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
Microbial phosphorus(P)turnover is critical in C utilization efficiency in agroecosystems.It is therefore necessary to understand the P mobilization processes occurring during P fertilization in order to ensure both c...Microbial phosphorus(P)turnover is critical in C utilization efficiency in agroecosystems.It is therefore necessary to understand the P mobilization processes occurring during P fertilization in order to ensure both crop yield and environmental quality.Here,we established a controlled pot experiment containing soil amended with three different levels of starter P fertilizer and collected soil samples after 30,60,and 90 days of incubation.Quantitative microbial element cycling(QMEC)smart chip technology and 16S rRNA gene sequencing were used to investigate functional gene structures involved in carbon,nitrogen and P cycling and the bacterial community composition of the collected samples.Although P fertilization did not significantly affect the structure of the soil microbial community,some rare microbiota were changed in particular phosphorus-solubilizing bacteria were enriched at the high P fertilization level,suggesting that the rare taxa make an important contribution to P turnover.P fertilization also altered the functional gene structure,and high P concentrations enhanced the functional gene diversity and abundance.Partial redundancy analysis further revealed that changes in rare taxa and functional genes of soil microorganisms drive the alteration of soil P pools.These findings extend our understanding of the microbial mechanisms of P turnover.展开更多
Unintentional food resources in urban areas(street litter,food leftovers,overflowing trash bins)are dietary components of some urban-exploiter bird species.In this study,we report on 13 bird species in six southern Fi...Unintentional food resources in urban areas(street litter,food leftovers,overflowing trash bins)are dietary components of some urban-exploiter bird species.In this study,we report on 13 bird species in six southern Finnish cities using urban trash bins and describe differences in their activity when provided with food resources(i.e.,bait)in different bin types.We used generalized linear models(GLM)and classification and regression trees(CART)to test for associations between environmental variables and bird activity at the binscapes.Bird activity at the binscapes significantly differed among all cities and among types of bins and was significantly higher after placing bait in all cases.Bins with the largest opening had more activity as opposed to those with smaller openings or lids.Corvids and gulls had the highest activity,with corvids usually being present before the bait was placed and gulls increasing their activity thereafter.These differences show that trash bin foraging is highly malleable and thus susceptible to management preventing its occurrence.Suitable waste management measures could aid in reducing the number of species close to bins and their surroundings,benefiting both bird and human health.展开更多
A complete ecosystem is also a complex network in which multifarious species interact with each other to achieve system-level functions, such as nutrient biogeochemistry (1)Microbial community is commonly considered a...A complete ecosystem is also a complex network in which multifarious species interact with each other to achieve system-level functions, such as nutrient biogeochemistry (1)Microbial community is commonly considered as the primary driving force of ecosystem nutrient mobilization and metabolism, especially carbon (C), nitrogen (N), phosphorus (P), sulfur (S) and methane coupling process (2)The rise of metagenomics and high-throughput array (e.g. PhyloChip, GeoChip, etc.展开更多
Soil bacterial and fungal communities play fundamental roles in biogeochemical cycles and ecosystem stability.Urbanization alters soil properties and microbial habitats,driving shifts in community composition,yet the ...Soil bacterial and fungal communities play fundamental roles in biogeochemical cycles and ecosystem stability.Urbanization alters soil properties and microbial habitats,driving shifts in community composition,yet the divergent responses of bacteria and fungi and their ecological consequences remain inadequately understood.To elucidate these differential responses,we investigated soil bacterial and fungal communities along an urbanization gradient,ranging from undisturbed reference forests to urban parks,across three distinct climatic regions.To capture different disturbance intensities,urban parks were classified by tree age into old parks(>60-year-old trees)and young parks(10-20-year-old trees).Climate had a strong influence on soil microbiota,yet urbanization still significantly altered both bacterial and fungal communities in all regions.Urban disturbances homogenized soil microbial communities:average similarity among bacterial communities increased from~79%in forests to~85%in young urban parks,indicating substantial homogenization,whereas fungal communities showed little homogenization.Urbanization also homogenized microbial functional traits,with a greater reduction in trait dissimilarity for bacteria than for fungi.Bacterial communities exhibited high adjustability to urban conditions,dominated by generalist taxa(~90%),whereas fungal communities consisted mostly of specialists(~83%).Despite these asynchronous responsesdbacteria adjusting and homogenizing more than fungidoverlapping functional traits between bacteria and fungi help maintain functional resilience in urban ecosystems.展开更多
Neighborhood gardens serve as sensitive sites for human microbial encounters,with phyllosphere microbes directly impacting our respiratory health.Yet,our understanding remains limited on how factors like season,garden...Neighborhood gardens serve as sensitive sites for human microbial encounters,with phyllosphere microbes directly impacting our respiratory health.Yet,our understanding remains limited on how factors like season,garden age,and land use shape the risk of respiratory diseases(RDs)tied to these garden microbes.Here we examined the microbial communities within the phyllosphere of 72 neighborhood gardens across Shanghai,spanning different seasons(warm and cold),garden ages(old and young),and locales(urban and rural).We found a reduced microbial diversity during the cold season,except for Gammaproteobacteria which exhibited an inverse trend.While land use influenced the microbial composition,urban and rural gardens had strikingly similar microbial profiles.Alarmingly,young gardens in the cold season hosted a substantial proportion of RDs-associated species,pointing towards increased respiratory inflammation risks.In essence,while newer gardens during colder periods show a decline in microbial diversity,they have an increased presence of RDs-associated microbes,potentially escalating respiratory disease prevalence.This underscores the pivotal role the garden age plays in enhancing both urban microbial diversity and respiratory health.展开更多
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This work was supported by the National Key Research and Development Program of China(No.2017YFD0200201)the Natural Science Foundation of China(No.21922608)the Strategic Priority Research Program of the Chinese Academy of Sciences(No.XDB15020402).
