{"id":40,"date":"2024-04-04T03:13:01","date_gmt":"2024-04-04T00:13:01","guid":{"rendered":"https:\/\/sisu.ut.ee\/cemce\/publications-2022\/"},"modified":"2024-04-04T03:15:00","modified_gmt":"2024-04-04T00:15:00","slug":"publications-2022","status":"publish","type":"page","link":"https:\/\/sisu.ut.ee\/cemce\/publications-2022\/","title":{"rendered":"CEMCE Publications 2022"},"content":{"rendered":"<p style=\"margin:0px0px0px72px\">\n\t<span><span><span style=\"line-height:normal\"><span>Publications\u00a02022<\/span><\/span><\/span><\/span>\n<\/p>\n<ul>\n<li style=\"margin:0px;text-align:justify;line-height:normal\">\n\t\tCherkashchenko, L., Rausalu, K., Basu, S., Alphey, L. and Merits, A. (2022). Expression of alphavirus nonstructural protein 2 (nsP2) in mosquito cells inhibits viral RNA replication in both a protease activity-dependent and -independent manner. <i>Viruses. <\/i>14, 1327.<i> <\/i><span style=\"text-decoration:underline\"><span style=\"color:#00000a\">https:\/\/doi.org\/10.3390\/v14061327.<\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;text-align:justify;line-height:normal\">\n\t\tWang, S. and Merits, A. (2022). G3BP\/Rin-binding motifs inserted into flexible regions of nsP2 support RNA replication of chikungunya virus. <i>Journal of Virology, <\/i>96(21): e0127822. doi: 10.1128\/jvi.01278-22.\n\t<\/li>\n<li style=\"margin:0px;text-align:justify;line-height:normal\">\n\t\tLello, L.S., Miilim\u00e4e, A., Cherkashchenko, L., Omler, A., Skilton, R., Ireland, R., Ulaeto, D. and Merits, A (2022). Activity, template preference and compatibility of components of RNA replicase of eastern equine encephalitis virus. <i>Journal of Virology, <\/i>DOI 10.1128\/jvi.01368-22 (in press).\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tBrodiazhenko, T., Turnbull, K.J., Wu, K.J.Y., Takada, H., Tresco, B.I.C., Tenson, T., Myers, A.G., Hauryliuk, V. (2022). Synthetic oxepanoprolinamide iboxamycin is active against <i>Listeria monocytogenes<\/i> despite the intrinsic resistance mediated by VgaL\/Lmo0919 ABCF ATPase. JAC Antimicrob Resist. doi: 10.1093\/jacamr\/dlac061.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tHinnu, M., Putrin\u0161, M., Kogermann, K., Bumann, D., Tenson, T. (2022). Making Antimicrobial Susceptibility Testing More Physiologically Relevant with Bicarbonate? Antimicrob Agents Chemother. doi: 10.1128\/aac.02412-21. Epub 2022 Apr 18.PMID: 35435706.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tKurata, T., Saha, C.K., Buttress, J.A., Mets, T., Brodiazhenko, T., Turnbull, K.J., Awoyomi, O.F., Oliveira, S.R.A., Jimmy, S., Ernits, K., Delannoy, M., Persson, K., Tenson, T., Strahl, H., Hauryliuk, V., Atkinson, G.C. (2022). A hyperpromiscuous antitoxin protein domain for the neutralization of diverse toxin domains. Proc Natl Acad Sci U S A. doi: 10.1073\/pnas.2102212119.PMID: 35121656.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tSafdari, H.A., Kasvandik, S., Polte, C., Ignatova, Z., Tenson, T., Wilson, D.N. (2022). Structure of Escherichia coli heat shock protein Hsp15 in complex with the ribosomal 50S subunit bearing peptidyl-tRNA. Nucleic Acids Res. 2022 Nov 12:gkac1035. doi: 10.1093\/nar\/gkac1035.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tKasari, M., Kasari, V., K\u00e4rmas, M., J\u00f5ers, A. (2022). Decoupling Growth and Production by Removing the Origin of Replication from a Bacterial Chromosome. ACS Synth Biol. 2022 Aug 19;11(8):2610-2622. doi: 10.1021\/acssynbio.1c00618.