chaotic oscillations of parasitemia in malaria are predicted as a result of communication between different parasites in different phases of cell replication.
Монографии
Rouzine IM. (2020) «Mathematical Models of Evolution. Volume 1: One-locus and multi-locus theory and recombination», in series Mathematics and life sciences, De Gruyter, Berlin/Boston.
Главы в книгах
* Auteur correspondant
Rouzine* IM, Coffin JM (1999) Interplay between experiment and theory in development of a working model for HIV-1 population dynamics, in: Origin and Evolution of Viruses, eds. E.Domingo, R.Webster and J.Holland, Academic, London, 1999, pp.225-262.
Raikh* ME, Ruzin IM (1991) Transmittance fluctuations in randomly non-uniform barriers and incoherent mesoscopics, review, in: Mesoscopic Phenomena in Solids, eds. B.L.Altshuler, P.A.Lee and R.A.Webb. North Holland, Amsterdam, 1991, pp. 301-354.
Raikh* ME, Ruzin IM (1990) Distribution function of conductance of finite-size inhomogeneous barrier structures, in: Hopping and Related Phenomena, eds. H. Fritzsche and M. Pollak. World Scientific, Singapore, 1990, pp. 217-241.
https://www.worldscientific.com/doi/abs/10.1142/9789814434447_0017
Рецензированные статьи (всего 64)
Вычислительная и теоретическая биология
Pedruzzi G, Rouzine* IM (2021) An evolution-based high-fidelity method of epistasis measurement: theory and application to influenza. PLoS. Pathog. 17, e1009669. IF 6.2
Barlukova A, Rouzine* IM (2021) The evolutionary origin of the universal distribution of mutation fitness effect. PLoS Comp. Bio. 17, e1008822. IF 4.5
Rouzine IM (2020) An evolutionary model of progression to AIDS. Microorganisms 8, 1714 IF 4.2
Pedruzzi G, Rouzine IM * (2019) Epistasis detectably alters correlations between genomic sites in a narrow parameter window. PLoS ONE 14, e0214036. IF 2.7
Pedruzzi G, Barlukova A, Rouzine* IM (2018) Evolutionary footprint of epistasis. PLoS Computational Biology 14, e1006426. IF 4.5
Rouzine* IM, Rozhnova G (2018) Antigenic evolution of viruses in host populations. PLoS Pathogens 14, e1007291. IF 6.5
Lidsky PV, Andino R *, Rouzine IM (2017) Variability in viral pathogenesis: modeling the dynamic of acute and persistent infections. Current Opinion in Virology 23, 120-124. IF 5.6
Xiao Y, Rouzine IM, Bianco S, Acevedo A, Goldstein EF, Farkov, M, Andino M *. RNA recombination enhances adaptability and is required for virus spread and virulence (2016). Cell host & microbe 19 (4), 493-503. IF 17.9
LI Rast, IM Rouzine, G Rozhnova, L Bishop, AD, Weinberger*, LS. Conflicting selection pressures will constrain viral escape from interfering particles: principles for designing resistance-proof antivirals (2016). PLoS Computational Biology 12 (5), e1004799. IF 4.0
Rouzine, IM, Weinberger, AD, and Weinberger*, LS (2015) An evolutionary role for HIV latency in enhancing viral transmission. Cell 160, 1002–1012. IF 31.4
Razooky, BS, Pai, A, Aull, K, Rouzine, IM, and Weinberger*, LS (2015) A hardwired HIV latency program. Cell 160, 990–1001. IF 31.4
Batorsky, R, Sergeev, RA, Rouzine*, IM (2014) The route of HIV escape from immune response targeting multiple sites is determined by the cost-benefit tradeoff of escape mutations. PLoS Comp. Bio. 10, e1003878. IF 4.0
Rouzine IM, Razooky, BS, Weinberger*, LS (2014) Stochastic variability in HIV affects viral eradication. Proc Natl. Acad. Sci. U S A 111, 13251–13252. IF 9.5
Rouzine* IM, Coffin JM, Weinberger LS (2014) 15 years later: Hard and soft selection sweeps confirm a large population number for HIV in vivo. PLOS Genetics 10, e1004179. IF 5.5
Rouzine IM, Weinberger* LS (2013) Reply to »Coadaptive stability of interfering particles with HIV-1 when there is an evolutionary conflict». J Virol 87: 9960. IF 4.4
Rouzine IM, Weinberger* LS (2013) Design requirements for interfering particles to maintain co-adaptive stability with HIV-1. J Virol 87: 2081-2093. IF 4.4
Rouzine* IM, Weinberger LS (2013) The quantitative theory of within-host viral evolution [review]. J Stat Mech (2013) P01009
Good BH, Rouzine IM, Balick DJ, Hallatschek O, and Desai* MM (2012) Distribution of fixed beneficial mutations and the rate of adaptation in asexual populations. Proc Natl Acad Sci U S A 109: 4950-4955 IF 9.5
Batorsky R, Kearney MF, Palmer SE, Maldarelli F, Rouzine* IM, Coffin JM (2011) Estimate of effective recombination rate and average selection coefficient for HIV in chronic infection. Proc Natl Acad Sci U S A 108: 5661- IF 9.5
Rouzine*, IM, and Coffin, JM (2010) Many-site adaptation in the presence of infrequent recombination. Theor Pop Bio 77: 189-204
Sergeev, RA, Batorsky, RE, and Rouzine*, IM (2010) Model with two types of CTL regulation and experiments on CTL dynamics. J Theor Bio 263: 369-84.
