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1. Transcriptomic profiles of non-embryogenic and embryogenic callus cells in a highly regenerative upland cotton line (Gossypium hirsutum L.)

   https://doi.org/10.1186/s12861-020-00230-4  

   Wen, Li ; Li, Wei ; Parris, Stephen ; West, Matthew ; Lawson, John ; Smathers, Michael ; Li, Zhigang ; Jones, Don ; Jin, Shuangxia ; Saski, Christopher A. ( December 2020 , BMC Developmental Biology)

   null (Ed.)

   Abstract Background Genotype independent transformation and whole plant regeneration through somatic embryogenesis relies heavily on the intrinsic ability of a genotype to regenerate. The critical genetic architecture of non-embryogenic callus (NEC) cells and embryogenic callus (EC) cells in a highly regenerable cotton genotype is unknown. Results In this study, gene expression profiles of a highly regenerable Gossypium hirsutum L. cultivar, Jin668, were analyzed at two critical developmental stages during somatic embryogenesis, non-embryogenic callus (NEC) cells and embryogenic callus (EC) cells. The rate of EC formation in Jin668 is 96%. Differential gene expression analysis revealed a total of 5333 differentially expressed genes (DEG) with 2534 genes upregulated and 2799 genes downregulated in EC. A total of 144 genes were unique to NEC cells and 174 genes were unique to EC. Clustering and enrichment analysis identified genes upregulated in EC that function as transcription factors/DNA binding, phytohormone response, oxidative reduction, and regulators of transcription; while genes categorized in methylation pathways were downregulated. Four key transcription factors were identified based on their sharp upregulation in EC tissue; LEAFY COTYLEDON 1 (LEC1), BABY BOOM (BBM), FUSCA (FUS3) and AGAMOUS-LIKE15 with distinguishable subgenome expression bias. Conclusions This comparative analysis of NEC and EC transcriptomes gives new insights into the genes involved in somatic embryogenesis in cotton. 

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2. A key to totipotency: Wuschel‐like homeobox 2a unlocks embryogenic culture response in maize ( Zea mays L.)

   https://doi.org/10.1111/pbi.14098  

   McFarland, Frank L. ; Collier, Ray ; Walter, Nathalie ; Martinell, Brian ; Kaeppler, Shawn M. ; Kaeppler, Heidi F. ( June 2023 , Plant Biotechnology Journal)

   The ability of plant somatic cells to dedifferentiate, form somatic embryos and regenerate whole plantsin vitrohas been harnessed for both clonal propagation and as a key component of plant genetic engineering systems. Embryogenic culture response is significantly limited, however, by plant genotype in most species. This impedes advancements in both plant transformation‐based functional genomics research and crop improvement efforts. We utilized natural variation among maize inbred lines to genetically map somatic embryo generation potential in tissue culture and identify candidate genes underlying totipotency. Using a series of maize lines derived from crosses involving the culturable parent A188 and the non‐responsive parent B73, we identified a region on chromosome 3 associated with embryogenic culture response and focused on three candidate genes within the region based on genetic position and expression pattern. Two candidate genes showed no effect when ectopically expressed in B73, but the geneWox2awas found to induce somatic embryogenesis and embryogenic callus proliferation. Transgenic B73 cells with strong constitutive expression of the B73 and A188 coding sequences ofWox2awere found to produce somatic embryos at similar frequencies, demonstrating that sufficient expression of either allele could rescue the embryogenic culture phenotype. Transgenic B73 plants were regenerated from the somatic embryos without chemical selection and no pleiotropic effects were observed in theWox2aoverexpression lines in the regenerated T0 plants or in the two independent events which produced T1 progeny. In addition to linking natural variation in tissue culture response toWox2a, our data support the utility ofWox2ain enabling transformation of recalcitrant genotypes.

    

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3. Embryogenic Calli Induction and Salt Stress Response Revealed by RNA-Seq in Diploid Wild Species Gossypium sturtianum and Gossypium raimondii

   https://doi.org/10.3389/fpls.2021.715041  

   Nie, Hushuai ; Wang, Yali ; Wei, Chengcheng ; Grover, Corrinne E. ; Su, Ying ; Wendel, Jonathan F. ; Hua, Jinping ( August 2021 , Frontiers in Plant Science)

