Project description:Friable embryogenic callus (FEC) has been considered as the most suitable materials for efficient genetic transformation of cassava. Due to heavy genotype dependence on FEC induction and being amenable to somaclonal variation, the production and maintaining of reliable FEC is a limitation factor for cassava genetic transformation. Identification of key elements involving in biological processes from somatic embryos (SEs) to the FEC at different stages will provide critical insights for FEC improvement. Cytological observation showed the dramatic change of subcellular structures among SEs, fresh FEC (FFEC) and old FEC (OFEC). Decrease of sucrose and increase of fructose and glucose were detected in OFEC. A total of 6871 differentially expressed genes (DEGs) were identified from SEs, FFEC and OFEC by RNA-seq. Analysis of the DEGs showed that FEC induction was accompanied by the process of dedifferentiation, whereas the epigenetics modification occurred during the continuous subculturing process. The cell structure was reconstructed, mainly including the GO terms of "cell periphery" and "external encapsulating structure"; in parallel, the internal mechanisms were changed correspondingly, including the metabolisms of process (glycolysis) and compounds(alanine, aspartate, and glutamate). The significant reduction of genomic DNA methylation in OFEC indicates altered gene expression via chromatin modification. These results indicate that the induction and long-term subculture of FEC is a complicated biological process involving changes of genome modification, gene expression and subcellular reconstruction. The findings will be useful for improving FEC induction and maintenance from farmer-preferred cassava cultivars that are recalcitrant to genetic transformation, hence improving cassava through genetic engineering. Two-week-old SEs cultured on GD, FFEC emerging from SEs, and 9-month-old OFEC were used for analysis. Each sample was mixtured from six indepedent replicates and were collected for RNA extraction respectively.

Project description:Agrobacterium-mediated transformation is an important research tool and a practical tool for an improvement of cassava cultivar. The induction of friable embryogenic callus (FEC) is considered as a one of key step in cassava transformation. In this article, we optimized a media composition for improving the frequency of FEC induction and investigated about the physiological mechanism of FEC induction under optimized media condition using the transcriptome analysis. These results showed that changing to 10-folds lower media in comparison to MS media on nitrogen, potassium and phosphate contents and the use of excess vitamin B1 (changing from 0.1 mg/L to 10 mg/L) in addition to use of picrolam were necessary for leading to the effective induction to FEC and delaying the growth of non-FEC. An increase of transcripts concerning lipid metabolism, cell membrane and cell cuticle and a decrease of transcripts related to cell-wall modification process under long-term subculture were observed by microarray analysis, expecting that the nitrogen, potassium and phosphate limited condition and use of excess vitamin B1 provide the suitable condition for FEC induction through inhibition of excess cell proliferation and maintenance of fine FEC through formation of protective barriers in cell membranes. Our results will benefit as a one of significant techniques for cassava transformation, providing the more convenience transformation process using cassava genotypes and landrace adapted to the various field environments

Project description:Agrobacterium-mediated cassava transformation via friable embryogenic callus (FEC) has allowed the robust production of transgenic cassava. So far, the transformation has been performed mostly for 60444 (the model cassava variety for transformation) and African varieties due to the high ability of callus induction and good regeneration capacity from embryogenic tissues. It is important to develop the transformation methods for elite cassava varieties in Asian area which is one of main cassava production area in the world, however, the suitable transformation method for Asian elite variety via FEC has not been reported. Here, we developed the transformation method in Kasetsart 50 (KU50) which has the highest planting area in Thailand and Vietnam. In cassava transformation, the preparation of FEC is considered as a key step. The ability of FEC induction from KU50 was improved efficiently by the use of media with reduced nutrients and excess vitamin B1, even if the FEC-inducible efficiency was 5 times lower compared with cv. 60444. The optimal concentration of NAA for regeneration from FEC to cotyledon was 1.0 mg/L and the optimal concentration of BAP for shoot formation from cotyledon was 0.4 mg/L. The transformation efficiency was estimated as 45% for 60444 and 22% for KU50. Transcriptome analysis indicated that KU50 FEC is out of balance between cell wall production and assembly, because the expression of the genes related to loosing cell wall was upregulated in the FEC from KU50 compared with 60444. We hope that the developed technology will contribute to molecular breeding of useful cassava plants in Asia by the simultaneous use of genome-editing technology.

Project description:Cassava (Manihot esculenta) is the food security crop that feeds approximately 800 million people worldwide. Although this crop displays high productivity under drought and poor soil conditions, it is susceptible to disease, postharvest deterioration and the roots contain low nutritional content. Cassava improvement programs are focused on addressing these constraints but are hindered by the crop’s high heterozygosity, difficulty in synchronizing flowering, low seed production and a poor understanding of the physiology of this plant. Among the major food crops, cassava is unique in its ability to develop massive, underground storage roots. Despite the importance of these structures, their basic physiology remains largely unknown, especially the molecular genetic basis of storage root development. Similarly, in cassava, the favored target tissue for transgene integration and genome editing is a friable embryogenic callus (FEC). Little is known concerning gene expression in this tissue, or its relatedness to the somatic organized embryogenic structures (OES) from which it originates. Here, we provide molecular identities for eleven cassava tissue types through RNA sequencing and develop an open access, web-based interface for further interrogation of the data. Through this dataset, we report novel insight into the physiology of cassava and identify promoters able to drive specified tissue expression profiles. The information gained from this study is of value for both conventional and biotechnological improvement programs.

