Recently,Prevotella spp.,a major genus of gram-negative commensal bacteria in humans,have emerged as a key microbial contributor to host metabolism due to its ability to ferment dietary fibers,produce beneficial short...Recently,Prevotella spp.,a major genus of gram-negative commensal bacteria in humans,have emerged as a key microbial contributor to host metabolism due to its ability to ferment dietary fibers,produce beneficial short-chain fatty acids,and influence immune responses.However,their diversity and functional differences have created challenges for their development and therapeutic use.Recent studies have shown that specific Prevotella species,such as P.copri,P.intestinalis,and P.histicola,can strengthen gut barrier integrity and reduce metabolic imbalances.Notably,Prevotella populations can be increased through high-fiber or herbal-based treatments.Traditional herbal medicines,including fiber-rich decoctions,also demonstrate the potential to boost endogenous Prevotella communities,enhance microbial fermentation,and improve glucose and lipid balance.This perspective examines the context-dependent roles of Prevotella spp.,with emphasis on the functional heterogeneity of key species such as P.copri,suggests a framework for combining herbal modulation with species-level microbiota profiling,and outlines a research plan to explore microbe-herb synergy in treating obesity,type 2 diabetes,and related metabolic disorders.This strategy offers a new,ecology-based approach to complement standard metabolic interventions.展开更多
Climate change impacts soil nitrogen, influencing plant responses to elevated atmospheric [CO2]. Understanding the interaction between nitrogen supply and elevated [CO2] is crucial for predicting plant future performa...Climate change impacts soil nitrogen, influencing plant responses to elevated atmospheric [CO2]. Understanding the interaction between nitrogen supply and elevated [CO2] is crucial for predicting plant future performance. This study examined the interactive effects of elevated [CO2] and nitrogen supply on the eco-physiological performance of yellow birch. Seedlings were exposed to two [CO2] levels and five nitrogen supply levels for 4 months. Growth parameters such as seedling height and root collar diameter increased with higher nitrogen supply and elevated [CO2], while specific leaf area decreased. [CO2] elevation and increasing nitrogen supply also increased the total and stem, and leaf biomass. The elevated [CO2] increased the stem mass ratio but decreased the root-to-shoot ratio and root mass ratio. However, decreases in nitrogen supply increased root mass ratio and root-to-shoot ratio. The elevated [CO2] increased the maximum rate of Rubisco carboxylation (Vcmax) and photosynthetic electron transport (Jmax), but the effect on Jmax was statistically significant only at the two highest nitrogen supply levels. The results indicate that yellow birch may increase photosynthetic capacity, biomass, and growth in the future when [CO2] is higher.展开更多
The acclimation capacity of Betula pendula and Betula pubescens was studied over 4 years in common gardens in central Italy(43°N)and southern(61°N)and northern Finland(67°N),representing drastically dif...The acclimation capacity of Betula pendula and Betula pubescens was studied over 4 years in common gardens in central Italy(43°N)and southern(61°N)and northern Finland(67°N),representing drastically different photoperiod and climate in temperate,boreal and subarctic vegetation zones.Two study sites that differed in soil fertility were established at each location,giving a total of six common gardens.The birch material was micropropagated from naturally regenerated stands of B.pendula and B.pubescens from Susa Valley and Rochemolle Valley in northern Italy,Punkaharju in southern Finland and Kittilä in northern Finland.The plants were measured for height growth,stem diameter,leaf chlorophyll content,leaf herbivory and pathogen damage.The effects of soil fertility on the common garden results were also analyzed.The results showed high acclimation capacity of B.pendula and B.pubescens after a long-range transfer from southern to northern Europe,despite the major shift in climate and photoperiod.First-year growth on average was best in boreal southern Finland for all origins.Betula pendula grew more than B.pubescens in Italy and southern Finland,while B.pubescens grew more in northern Finland and better tolerated the northward transfer.The height growth of origins showed a clear latitude gradient from slowly growing northern to fast growing southern origins in the nursery and laboratory,but not in the field.Soil fertility explained a significant part of variation among locations not only for growth variables,but also for leaf chlorophyll content and leaf herbivory and pathogen damage.Leaf herbivore and pathogen damage was greatest in southern Finland.Our results demonstrate good survival of birch from northern Italy in Finnish conditions and support the possibility of long-range south-to-north transfer of Betula species to provide resistant planting material in boreal forests for the rapidly changing climate.展开更多
