FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2972539401> ?p ?o ?g. }

• W2972539401 endingPage "674" @default.
• W2972539401 startingPage "661" @default.
• W2972539401 abstract "The yellow drum Nibea albiflora is less susceptible to Cryptocaryon irritans infection than is the case with other marine fishes such as Larimichthys crocea, Lateolabrax japonicus, and Pagrus major. To investigate further their resistance mechanism, we infected the N. albiflora with the C. irritans at a median lethal concentration of 2050 theronts/g fish. The skins of the infected and the uninfected fishes were sampled at 24 h and 72 h followed by an extensive analysis of metabolism. The study results revealed that there were 2694 potential metabolites. At 24 h post-infection, 12 metabolites were up-regulated and 17 were down-regulated whereas at 72 h post-infection, 22 metabolites were up-regulated and 26 were down-regulated. Pathway enrichment analysis shows that the differential enriched pathways were higher at 24 h with 22 categories and 58 subcategories (49 up, 9 down) than at 72 h whereby the differential enriched pathways were 6 categories and 8 subcategories (4 up, 4 down). In addition, the principal component analysis (PCA) plot shows that at 24 h the metabolites composition of infected group were separately clustered to uninfected group while at 72 h the metabolites composition in infected group were much closer to uninfected group. This indicated that C. irritans caused strong metabolic stress on the N. albiflora at 24 h and restoration of the dysregulated metabolic state took place at 72 h of infection. Also, at 72 h post infection a total of 17 compounds were identified as potential biomarkers. Furthermore, out of 2694 primary metabolites detected, 23 metabolites could be clearly identified and semi quantified with a known identification number and assigned into 66 Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways. Most of the enriched KEGG pathways were mainly from metabolic pathway classes, including the metabolic pathway, biosynthesis of secondary metabolites, taurine and hypotaurine metabolism, purine metabolism, linoleic acid metabolism, phenylalanine, tyrosine and tryptophan biosynthesis. Others were glyoxylate and dicarboxylate metabolism, glutathione metabolism, and alanine, aspartate, and glutamate metabolism. Moreover, out of the identified metabolites, only 6 metabolites were statistically differentially expressed, namely, L -glutamate (up-regulated) at 24 h was important for energy and precursor for other glutathiones and instruments of preventing oxidative injury; 15-hydroxy- eicosatetraenoic acid (15-HETE), (S)-(-)-2-Hydroxyisocaproic acid, and adenine (up-regulated) at 72 h were important for anti-inflammatory and immune responses during infection; others were delta-valerolactam and betaine which were down-regulated compared to uninfected group at 72 h, might be related to immure responses including stimulation of immune system such as production of antibodies. Our results therefore further advance our understanding on the immunological regulation of N. albiflora during immune response against infections as they indicated a strong relationship between skin metabolome and C. irritans infection." @default.
• W2972539401 created "2019-09-19" @default.
• W2972539401 creator A5003938756 @default.
• W2972539401 creator A5004354888 @default.
• W2972539401 creator A5011194717 @default.
• W2972539401 creator A5029522351 @default.
• W2972539401 creator A5045498522 @default.
• W2972539401 creator A5051379153 @default.
• W2972539401 creator A5052824438 @default.
• W2972539401 creator A5076409244 @default.
• W2972539401 creator A5081461782 @default.
• W2972539401 creator A5090762296 @default.
• W2972539401 date "2019-11-01" @default.
• W2972539401 modified "2023-10-18" @default.
• W2972539401 title "Skin metabolome reveals immune responses in yellow drum Nibea albiflora to Cryptocaryon irritans infection" @default.
• W2972539401 cites W1574486203 @default.
• W2972539401 cites W1709576524 @default.
• W2972539401 cites W1757557138 @default.
• W2972539401 cites W1881752730 @default.
• W2972539401 cites W1938793937 @default.
• W2972539401 cites W1968690534 @default.
• W2972539401 cites W1975348273 @default.
• W2972539401 cites W1977633636 @default.
• W2972539401 cites W1978361535 @default.
• W2972539401 cites W1980104013 @default.
• W2972539401 cites W1983564432 @default.
• W2972539401 cites W1985840227 @default.
• W2972539401 cites W1986388841 @default.
• W2972539401 cites W1988441129 @default.
• W2972539401 cites W1990821243 @default.
• W2972539401 cites W1996424451 @default.
• W2972539401 cites W1997206404 @default.
• W2972539401 cites W1997872881 @default.
• W2972539401 cites W2000449318 @default.
• W2972539401 cites W2012216170 @default.
• W2972539401 cites W2013388043 @default.
• W2972539401 cites W2015775982 @default.
• W2972539401 cites W2019700360 @default.
• W2972539401 cites W2024992865 @default.
• W2972539401 cites W2025257333 @default.
• W2972539401 cites W2044158587 @default.
• W2972539401 cites W2047612167 @default.
• W2972539401 cites W2051029989 @default.
• W2972539401 cites W2059898775 @default.
• W2972539401 cites W2068542211 @default.
• W2972539401 cites W2072479910 @default.
• W2972539401 cites W2074126193 @default.
• W2972539401 cites W2074424976 @default.
• W2972539401 cites W2080957914 @default.
• W2972539401 cites W2092138818 @default.
• W2972539401 cites W2093381843 @default.
• W2972539401 cites W2094348712 @default.
• W2972539401 cites W2098539376 @default.
• W2972539401 cites W2113302824 @default.
• W2972539401 cites W2117926778 @default.
• W2972539401 cites W2126214604 @default.
• W2972539401 cites W2128106102 @default.
• W2972539401 cites W2133137948 @default.
• W2972539401 cites W2142716304 @default.
• W2972539401 cites W2146331099 @default.
• W2972539401 cites W2160352483 @default.
• W2972539401 cites W2164087848 @default.
• W2972539401 cites W2167121498 @default.
• W2972539401 cites W2169559026 @default.
• W2972539401 cites W2193608385 @default.
• W2972539401 cites W2225272104 @default.
• W2972539401 cites W2292051166 @default.
• W2972539401 cites W2294192974 @default.
• W2972539401 cites W2327229862 @default.
• W2972539401 cites W2515558325 @default.
• W2972539401 cites W2556115163 @default.
• W2972539401 cites W2588657333 @default.
• W2972539401 cites W2591792212 @default.
• W2972539401 cites W2591978130 @default.
• W2972539401 cites W2594364105 @default.
• W2972539401 cites W2614659915 @default.
• W2972539401 cites W2621521230 @default.
• W2972539401 cites W2768684947 @default.
• W2972539401 cites W2778470476 @default.
• W2972539401 cites W2792042705 @default.
• W2972539401 cites W2792106006 @default.
• W2972539401 cites W2795056734 @default.
• W2972539401 cites W2795669040 @default.
• W2972539401 cites W2795889744 @default.
• W2972539401 cites W2805545211 @default.
• W2972539401 cites W2884127329 @default.
• W2972539401 cites W2890986672 @default.
• W2972539401 cites W2899111084 @default.
• W2972539401 cites W2902685697 @default.
• W2972539401 cites W2903254604 @default.
• W2972539401 cites W2939030139 @default.
• W2972539401 cites W31775651 @default.
• W2972539401 cites W573679988 @default.
• W2972539401 cites W67545376 @default.
• W2972539401 doi "https://doi.org/10.1016/j.fsi.2019.09.027" @default.
• W2972539401 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/31521785" @default.
• W2972539401 hasPublicationYear "2019" @default.
• W2972539401 type Work @default.

• next