Project description:Xanthomonas axonopodis pv. manihotis (Xam) is a gram negative bacterium causing Cassava Bacterial Blight (CBB), an important limitation for cassava production. The genetic bases underlying cassava resistance and susceptibility to different Xam strains are currently unknown. To identify genes and pathways important for the interaction, we used RNA-seq data to study transcriptomic changes in cassava plants inoculated with the non-pathogenic Xam strain, (ORST4) and a pathogenic strain, ORST4 transformed with the TAL effector TALE1Xam (ORST4+TALE1Xam). This analysis revealed that transcriptomic responses to both strains were very similar and were dominated by the induction of genes related to photosynthesis and phenylpropanoid biosynthesis and the down-regulation of genes related to jasmonic acid signaling, features possibly related to defense responses. Among the genes induced exclusively in cassava plants inoculated with ORST4 + TALE1Xam we found one gene containing a predicted binding site for TALE1Xam in its promoter region. This gene encodes for a Heat Shock Transcription Factor B3 (HsfB3) and likely acts a transcriptional repressor. HsfB3 may constitute a new type of susceptibility gene activated by a TAL effector that manages to be sufficient for symptom development without suppressing defense responses in the plant. mRNA of Cassava stems inoculated with a non-pathogenic (ORST4) and pathogenic (+TALE1Xam) strain of Xanthomonas axonopodis pv. Manihotis, tissues collected at 0, 5 and7 days post-inoculation, 2 technical replicates used

Project description:Xanthomonas axonopodis pv. manihotis (Xam) is a gram negative bacterium causing Cassava Bacterial Blight (CBB), an important limitation for cassava production. The genetic bases underlying cassava resistance and susceptibility to different Xam strains are currently unknown. To identify genes and pathways important for the interaction, we used RNA-seq data to study transcriptomic changes in cassava plants inoculated with the non-pathogenic Xam strain, (ORST4) and a pathogenic strain, ORST4 transformed with the TAL effector TALE1Xam (ORST4+TALE1Xam). This analysis revealed that transcriptomic responses to both strains were very similar and were dominated by the induction of genes related to photosynthesis and phenylpropanoid biosynthesis and the down-regulation of genes related to jasmonic acid signaling, features possibly related to defense responses. Among the genes induced exclusively in cassava plants inoculated with ORST4 + TALE1Xam we found one gene containing a predicted binding site for TALE1Xam in its promoter region. This gene encodes for a Heat Shock Transcription Factor B3 (HsfB3) and likely acts a transcriptional repressor. HsfB3 may constitute a new type of susceptibility gene activated by a TAL effector that manages to be sufficient for symptom development without suppressing defense responses in the plant.

Project description:Streptococcus pyogenes or group A Streptococcus (GAS) is a leading cause of bacterial pharyngitis, skin and soft tissue infections, life-threatening invasive infections, and the post-infectious autoimmune syndromes of acute rheumatic fever and post-streptococcal glomerulonephritis. Genetic manipulation of this important pathogen is complicated by resistance of the organism to genetic transformation. Very low transformation efficiency is attributed to recognition and degradation of introduced foreign DNA by a type I restriction-modification system encoded by the hsdRSM locus. DNA sequence analysis of this locus in ten GAS strains that had been previously transformed with an unrelated plasmid revealed that six of the ten harbored a spontaneous mutation in hsdR, S, or M. The mutations were all different, and at least five of the six were predicted to result in loss of function of the respective hsd gene product. The unexpected occurrence of such mutations in previously transformed isolates suggested that the process of transformation selects for spontaneous inactivating mutations in the Hsd system. We investigated the possibility of exploiting the increased transformability of hsd mutants by constructing a deletion mutation in hsdM in GAS strain 854, a clinical isolate representative of the globally dominant M1T1 clonal group. Mutant strain 854hsdM exhibited a 5-fold increase in transformation efficiency compared to the wild type parent strain and no obvious change in growth or off-target gene expression. We conclude that genetic transformation of GAS selects for spontaneous mutants in the hsdRSM restriction modification system. We propose that use of a defined hsdM mutant as a parent strain for genetic manipulation of GAS will enhance transformation efficiency and reduce the likelihood of selecting spontaneous hsd mutants with uncharacterized genotypes.

Project description:The transport of mRNAs to distal subcellular compartments is an important component of spatial gene expression control in neurons. However, the mechanisms that control mRNA localization in neurons are not completely understood. Here, we identify the abundant base modification, m6A, as a novel regulator of this process. Transcriptome-wide analysis following genetic loss of m6A reveals hundreds of transcripts that exhibit altered subcellular localization in hippocampal neurons. Additionally, using a reporter system, we show that mutation of specific m6A sites in select neuronal transcripts diminishes their localization to neurites. Single molecule fluorescent in situ hybridization experiments further confirm our findings and identify the m6A reader proteins YTHDF2 and YTHDF3 as mediators of this effect. Our findings reveal a novel function for m6A in controlling mRNA localization in neurons and enable a better understanding of the mechanisms through which m6A influences gene expression in the brain.

Project description:E0771 subcutaneous tumors in C57/Bl6 mice were treated with saline, FEC (chemotherapy), oHSV-1 (oncolytic virus) or FEC + oHSV-1

Project description:Regeneration of transgenic cells remains a major obstacle to research and commercial deployment of transgenic plants for most species. Our aims are to improve knowledge of gene regulatory circuits important to meristem organization, and to identify regulatory genes that might be useful for improving the efficiency of regeneration during transformation. We analyzed gene expression during poplar regeneration using an Affymetrix GeneChip® array representing over 56,000 poplar transcripts. Experiment Overall Design: We focused on callus induction and shoot formation, thus sample RNAs were collected from tissues: prior to callus induction, 3 days and 15 days after callus induction, and 3 days and 8 days after the start of shoot induction. Experiment Overall Design: Two biological replicates were used for each of the five time points.