Sulfate-reducing bacteria(SRB)are ubiquitous anaerobic microorganisms that play signifi cant roles in the global biogeochemical cycle.Coastal wetlands,one of the major habitats of SRB,exhibit high sulfate-reducing act...Sulfate-reducing bacteria(SRB)are ubiquitous anaerobic microorganisms that play signifi cant roles in the global biogeochemical cycle.Coastal wetlands,one of the major habitats of SRB,exhibit high sulfate-reducing activity and thus play signifi cant roles in organic carbon remineralization,benthic geochemical action,and plant-microbe interactions.Recent studies have provided credible evidence that the functional rather than the taxonomic composition of microbes responds more closely to environmental factors.Therefore,in this study,functional gene prediction based on PacBio single molecular real-time sequencing of 16S rDNA was applied to determine the sulfate-reducing and organic substrate-decomposing activities of SRB in the rhizospheres of two typical coastal wetland plants in North and South China:Zostera japonica and Scirpus mariqueter.To this end,some physicochemical characteristics of the sediments as well as the phylogenetic structure,community composition,diversity,and proportions of several functional genes of the SRB in the two plant rhizospheres were analyzed.The Z.japonic a meadow had a higher dissimilatory sulfate reduction capability than the S.mariqueter-comprising saltmarsh,owing to its larger proportion of SRB in the microbial community,larger proportions of functional genes involved in dissimilatory sulfate reduction,and the stronger ability of the SRB to degrade organic substrates completely.This study confi rmed the feasibility of applying microbial community function prediction in research on the metabolic features of SRB,which will be helpful for gaining new knowledge of the biogeochemical and ecological roles of these bacteria in coastal wetlands.展开更多
Sepsis-induced liver injury(SILI)is an important cause of septicemia deaths.BaWeiBaiDuSan(BWBDS)was extracted from a formula of Panax ginseng C.A.Meyer,Lilium brownie F.E.Brown ex Miellez var.viridulum Baker,Polygonat...Sepsis-induced liver injury(SILI)is an important cause of septicemia deaths.BaWeiBaiDuSan(BWBDS)was extracted from a formula of Panax ginseng C.A.Meyer,Lilium brownie F.E.Brown ex Miellez var.viridulum Baker,Polygonatum sibiricum Delar.ex Redoute,Lonicera japonica Thunb.,Hippophae rhamnoides Linn.,Amygdalus Communis Vas,Platycodon grandiflorus(Jacq.)A.DC.,and Cortex Phelloderdri.Herein,we investigated whether the BWBDS treatment could reverse SILI by the mechanism of modulating gut microbiota.BWBDS protected mice against SILI,which was associated with promoting macrophage anti-inflammatory activity and enhancing intestinal integrity.BWBDS selectively promoted the growth of Lactobacillus johnsonii(L.johnsonii)in cecal ligation and puncture treated mice.Fecal microbiota transplantation treatment indicated that gut bacteria correlated with sepsis and was required for BWBDS anti-sepsis effects.Notably,L.johnsonii significantly reduced SILI by promoting macrophage anti-inflammatory activity,increasing interleukin-10+M2 macrophage production and enhancing intestinal integrity.Furthermore,heat inactivation L.johnsonii(HI-L.johnsonii)treatment promoted macrophage anti-inflammatory activity and alleviated SILI.Our findings revealed BWBDS and gut microbiota L.johnsonii as novel prebiotic and probiotic that may be used to treat SILI.The potential underlying mechanism was at least in part,via L.johnsonii-dependent immune regulation and interleukin-10+M2 macrophage production.展开更多
基金Supported by the Scientifi c Research Fund of the Second Institute of Oceanography,Ministry of Natural Resources(MNR)(Nos.JB1906,JG1616,JG1910)the Zhejiang Qingshan Lake Innovation Platform for Marine Science and Technology(No.2017E80001)+4 种基金the Key Projects of Philosophy and Social Sciences Research,Ministry of Education(No.18JZD059)the National Key Technology Research and Development Program of the Ministry of Science and Technology of the China(No.2015BAD08B01)the State Key Laboratory of Satellite Ocean Environment Dynamics(No.SOEDZZ1902)the National Natural Science Foundation of China(No.41806136)the Project of Long Term Observation and Research Plan in the Changjiang Estuary and the Adjacent East China Sea(LORCE,14282)。
