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Literature DB >> 32817252

PhasiRNAs in Plants: Their Biogenesis, Genic Sources, and Roles in Stress Responses, Development, and Reproduction.

Yuanlong Liu^1,2,3, Chong Teng⁴, Rui Xia^5,2,3, Blake C Meyers^6,7.

Abstract

Phased secondary small interfering RNAs (phasiRNAs) constitute a major category of small RNAs in plants, but most of their functions are still poorly defined. Some phasiRNAs, known as trans-acting siRNAs, are known to target complementary mRNAs for degradation and to function in development. However, the targets or biological roles of other phasiRNAs remain speculative. New insights into phasiRNA biogenesis, their conservation, and their variation across the flowering plants continue to emerge due to the increased availability of plant genomic sequences, deeper and more sophisticated sequencing approaches, and improvements in computational biology and biochemical/molecular/genetic analyses. In this review, we survey recent progress in phasiRNA biology, with a particular focus on two classes associated with male reproduction: 21-nucleotide (accumulate early in anther ontogeny) and 24-nucloetide (produced in somatic cells during meiosis) phasiRNAs. We describe phasiRNA biogenesis, function, and evolution and define the unanswered questions that represent topics for future research.

Entities: Disease Species

Mesh：

Substances：

Year: 2020 PMID： 32817252 PMCID： PMC7534485 DOI： 10.1105/tpc.20.00335

Source DB: PubMed Journal: Plant Cell ISSN： 1040-4651 Impact factor: 11.277

136 in total

1. 22-Nucleotide RNAs trigger secondary siRNA biogenesis in plants.

Authors: Ho-Ming Chen; Li-Teh Chen; Kanu Patel; Yi-Hang Li; David C Baulcombe; Shu-Hsing Wu
Journal: Proc Natl Acad Sci U S A Date: 2010-07-19 Impact factor: 11.205

2. MicroRNA regulation of plant innate immune receptors.

Authors: Feng Li; Daniela Pignatta; Claire Bendix; Jacob O Brunkard; Megan M Cohn; Jeffery Tung; Haoyu Sun; Pavan Kumar; Barbara Baker
Journal: Proc Natl Acad Sci U S A Date: 2012-01-18 Impact factor: 11.205

Review 3. Pre-Meiotic Anther Development: Cell Fate Specification and Differentiation.

Authors: Virginia Walbot; Rachel L Egger
Journal: Annu Rev Plant Biol Date: 2016-01-06 Impact factor: 26.379

Review 4. Pentatricopeptide repeat proteins: a socket set for organelle gene expression.

Authors: Christian Schmitz-Linneweber; Ian Small
Journal: Trends Plant Sci Date: 2008-11-12 Impact factor: 18.313

5. The poly(A) tail blocks RDR6 from converting self mRNAs into substrates for gene silencing.

Authors: Kyungmin Baeg; Hiro-Oki Iwakawa; Yukihide Tomari
Journal: Nat Plants Date: 2017-03-20 Impact factor: 15.793

6. Rice germline-specific Argonaute MEL1 protein binds to phasiRNAs generated from more than 700 lincRNAs.

Authors: Reina Komiya; Hajime Ohyanagi; Mitsuru Niihama; Toshiaki Watanabe; Mutsuko Nakano; Nori Kurata; Ken-Ichi Nonomura
Journal: Plant J Date: 2014-04-15 Impact factor: 6.417

7. Regulation of AUXIN RESPONSE FACTOR3 by TAS3 ta-siRNA affects developmental timing and patterning in Arabidopsis.

Authors: Noah Fahlgren; Taiowa A Montgomery; Miya D Howell; Edwards Allen; Sarah K Dvorak; Amanda L Alexander; James C Carrington
Journal: Curr Biol Date: 2006-05-09 Impact factor: 10.834

8. Plant Extracellular Vesicles Contain Diverse Small RNA Species and Are Enriched in 10- to 17-Nucleotide "Tiny" RNAs.

Authors: Patricia Baldrich; Brian D Rutter; Hana Zand Karimi; Ram Podicheti; Blake C Meyers; Roger W Innes
Journal: Plant Cell Date: 2019-01-31 Impact factor: 11.277

9. A loop-to-base processing mechanism underlies the biogenesis of plant microRNAs miR319 and miR159.

Authors: Nicolás G Bologna; Julieta L Mateos; Edgardo G Bresso; Javier F Palatnik
Journal: EMBO J Date: 2009-10-08 Impact factor: 11.598

Review 10. The expanding world of small RNAs in plants.

Authors: Filipe Borges; Robert A Martienssen
Journal: Nat Rev Mol Cell Biol Date: 2015-11-04 Impact factor: 94.444

28 in total

1. The dissection of R genes and locus Pc5.1 in Phytophthora capsici infection provides a novel view of disease resistance in peppers.

Authors: Jin-Song Du; Lin-Feng Hang; Qian Hao; Hai-Tao Yang; Siyad Ali; Radwa Salah Ezaat Badawy; Xiao-Yu Xu; Hua-Qiang Tan; Li-Hong Su; Huan-Xiu Li; Kai-Xi Zou; Yu Li; Bo Sun; Li-Jin Lin; Yun-Song Lai
Journal: BMC Genomics Date: 2021-05-21 Impact factor: 3.969

2. Ubiquitination-dependent degradation of MEL1 is critical for microsporogenesis.

Authors: Junpeng Zhan
Journal: Plant Cell Date: 2021-08-31 Impact factor: 11.277

3. An atypical class of non-coding small RNAs is produced in rice leaves upon bacterial infection.

Authors: Ganna Reshetnyak; Jonathan M Jacobs; Florence Auguy; Coline Sciallano; Lisa Claude; Clemence Medina; Alvaro L Perez-Quintero; Aurore Comte; Emilie Thomas; Adam Bogdanove; Ralf Koebnik; Boris Szurek; Anne Dievart; Christophe Brugidou; Severine Lacombe; Sebastien Cunnac
Journal: Sci Rep Date: 2021-12-17 Impact factor: 4.379

4. Mobile ARGONAUTE 1d binds 22-nt miRNAs to generate phasiRNAs important for low-temperature male fertility in rice.

Authors: Fuyan Si; Haofei Luo; Chao Yang; Jie Gong; Bin Yan; Chunyan Liu; Xianwei Song; Xiaofeng Cao
Journal: Sci China Life Sci Date: 2022-10-11 Impact factor: 10.372

Review 5. Roles of RNA silencing in viral and non-viral plant immunity and in the crosstalk between disease resistance systems.

Authors: Sara Lopez-Gomollon; David C Baulcombe
Journal: Nat Rev Mol Cell Biol Date: 2022-06-16 Impact factor: 113.915

Review 10. Interplay between miRNAs and lncRNAs: Mode of action and biological roles in plant development and stress adaptation.

Authors: Xiangxiang Meng; Aixia Li; Bin Yu; Shengjun Li
Journal: Comput Struct Biotechnol J Date: 2021-04-27 Impact factor: 7.271