Sergeev, RA, Batorsky, RE, and Rouzine*, IM (2010) Interpreting the effect of vaccination on steady state infection in animals challenged with simian immunodeficiency virus. J Theor Bio 263: 385-92.
Brunet*, E, Rouzine, IM, and Wilke, CO (2008) The stochastic edge in adaptive evolution. Genetics 179: 603-620 IF 3.8
Dutta, RN, Rouzine, IM, Smith, SD, Wilke, CO, and Novella*, IS (2008) Rapid adaptive amplification of preexisting variation in an RNA virus. J Virol 82: 4354-4362. IF 4.4
Rouzine*, IM, Brunet, E, and Wilke, CO (2008) The traveling-wave approach to asexual evolution: Muller’s ratchet and speed of adaptation. Theor Popul Biol 73: 24-46.
Rouzine* IM, Coffin JM (2007) Highly fit ancestors of partly sexual populations. Theor Pop Bio 71: 239-150.
Gheorghiu-Svirschevski S, Rouzine* IM, Coffin JM (2007) Increasing sequence correlations limits the efficiency of recombination in a multi-site evolution model. Mol Bio Evol 254: 574-586. IF 10.2
Rouzine* IM, Sergeev RA, Glushtsov AI (2006) Two types of cytotoxic lymphocyte regulation explain kinetics of immune response to human immunodeficiency virus. Proc Nat Acad Sci 103: 666-671 IF 9.5
Rouzine* IM, Coffin JM (2005) Evolution of HIV under selection and weak recombination. Genetics 170: 7-18 IF 3.8
Rouzine* IM, Murali-Krishna K, Ahmed R (2005) Generals die in friendly fire, or modeling immune response to HIV. J Comp Appl Math 184: 258-274. IF 1.4
Rouzine* IM, Wakeley J, Coffin JM (2003) The solitary wave of asexual evolution. Proc Nat Acad Sci 96: 587-592 IF 9.5
Rouzine* IM, McKenzie FE (2003) Link between immune response and parasite synchronization in malaria. Proc Nat Acad Sci 100: 3473-3478 IF 9.5
Rouzine* IM, Coffin JM (2001) Transition between stochastic evolution and deterministic evolution in the presence of selection: general theory and application to virology [review]. Microbio Mol Bio Rev 65: 151-185 IF 13.4
Rouzine* IM, Coffin JM (1999) Linkage disequilibrium test implies a large effective population number for HIV in vivo. Proc Nat Acad Sci 96: 10758-10763 IF 9.5
Rouzine* IM, Coffin JM (1999) Search for the mechanism of evolution in the pro gene of HIV in vivo. J Virol 73: 8167-8178 IF 4.4
Rouzine* IM, Coffin JM (1999) T cell turnover in SIV infection [comment]. Science 284: 555b IF 37.2
Теоретическая физика
NB: Рузин писался в публикациях по физике как Ruzin, а в публикациях по биологии как Rouzine.