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tTamman, H., Ernits, K., Roghanian, M., Ainelo, A., Julius, C., Perrier, A., Talavera, A., Ainelo, H., Dugauquier, R., Zedek, S., Thureau, A., P\u00e9rez, J., Lima-Mendez, G., Hallez, R., Atkinson, GC., Hauryliuk, V., Garcia-Pino, A. (2022). Structure of SpoT reveals evolutionary tuning of catalysis via conformational constraint. Nat Chem Biol. 2022 Dec 5. doi: 10.1038\/s41589-022-01198-x.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tZhang, T., Tamman, H., Coppieters \u2018t Wallant K., Kurata, T., LeRoux, M., Srikant, S., Brodiazhenko, T., Cepauskas, A., Talavera, A., Martens, C., Atkinson, G.C., Hauryliuk, V., Garcia-Pino, A., Laub, M.T. (2022). Direct activation of a bacterial innate immune system by a viral capsid protein. Nature. 2022 Dec;612(7938):132-140. doi: 10.1038\/s41586-022-05444-z.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tKoller, T.O., Turnbull, K.J., Vaitkevicius, K., Crowe-McAuliffe, C., Roghanian, M., Bulvas, O., Nakamoto, J.A., Kurata, T., Julius, C., Atkinson, G.C., Johansson, J., Hauryliuk, V., Wilson, D.N. (2022). Structural basis for HflXr-mediated antibiotic resistance in Listeria monocytogenes. Nucleic Acids Res. 2022 Oct 28;50(19):11285-11300.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tTakada, H., Mandell, Z.F., Yakhnin, H., Glazyrina, A., Chiba, S., Kurata, T., Wu, K.J.Y., Tresco, B.I.C., Myers, A.G., Aktinson, G.C., Babitzke, P., Hauryliuk, V. (2022). Expression of Bacillus subtilis ABCF antibiotic resistance factor VmlR is regulated by RNA polymerase pausing, transcription attenuation, translation attenuation and (p)ppGpp. Nucleic Acids Res. 2022 Jun 24;50(11):6174-6189. doi: 10.1093\/nar\/gkac497.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tCrowe-McAuliffe, C., Murina, V., Turnbull, K.J., Huch, S., Kasari, M., Takada, H., Nersisyan, L., Sundsfjord, A., Hegstad, K., Atkinson, G.C., Pelechano, V., Wilson, D.N., Hauryliuk, V. (2022). Structural basis for PoxtA-mediated resistance to phenicol and oxazolidinone antibiotics. Nat Commun. 2022 Apr 6;13(1):1860.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tOja, M., Sild, S., Piir, G., Maran, U. (2022). Intrinsic Aqueous Solubility: Mechanistically Transparent Data-Driven Modeling of Drug Substances. Pharmaceutics, 14 (10), 2248. DOI: <span style=\"text-decoration:underline\">10.3390\/pharmaceutics14102248.<\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tHunt, K.E., Garcia-Sosa, A.T., Shalima, T., Maran, U., Vilu, R., Kanger, T. (2022). Synthesis of 6 \u2018-galactosyllactose, a deviant human milk oligosaccharide, with the aid of Candida antarctica lipase-B. Organic &amp; Biomolecular Chemistry, 20, 4724\u22124735. DOI: <span style=\"text-decoration:underline\">10.1039\/d2ob00550f.<\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tToots, K.M., Sild, S., Leis, J., Acree, W.E., Maran, U. (2022). Machine Learning Quantitative Structure\u2013Property Relationships as a Function of Ionic Liquid Cations for the Gas-Ionic Liquid Partition Coefficient of Hydrocarbons. International Journal of Molecular Sciences, 23 (14), 7534. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">10.3390\/ijms23147534.<\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tKosimov, A., Yusibova, G., Aruvali, J., Paiste, P., Kaarik, M., Leis, J., Kikas, A., Kisand, V., Smits, K., Kongi, N. (2022). Liquid-assisted grinding\/compression: a facile mechanosynthetic route for the production of high-performing Co-N-C electrocatalyst materials. Green Chemistry, 24, 305\u2212314.<br>DOI: <span style=\"text-decoration:underline\">http:\/\/dx.doi.org\/10.1039\/D1GC03433B<\/span> .