As global warming persistently alters and rapidly reshapes landscapes and habitats, conventional species distribution models relying solely on maintaining static conditions within the current climate are likely to fal...As global warming persistently alters and rapidly reshapes landscapes and habitats, conventional species distribution models relying solely on maintaining static conditions within the current climate are likely to falter, particularly at the genus level. Hence, we hypothesize that climate change will differentially affect ecological niches of the same genus species with various latitudinal positioning and local topography, and the high-latitude species may experience greater niche contraction than low-latitude species, and that mountainous regions with high elevational variability may serve as critical climate refugia. Herein, we simulate niche alterations and integrate an ensemble model(EM) strategy, taking into account species dispersal limitations factors(topography, soil, and ultraviolet), to construct a comprehensive habitat suitability(CHS) model for assessing the future vulnerability of the Betula genus, most of which are timber species in China. Our findings reveal that the niche spatial(geographic distribution) of most species(62%) within the Betula genus will undergo a gradual decline under climate change, supporting our hypothesis of latitudinal differentiation in climate vulnerability. Intriguingly, the projected high-latitude niche reduction within the genus cannot be counterbalanced by the anticipated niche expansion of closely related species in low-latitude regions, even considering the evident latitudinal gradient distribution of species. Nonetheless, the niche spatial of six Betula species in southwestern China remains stable or expands under warming scenarios, strongly supporting our secondary hypothesis about topographic buffering effects, which probably means the unique topography(i.e., the largest elevation difference) of this region may serve as a sanctuary for preserving Betula genetic diversity. Our results underscore the uncertain nature of pre-existing niche systems at the genus level under climate change, emphasizing the need for diligent resource management and conservation planning for vulnerable timber species.展开更多
Glutathione-S-transferase(GST,EC2.5.1.18)multifunctional protease is important for detoxification,defense against biotic and abiotic stresses,and secondary metabolic material transport for plant growth and development...Glutathione-S-transferase(GST,EC2.5.1.18)multifunctional protease is important for detoxification,defense against biotic and abiotic stresses,and secondary metabolic material transport for plant growth and development.In this study,71 members of the BpGST family were identified from the entire Betula platyphylla Suk.genome.Most of the members encode proteins with amino acid lengths ranging from 101 to 875 and were localized to the cytoplasm by a prediction.BpGSTs can be divided into seven subfamilies,with a majority of birch U and F subfamily members according to gene structure,conserved motifs and evolutionary analysis.GST family genes showed collinearity with 22 genes in Oryza sativa L.,and three genes in Arabidopsis thaliana;promoter cis-acting elements predicted that the GST gene family is functional in growth,hormone regulation,and abiotic stress response.Most members of the F subfamily of GST(BpGSTFs)were expressed in roots,stems,leaves,and petioles,with the most expression observed in leaves.On the basis of the expression profiles of F subfamily genes(BpGSTF1 to BpGSTF13)during salt,mannitol and ABA stress,BpGSTF proteins seem to have multiple functions depending on the type of abiotic stress;for instance,BpGSTs may function at different times during abiotic stress.This study enhances understanding of the GST gene family and provides a basis for further exploration of their function in birch.展开更多
Glycosyltransferases(GTs)constitute a diverse family of synthetic polysaccharides with important roles in plant growth and development.This study characterized the GT14 family gene BpGT14;6 of birch(Betula platyphylla...Glycosyltransferases(GTs)constitute a diverse family of synthetic polysaccharides with important roles in plant growth and development.This study characterized the GT14 family gene BpGT14;6 of birch(Betula platyphylla Suk.).BpGT14;6 was highly expressed in the xylem and stem of birch plants.Subcellular localization analysis suggested that BpGT14;6 was located in the Golgi apparatus.RNA interference(RNAi)silencing of BpGT14;6 revealed lower lignin,hemicellulose,and pectin contents compared to wild type(WT)plants.Following treatment with abscisic acid(ABA),compared to WT plants,RNAi-BpGT14;6 plants were more sensitive to ABA,suffered more membrane lipid damage,and accumulated more reactive oxygen species.The inhibition of BpGT14;6 expression narrowed the birch xylem and thinned the cell wall,and increased the expression of multiple ABA pathway-related genes in birch under ABA treatment.Compared to WT plants,RNAi-BpGT14;6 plants showed increased tolerance to drought stress.Promoter analysis revealed that BpGT14;6 is involved in hormone regulation and adaptation to adversity.Using the 1156 bp BpGT14;6 promoter as bait,two potential transcription factors,BpWRKY1 and BpARF2,were identified through Y1H screening that may regulate its expression.EMSA confirmed that BpWRKY1 and BpARF2 can directly bind to the W-BOX and AuxRE cis-acting elements on the BpGT14;6 promoter,respectively.The collective results suggest that BpGT14;6 affects birch xylem and cell wall development by affecting lignin,hemicellulose,and pectin synthesis,and participates in birch adversity adaptation.展开更多