文摘Sulfate-reducing bacteria(SRB)are ubiquitous anaerobic microorganisms that play signifi cant roles in the global biogeochemical cycle.Coastal wetlands,one of the major habitats of SRB,exhibit high sulfate-reducing activity and thus play signifi cant roles in organic carbon remineralization,benthic geochemical action,and plant-microbe interactions.Recent studies have provided credible evidence that the functional rather than the taxonomic composition of microbes responds more closely to environmental factors.Therefore,in this study,functional gene prediction based on PacBio single molecular real-time sequencing of 16S rDNA was applied to determine the sulfate-reducing and organic substrate-decomposing activities of SRB in the rhizospheres of two typical coastal wetland plants in North and South China:Zostera japonica and Scirpus mariqueter.To this end,some physicochemical characteristics of the sediments as well as the phylogenetic structure,community composition,diversity,and proportions of several functional genes of the SRB in the two plant rhizospheres were analyzed.The Z.japonic a meadow had a higher dissimilatory sulfate reduction capability than the S.mariqueter-comprising saltmarsh,owing to its larger proportion of SRB in the microbial community,larger proportions of functional genes involved in dissimilatory sulfate reduction,and the stronger ability of the SRB to degrade organic substrates completely.This study confi rmed the feasibility of applying microbial community function prediction in research on the metabolic features of SRB,which will be helpful for gaining new knowledge of the biogeochemical and ecological roles of these bacteria in coastal wetlands.
基金funded by regular grants and joint grant(File No.0096/2018/A3,0111/2020/A3 and 0056/2020/AMJ)Dr.Neher’s Biophysics Laboratory for Innovative Drug Discovery(File No.001/2020/ALC)+4 种基金supported by the Macao Science and Technology Development Fundsupported by 2020 Young Qihuang Scholar funded by the National Administration of Traditional Chinese Medicinesupported by National Natural Science Foundation of China(82025036)supported by the Start-up Research Grant of University of Macao(SRG2022-00020-FHS,China)the Faculty of Health Science,University of Macao(Macao,China).
文摘Sepsis-induced liver injury(SILI)is an important cause of septicemia deaths.BaWeiBaiDuSan(BWBDS)was extracted from a formula of Panax ginseng C.A.Meyer,Lilium brownie F.E.Brown ex Miellez var.viridulum Baker,Polygonatum sibiricum Delar.ex Redoute,Lonicera japonica Thunb.,Hippophae rhamnoides Linn.,Amygdalus Communis Vas,Platycodon grandiflorus(Jacq.)A.DC.,and Cortex Phelloderdri.Herein,we investigated whether the BWBDS treatment could reverse SILI by the mechanism of modulating gut microbiota.BWBDS protected mice against SILI,which was associated with promoting macrophage anti-inflammatory activity and enhancing intestinal integrity.BWBDS selectively promoted the growth of Lactobacillus johnsonii(L.johnsonii)in cecal ligation and puncture treated mice.Fecal microbiota transplantation treatment indicated that gut bacteria correlated with sepsis and was required for BWBDS anti-sepsis effects.Notably,L.johnsonii significantly reduced SILI by promoting macrophage anti-inflammatory activity,increasing interleukin-10+M2 macrophage production and enhancing intestinal integrity.Furthermore,heat inactivation L.johnsonii(HI-L.johnsonii)treatment promoted macrophage anti-inflammatory activity and alleviated SILI.Our findings revealed BWBDS and gut microbiota L.johnsonii as novel prebiotic and probiotic that may be used to treat SILI.The potential underlying mechanism was at least in part,via L.johnsonii-dependent immune regulation and interleukin-10+M2 macrophage production.
