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Тоневицкий Александр Григорьевич

Факультет биологии и биотехнологии

Профиль на hse.ru ↗ тел.: +7 (495) 772-95-90 | 15093
Публикаций
92
Языков
1
Наград
8
Конференций
1
Профиль Публикации (92) Курсы (6)

Профессиональные интересы

молекулярная биологиямикрофлюидные системыбелковые молекулы

Должности

  • ДеканФакультет биологии и биотехнологии
  • ПрофессорФакультет биологии и биотехнологии, Базовая кафедра Института биоорганической химии им. академиков М.М. Шемякина и Ю.А. Овчинникова РАН
  • Главный научный сотрудникФакультет биологии и биотехнологии, Лаборатория исследований молекулярных механизмов долголетия
  • Главный научный сотрудникФакультет биологии и биотехнологии, Международная лаборатория микрофизиологических систем

Био

  • · Начал работать в НИУ ВШЭ в 2018 году.
  • · Научно-педагогический стаж: 18 лет.

Образование

  • 2025 · Академик РАН
  • 2006 · Член-корреспондент РАН
  • 1995 · Ученое звание: Профессор
  • 1993 · Доктор биологических наук
  • 1985 · Кандидат биологических наук
  • 1979 · Специалитет: Московский государственный университет им. М.В. Ломоносова, специальность «Биология», квалификация «Биолог»

Опыт работы

  • · 1974-1981: Российский кардиологический центр РКНПК МЗ РФ
  • · 1994: Присвоено звание профессора по специальности «Молекулярная биология»
  • · 1991-1995: Заведующий лабораторией в «Государственный НИИ генетики»
  • · 1995-1996: Заместитель директора Института иммунологии МЗ и МПРФ
  • · 1996-2006: Заместитель директора НИИ Трансплантологии и искусственных органов МЗ РФ
  • · 2006: Избран членом-корреспондентом Российской Академии Наук
  • · 2006-2011: Директор ФГУ «Всероссийский научно-исследовательский институт физической культуры и спорта» Министерства спорта, туризма и молодежной политики Российской Федерации
  • · 2011-2014: Заведующий лабораторией НИИ общей патологии и патофизиологии РАМН
  • · 2014-2017: Заведующий отделом трансляционной онкологии ФГБУ «НМИРЦ» Минздрава России
  • · 2017-2018: Ведущий научный сотрудник лаборатории биокатализа ФГБУН Институт биоорганической химии им. академиков М.М. Шемякина и Ю.А. Овчинникова Российской академии наук (ИБХ РАН)
  • · 2018: с Заведующий кафедры клеточной биологии ФГАОУ ВО Национального исследовательского университета «Высшая школа экономики»
  • · Другие занимаемые должности
  • · Председатель экспертной комиссии по биологии и наукам о жизни Совета по грантам Президента РФ Министерства образования и науки РФ;
  • · Член экспертного совета по биотехнологии Министерства промышленности и торговли РФ;
  • · Заместитель председателя экспертного совета РФФИ по международным грантам.

Награды и поощрения

  • · Орден Дружбы народов (сентябрь 2024)
  • · Почетная грамота НИУ ВШЭ (март 2022)
  • · Благодарность Высшей школы экономики (декабрь 2021)
  • · Почетное звание "Заслуженный деятель науки Российской Федерации" (июнь 2018)
  • · Почетная грамота Российской Академии медицинских наук (июнь 2012)
  • · Надбавка за публикацию в журнале из Списка А (и приравненном к нему научном издании) (2024–2025, 2023–2024)
  • · Надбавка за публикацию в международном рецензируемом научном издании (2022–2023, 2021–2022, 2019–2021)
  • · Надбавка за регулярные публикации в международных рецензируемых научных изданиях (2025–2030)

Гранты и проекты

  • · на соискание учёной степени кандидата наук

Конференции (1)

Показать все
  • · 2024: Седьмой онлайн-семинар по математическому моделированию в области иммунологии (Москва). Доклад: Моделирование динамики SARS-CoV-2 в клеточных линиях

Идентификаторы исследователя

Публикации (92)