Cronobacter spp.has strong resistance to desiccation and high permeability in Enterobacteriaceae,and powdered infant formula(PIF)is one of the main contamination routes.In recent years,the contamination of Cronobacter...Cronobacter spp.has strong resistance to desiccation and high permeability in Enterobacteriaceae,and powdered infant formula(PIF)is one of the main contamination routes.In recent years,the contamination of Cronobacter spp.in PIF incidents occurs from time to time,causing infant serious diseases or death.In this investigation,matrix-assisted laser desorption/ionization time of flight mass spectrometry was used to identify the phenotypes of 35 Cronobacter strains isolated from PIF and its processing environment.Subsequently,the isolates were evaluated for drying and osmotic pressure tolerance.The results showed that the deactivation rate of the strains ranged from 9.01%to 77.57%,and the highest osmotic pressure condition the strains could tolerate was 6 g/100 mL Na Cl.In addition,there was a positive correlation between biofilm formation ability and desiccation resistance.Combined with transcriptomics,Cronobacter spp.could activate biofilm synthesis,produce more trehalose,accumulate betaine and electrolytes to stabilize intracellular structure under the two treatment conditions.A total of 31 and 43 genes were found related to desiccation and permeability resistance,respectively.And some genes(cysM,thuF,ycjO,etc.)were found to be associated with two tolerances for the first time.展开更多
Objective:To evaluate the predictive value of secreted phosphoprotein 1(SPP1)gene expression for postoperative survival in patients with advanced liver cancer undergoing hepatic artery interventional chemoembolization...Objective:To evaluate the predictive value of secreted phosphoprotein 1(SPP1)gene expression for postoperative survival in patients with advanced liver cancer undergoing hepatic artery interventional chemoembolization treatment.Method:Bioinformatics methods,including gene ontology(GO)and Kyoto Encyclopedia of Genes and Genomes(KEGG)pathway analysis,were used to identify genes related to survival prognosis in hepatocellular carcinoma(HCC)patients.A retrospective analysis of 115 advanced liver cancer patients treated between January 2016 and October 2017 was conducted.Patients were categorized into SPP1 high-expression(n=89)and low-expression groups(n=26).Additionally,115 healthy individuals served as the control group.The relationship between SPP1 expression and clinical pathological features was analyzed.A 60-month follow-up and logistic regression analysis identified risk factors affecting survival.Results:SPP1 mRNA expression was significantly higher in liver cancer patients compared to healthy controls(P<0.05).SPP1 expression levels were significantly associated with tumor size,Child-Pugh grading,lymph node metastasis,and BCLC staging(P<0.05).High SPP1 expression,along with tumor size,Child-Pugh grading,lymph node metastasis,and BCLC staging,were independent risk factors for survival(P<0.05).The 60-month survival rate was 17.39%,with a median survival of 40 months in the low-expression group versus 18 months in the high-expression group(P<0.05).Conclusion:SPP1 expression is significantly upregulated in advanced liver cancer patients and has predictive value for postoperative survival following hepatic artery chemoembolization treatment.SPP1,combined with clinical indicators such as tumor size,Child-Pugh grading,lymph node metastasis,and BCLC staging,may serve as a prognostic biomarker for interventional treatment outcomes.展开更多
Influences of temperature, humidity, and CO2 concentration on the photosynthesis and respiration of three-year-oldBetula platyphylla was investigated. Light compensation point, saturation point and CO2 compensation po...Influences of temperature, humidity, and CO2 concentration on the photosynthesis and respiration of three-year-oldBetula platyphylla was investigated. Light compensation point, saturation point and CO2 compensation point were also determined. The results showed that the optimal temperature of photosynthesis and dark respiration was 24 °C and 30 °C, respectively, at ambient CO2. When relative humidity was 80%,Betula platyphylla could maintain strong photosynthesis. There was no significant correlation between respiration and relative humidity. The light compensation and saturation point was 25 μmol·m?2·s?1 and 1 375 μmol·m?2·s?1, respectively. The CO2 compensation point was 180 μL·L?1. The results showed thatBetula platyphylla still had potential to assimilate CO2 when CO2 concentration was above 2 400 μL·L?1.展开更多
基金supported by the National Research Foundation of Korea(2020R1F1A1074155).