\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tLilloja, J., Kibena-P\u00f5ldsepp, E., Sarapuu, A.; K\u00e4\u00e4rik, M.; Kozlova, J.; Paiste, P., Kikas, A., Treshchalov, A., Leis, J., Tamm, A., Kisand, V., Holdcroft, S., Tammeveski, K. (2022). Transition metal and nitrogen-doped mesoporous carbons as cathode catalysts for anion-exchange membrane fuel cells. Applied Catalysis B Environmental, 306, 121113. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1016\/j.apcatb.2022.121113<\/span><\/span> .\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tSokka, A., Mooste, M., Marandi, M., K\u00e4\u00e4rik, M., Kozlova, J., Kikas, A., Kisand, V., Treshchalov, A., Tamm, A., Leis, J., Holdcroft, S., Tammeveski, K. (2022). Polypyrrole and polythiophene modified carbon nanotube-based cathode catalysts for anion exchange membrane fuel cell. ChemElectroChem, 9 (7), e202200161.<br>DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1002\/celc.202200161.<\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t\u00c1vila-Bol\u00edvar, B., Cepitis, R., Alam, M., Assafrei, J-M., Ping, K., Aruv\u00e4li, J., Kikas, A., Kisand, V., Vlassov, S., K\u00e4\u00e4rik, M., Leis, J., Ivani\u0161t\u0161tev, V., Starkov, P., Montiel, V., Solla-Gull\u00f3n, J., Kongi, N. (2022). CO2 reduction to formate on an affordable bismuth metal-organic framework based catalyst. Journal of CO2 Utilization, 59, 101937. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1016\/j.jcou.2022.101937<\/span><\/span> .\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tPalm, I., Kibena-P\u00f5ldsepp, E., Mooste, M., Kozlova, J., K\u00e4\u00e4rik, M., Kikas, A., Treshchalov, A., Leis, J., Kisand, V., Tamm, A., Holdcroft, S., Atanassov, P., Tammeveski, K. (2022). Nitrogen and phosphorus dual-doped silicon carbide-derived carbon\/carbon nanotube composite for the anion-exchange membrane fuel cell cathode. ACS Applied Energy Materials, 5 (3), 2949\u22122958. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1021\/acsaem.1c03627<\/span><\/span> .\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tVeske, K., Sarapuu, A., K\u00e4\u00e4rik, M., Kikas, A., Kisand, V., Piirsoo, H.-M., Treshchalov, A., Leis, J., Tamm, A., Tammeveski, K. (2022). Cobalt-Containing Nitrogen-Doped Carbon Materials Derived from Saccharides as Efficient Electrocatalysts for Oxygen Reduction Reaction. Catalysts, 12 (5), 568.<br>DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.3390\/catal12050568<\/span><\/span>.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tJuvanen, S., Sarapuu, A., Mooste, M., K\u00e4\u00e4rik, M., M\u00e4eorg, U., Kikas, A., Kisand, V., Kozlova, J., Treshchalov, A., Aruv\u00e4li, J., Leis, J., Tamm, A., Tammeveski, K. (2022). Electroreduction of oxygen on iron- and cobalt-containing nitrogen-doped carbon catalysts prepared from the rapeseed press cake. Journal of Electroanalytical Chemistry, 920, 116599. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1016\/j.jelechem.2022.116599.<\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tK\u00e4\u00e4rik, M., Arulepp, M., Kozlova, J., Aruv\u00e4li, J., M\u00e4eorg, U., Kikas, A., Kisand, V., Tamm, A., Leis, J. (2022). Effect of partial oxidation and repolarization of TiC-derived nanoporous carbon electrodes on supercapacitor performance using a pH-neutral aqueous electrolyte. Journal of Solid State Electrochemistry, 26 (11), 2365\u22122378. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1007\/s10008-022-05253-4<\/span><\/span> .\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tKumar, Y., Kibena-P\u00f5ldsepp, E., Mooste, M., Kozlova, J., Kikas, A., Aruv\u00e4li, J., K\u00e4\u00e4rik, M., Kisand, V., Leis, J., Tamm, A., Holdcroft, S., Zagal, J.H., Tammeveski, K. (2022). Iron and nickel phthalocyanine-modified nanocarbon materials as cathode catalysts for anion-exchange membrane fuel cells and zinc-air batteries. ChemElectroChem, 9 (20), e202200717. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1002\/celc.202200717.<\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tKisand, K., Sarapuu, A., Douglin, J.C., Kikas, A., Treshchalov, A., K\u00e4\u00e4rik, M., Piirsoo, H.-M., Paiste, P., Aruv\u00e4li, J., Leis, J., Kisand, V., Tamm, A., Dekel, D.R., Tammeveski, K. (2022). Templated nitrogen-, iron-, and cobalt-doped mesoporous nanocarbon derived from an alkylresorcinol mixture for anion-exchange membrane fuel cell application. ACS Catalysis, 12 (22), 14050\u221214061. DOI: <span style=\"text-decoration:underline\"><span style=\"color:#00000a\">http:\/\/dx.doi.org\/10.1021\/acscatal.2c03683.<\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tAlov, P., Al Sharif, M., Aluani, D., Chegaev, K., Dinic, J., Divac Rankov, A., Fernandes. M.X., Fusi, F., Garc\u00eda-Sosa, AT., Juvonen, R., Kondeva-Burdina, M., Padr\u00f3n, JM., Pajeva, I., Pencheva, T., Puerta, A., Raunio, H., Riganti, C., Tsakovska, I., Tzankova, V., Yordanov, Y., Saponara, S. (2022). A comprehensive evaluation of Sdox, a promising H2S-releasing doxorubicin for the treatment of chemoresistant tumors. Frontiers in Pharmacology, 13, 831791. DOI: <span style=\"text-decoration:underline\">https:\/\/dx.doi.org\/10.3389\/fphar.2022.831791.<\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tPorosk, L., Nebogatova, J., H\u00e4rk,H.H., Vunk, B., Arukuusk, P., Toots, U.,Ustav, M., Langel; \u00dc., Kurrikoff, K., \u201cPredicting Transiently Expressed Protein Yields: Comparison of Transfection Methods in CHO and HEK293\u201d Pharmaceutics 2022, 14(9), 1949.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tCerrato, C.P., Langel, \u00dc. \u201cAn update on cell-penetrating peptides with intracellular organelle targeting.\u201d Expert Opin Drug Deliv. 2022 Feb;19(2):133-146. doi: 10.1080\/17425247.2022.2034784. Epub 2022 Feb 8. PMID: 35086398.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tKurrikoff, K., Teesalu, T. Editorial on Special Issue \u201cPrecision Delivery of Drugs and Imaging Agents with Peptides\u201d.Pharmaceutics. 2022 Feb 23;14(3):486. doi: 10.3390\/pharmaceutics14030486. PMID: 35335863.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tKurrikoff, K., Vunk, B., Langel, \u00dc. \u201cTissue Analysis of Lung-Targeted Delivery of siRNA and Plasmid DNA.\u201d Methods Mol Biol. 2022;2383:547-553. doi: 10.1007\/978-1-0716-1752-6_34. PMID: 34766312.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tArukuusk, P., H\u00e4rk, H.H., Langel, \u00dc. \u201cUtilization of Cell-Penetrating Peptides for In Vivo Delivery of Bioactive Cargo: The Effect of Nanoparticle Formulation.\u201d Methods Mol Biol. 2022;2383:247-253. doi: 10.1007\/978-1-0716-1752-6_16. PMID: 34766294\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tPorosk, L., Nebogatova, J., Gaidut\u0161ik, I., Langel, \u00dc. \u201cEndpoint and Kinetic Approaches for Assessing Transfection Efficacy in Mammalian Cell Culture.\u201d Methods Mol Biol. 2022;2383:529-545. doi: 10.1007\/978-1-0716-1752-6_33. PMID: 34766311.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>Barghi, B.; J\u00fcrisoo, M.; Volokhova, M.; Seinberg, L.; Reile, I.; Mikli, V.; Niidu, A. (2022). Process Optimization for Catalytic Oxidation of Dibenzothiophene over UiO-66-NH2 by Using Response Surface Methodology. ACS Omega, 7 (19), 16288\u221216297. DOI: 10.1021\/acsomega.1c05965.<\/b>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>Dalidovich, T.; Nallaparaju, J. V.; Shalima, T.; Aav, R.; Kananovich, D. G. (2022). Mechanochemical Nucleophilic Substitution of Alcohols via Isouronium Intermediates. ChemSusChem, 15, e202102286. DOI: <\/b><span style=\"text-decoration:underline\"><span style=\"color:#00000a\"><b>10.1002\/cssc.202102286.