Potential role of cellular miRNAs in coronavirus-host interplay

2020 · ARTICLE · en

Host miRNAs are known as important regulators of virus replication and pathogenesis. They can interact with various viruses through several possible mechanisms including direct binding of viral RNA. Identification of human miRNAs involved in coronavirus-host interplay becomes important due to the ongoing COVID-19 pandemic. In this article we performed computational prediction of high-confidence direct interactions between miRNAs and seven human coronavirus RNAs. As a result, we identified six miRNAs (miR-21-3p, miR-195-5p, miR-16-5p, miR-3065-5p, miR-424-5p and miR-421) with high binding probability across all analyzed viruses. Further bioinformatic analysis of binding sites revealed high conservativity of miRNA binding regions within RNAs of human coronaviruses and their strains. In order to discover the entire miRNA-virus interplay we further analyzed lungs miRNome of SARS-CoV infected mice using publicly available miRNA sequencing data. We found that miRNA miR-21-3p has the largest probability of binding the human coronavirus RNAs and being dramatically up-regulated in mouse lungs during infection induced by SARS-CoV.

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Взаимосвязь изменения экспрессии микроРНК и мРНК в клетках линии НТ-29 в условиях гипоксии

2020 · ARTICLE · ru

Гипоксия возникает в различных патофизиологических процессах, включая прогрессирование опухолевых заболеваний и метастазирование. Один из механизмов молекулярного ответа клеток на гипоксию состоит в рекрутировании специфичных микроРНК, регулирующих экспрессию своих генов-мишеней. Целью работы было оценить изменения экспрессии микроРНК и их генов-мишеней в клеточной линии колоректальной аденокарциномы человека HT-29 в ответ на гипоксию с помощью интегрированного секвенирования микроРНК и мРНК. Для моделирования условий гипоксии клетки обрабатывали хлоридом кобальта (II). Было обнаружено достоверное изменение экспрессии шестнадцати человеческих микроРНК, шесть из них (hsa-miR-18a-5p, hsa-miR-22-3p, hsa-miR-27a-5p, hsa-miR-182-5p, hsa-miR- 215-5p, hsa-miR-425-5p) имели статистически значимую долю генов-мишеней с противоположным направлением изменения экспрессии. На основании биоинформатического анализа взаимодействий дифференциально экспрессированных факторов транскрипции и микроРНК была построена возможная регуляторная сеть, основыми узлами которой оказались HIF-1a, p65, с-Myc и Egr1 (кодируемые генами HIF1A, RELA, MYC и EGR1).

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Xenograft-derived mRNA/miR and protein interaction networks of systemic dissemination in human prostate cancer

2020 · ARTICLE · en

Background Distant metastasis formation is the major clinical problem in prostate cancer (PCa) and the underlying mechanisms remain poorly understood. Our aim was to identify novel molecules that functionally contribute to human PCa systemic dissemination based on unbiased approaches. Methods We compared mRNA, microRNA (miR) and protein expression levels in established human PCa xenograft tumours with high (PC-3), moderate (VCaP) or weak (DU-145) spontaneous micrometastatic potential. By focussing on those mRNAs, miRs and proteins that were differentially regulated among the xenograft groups and known to interact with each other we constructed dissemination-related mRNA/miR and protein/miR networks. Next, we clinically and functionally validated our findings. Results Besides known determinants of PCa progression and/or metastasis, our interaction networks include several novel candidates. We observed a clear role of epithelial-to-mesenchymal transition (EMT) pathways for PCa dissemination, which was additionally confirmed by an independent human PCa model (ARCAP-E/-M). Two converging nodes, CD46 (decreasing with metastatic potential) and DDX21 (increasing with metastatic potential), were used to test the clinical relevance of the networks. Intriguingly, both network nodes consistently added prognostic information for patients with PCa whereas CD46 loss predicted poor outcome independent of established parameters. Accordingly, depletion of CD46 in weakly metastatic PCa cells induced EMT-like properties in vitro and spontaneous micrometastasis formation in vivo. Conclusions The clinical and functional relevance of the dissemination-related interaction networks shown here could be successfully validated by proof-of-principle experiments. Therefore, we suggest a direct pro-metastatic, clinically relevant role for the multiple novel candidates included in this study; these should be further exploited by future studies.

