The US National Park System is significantly different-in scope, number of units, size and complexitythan in the 1960s when the Leopold Report. Scientific understanding of natural and cultural resources has expanded dramatically. Developments since the 1960s include increasing biodiversity loss, habitat fragmentation, land use change, groundwater depletion, invasive species, rapid and sometimes unplanned development, growing air, noise, and light pollution and the impacts of climate change. The cultural values and interests held by the American people have also broadened, generating pressing demands for parks to reflect diversity and relevance for new generations. Fifty years on, the National Parks Service and its National Park System Advisory Board have revisited the Leopold Report. The new report, Revisiting Leopold, published here, focuses on the natural and cultural resource management of the National Park System and answers three questions: 1) What should be the goals of resource management in the National Park System?; 2) What policies for resource management are necessary to achieve these goals?; 3) What actions are required to implement these policies?
Background : Celiac disease (CD) is an autoimmune digestive disorder that occurs in genetically susceptible individuals in response to ingesting gluten, a protein found in wheat, rye, and barley. Research shows that genetic predisposition and exposure to gluten are necessary but not sufficient to trigger the development of CD. This suggests that exposure to other environmental stimuli early in life, e.g., cesarean section delivery, exposure to antibiotics or formula feeding, may also play a key role in CD pathogenesis through yet unknown mechanisms. Here, we use multi-omics analysis to investigate how genetic and early environmental risk factors alter the development of the gut microbiota in infants at risk of CD. Results : Toward this end, we took advantage of a large-scale prospective birth cohort study of infants with a first-degree relative with CD. We then performed rigorous multivariate association, cross-sectional and longitudinal analyses using metagenomic and metabolomic data collected at birth, three months and six months of age to explore the impact of genetic predisposition and environmental risk factors on the gut microbiota composition, function and metabolome prior to the introduction of trigger (gluten). These analyses revealed several microbial species, functional pathways and metabolites that are associated with each genetic and environmental risk factor or that are differentially abundant between environmentally exposed and non-exposed infants or between time points. Among our significant findings, we found that cesarean section delivery is associated with a decreased abundance of Bacteroides vulgatus and Bacteroides dorei and of folate biosynthesis pathway, and with an increased abundance of hydroxyphenylacetic acid, alterations that are implicated in immune system dysfunction and inflammatory conditions. Additionally, longitudinal analysis revealed that, in infants not exposed to any environmental risk factor, the abundances of Bacteroides uniforms and of metabolite 3-3-hydroxyphenylproprionic acid increase over time, while those for lipoic acid and methane metabolism pathways decrease, patterns that are linked to beneficial immunomodulatory and anti-inflammatory effects. Conclusions : Overall, our study provides unprecedented insights into major taxonomic and functional shifts in the developing gut microbiota of infants at risk of CD ultimately linking genetic and environmental risk factors to detrimental immunomodulatory and inflammatory effects. Keywords: Microbiota; Celiac disease; Multi-omics analysis, gut microbiome
Background: Celiac disease (CD) is an autoimmune digestive disorder that occurs in genetically susceptible individuals in response to ingesting gluten, a protein found in wheat, rye, and barley. Research shows that genetic predisposition and exposure to gluten are necessary but not sufficient to trigger the development of CD. This suggests that exposure to other environmental stimuli early in life, e.g., cesarean section delivery, exposure to antibiotics or formula feeding, may also play a key role in CD pathogenesis through yet unknown mechanisms. Here, we use multi-omics analysis to investigate how genetic and early environmental risk factors alter the development of the gut microbiota in infants at risk of CD. Results: Toward this end, we selected 31 infants from a large-scale prospective birth cohort study of infants with a first-degree relative with CD. We then performed rigorous multivariate association, cross-sectional and longitudinal analyses using metagenomic and metabolomic data collected at birth, three months and six months of age to explore the impact of genetic predisposition and environmental risk factors on the gut microbiota composition, function and metabolome prior to the introduction of trigger (gluten). These analyses revealed several microbial species, functional pathways and metabolites that are associated with each genetic and environmental risk factor or that are differentially abundant between environmentally exposed and non-exposed infants or between time points. Among our significant findings, we found that cesarean section delivery is associated with a decreased abundance of Bacteroides vulgatus and Bacteroides dorei and of folate biosynthesis pathway, and with an increased abundance of hydroxyphenylacetic acid, alterations that are implicated in immune system dysfunction and inflammatory conditions. Additionally, longitudinal analysis revealed that, in infants not exposed to any environmental risk factor, the abundances of Bacteroides uniformis and of metabolite 3-3-hydroxyphenylproprionic acid increase over time while those for lipoic acid and methane metabolism pathways decrease, patterns that are linked to beneficial immunomodulatory and anti-inflammatory effects. Conclusions: Overall, our study provides unprecedented insights into major taxonomic and functional shifts in the developing gut microbiota of infants at risk of CD linking genetic and environmental risk factors to detrimental immunomodulatory and inflammatory effects.
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