文摘Recently,Prevotella spp.,a major genus of gram-negative commensal bacteria in humans,have emerged as a key microbial contributor to host metabolism due to its ability to ferment dietary fibers,produce beneficial short-chain fatty acids,and influence immune responses.However,their diversity and functional differences have created challenges for their development and therapeutic use.Recent studies have shown that specific Prevotella species,such as P.copri,P.intestinalis,and P.histicola,can strengthen gut barrier integrity and reduce metabolic imbalances.Notably,Prevotella populations can be increased through high-fiber or herbal-based treatments.Traditional herbal medicines,including fiber-rich decoctions,also demonstrate the potential to boost endogenous Prevotella communities,enhance microbial fermentation,and improve glucose and lipid balance.This perspective examines the context-dependent roles of Prevotella spp.,with emphasis on the functional heterogeneity of key species such as P.copri,suggests a framework for combining herbal modulation with species-level microbiota profiling,and outlines a research plan to explore microbe-herb synergy in treating obesity,type 2 diabetes,and related metabolic disorders.This strategy offers a new,ecology-based approach to complement standard metabolic interventions.
文摘Climate change impacts soil nitrogen, influencing plant responses to elevated atmospheric [CO2]. Understanding the interaction between nitrogen supply and elevated [CO2] is crucial for predicting plant future performance. This study examined the interactive effects of elevated [CO2] and nitrogen supply on the eco-physiological performance of yellow birch. Seedlings were exposed to two [CO2] levels and five nitrogen supply levels for 4 months. Growth parameters such as seedling height and root collar diameter increased with higher nitrogen supply and elevated [CO2], while specific leaf area decreased. [CO2] elevation and increasing nitrogen supply also increased the total and stem, and leaf biomass. The elevated [CO2] increased the stem mass ratio but decreased the root-to-shoot ratio and root mass ratio. However, decreases in nitrogen supply increased root mass ratio and root-to-shoot ratio. The elevated [CO2] increased the maximum rate of Rubisco carboxylation (Vcmax) and photosynthetic electron transport (Jmax), but the effect on Jmax was statistically significant only at the two highest nitrogen supply levels. The results indicate that yellow birch may increase photosynthetic capacity, biomass, and growth in the future when [CO2] is higher.
基金supported by Academy of Finland(project 284931)the Finnish Cultural Foundation/Eva Barbara WilhelminaFoundation(Decision 27.2.2021).
文摘The acclimation capacity of Betula pendula and Betula pubescens was studied over 4 years in common gardens in central Italy(43°N)and southern(61°N)and northern Finland(67°N),representing drastically different photoperiod and climate in temperate,boreal and subarctic vegetation zones.Two study sites that differed in soil fertility were established at each location,giving a total of six common gardens.The birch material was micropropagated from naturally regenerated stands of B.pendula and B.pubescens from Susa Valley and Rochemolle Valley in northern Italy,Punkaharju in southern Finland and Kittilä in northern Finland.The plants were measured for height growth,stem diameter,leaf chlorophyll content,leaf herbivory and pathogen damage.The effects of soil fertility on the common garden results were also analyzed.The results showed high acclimation capacity of B.pendula and B.pubescens after a long-range transfer from southern to northern Europe,despite the major shift in climate and photoperiod.First-year growth on average was best in boreal southern Finland for all origins.Betula pendula grew more than B.pubescens in Italy and southern Finland,while B.pubescens grew more in northern Finland and better tolerated the northward transfer.The height growth of origins showed a clear latitude gradient from slowly growing northern to fast growing southern origins in the nursery and laboratory,but not in the field.Soil fertility explained a significant part of variation among locations not only for growth variables,but also for leaf chlorophyll content and leaf herbivory and pathogen damage.Leaf herbivore and pathogen damage was greatest in southern Finland.Our results demonstrate good survival of birch from northern Italy in Finnish conditions and support the possibility of long-range south-to-north transfer of Betula species to provide resistant planting material in boreal forests for the rapidly changing climate.
基金funded by the National Science Foundation for Young Scientists of China(No.32001327)the National Key Research and Development Program of China(No.2021YFD2200304-2).