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Towards embedding Caco-2 model of gut interface in a microfluidic device to enable multi-organ models for systems biology

2019 · ARTICLE · en

A cancer cell line originating from human epithelial colorectal adenocarcinoma (Caco-2 cells) serves as a high capacity model for a preclinical screening of drugs. Recent need for incorporating barrier tissue into multi-organ chips calls for inclusion of Caco-2 cells into microperfused environment. This article describes a series of systems biology insights obtained from comparing Caco-2 models cells grown as conventional 2D layer and in a microfluidic chip. When basic electrical parameters of Caco-2 monolayers were evaluated using impedance spectrometry and MTT assays, no differences were noted. On the other hand, the microarray profiling of mRNAs and miRNAs revealed that grows on a microfluidic chip leads to the change in the production of specific miRNA, which regulate a set of genes for cell adhesion molecules (CAMs), and provide for more complete differentiation of Caco-2 monolayer. Moreover, the sets of miRNAs secreted at the apical surface of Caco-2 monolayers grown in conventional 2D culture and in microfluidic device differ. When integrated into a multi-tissue platform, Caco-2 cells may aid in generating insights into complex pathophysiological processes, not possible to dissect in conventional cultures.

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Specific refolding pathway of viscumin A chain in membrane-like medium reveals a possible mechanism of toxin entry into cell.

2019 · ARTICLE · en

How is a water-soluble globular protein able to spontaneously cross a cellular membrane? It is commonly accepted that it undergoes significant structural rearrangements on the lipid-water interface, thus acquiring membrane binding and penetration ability. In this study molecular dynamics (MD) simulations have been used to explore large-scale conformational changes of the globular viscumin A chain in a complex environment – comprising urea and chloroform/methanol (CHCl3/MeOH) mixture. Being well-packed in aqueous solution, viscumin A undergoes global structural rearrangements in both organic media. In urea, the protein is “swelling” and gradually loses its long-distance contacts, thus resembling the “molten globule” state. In CHCl3/MeOH, viscumin A is in effect turned “inside out”. This is accompanied with strengthening of the secondary structure and surface exposure of hydrophobic epitopes originally buried inside the globule. Resulting solvent-adapted models were further subjected to Monte Carlo simulations with an implicit hydrophobic slab membrane. In contrast to only a few point surface contacts in water and two short regions with weak protein-lipid interactions in urea, MD-derived structures in CHCl3/MeOH reveal multiple determinants of membrane interaction. Consequently it is now possible to propose a specific pathway for the structural adaptation of viscumin A with respect to the cell membrane – a probable first step of its translocation into cytoplasmic targets.

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Transcriptome of Extracellular Vesicles: State-of-the-Art

2019 · ARTICLE · en

Exosomes and microvesicles are two major categories of extracellular vesicles (EVs) released by almost all cell types and are highly abundant in biological fluids. Both the molecular composition of EVs and their release are thought to be strictly regulated by external stimuli. Multiple studies have consistently demonstrated that EVs transfer proteins, lipids and RNA between various cell types, thus mediating intercellular communication, and signaling. Importantly, small non-coding RNAs within EVs are thought to be major contributors to the molecular events occurring in the recipient cell. Furthermore, RNA cargo in exosomes and microvesicles could hold tremendous potential as non-invasive biomarkers for multiple disorders, including pathologies of the immune system. This mini-review is aimed to provide the state-of-the-art in the EVs-associated RNA transcriptome field, as well as the comprehensive analysis of previous studies characterizing RNA content within EVs released by various cells using next-generation sequencing. Finally, we highlight the technical challenges associated with obtaining pure EVs and deep sequencing of the EV-associated RNAs.

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Metabolic Reprogramming of Trophoblast Cells in Response to Hypoxia

2019 · ARTICLE · en

Hypoxia of trophoblast cells is an important regulator of normal development of the placenta. However, some pathological states associated with hypoxia, e.g. preeclampsia, impair the functions of placental cells. Oxyquinoline derivative inhibits HIF-prolyl hydroxylase by stabilizing HIF-1 transcription complex, thus modeling cell response to hypoxia. In human choriocarcinoma cells BeWo b30 (trophoblast model), oxyquinoline increased the expression of a core hypoxia response genes along with up-regulation of NOS3, PDK1, and BNIP3 genes and down-regulation of the PPARGC1B gene. These changes in the expression profile attest to activation of the metabolic cell reprogramming mechanisms aimed at reducing oxygen consumption by enabling the switch from aerobic to anaerobic glucose metabolism and the respective decrease in number of mitochondria. The possibility of practical use of the therapeutic properties of oxyquinoline derivatives is discussed.