文摘Microbial phosphorus(P)turnover is critical in C utilization efficiency in agroecosystems.It is therefore necessary to understand the P mobilization processes occurring during P fertilization in order to ensure both crop yield and environmental quality.Here,we established a controlled pot experiment containing soil amended with three different levels of starter P fertilizer and collected soil samples after 30,60,and 90 days of incubation.Quantitative microbial element cycling(QMEC)smart chip technology and 16S rRNA gene sequencing were used to investigate functional gene structures involved in carbon,nitrogen and P cycling and the bacterial community composition of the collected samples.Although P fertilization did not significantly affect the structure of the soil microbial community,some rare microbiota were changed in particular phosphorus-solubilizing bacteria were enriched at the high P fertilization level,suggesting that the rare taxa make an important contribution to P turnover.P fertilization also altered the functional gene structure,and high P concentrations enhanced the functional gene diversity and abundance.Partial redundancy analysis further revealed that changes in rare taxa and functional genes of soil microorganisms drive the alteration of soil P pools.These findings extend our understanding of the microbial mechanisms of P turnover.
基金supported by funds from the Otto A.Malm Foundation(to MG-A)the University of Helsinki Lahti fund(to MG-A)。
文摘Unintentional food resources in urban areas(street litter,food leftovers,overflowing trash bins)are dietary components of some urban-exploiter bird species.In this study,we report on 13 bird species in six southern Finnish cities using urban trash bins and describe differences in their activity when provided with food resources(i.e.,bait)in different bin types.We used generalized linear models(GLM)and classification and regression trees(CART)to test for associations between environmental variables and bird activity at the binscapes.Bird activity at the binscapes significantly differed among all cities and among types of bins and was significantly higher after placing bait in all cases.Bins with the largest opening had more activity as opposed to those with smaller openings or lids.Corvids and gulls had the highest activity,with corvids usually being present before the bait was placed and gulls increasing their activity thereafter.These differences show that trash bin foraging is highly malleable and thus susceptible to management preventing its occurrence.Suitable waste management measures could aid in reducing the number of species close to bins and their surroundings,benefiting both bird and human health.
基金supported by the National Natural Science Foundation of China (41701299)support from the Academy of Finland funding PARKTRAITS project (WBS 1315987)
文摘A complete ecosystem is also a complex network in which multifarious species interact with each other to achieve system-level functions, such as nutrient biogeochemistry (1)Microbial community is commonly considered as the primary driving force of ecosystem nutrient mobilization and metabolism, especially carbon (C), nitrogen (N), phosphorus (P), sulfur (S) and methane coupling process (2)The rise of metagenomics and high-throughput array (e.g. PhyloChip, GeoChip, etc.
基金financially supported by the National Key R&D Program of China(no.2023YFE0112000)the National Science Foundation of China(no.32371843)which were originated from the PARKTRAITS project(Academy of Finland,no.1315987).
文摘Soil bacterial and fungal communities play fundamental roles in biogeochemical cycles and ecosystem stability.Urbanization alters soil properties and microbial habitats,driving shifts in community composition,yet the divergent responses of bacteria and fungi and their ecological consequences remain inadequately understood.To elucidate these differential responses,we investigated soil bacterial and fungal communities along an urbanization gradient,ranging from undisturbed reference forests to urban parks,across three distinct climatic regions.To capture different disturbance intensities,urban parks were classified by tree age into old parks(>60-year-old trees)and young parks(10-20-year-old trees).Climate had a strong influence on soil microbiota,yet urbanization still significantly altered both bacterial and fungal communities in all regions.Urban disturbances homogenized soil microbial communities:average similarity among bacterial communities increased from~79%in forests to~85%in young urban parks,indicating substantial homogenization,whereas fungal communities showed little homogenization.Urbanization also homogenized microbial functional traits,with a greater reduction in trait dissimilarity for bacteria than for fungi.Bacterial communities exhibited high adjustability to urban conditions,dominated by generalist taxa(~90%),whereas fungal communities consisted mostly of specialists(~83%).Despite these asynchronous responsesdbacteria adjusting and homogenizing more than fungidoverlapping functional traits between bacteria and fungi help maintain functional resilience in urban ecosystems.
基金supported by the Natural Science Foundation of China(Project number:32371843)the Science and Technology Commission of Shanghai Municipality(Project number:22230713300).
文摘Neighborhood gardens serve as sensitive sites for human microbial encounters,with phyllosphere microbes directly impacting our respiratory health.Yet,our understanding remains limited on how factors like season,garden age,and land use shape the risk of respiratory diseases(RDs)tied to these garden microbes.Here we examined the microbial communities within the phyllosphere of 72 neighborhood gardens across Shanghai,spanning different seasons(warm and cold),garden ages(old and young),and locales(urban and rural).We found a reduced microbial diversity during the cold season,except for Gammaproteobacteria which exhibited an inverse trend.While land use influenced the microbial composition,urban and rural gardens had strikingly similar microbial profiles.Alarmingly,young gardens in the cold season hosted a substantial proportion of RDs-associated species,pointing towards increased respiratory inflammation risks.In essence,while newer gardens during colder periods show a decline in microbial diversity,they have an increased presence of RDs-associated microbes,potentially escalating respiratory disease prevalence.This underscores the pivotal role the garden age plays in enhancing both urban microbial diversity and respiratory health.