文摘As global warming persistently alters and rapidly reshapes landscapes and habitats, conventional species distribution models relying solely on maintaining static conditions within the current climate are likely to falter, particularly at the genus level. Hence, we hypothesize that climate change will differentially affect ecological niches of the same genus species with various latitudinal positioning and local topography, and the high-latitude species may experience greater niche contraction than low-latitude species, and that mountainous regions with high elevational variability may serve as critical climate refugia. Herein, we simulate niche alterations and integrate an ensemble model(EM) strategy, taking into account species dispersal limitations factors(topography, soil, and ultraviolet), to construct a comprehensive habitat suitability(CHS) model for assessing the future vulnerability of the Betula genus, most of which are timber species in China. Our findings reveal that the niche spatial(geographic distribution) of most species(62%) within the Betula genus will undergo a gradual decline under climate change, supporting our hypothesis of latitudinal differentiation in climate vulnerability. Intriguingly, the projected high-latitude niche reduction within the genus cannot be counterbalanced by the anticipated niche expansion of closely related species in low-latitude regions, even considering the evident latitudinal gradient distribution of species. Nonetheless, the niche spatial of six Betula species in southwestern China remains stable or expands under warming scenarios, strongly supporting our secondary hypothesis about topographic buffering effects, which probably means the unique topography(i.e., the largest elevation difference) of this region may serve as a sanctuary for preserving Betula genetic diversity. Our results underscore the uncertain nature of pre-existing niche systems at the genus level under climate change, emphasizing the need for diligent resource management and conservation planning for vulnerable timber species.
基金supported by the National Key Research and Development Program of China(No.2021YFD2200304)FundamentalResearch Funds for the Central Universities(2572022DQ08)the National Natural Science Foundation of China(No32171738).
文摘Glutathione-S-transferase(GST,EC2.5.1.18)multifunctional protease is important for detoxification,defense against biotic and abiotic stresses,and secondary metabolic material transport for plant growth and development.In this study,71 members of the BpGST family were identified from the entire Betula platyphylla Suk.genome.Most of the members encode proteins with amino acid lengths ranging from 101 to 875 and were localized to the cytoplasm by a prediction.BpGSTs can be divided into seven subfamilies,with a majority of birch U and F subfamily members according to gene structure,conserved motifs and evolutionary analysis.GST family genes showed collinearity with 22 genes in Oryza sativa L.,and three genes in Arabidopsis thaliana;promoter cis-acting elements predicted that the GST gene family is functional in growth,hormone regulation,and abiotic stress response.Most members of the F subfamily of GST(BpGSTFs)were expressed in roots,stems,leaves,and petioles,with the most expression observed in leaves.On the basis of the expression profiles of F subfamily genes(BpGSTF1 to BpGSTF13)during salt,mannitol and ABA stress,BpGSTF proteins seem to have multiple functions depending on the type of abiotic stress;for instance,BpGSTs may function at different times during abiotic stress.This study enhances understanding of the GST gene family and provides a basis for further exploration of their function in birch.
基金financially supported by the National Natural Science Foundation of China(Grant Nos.31870588 and 31200463)The Innovation Project of State Key Laboratory of Tree Genetics and Breeding(Northeast Forestry University)(Grant No.2022A03)Heilongjiang Touyan Innovation Team Program.
文摘Glycosyltransferases(GTs)constitute a diverse family of synthetic polysaccharides with important roles in plant growth and development.This study characterized the GT14 family gene BpGT14;6 of birch(Betula platyphylla Suk.).BpGT14;6 was highly expressed in the xylem and stem of birch plants.Subcellular localization analysis suggested that BpGT14;6 was located in the Golgi apparatus.RNA interference(RNAi)silencing of BpGT14;6 revealed lower lignin,hemicellulose,and pectin contents compared to wild type(WT)plants.Following treatment with abscisic acid(ABA),compared to WT plants,RNAi-BpGT14;6 plants were more sensitive to ABA,suffered more membrane lipid damage,and accumulated more reactive oxygen species.The inhibition of BpGT14;6 expression narrowed the birch xylem and thinned the cell wall,and increased the expression of multiple ABA pathway-related genes in birch under ABA treatment.Compared to WT plants,RNAi-BpGT14;6 plants showed increased tolerance to drought stress.Promoter analysis revealed that BpGT14;6 is involved in hormone regulation and adaptation to adversity.Using the 1156 bp BpGT14;6 promoter as bait,two potential transcription factors,BpWRKY1 and BpARF2,were identified through Y1H screening that may regulate its expression.EMSA confirmed that BpWRKY1 and BpARF2 can directly bind to the W-BOX and AuxRE cis-acting elements on the BpGT14;6 promoter,respectively.The collective results suggest that BpGT14;6 affects birch xylem and cell wall development by affecting lignin,hemicellulose,and pectin synthesis,and participates in birch adversity adaptation.