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Oxyquinoline-Dependent Changes in Claudin-Encoding Genes Contribute to Impairment of the Barrier Function of the Trophoblast Monolayer

2019 · ARTICLE · en

Natural response to hypoxia critically depends on rapid stabilization of hypoxia-inducible factor (HIF). Under normoxic conditions, HIF-prolyl hydroxylases mark α-subunits of HIF for degradation, while hypoxia results in stabilization of HIF-α. Oxyquinoline derivatives suppress activity of HIF-prolyl hydroxylases leading to HIF activation in the cell. Here we show that 24-h incubation of BeWo b30 choriocarcinoma cells (a model of trophoblast in the placental barrier) with oxyquinoline derivative leads to a decrease in transepithelial electrical resistance (TEER) of the cell monolayer, while the permeability of the monolayer for FITC-dextran (70 kDa) remains unchanged. These findings suggest that the overall barrier function is preserved, while the structure of intercellular tight junctions can undergo minor changes. Using Affymetrix Human Transcriptome Array 2.0, we showed that the treatment with oxyquinoline derivative was followed by a decrease in the expression of claudins 6 and 7 (CLDN6, CLDN7), occludin (OCLN), contact adhesion molecule 3 (JAM3), and angiomotinlike protein 1 (AMOTL1).

DOI ↗ PDF ↗

Specific refolding pathway of viscumin A chain in membrane-like medium reveals a possible mechanism of toxin entry into cell

2019 · ARTICLE · en

How is a water-soluble globular protein able to spontaneously cross a cellular membrane? It is commonly accepted that it undergoes significant structural rearrangements on the lipid-water interface, thus acquiring membrane binding and penetration ability. In this study molecular dynamics (MD) simulations have been used to explore large-scale conformational changes of the globular viscumin A chain in a complex environment – comprising urea and chloroform/methanol (CHCl3/MeOH) mixture. Being well-packed in aqueous solution, viscumin A undergoes global structural rearrangements in both organic media. In urea, the protein is “swelling” and gradually loses its long-distance contacts, thus resembling the “molten globule” state. In CHCl3/MeOH, viscumin A is in effect turned “inside out”. This is accompanied with strengthening of the secondary structure and surface exposure of hydrophobic epitopes originally buried inside the globule. Resulting solvent-adapted models were further subjected to Monte Carlo simulations with an implicit hydrophobic slab membrane. In contrast to only a few point surface contacts in water and two short regions with weak protein-lipid interactions in urea, MD-derived structures in CHCl3/MeOH reveal multiple determinants of membrane interaction. Consequently it is now possible to propose a specific pathway for the structural adaptation of viscumin A with respect to the cell membrane – a probable first step of its translocation into cytoplasmic targets.

DOI ↗ PDF ↗

Adipose may actively delay progression of NAFLD by releasing tumor‐suppressing, anti‐fibrotic miR‐122 into circulation

2019 · ARTICLE · en

Nonalcoholic fatty liver disease (NAFLD) is the most common liver pathology. Here we propose tissue‐cooperative, homeostatic model of NAFLD. During early stages of NAFLD the intrahepatic production of miR‐122 falls, while the secretion of miRNA‐containing exosomes by adipose increases. Bloodstream carries exosome to the liver, where their miRNA cargo is released to regulate their intrahepatic targets. When the deterioration of adipose catches up with the failing hepatic parenchyma, the external supply of liver‐supporting miRNAs gradually tapers off, leading to the fibrotic decompensation of the liver and an increase in hepatic carcinogenesis. This model may explain paradoxical observations of the disease‐associated decrease in intrahepatic production of certain miRNAs with an increase in their levels in serum. Infusions of miR‐122 and, possibly, some other miRNAs may be efficient for preventing NAFLD‐associated hepatocellular carcinoma. The best candidates for exosome‐wrapped miRNA producer are adipose tissue‐derived mesenchymal stem cells (MSCs), known for their capacity to shed large amounts of exosomes into the media. Notably, MSC‐derived exosomes with no specific loading are already tested in patients with liver fibrosis. Carrier exosomes may be co‐manufactured along with their cargo. Exosome‐delivered miRNA cocktails may augment functioning of human organs suffering from a variety of chronic diseases.

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Курсы (6)