Ore, it is actually critical to elucidate the mechanism of wheat starch synthesis in response to drought and high-temperature pressure during the grain filling period. In current years, lots of research have revealed that most of these quality traits are undergoing improvement by way of genetic modification. The new details collected from hybrid and transgenic plants is anticipated to help create novel starch for understanding wheat starch biosynthesis and industrial use. In addition, standard breeding and genetic modification could be utilised collectively to generate new starches with modified properties. Nevertheless, chemical or physical radiation-induced mutations might be accompanied by un-desirable and uncharacterized mutations inside the entire genome [207,208]. In addition, RNAi-mediated interference of gene expression is typically incomplete and transgene expression varies in distinct lineages. In addition, transgenic lines are regarded as genetically modified and should undergo a costly and time-consuming regulatory procedure [209]. At the moment, wheat transformation investigation applying plant genetic engineering technologies could be the key purpose of continuously controlling and analyzing the properties of wheat starch.Author Contributions: Conceptualization, K.-H.K.; methodology, K.-H.K.; formal analysis, K.-H.K.; data curation, K.-H.K.; writing–original draft preparation, K.-H.K.; Icosabutate MedChemExpress writing–review and editing, J.-Y.K.; visualization, J.-Y.K.; supervision, J.-Y.K.; project administration, J.-Y.K.; funding acquisition, J.-Y.K. All authors have study and agreed for the published version with the manuscript. Funding: This study was funded by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MSIP) (NRF-2020R1I1A3069901), Republic of Korea. Data Availability Statement: Not applicable. Acknowledgments: This function was supported by the research grant of the Kongju National University in 2021. Conflicts of Interest: The authors declare no conflict of interest.
plantsArticleDetection of Persistent Viruses by High-Throughput Sequencing in Tomato and Pepper from Panama: Phylogenetic and Evolutionary StudiesLuis Galipienso 1, , Laura Elvira-Gonz ez 2 , Leonardo Velasco three , Jos gel Herrera-V quez four and Luis RubioPlant Protection and Biotechnology Center from the Valencian Institute of Agricultural Investigation, 46113 Moncada, Valencia, Spain; [email protected] Subtropical and Mediterranean Horticulture Institute (LaMayora), 29010 Algarrobo-Costa, M aga, Spain; [email protected] Churriana Center of Andalusian Institute of Agricultural Analysis, 29140 Churriana, M aga, Spain; [email protected] Divisa Center from the Panamanian Agricultural and Innovation Institute, Divisa 0619, Herrera, Panama; [email protected] Correspondence: [email protected]: Galipienso, L.; Elvira-Gonz ez, L.; Velasco, L.; Herrera-V quez, J.; Rubio, L. Detection of Persistent Viruses by High-Throughput Sequencing in Tomato and Pepper from Panama: Phylogenetic and Evolutionary Research. Plants 2021, ten, 2295. https://doi.org/10.3390/ plants10112295 Academic Editors: Beatriz Nocodazole Biological Activity Navarro and Michela Chiumenti Received: 1 October 2021 Accepted: 22 October 2021 Published: 26 OctoberAbstract: High-throughput sequencing from symptomatic tomato and pepper plants collected in Panama rendered the complete genome of your southern tomato virus (isolate STV_Panama) and bell pepper endornavirus (isolate BPEV_Panama), and almost-complete genomes of three other BPEV isolates. Tomato c.