Microplastics(MPs),particularly polyvinyl chloride microplastics(PVC MPs)have become a notable environmental pollutant that affect various marine organisms such as Pinctada fucata martensii.As filter feeders,these biv...Microplastics(MPs),particularly polyvinyl chloride microplastics(PVC MPs)have become a notable environmental pollutant that affect various marine organisms such as Pinctada fucata martensii.As filter feeders,these bivalves consume significant volumes of water containing MPs,leading to contact with and ingestion of MPs.Moreover,given the ecological and economic importance of P.f.martensii in artificial pearl production,investigating the effects of PVC MPs exposure is crucial.This study aimed to investigate the effects of PVC MPs exposure on nucleus retention,pearl formation,oxidative stress by examining superoxide dismutase(SOD)activity,catalase(CAT)activity,lipid peroxidation(LPO),and total antioxidant capacity(TAOC)of P.f.martensii,while also exploring transcriptomic changes at different concentrations and exposure time points,including a recovery period.The pearl oysters were exposed to PVC MPs at concentrations of 1-,2.5-,and 5-mg PVC MPs/L for 10 d followed by 6 d of recovery.After 1-,4-,10-d of exposure,and additional 6 d of recovery,samples were taken and analyzed.Findings revealed that only prolonged exposure(10 d)to PVC MPs affected SOD activity,while CAT activity,LPO,and TAOC remained unaffected throughout the experiment.Notably,SOD activity was restored during the 6-d recovery phase.Transcriptome analysis highlighted significant gene alterations linked to various pathways,affecting cellular processes,environmental information processing,genetic information processing,metabolism,and organismal systems,with an increase in pathway-related genes during recovery,implying a potential role of PVC MPs as gene inhibitors.This study provided insights into the effects of PVC MPs on P.f.martensii,shedding light on pearl retention,oxidative systems,and molecular pathways influenced by PVC MPs.Additionally,it contributed novel information on potential MPs exposure biomarkers,particularly relevant to marine organisms like P.f.martensii.展开更多
Bivalves are species-rich mollusks with prominent protective roles in coastal ecosystems.Across these ancient lineages,colony-founding larvae anchor themselves either by byssus production or by cemented attachment.The...Bivalves are species-rich mollusks with prominent protective roles in coastal ecosystems.Across these ancient lineages,colony-founding larvae anchor themselves either by byssus production or by cemented attachment.The latter mode of sessile life is strongly molded by left-right shell asymmetry during larval development of Ostreoida oysters such as Crassostrea hongkongensis.Here,we sequenced the genome of C.hongkongensis in high resolution and compared it to reference bivalve genomes to unveil genomic determinants driving cemented attachment and shell asymmetry.Importantly,loss of the homeobox gene Antennapedia(Antp)and broad expansion of lineagespecific extracellular gene families are implicated in a shift from byssal to cemented attachment in bivalves.Comparative transcriptomic analysis shows a conspicuous divergence between leftright asymmetrical C.hongkongensis and symmetrical Pinctada fucata in their expression profiles.Especially,a couple of orthologous transcription factor genes and lineage-specific shell-related gene families including that encoding tyrosinases are elevated,and may cooperatively govern asymmetrical shell formation in Ostreoida oysters.展开更多
基金Supported by the Science and Technology Program of Guangdong Province(No.2022A1515010030)the National Natural Science Foundation of China(No.32102817)+3 种基金the Department of Education of Guangdong Province(Nos.2020ZDZX1045,2021KCXTD026)the earmarked fund for CARS-49,Students Innovation and Entrepreneurship Training Program(No.CXXL2022015)the Technology Program of Guangdong Zhanjiang(No.2022A01010)the Hengli Biosciences Excellence Project of Guangdong Ocean University(No.B23335-4)。
文摘Microplastics(MPs),particularly polyvinyl chloride microplastics(PVC MPs)have become a notable environmental pollutant that affect various marine organisms such as Pinctada fucata martensii.As filter feeders,these bivalves consume significant volumes of water containing MPs,leading to contact with and ingestion of MPs.Moreover,given the ecological and economic importance of P.f.martensii in artificial pearl production,investigating the effects of PVC MPs exposure is crucial.This study aimed to investigate the effects of PVC MPs exposure on nucleus retention,pearl formation,oxidative stress by examining superoxide dismutase(SOD)activity,catalase(CAT)activity,lipid peroxidation(LPO),and total antioxidant capacity(TAOC)of P.f.martensii,while also exploring transcriptomic changes at different concentrations and exposure time points,including a recovery period.The pearl oysters were exposed to PVC MPs at concentrations of 1-,2.5-,and 5-mg PVC MPs/L for 10 d followed by 6 d of recovery.After 1-,4-,10-d of exposure,and additional 6 d of recovery,samples were taken and analyzed.Findings revealed that only prolonged exposure(10 d)to PVC MPs affected SOD activity,while CAT activity,LPO,and TAOC remained unaffected throughout the experiment.Notably,SOD activity was restored during the 6-d recovery phase.Transcriptome analysis highlighted significant gene alterations linked to various pathways,affecting cellular processes,environmental information processing,genetic information processing,metabolism,and organismal systems,with an increase in pathway-related genes during recovery,implying a potential role of PVC MPs as gene inhibitors.This study provided insights into the effects of PVC MPs on P.f.martensii,shedding light on pearl retention,oxidative systems,and molecular pathways influenced by PVC MPs.Additionally,it contributed novel information on potential MPs exposure biomarkers,particularly relevant to marine organisms like P.f.martensii.
基金support from the Key Special Project for Introduced Talents Team of Southern Marine Science and Engineering Guangdong Laboratory (Guangzhou),China(Grant No. GML2019ZD0407)the Key Deployment Project of Centre for Ocean Mega-Research of Science, Chinese Academy of Science (Grant No. COMS2019Q11)+6 种基金the National Natural Science Foundation of China (Grant Nos. 32073002 and 31902404)the China Agricultural Research System (Grant No. CARS-49)the Science and Technology Program of Guangzhou, China (Grant No. 201804020073)Natural Science Foundation of Guangdong, China (Grant No. 2020A1515011533)the Program of the Pearl River Young Talents of Science and Technology in Guangzhou of China (Grant No. 201806010003)the Institution of South China Sea Ecology and Environmental Engineering, Chinese Academy of Sciences (Grant Nos. ISEE2018PY01, ISEE2018PY03, and ISEE2018ZD01)the Science and Technology Planning Project of Guangdong Province, China (Grant Nos. 2017B030314052 and 201707010177)
文摘Bivalves are species-rich mollusks with prominent protective roles in coastal ecosystems.Across these ancient lineages,colony-founding larvae anchor themselves either by byssus production or by cemented attachment.The latter mode of sessile life is strongly molded by left-right shell asymmetry during larval development of Ostreoida oysters such as Crassostrea hongkongensis.Here,we sequenced the genome of C.hongkongensis in high resolution and compared it to reference bivalve genomes to unveil genomic determinants driving cemented attachment and shell asymmetry.Importantly,loss of the homeobox gene Antennapedia(Antp)and broad expansion of lineagespecific extracellular gene families are implicated in a shift from byssal to cemented attachment in bivalves.Comparative transcriptomic analysis shows a conspicuous divergence between leftright asymmetrical C.hongkongensis and symmetrical Pinctada fucata in their expression profiles.Especially,a couple of orthologous transcription factor genes and lineage-specific shell-related gene families including that encoding tyrosinases are elevated,and may cooperatively govern asymmetrical shell formation in Ostreoida oysters.
