SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4319962883> ?p ?o ?g. }

Showing items 1 to 100 of ±155 with 100 items per page.

W4319962883 endingPage "789" @default.
W4319962883 startingPage "789" @default.
W4319962883 abstract "Selenium (Se) is an essential element for mammals, and its deficiency in the diet is a global problem. Agronomic biofortification through exogenous Se provides a valuable strategy to enhance human Se intake. Selenium nanoparticles (SeNPs) have been regarded to be higher bioavailability and less toxicity in comparison with selenite and selenate. Still, little has been known about the mechanism of their metabolism in plants. Soybean (Glycine max L.) can enrich Se, providing an ideal carrier for Se biofortification. In this study, soybean sprouts were treated with SeNPs, and a combination of next-generation sequencing (NGS) and single-molecule real-time (SMRT) sequencing was applied to clarify the underlying molecular mechanism of SeNPs metabolism. A total of 74,662 nonredundant transcripts were obtained, and 2109 transcription factors, 9687 alternative splice events, and 3309 long non-coding RNAs (lncRNAs) were predicted, respectively. KEGG enrichment analysis of the DEGs revealed that metabolic pathways, biosynthesis of secondary metabolites, and peroxisome were most enriched both in roots and leaves after exposure to SeNPs. A total of 117 transcripts were identified to be putatively involved in SeNPs transport and biotransformation in soybean. The top six hub genes and their closely coexpressed Se metabolism-related genes, such as adenylylsulfate reductase (APR3), methionine-tRNA ligase (SYM), and chloroplastic Nifs-like cysteine desulfurases (CNIF1), were screened by WGCNA and identified to play crucial roles in SeNPs accumulation and tolerance in soybean. Finally, a putative metabolism pathway of SeNPs in soybean was proposed. These findings have provided a theoretical foundation for future elucidation of the mechanism of SeNPs metabolism in plants." @default.
W4319962883 created "2023-02-11" @default.
W4319962883 creator A5006085257 @default.
W4319962883 creator A5024058852 @default.
W4319962883 creator A5027475930 @default.
W4319962883 creator A5032273145 @default.
W4319962883 creator A5042467158 @default.
W4319962883 creator A5051423189 @default.
W4319962883 creator A5066446276 @default.
W4319962883 creator A5077760729 @default.
W4319962883 date "2023-02-09" @default.
W4319962883 modified "2023-10-14" @default.
W4319962883 title "Illumina RNA and SMRT Sequencing Reveals the Mechanism of Uptake and Transformation of Selenium Nanoparticles in Soybean Seedlings" @default.
W4319962883 cites W1521649230 @default.
W4319962883 cites W1872897137 @default.
W4319962883 cites W1926084036 @default.
W4319962883 cites W1968444065 @default.
W4319962883 cites W1980888233 @default.
W4319962883 cites W1989315201 @default.
W4319962883 cites W1996750559 @default.
W4319962883 cites W1998422171 @default.
W4319962883 cites W2028357188 @default.
W4319962883 cites W2038350406 @default.
W4319962883 cites W2049165375 @default.
W4319962883 cites W2056116250 @default.
W4319962883 cites W2061548680 @default.
W4319962883 cites W2070544064 @default.
W4319962883 cites W2072921949 @default.
W4319962883 cites W2075320162 @default.
W4319962883 cites W2080316641 @default.
W4319962883 cites W2100493050 @default.
W4319962883 cites W2103996971 @default.
W4319962883 cites W2104911952 @default.
W4319962883 cites W2106678197 @default.
W4319962883 cites W2111331422 @default.
W4319962883 cites W2116186771 @default.
W4319962883 cites W2124516931 @default.
W4319962883 cites W2129628169 @default.
W4319962883 cites W2130180097 @default.
W4319962883 cites W2148588871 @default.
W4319962883 cites W2152999824 @default.
W4319962883 cites W2154878082 @default.
W4319962883 cites W2158714788 @default.
W4319962883 cites W2160177274 @default.
W4319962883 cites W2175928435 @default.
W4319962883 cites W2208186786 @default.
W4319962883 cites W2224056471 @default.
W4319962883 cites W2323249901 @default.
W4319962883 cites W2346257736 @default.
W4319962883 cites W2401758076 @default.
W4319962883 cites W2472351724 @default.
W4319962883 cites W2516737311 @default.
W4319962883 cites W2529592713 @default.
W4319962883 cites W2562784299 @default.
W4319962883 cites W2670227869 @default.
W4319962883 cites W2795530058 @default.
W4319962883 cites W2803122530 @default.
W4319962883 cites W2803813763 @default.
W4319962883 cites W2804724578 @default.
W4319962883 cites W2899547716 @default.
W4319962883 cites W2900044275 @default.
W4319962883 cites W2913040423 @default.
W4319962883 cites W2931286964 @default.
W4319962883 cites W2949317881 @default.
W4319962883 cites W2968576696 @default.
W4319962883 cites W2989866585 @default.
W4319962883 cites W2990301517 @default.
W4319962883 cites W2995511781 @default.
W4319962883 cites W3014526398 @default.
W4319962883 cites W3023678329 @default.
W4319962883 cites W3035877643 @default.
W4319962883 cites W3042953105 @default.
W4319962883 cites W3044191436 @default.
W4319962883 cites W3064789162 @default.
W4319962883 cites W3092628293 @default.
W4319962883 cites W3094645287 @default.
W4319962883 cites W3094862694 @default.
W4319962883 cites W3095583226 @default.
W4319962883 cites W3096058518 @default.
W4319962883 cites W3100584158 @default.
W4319962883 cites W3106670229 @default.
W4319962883 cites W3112521968 @default.
W4319962883 cites W3127206605 @default.
W4319962883 cites W3154413160 @default.
W4319962883 cites W3159533326 @default.
W4319962883 cites W3171260749 @default.
W4319962883 cites W3173435816 @default.
W4319962883 cites W3186859168 @default.
W4319962883 cites W3197573541 @default.
W4319962883 cites W3199985538 @default.
W4319962883 cites W3207156624 @default.
W4319962883 cites W3215674187 @default.
W4319962883 cites W4220756050 @default.
W4319962883 cites W4225386181 @default.
W4319962883 cites W4282912841 @default.
W4319962883 cites W4283796805 @default.
W4319962883 cites W4313458144 @default.
W4319962883 doi "https://doi.org/10.3390/plants12040789" @default.