<\/b><\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>Hunt, K. E.; Garcia-Sosa, A. T.; Shalima, T.; Maran, U.; Vilu, R.; Kanger, T. (2022). Synthesis of 6 \u2018-galactosyllactose, a deviant human milk oligosaccharide, with the aid of Candida antarctica lipase-B. Organic &amp; Biomolecular Chemistry, 20, 4724\u22124735. DOI: <\/b><span style=\"text-decoration:underline\"><span style=\"color:#00000a\"><b>10.1039\/d2ob00550f<\/b><\/span><\/span><b>.<\/b>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tKooli, A.; Wesenberg, L.; Besla\u0107, M.; Krech, An.; Lopp, M.; No\u0451l, T.; O\u0161eka, M. (2022). Electrochemical Hydroxylation of Electron\u2010Rich Arenes in Continuous\u2010Flow. European Journal of Organic Chemistry. DOI: 10.1002\/ejoc.202200011.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tKriis, K.; Mart\u00f5nov, H.; Miller, A.; Erkman, K.; J\u00e4rving, I.; Kaasik, M.; Kanger, T. (2022). Multifunctional Catalysts in the Asymmetric Mannich Reaction of Malononitrile with <i>N<\/i>-Phosphinoylimines: Coactivation by Halogen Bonding versus Hydrogen Bonding. The Journal of Organic Chemistry, 87 (11), 7422\u22127435. DOI: <span style=\"text-decoration:underline\">10.1021\/acs.joc.2c00674<\/span>.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>Kriis, K. Mart\u00f5nov, H.; Miller, A.; Erkman, K.; J\u00e4rving, I.; Kaasik, M.; Kanger, T. (2022). Synthesis of 6 \u2018-galactosyllactose, a deviant human milk oligosaccharide, with the aid of Candida antarctica lipase-B. Organic &amp; Biomolecular Chemistry, 20, 4724\u22124735. DOI: <\/b><span style=\"text-decoration:underline\"><span style=\"color:#00000a\"><b>10.1039\/d2ob00550f<\/b><\/span><\/span><b>.<\/b>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tK\u00f5llo, M., R\u00f5uk, K. Lopp, M. (2022) Synthesis of 2-(S)-[(4-methylphenyl)sulfinyl]-2-cyclo penten-1-one, a D-ring precursor of 9,11-secosterols. Proceedings of Estonian Academy of Sciences, 71(4), 307\u2013313. DPI\/10.3176\/proc.2022.4.0\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tSharma, M.; Hussain, S.; Shalima, T.;Aav, R.;Bhat<sup>, <\/sup>R. (2022). Valorization of seabuckthorn pomace to obtain bioactive carotenoids: An innovative approach of using green extraction techniques (ultrasonic and microwave-assisted extractions) synergized with green solvents (edible oils). Industrial Crops and Products, 2022, 175, 114257. DOI: 10.1016\/j.indcorp.2021.114257.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>Sihtmae, M.; Silm, E.; Kriis, K.; Kahru, A.; Kanger, T. (2022). Aminocatalysts are More Environmentally Friendly than Hydrogen-Bonding Catalysts. ChemSusChem, ARTN e202201045. DOI: <\/b><span style=\"text-decoration:underline\"><span style=\"color:#00000a\"><b>10.1002\/cssc.202201045<\/b><\/span><\/span><b>.<\/b>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>Silm, E.; J\u00e4rving, I.; Kanger, T. (2022). Asymmetric organocatalytic Michael addition of cyclopentane-1,2-dione to alkylidene oxindole. Beilstein Journal of Organic Chemistry, 18, 167\u2212173. DOI: <\/b><span style=\"text-decoration:underline\"><span style=\"color:#00000a\"><b>10.3762\/bjoc.18.18<\/b><\/span><\/span><b>.<\/b>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>\u0160akara\u0161vili, M.; Ustrnul, L.; Suut, E.; Nallaparaju, J. V.; Mishra, K. A.; Konrad, N.; Adamson, J.; Borovkov, V.; Aav, R. (2022). Self-Assembly of Chiral Cyclohexanohemicucurbit[n]urils with Bis(Zn Porphyrin): Size, Shape, and Time-Dependent Binding. 