%0 Journal Article
%T Identification of novel genes potentially involved in somatic embryogenesis in chicory (Cichorium intybus L.)
%A Anca Lucau-Danila
%A Laurent Laborde
%A Sylvain Legrand
%A Ludovic Huot
%A David Hot
%A Yves Lemoine
%A Jean-Louis Hilbert
%A Simon Hawkins
%A Marie-Christine Quillet
%A Theo Hendriks
%A Anne-Sophie Blervacq
%J BMC Plant Biology
%D 2010
%I BioMed Central
%R 10.1186/1471-2229-10-122
%X Microscopy confirmed that only the K59, but not the C15 genotype underwent complete cell reactivation leading to SE formation. ¦Ā-GlcY-treatment of explants blocked in vitro SE induction, but not cell reactivation, and induced cell wall modifications. Microarray analyses revealed that 78 genes were differentially expressed between induced K59 and C15 genotypes. The expression profiles of 19 genes were modified by ¦Ā-GlcY-treatment. Eight genes were both differentially expressed between K59 and C15 genotypes during SE induction and transcriptionally affected by ¦Ā-GlcY-treatment: AGP (DT212818), 26 S proteasome AAA ATPase subunit 6 (RPT6), remorin (REM), metallothionein-1 (MT1), two non-specific lipid transfer proteins genes (SDI-9 and DEA1), 3-hydroxy-3-methylglutaryl-CoA reductase (HMG-CoA reductase), and snakin 2 (SN2). These results suggest that the 8 genes, including the previously-identified AGP gene (DT212818), could be involved in cell fate determination events leading to SE commitment in chicory.The use of two different chicory genotypes differing in their responsiveness to SE induction, together with ¦Ā-GlcY-treatment represented an efficient tool to discriminate cell reactivation from the SE morphogenetic pathway. Such an approach, together with microarray analyses, permitted us to identify several putative key genes related to the SE morphogenetic pathway in chicory.Plants show a high level of plasticity and adapt to changing environmental conditions by extensive modifications in developmental programmes. A striking example concerns the plant's capacity to implement cell pluripotency and totipotency programmes [3]. In pluripotency, a single cell gives rise to most, but not all, of the various cell types that make up a plant. In totipotency, a single cell can develop into an embryo (under certain conditions), thereby producing a new adult organism. During both of these programmes, a single differentiated somatic cell re-enters the cell cycle via the cell-react
%U http://www.biomedcentral.com/1471-2229/10/122