   Wild cotton species can contribute to a valuable gene pool for genetic improvement, such as genes related to salt tolerance. However, reproductive isolation of different species poses an obstacle to produce hybrids through conventional breeding. Protoplast fusion technology for somatic cell hybridization provides an opportunity for genetic manipulation and targeting of agronomic traits. Transcriptome sequencing analysis of callus under salt stress is conducive to study salt tolerance genes. In this study, calli were induced to provide materials for extracting protoplasts and also for screening salt tolerance genes. Calli were successfully induced from leaves of Gossypium sturtianum (C 1 genome) and hypocotyls of G. raimondii (D 5 genome), and embryogenic calli of G. sturtianum and G. raimondii were induced on a differentiation medium with different concentrations of 2, 4-D, KT, and IBA, respectively. In addition, embryogenic calli were also induced successfully from G. raimondii through suspension cultivation. Transcriptome sequencing analysis was performed on the calli of G. raimondii and G. sturtianum , which were treated with 200 mM NaCl at 0, 6, 12, 24, and 48 h, and a total of 12,524 genes were detected with different expression patterns under salt stress. Functional analysis showed that 3,482 genes, which were differentially expressed in calli of G. raimondii and G. sturtianum , were associated with biological processes of nucleic acid binding, plant hormone (such as ABA) biosynthesis, and signal transduction. We demonstrated that DEGs or TFs which related to ABA metabolism were involved in the response to salt stress, including xanthoxin dehydrogenase genes ( ABA2 ), sucrose non-fermenting 1-related protein kinases ( SnRK2 ), NAM, ATAT1 / 2 , and CUC2 transcription factors ( NAC ), and WRKY class of zinc-finger proteins ( WRKY ). This research has successfully induced calli from two diploid cotton species and revealed new genes responding to salt stress in callus tissue, which will lay the foundation for protoplast fusion for further understanding of salt stress responses in cotton. 

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4. Genome‐wide methylation landscape during somatic embryogenesis in Medicago truncatula reveals correlation between Tnt1 retrotransposition and hyperactive methylation regions

   https://doi.org/10.1111/tpj.16744  

   Nandety, Raja Sekhar ; Oh, Sunhee ; Lee, Hee‐Kyung ; Krom, Nick ; Gupta, Rajeev ; Mysore, Kirankumar S. ( April 2024 , The Plant Journal)

   Medicago truncatulais a model legume for fundamental research on legume biology and symbiotic nitrogen fixation.Tnt1, a retrotransposon from tobacco, was used to generate insertion mutants inM. truncatulaR108. Approximately 21 000 insertion lines have been generated and publicly available.Tnt1retro‐transposition event occurs during somatic embryogenesis (SE), a pivotal process that triggers massive methylation changes. We studied the SE ofM. truncatulaR108 using leaf explants and explored the dynamic shifts in the methylation landscape from leaf explants to callus formation and finally embryogenesis. Higher cytosine methylation in all three contexts of CG, CHG, and CHH patterns was observed during SE compared to the controls. Higher methylation patterns were observed in assumed promoter regions (~2‐kb upstream regions of transcription start site) of the genes, while lowest was recorded in the untranslated regions. Differentially methylated promoter region analysis showed a higher CHH methylation in embryogenesis tissue samples when compared to CG and CHG methylation. Strong correlation (89.71%) was identified between the differentially methylated regions (DMRs) and the site ofTnt1insertions inM. truncatulaR108 and stronger hypermethylation of genes correlated with higher number ofTnt1insertions in all contexts of CG, CHG, and CHH methylation. Gene ontology enrichment and KEGG pathway enrichment analysis identified genes and pathways enriched in the signal peptide processing, ATP hydrolysis, RNA polymerase activity, transport, secondary metabolites, and nitrogen metabolism pathways. Combined gene expression analysis and methylation profiling showed an inverse relationship between methylation in the DMRs (regions spanning genes) and the expression of genes. Our results show that a dynamic shift in methylation happens during the SE process in the context of CG, CHH and CHG methylation, and theTnt1retrotransposition correlates with the hyperactive methylation regions.

    

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5. Somatic embryo initiation by rice BABY BOOM1 involves activation of zygote‐expressed auxin biosynthesis genes

   https://doi.org/10.1111/nph.18774  

   Khanday, Imtiyaz ; Santos‐Medellín, Christian ; Sundaresan, Venkatesan ( February 2023 , New Phytologist)

   Plant embryogenesis results from the fusion of male and female gametes but can also be induced in somatic cells. The molecular pathways for embryo initiation are poorly understood, especially in monocots. In rice, the male gamete expressed BABY BOOM1 (OsBBM1) transcription factor functions as an embryogenic trigger in the zygote and can also promote somatic embryogenesis when ectopically expressed in somatic tissues.

   We used gene editing, transcriptome profiling, and chromatin immunoprecipitation to determine the molecular players involved in embryo initiation downstream ofOsBBM1.

   We identifyOsYUCCA(OsYUC) auxin biosynthesis genes as direct targets ofOsBBM1. Unexpectedly, theseOsYUCtargets in zygotes are expressed only from the maternal genome, whereas the paternal genome exclusively provides functionalOsBBM1to initiate embryogenesis. Induction of somatic embryogenesis by exogenous auxin requiresOsBBMgenes and downstreamOsYUCtargets. EctopicOsBBM1initiates somatic embryogenesis without exogenous auxins but requires functionalOsYUCgenes.

   Thus, anOsBBM‐OsYUCmodule is a key player for both somatic and zygotic embryogenesis in rice. Zygotic embryo initiation involves a partnership of male and female genomes, through which paternalOsBBM1activates maternalOsYUCgenes. In somatic embryogenesis, exogenous auxin triggersOsBBM1expression, which then activates endogenous auxin biosynthesisOsYUCgenes.

    

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