Cooper* NR, Halperin BI, Hu C, Ruzin IM Statistical properties of the low-temperature conductance peak heights for Corbino disks in the quantum Hall regime. Phys Rev B 1997; 55: 4551-
Cooper* NR, Halperin BI, Ruzin IM Thermoelectric response of an interacting two-dimensional electron gas in quantizing magnetic field. Phys Rev B 1997; 55: 2344-
Ruzin* IM, Cooper N, Halperin BI Non-universal behavior of finite quantum Hall systems as a result of weak macroscopic inhomogeneities. Phys Rev B 1996; 53: 1558-
Ruzin* I, Feng S Universal relation between longitudinal and transverse conductivities in quantum Hall effect. Phys Rev Lett 1995; 74: 154-
Dykhne AM, Ruzin* IM Theory of the fractional quantum Hall effect: The two-phase model. Phys Rev B 1994; 50: 2369-2379
Aleiner IL, Ruzin* IM Density of states of localized phonons in a pinned Wigner crystal. Phys Rev Lett 1994; 72: 1056-1060
Ruzin IM Hall transport in non-uniform two-dimensional conductors. Phys Rev B 1993; 47: 15727-15734
Ruzin* IM, Marianer S, Shklovskii BI Pinning of a two-dimensional Wigner crystal by charged impurities. Phys Rev B 1992: 46: 3999-4008
Ruzin IM, Chandrasekhar V, Levin EI, Glazman* LI Stochastic Coulomb blockade in a double-dot system. Phys Rev B 1992; 45: 13469-13478
Glazman LI, Ruzin IM, Shklovskii* BI Quantum transport and pinning of one-dimensional Wigner crystal. Phys Rev B 1992; 45: 8454-8463
Glazman* LI, Ruzin IM Metal-to-insulator crossover in mesoscopic wires [review]. Physica Scripta 1992; T42: 122-
Ruzin IM Fine structure of hopping conductance fluctuations in finite-size semiconductors. Phys Rev B 1991; 43: 11864-11872
SD Baranovskii, EI Levin, IM Ruzin, H Fritzsche, BI Shklovskii Computer simulation of energy relaxation and recombination of nonequilibriumelectrons in a disordered system with localized electronic states International Journal of Modern Physics C 1991; 2 : 220-222
Raikh ME, Ruzin* IM Size effect in the longitudinal hopping conduction of a narrow two-dimensional channel. Phys Rev B 1990; 42: 11203-11207
Ruzin IM, Shklovskii BI Theory of hopping conductivity due to long-wavelength excitation. Sov Phys Semicond 1989; 23: 1164-1167
Orlov AO, Raikh ME, Ruzin IM, Savchenko AK Statistical properties of mesoscopic conductivity fluctuations in a short-channel GaAs field-effect transistor. Sov Phys JETP 1989; 69: 1229-1236
Baranovskii SD, Fritzsche H, Levin EI, Ruzin IM, Shklovskii BI Theory of low-temperature photoconductivity and photoluminescence in amorphous semiconductors. Sov Phys JETP 1989; 69: 773-782
Raikh ME, Ruzin IM Fluctuations of the hopping conductance of one-dimensional systems. Sov Phys JETP 1989; 68: 642-647
Orlov AO, Raikh ME, Ruzin IM, Savchenko AK Distribution function of hopping conductance fluctuations of a short GaAs field- effect transistor channel. Solid State Communic 1989; 72: 169-172
Raikh ME, Ruzin IM, Shklovskii BI Influence of localized states in a barrier on a fluctuation tunnel current flowing across a metal-semiconductor contact. Sov Phys Semicond 1988; 22: 1254-1257
Raikh ME, Ruzin IM Mesoscopic behavior of the transverse hopping conductivity of an amorphous film. Sov Phys Semicond 1988; 22: 799-805
Levin EI, Ruzin IM, Shklovskii BI Transverse hopping conductivity of amorphous films in strong electric fields. Sov Phys Semicond 1988; 22: 401-408
Raikh ME, Ruzin IM Transparency fluctuations in randomly inhomogeneous barriers of finite area. Sov Phys JETP 1987; 65: 1273-1282
Tartakovskii AV, Fistul MV, Raikh ME, Ruzin IM Hopping conductivity of metal-semiconductor-metal contacts. Sov Phys Semicond 1987; 21: 370-373
Raikh ME, Ruzin IM Temperature dependence of fluctuation excess currents flowing across a metal-semiconductor contact. Sov Phys Semicond 1987; 21: 283-285
Raikh ME, Ruzin IM Mesoscopic behavior of the temperature dependence of the transverse hopping conductivity of an amorphous film. JETP Lett 1986; 43: 563-565
Gerbstein* YuM, Ruzin IM, Chudnovskii FA Fractal dimensionality of silver dendrites in the two-dimensional ionically conducting system Ag-AgI-Ag. Sov Phys Solid State 1986; 28: 1073-1074
Raikh* ME, Ruzin IM Fluctuation mechanism of excess tunnel currents in reverse-biased p-n— junctions. Sov Phys Semicond 1985; 19: 745-750
