Integrative transcriptomics reveals association of abscisic acid and lignin pathways with cassava whitefly resistance

Can the molecular and transgenic breeding of crops be an alternative and sustainable technology to meet food demand?

The gradual increase in the worldwide population represents various challenges, and one of the most alarming being the food demand. Historically technological advances led to the development of crops that meets the requirements and demands. Currently, molecular breeding unlocks the genetic potential of crops for their improvement, positioning it as a key technology for the development of new crops. The implementation of OMICs sciences, such spatial and single cell transcriptomics is providing a large and precise information, which can be exploited for crop improvement related to increasing yield, improving the nutritional value; designing new strategies for diseases resistance and management and for conserving biodiversity. Furthermore, the use of new technologies such CRISPR/CAS9 brought us the ability to modify the selected regions of the genome to select the superior's genotypes at a short time and the use of artificial intelligence aid in the analysis of big data generated by OMICS sciences. On the other hand, the application of molecular improvement technologies open up discussion on global regulatory measures, the socio-economic and socio-ethics, as the frameworks on its global regulation and its impact on the society create the public perception on its acceptance. In this review, the use and impact of OMICs sciences and genetic engineering in crops development, the regulatory measures, the socio-economic impact and as well as the mediatic information on genetically modified crops worldwide is discussed along with comprehensive insights on the potential of molecular plant breeding as an alternative and sustainable technology to meet global food demand.

Using salicylic acid-responsive promoters to drive the expression of jasmonic acid-regulated genes enhances plant resistance to whiteflies

BACKGROUND

Jasmonic acid (JA) is an important phytohormone used to defend against herbivores, but it does not respond to whitefly feeding. Conversely, another phytohormone, salicylic acid (SA), is induced when plants are fed upon by whiteflies. JA has a better anti-whitefly effect than SA; however, there is limited research on how to effectively improve plant resistance by utilizing the different responses of these phytohormones to whitefly feeding.

RESULTS

We discovered that protease inhibitors 8 (PI8) and terpene synthase 10 (TPS10) located downstream of the JA-regulated pathway in plants have anti-whitefly effects, but these two genes were not induced by whitefly feeding. To identify whitefly-inducible promoters, we compared the transcriptome data of tobacco fed upon by Bemisia tabaci with the control. We focused on pathogenesis-related (PR) genes because they are known to be induced by SA. Among these PR genes, we found that expression levels of pathogenes-related protein 1C-like (PR1) and glucose endo-1,3-beta-glucosidase (BGL) can be significantly induced by whitefly feeding and regulated by SA. We then engineered the whitefly-inducible promoters of BGL and PR1 to drive the expression of PI8 and TPS10. We found that compared with control plants that did not induce the expression of PI8 or TPS10, transformed plants expressing PI8 or TPS10 under the PR1 or BGL promoter showed a significant increase in the expression levels of PI8 and TPS10 after whitefly infection, significantly improving their resistance to whiteflies.

CONCLUSION

Our findings suggest that using SA-inducible promoters as tools to drive the expression of JA-regulated defense genes can enhance plant resistance to whiteflies. Our study provides a novel pathway for the enhancement of plant resistance against insects. © 2024 Society of Chemical Industry.

Pan-genome analysis of GT64 gene family and expression response to Verticillium wilt in cotton

BACKGROUND

The GT64 subfamily, belonging to the glycosyltransferase family, plays a critical function in plant adaptation to stress conditions and the modulation of plant growth, development, and organogenesis processes. However, a comprehensive identification and systematic analysis of GT64 in cotton are still lacking.

RESULTS

This study used bioinformatics techniques to conduct a detailed investigation on the GT64 gene family members of eight cotton species for the first time. A total of 39 GT64 genes were detected, which could be classified into five subfamilies according to the phylogenetic tree. Among them, six genes were found in upland cotton. Furthermore, investigated the precise chromosomal positions of these genes and visually represented their gene structure details. Moreover, forecasted cis-regulatory elements in GhGT64s and ascertained the duplication type of the GT64 in the eight cotton species. Evaluation of the Ka/Ks ratio for similar gene pairs among the eight cotton species provided insights into the selective pressures acting on these homologous genes. Additionally, analyzed the expression profiles of the GT64 gene family. Overexpressing GhGT64_4 in tobacco improved its disease resistance. Subsequently, VIGS experiments conducted in cotton demonstrated reduced disease resistance upon silencing of the GhGT64_4, may indicate its involvement in affecting lignin and jasmonic acid biosynthesis pathways, thus impacting cotton resistance. Weighted Gene Co-expression Network Analysis (WGCNA) revealed an early immune response against Verticillium dahliae in G. barbadense compared to G. hirsutum. Quantitative Reverse Transcription Polymerase Chain Reaction (qRT-PCR) analysis indicated that some GT64 genes might play a role under various biotic and abiotic stress conditions.

CONCLUSIONS

These discoveries enhance our knowledge of GT64 family members and lay the groundwork for future investigations into the disease resistance mechanisms of this gene in cotton.