2022, Molecules, 27 (3), 937. DOI: <\/b><span style=\"text-decoration:underline\"><span style=\"color:#00000a\"><b>10.3390\/molecules27030937.<\/b><\/span><\/span>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\t<b>Kurg, K., Planken, A., Kurg, R. \u201cProteomic and Biochemical Analysis of Extracellular Vesicles Isolated from Blood Serum of Patients with Melanoma\u201d Separations, 9 (4), 86. DOI: 10.3390\/separations9040086.<\/b>\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tTakahashi, Y., Bosmans, K.C., Hsu, P.-K., Paul, K., Seitz, C., Yeh, C.-Y., Wang, Y.-S., Yarmolinsky, D., Sierla, M., Vahisalu, T., McCammon, J. A., Kangasj\u00e4rvi, J., Zhang, L., Kollist, H., Trac, T., Schroeder, J. (2022) Stomatal CO2\/bicarbonate sensor consists of two interacting proteiin kinases, Raf-like HT1 and non-kinase-activity activity requiring MPK12\/MPK4. <i>Science Advances<\/i>, 8, 49, eabq6161.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal;color:#00000a\">\n\t\tBacete, L; Schulz, J; Engelsdorf, T; Bartosova, Z; Vaahtera, L; Yan, GQ; Gerhold, JM; Ticha, T; Ovstebo, C; Gigli-Bisceglia, N; Johannessen-Starheim, S; Margueritat, J; Kollist, H; Dehoux, T; McAdam, SAM; Hamann, T. (2022) THESEUS1 modulates cell wall stiffness and abscisic acid production in Arabidopsis thaliana. <i>PNAS<\/i>, 119: e2119258119.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tFaustova, I., \u00d6rd, M., Kiselev, V., Fedorenko, D., Borovko, I., Macs, D., P\u00e4\u00e4bo, K., L\u00f5oke, M., Loog, M \u201eA synthetic biology approach reveals diverse and dynamic CDK response profiles via sisu phosphorylation of NLS-NES modules\u201c Science Advances, 8 (33). DOI: 10.1126\/sciadv.abp8992.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tPhilip, J., Ord, M., Silva, A., Singh, S., Diffley, J.,F.X., Remus, D., Loog, M., Ikui, A.E.\u201eCdc6 is sequentially regulated by PP2A-Cdc55, Cdc14, and Sic1 for origin licensing in S. Cerevisiae\u201c. eLife, 11, ARTN e74437. DOI: 10.7554\/eLife.74437.sa2.\n\t<\/li>\n<li style=\"margin:0px;line-height:normal\">\n\t\tAsfaha, J.B., \u00d6rd, M., Carlson, C.R., Faustova, I., Loog, M.,. Morgan, D.O. \u201eMultisite phosphorylation by Cdk1 initiates delayed negative feedback to control mitotic transcription\u201c. Current Biology, 32 (1), 256\u2212263. DOI: 10.1016\/j.cub.2021.11.001.\n\t<\/li>\n<\/ul>\n<p style=\"margin:0px0px0px35.1px\">\n\t\u00a0\n<\/p>\n<p style=\"margin:0px0px0px2.9px\">\n\t\u00a0<\/p>\n","protected":false},"excerpt":{"rendered":"<p>Publications\u00a02022 Cherkashchenko, L., Rausalu, K., Basu, S., Alphey, L. and Merits, A. (2022). Expression of alphavirus nonstructural protein 2 (nsP2) in mosquito cells inhibits viral RNA replication in both a protease activity-dependent and -independent manner. Viruses. 14, 1327. https:\/\/doi.org\/10.3390\/v14061327. Wang, &#8230;<\/p>\n","protected":false},"author":39,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"inline_featured_image":false,"footnotes":""},"class_list":["post-40","page","type-page","status-publish","hentry"],"acf":[],"_links":{"self":[{"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/pages\/40","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/users\/39"}],"replies":[{"embeddable":true,"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/comments?post=40"}],"version-history":[{"count":1,"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/pages\/40\/revisions"}],"predecessor-version":[{"id":381,"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/pages\/40\/revisions\/381"}],"wp:attachment":[{"href":"https:\/\/sisu.ut.ee\/cemce\/wp-json\/wp\/v2\/media?parent=40"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}