about
Specific impact of tobamovirus infection on the Arabidopsis small RNA profileMechanism of ribosome shunting in Rice tungro bacilliform pararetrovirus.Massive production of small RNAs from a non-coding region of Cauliflower mosaic virus in plant defense and viral counter-defenseFour plant Dicers mediate viral small RNA biogenesis and DNA virus induced silencingMolecular characterization of geminivirus-derived small RNAs in different plant speciesHow can plant DNA viruses evade siRNA-directed DNA methylation and silencing?Silencing and innate immunity in plant defense against viral and non-viral pathogensRole of a short open reading frame in ribosome shunt on the cauliflower mosaic virus RNA leaderRibosome shunting in cauliflower mosaic virus. Identification of an essential and sufficient structural elementTranslation reinitiation and leaky scanning in plant virusesRDR6-mediated synthesis of complementary RNA is terminated by miRNA stably bound to template RNACross-species functionality of pararetroviral elements driving ribosome shunting.Promoters, transcripts, and regulatory proteins of Mungbean yellow mosaic geminivirusShort ORF-dependent ribosome shunting operates in an RNA picorna-like virus and a DNA pararetrovirus that cause rice tungro diseaseEvasion of short interfering RNA-directed antiviral silencing in Musa acuminata persistently infected with six distinct banana streak pararetroviruses.Primary and secondary siRNAs in geminivirus-induced gene silencing.MISIS: a bioinformatics tool to view and analyze maps of small RNAs derived from viruses and genomic loci generating multiple small RNAs.De novo reconstruction of consensus master genomes of plant RNA and DNA viruses from siRNAsInteractions of Rice tungro bacilliform pararetrovirus and its protein P4 with plant RNA-silencing machinery.MISIS-2: A bioinformatics tool for in-depth analysis of small RNAs and representation of consensus master genome in viral quasispecies.Sequencing of RDR6-dependent double-stranded RNAs reveals novel features of plant siRNA biogenesis.The CaMV transactivator/viroplasmin interferes with RDR6-dependent trans-acting and secondary siRNA pathways in Arabidopsis.Emergence of a Latent Indian Cassava Mosaic Virus from Cassava Which Recovered from Infection by a Non-Persistent Sri Lankan Cassava Mosaic Virus.RNAi-mediated resistance to viruses: a critical assessment of methodologies.Field Trial and Molecular Characterization of RNAi-Transgenic Tomato Plants That Exhibit Resistance to Tomato Yellow Leaf Curl Geminivirus.Viral protein suppresses oxidative burst and salicylic acid-dependent autophagy and facilitates bacterial growth on virus-infected plants.Suppression of RNA silencing by a geminivirus nuclear protein, AC2, correlates with transactivation of host genes.Transgenic cassava resistance to African cassava mosaic virus is enhanced by viral DNA-A bidirectional promoter-derived siRNAs.Complete genome sequence of an Iranian isolate of Potato virus X from the legume plant Pisum sativum.Revisiting the Roles of Tobamovirus Replicase Complex Proteins in Viral Replication and Silencing Suppression.Small RNA-omics for virome reconstruction and antiviral defense characterization in mixed infections of cultivated Solanum plants.Ribosome Shunting, Polycistronic Translation, and Evasion of Antiviral Defenses in Plant Pararetroviruses and Beyond.Generation of marker free salt tolerant transgenic plants of Arabidopsis thaliana using the gly I gene and cre gene under inducible promotersSalt stress alleviation in transgenic Vigna mungo L. Hepper (blackgram) by overexpression of the glyoxalase I gene using a novel Cestrum yellow leaf curling virus (CmYLCV) promoterThe Mungbean Yellow Mosaic Begomovirus Transcriptional Activator Protein Transactivates the Viral Promoter-Driven Transgene and Causes Toxicity in Transgenic Tobacco PlantsFighting geminiviruses by RNAi and vice versa
P50
Q21135462-9E94F9E7-031A-41DB-BC3D-10DEA2583B56Q24543933-5272AA69-1290-4AEA-B876-121EAE9D1C07Q24597396-96E335A6-B56B-46D3-A546-24AC432F3EF5Q24675659-71A15F65-F050-4874-B451-557B535A9778Q25255680-14072D01-6D28-4145-AE1E-4E23B2AD5FDAQ27007502-086357C4-1AA8-4363-83B7-84B8D6FD2A42Q27010305-2815F868-D1F6-4DB2-8FAD-C292F28FAECAQ28140564-60C3C880-8C95-4B11-B11F-C8C253973BB9Q28260822-120FCB12-8792-4AA0-BF8A-9EFB984FEB5FQ28284997-4B7B4417-EA66-4076-8B10-6E1E48CFC3D4Q28732831-8E22B9CA-0C92-4CFE-98B2-A847D1196D14Q33320545-562A4DD2-7478-437F-8F68-63EFA350B417Q33843393-6C290D72-464E-43E6-AF5F-818A8D361437Q34186987-21C236E7-D752-4678-9E03-99AE4E707E21Q34261820-A8D22632-0162-41C1-9FCD-795753D79D0BQ34426509-CFF496A4-3439-4DDF-A3AB-91C51ECA27FCQ35019829-E0C728A7-33B5-447C-9D2C-72E10EFE25BEQ35093642-BD16FCDE-9D72-424E-ACF7-7C64918BB7C0Q35224906-A7A4C254-A13C-4FA6-86A0-ED5C37D558F9Q35963797-72E0A5C9-97FB-4B13-9FAC-D581050D43BDQ36106875-ACB8E04D-9605-4A4E-9C6F-6FB277F8A55CQ36935398-A5E37820-D08E-4258-ACB7-259B20885918Q37378789-E0A47A63-6F7E-4E25-8260-DA345A522426Q40104159-8F1E819F-FB6C-44FE-9F21-CBF494602907Q40162512-566981FD-FD87-411E-9BEB-8AABF782A33DQ40696617-7CA04421-8593-464A-84D6-DDA214BEBD5AQ40977533-BB682413-1810-4270-B245-871A7507F965Q44105084-18979800-87D4-45E1-8E36-4158770BBD90Q44952903-6DE8BCC8-9089-4637-B2B7-0C2B4F0310E6Q47400469-6AC47A31-FC3A-4C52-BEFA-37DADC7F602EQ50101715-769D11E6-908A-49BB-8927-7A3A5E3B05DBQ54114449-F3C92399-FDFC-4E0E-8460-D2009885DD95Q63979694-3F71F3E1-60AF-47CD-B611-80A89561F18BQ63979696-C60BF846-05C0-470C-9022-664A9BED0839Q63979699-6FE88795-7301-44A2-B95F-F3B4E9B8CF0AQ63979701-32017771-16E8-49D4-8762-CA347862A820
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Mikhail M Pooggin
@ast
Mikhail M Pooggin
@en
Mikhail M Pooggin
@es
Mikhail M Pooggin
@nl
Mikhail M Pooggin
@sl
type
label
Mikhail M Pooggin
@ast
Mikhail M Pooggin
@en
Mikhail M Pooggin
@es
Mikhail M Pooggin
@nl
Mikhail M Pooggin
@sl
prefLabel
Mikhail M Pooggin
@ast
Mikhail M Pooggin
@en
Mikhail M Pooggin
@es
Mikhail M Pooggin
@nl
Mikhail M Pooggin
@sl
P106
P1153
6602750491
P31
P496
0000-0003-2308-393X