基金supported by the Joint Funds of the National Natural Science Foundation of China(U21A20272)。
文摘Cronobacter spp.has strong resistance to desiccation and high permeability in Enterobacteriaceae,and powdered infant formula(PIF)is one of the main contamination routes.In recent years,the contamination of Cronobacter spp.in PIF incidents occurs from time to time,causing infant serious diseases or death.In this investigation,matrix-assisted laser desorption/ionization time of flight mass spectrometry was used to identify the phenotypes of 35 Cronobacter strains isolated from PIF and its processing environment.Subsequently,the isolates were evaluated for drying and osmotic pressure tolerance.The results showed that the deactivation rate of the strains ranged from 9.01%to 77.57%,and the highest osmotic pressure condition the strains could tolerate was 6 g/100 mL Na Cl.In addition,there was a positive correlation between biofilm formation ability and desiccation resistance.Combined with transcriptomics,Cronobacter spp.could activate biofilm synthesis,produce more trehalose,accumulate betaine and electrolytes to stabilize intracellular structure under the two treatment conditions.A total of 31 and 43 genes were found related to desiccation and permeability resistance,respectively.And some genes(cysM,thuF,ycjO,etc.)were found to be associated with two tolerances for the first time.
基金Medical Research Project of Xi’an Science and Technology Bureau“Molecular Mechanism of miR-1305 Competitive Endogenous circRNA in the Development of Liver Cancer”(Project No.22YXYJ0134)General Project of Key Research and Development Program of Shaanxi Provincial Department of Science and Technology“Mechanism Study on the Inhibition of Liver Cancer Invasion and Metastasis by Downregulating METTL3 and Reducing the m6A Modification Level of MMP3 with Honokiol”(Project No.2023-YBSF-631)。
文摘Objective:To evaluate the predictive value of secreted phosphoprotein 1(SPP1)gene expression for postoperative survival in patients with advanced liver cancer undergoing hepatic artery interventional chemoembolization treatment.Method:Bioinformatics methods,including gene ontology(GO)and Kyoto Encyclopedia of Genes and Genomes(KEGG)pathway analysis,were used to identify genes related to survival prognosis in hepatocellular carcinoma(HCC)patients.A retrospective analysis of 115 advanced liver cancer patients treated between January 2016 and October 2017 was conducted.Patients were categorized into SPP1 high-expression(n=89)and low-expression groups(n=26).Additionally,115 healthy individuals served as the control group.The relationship between SPP1 expression and clinical pathological features was analyzed.A 60-month follow-up and logistic regression analysis identified risk factors affecting survival.Results:SPP1 mRNA expression was significantly higher in liver cancer patients compared to healthy controls(P<0.05).SPP1 expression levels were significantly associated with tumor size,Child-Pugh grading,lymph node metastasis,and BCLC staging(P<0.05).High SPP1 expression,along with tumor size,Child-Pugh grading,lymph node metastasis,and BCLC staging,were independent risk factors for survival(P<0.05).The 60-month survival rate was 17.39%,with a median survival of 40 months in the low-expression group versus 18 months in the high-expression group(P<0.05).Conclusion:SPP1 expression is significantly upregulated in advanced liver cancer patients and has predictive value for postoperative survival following hepatic artery chemoembolization treatment.SPP1,combined with clinical indicators such as tumor size,Child-Pugh grading,lymph node metastasis,and BCLC staging,may serve as a prognostic biomarker for interventional treatment outcomes.
基金This paper was supported by the National Natural Science Foundation of China (No. 39970627) and the Key Project of State Department of Science Technology (2002BA515B05).
文摘Influences of temperature, humidity, and CO2 concentration on the photosynthesis and respiration of three-year-oldBetula platyphylla was investigated. Light compensation point, saturation point and CO2 compensation point were also determined. The results showed that the optimal temperature of photosynthesis and dark respiration was 24 °C and 30 °C, respectively, at ambient CO2. When relative humidity was 80%,Betula platyphylla could maintain strong photosynthesis. There was no significant correlation between respiration and relative humidity. The light compensation and saturation point was 25 μmol·m?2·s?1 and 1 375 μmol·m?2·s?1, respectively. The CO2 compensation point was 180 μL·L?1. The results showed thatBetula platyphylla still had potential to assimilate CO2 when CO2 concentration was above 2 400 μL·L?1.
