The role of reactive oxygen species and nitric oxide in programmed cell death associated with self-incompatibility

Journal of Experimental Botany
Irene SerranoAdela Olmedilla

Abstract

Successful sexual reproduction often relies on the ability of plants to recognize self- or genetically-related pollen and prevent pollen tube growth soon after germination in order to avoid self-fertilization. Angiosperms have developed different reproductive barriers, one of the most extended being self-incompatibility (SI). With SI, pistils are able to reject self or genetically-related pollen thus promoting genetic variability. There are basically two distinct systems of SI: gametophytic (GSI) and sporophytic (SSI) based on their different molecular and genetic control mechanisms. In both types of SI, programmed cell death (PCD) has been found to play an important role in the rejection of self-incompatible pollen. Although reactive oxygen species (ROS) were initially recognized as toxic metabolic products, in recent years, a new role for ROS has become apparent: the control and regulation of biological processes such as growth, development, response to biotic and abiotic environmental stimuli, and PCD. Together with ROS, nitric oxide (NO) has become recognized as a key regulator of PCD. PCD is an important mechanism for the controlled elimination of targeted cells in both animals and plants. The major focus of this review is...Continue Reading

References

Mar 15, 1994·Proceedings of the National Academy of Sciences of the United States of America·H C FooteF C Franklin
Aug 26, 1998·Proceedings of the National Academy of Sciences of the United States of America·J DurnerD F Klessig
Aug 4, 1999·Trends in Plant Science·M a Beligni, L Lamattina
Nov 27, 1999·Science·C R SchopferJ B Nasrallah
Feb 13, 2001·The Plant Journal : for Cell and Molecular Biology·P C Bethke, R L Jones
Oct 19, 2001·Proceedings of the National Academy of Sciences of the United States of America·M DelledonneC Lamb
Mar 15, 1994·Proceedings of the National Academy of Sciences of the United States of America·D P MattonE Newbigin
Nov 8, 2001·Proceedings of the National Academy of Sciences of the United States of America·B Igic, J R Kohn
Aug 15, 2002·Plant Physiology·Maria Veronica BeligniRussell L Jones
Jul 1, 1997·The Plant Cell·R. I. Pennell, C. Lamb
Mar 1, 2003·The Plant Journal : for Cell and Molecular Biology·Atsushi SakamotoHiromichi Morikawa
Jul 25, 2003·Trends in Plant Science·Kirk OvermyerJaakko Kangasjärvi
Jun 1, 1997·Annual Review of Plant Physiology and Plant Molecular Biology·Chris Lamb, Richard A. Dixon
May 7, 2004·Development·Ana Margarida PradoJosé A Feijó
Sep 21, 2004·Annual Review of Plant Biology·Klaus Apel, Heribert Hirt
Mar 8, 2005·Trends in Plant Science·Wouter G van Doorn, Ernst J Woltering
Sep 13, 2005·Trends in Plant Science·Wouter G van Doorn
Jul 13, 2006·The Journal of Cell Biology·Steven G ThomasVernonica E Franklin-Tong
Oct 17, 2006·BioEssays : News and Reviews in Molecular, Cellular and Developmental Biology·Tsanko S GechevChristophe Laloi
Jan 24, 2007·Physiological Reviews·Pál PacherLucas Liaudet
Sep 18, 2007·Journal of Experimental Botany·Maurice Bosch, Vernonica E Franklin-Tong
Nov 3, 2007·Journal of Experimental Botany·Steven NeillIan Wilson
Nov 9, 2007·Proceedings of the National Academy of Sciences of the United States of America·Maurice Bosch, Vernonica E Franklin-Tong
Nov 23, 2007·Annual Review of Plant Biology·Angélique Besson-BardDavid Wendehenne
Jan 1, 2008·The Plant Cell·Maria C Romero-PuertasMassimo Delledonne
Jan 12, 2008·Molecular Biology and Evolution·Korneel VandenbrouckeFrank Van Breusegem
Feb 8, 2008·Journal of Experimental Botany·Theresa J ReapePaul F McCabe
Feb 15, 2008·Journal of Experimental Botany·M Cristina PalmieriChristian Lindermayr
Dec 5, 2008·The Plant Journal : for Cell and Molecular Biology·Reetta AhlforsJaakko Kangasjärvi
Mar 6, 2009·Plant Physiology·Roberto De MicheleFiorella Lo Schiavo
Jun 2, 2009·Nature·Michael J WheelerVernonica E Franklin-Tong

❮ Previous
Next ❯

Citations

Feb 24, 2016·Frontiers in Plant Science·Jorge LoraMaría Herrero
Oct 13, 2016·Frontiers in Plant Science·Rachana SinghSheo M Prasad
Nov 26, 2016·Scientific Reports·José LeónMari-Cruz Castillo
Jan 18, 2018·Plant Signaling & Behavior·Mohamed M MiraClaudio Stasolla
Mar 7, 2019·Journal of Experimental Botany·Claudio StasollaAbir U Igamberdiev
Feb 21, 2019·Cellular and Molecular Life Sciences : CMLS·Dengjing HuangWeibiao Liao
Jun 10, 2018·BMC Plant Biology·Adoración ZafraJuan de Dios Alché
Jan 24, 2019·Frontiers in Plant Science·Xiquan GaoBaomin Feng
Aug 28, 2020·Frontiers in Plant Science·Subramanian SankaranarayananSharon A Kessler
Apr 26, 2017·BMC Plant Biology·Amanda K BrozPatricia A Bedinger
Sep 21, 2018·International Journal of Molecular Sciences·Martin ČernýBřetislav Brzobohatý
Mar 2, 2019·Environmental Science and Pollution Research International·Mustafa Okant, Cengiz Kaya
Jan 11, 2019·International Journal of Molecular Sciences·Stefano Del DucaGiampiero Cai
Mar 23, 2019·Frontiers in Plant Science·Attila FábiánKatalin Jäger
Mar 18, 2020·Frontiers in Plant Science·Ming Jun ZhangXin-Qi Gao
May 2, 2018·Frontiers in Plant Science·Nobuhiro Suzuki, Kazuma Katano
Aug 11, 2018·Development·Amna Mhamdi, Frank Van Breusegem
Sep 22, 2019·Nitric Oxide : Biology and Chemistry·Zs KolbertJ T Hancock
Mar 12, 2021·Plant Science : an International Journal of Experimental Plant Biology·Chuanbao WuWei Li
Sep 23, 2021·Plant Signaling & Behavior·Kazuma Katano, Nobuhiro Suzuki

❮ Previous
Next ❯

Related Concepts

Related Feeds

Apoptosis

Apoptosis is a specific process that leads to programmed cell death through the activation of an evolutionary conserved intracellular pathway leading to pathognomic cellular changes distinct from cellular necrosis

Related Papers

The International Journal of Developmental Biology
Anne C Rea, J B Nasrallah
Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences
Simon J Hiscock, David A Tabah
© 2022 Meta ULC. All rights reserved