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PubMed Publications| Keyword search (4,163 papers available) |  |
"climate change" Keyword-tagged Publications:
| Title | Authors | PubMed ID | |
|---|---|---|---|
| 1 | Assessing Port-related Greenhouse Gas Emissions and Mitigation Pathways Through a Comprehensive Framework Applied to the Vancouver Fraser Port Authority | Wang Z; Su Y; Lu Z; An C; | 41925888 ENCS |
| 2 | Creeping snow drought threatens Canada s water supply | Sarpong R; Nazemi A; AghaKouchak A; | 41675434 ENCS |
| 3 | From pollution barriers to health buffers: Rethinking building airtightness under climate variability | Fu N; Zhang R; Haghighat F; Kumar P; Cao SJ; | 41252997 ENCS |
| 4 | The temperate forest phyllosphere and rhizosphere microbiome: a case study of sugar maple | Enea M; Beauregard J; De Bellis T; Faticov M; Laforest-Lapointe I; | 39881993 BIOLOGY |
| 5 | Testing the predictions of reinforcement: long-term empirical data from a damselfly mottled hybrid zone | Arce-Valdés LR; Ballén-Guapacha AV; Rivas-Torres A; Chávez-Ríos JR; Wellenreuther M; Hansson B; Guillén RAS; | 39325673 BIOLOGY |
| 6 | Navigating the nexus: climate dynamics and microplastics pollution in coastal ecosystems | Ahmed Dar A; Chen Z; Sardar MF; An C; | 38642636 ENCS |
| 7 | Assessing greenhouse gas emissions in Cuban agricultural soils: Implications for climate change and rice (Oryza sativa L.) production | Dar AA; Chen Z; Rodríguez-Rodríguez S; Haghighat F; González-Rosales B; | 38295640 ENCS |
| 8 | A multiyear time series (2004-2012) of bacterial and archaeal community dynamics in a changing Arctic Ocean | Kraemer SA; Ramachandran A; Onana VE; Li WKW; Walsh DA; | 38282643 BIOLOGY |
| 9 | Microgeographic variation in demography and thermal regimes stabilize regional abundance of a widespread freshwater fish | Gallagher BK; Fraser DJ; | 38071739 BIOLOGY |
| 10 | Identifying climate change refugia for South American biodiversity | Sales LP; Pires MM; | 36919472 BIOLOGY |
| 11 | Moderate support for the use of digital tracking to support climate-mitigation strategies | Garard J; Wood SLR; Sabet-Kassouf N; Ventimiglia A; Matthews HD; Ubalijoro É; Chaudhari K; Ivanova M; Luers AL; | 36128017 ENCS |
| 12 | Can Science-Based Targets Make the Private Sector Paris-Aligned? A Review of the Emerging Evidence | Bjørn A; Tilsted JP; Addas A; Lloyd SM; | 35854785 JMSB |
| 13 | COVID-19 Disruption Demonstrates Win-Win Climate Solutions for Major League Sports | Seth Wynes | 34779201 CONCORDIA |
| 14 | Assessing the regional biogenic methanol emission from spring wheat during the growing season: A Canadian case study | Cai M; An C; Guy C; Lu C; Mafakheri F; | 34182392 ENCS |
| 15 | A Novel Freshwater to Marine Evolutionary Transition Revealed within Methylophilaceae Bacteria from the Arctic Ocean | Ramachandran A; McLatchie S; Walsh DA; | 34154421 BIOLOGY |
| 16 | Monitoring the evolution of individuals' flood-related adaptive behaviors over time: two cross-sectional surveys conducted in the Province of Quebec, Canada. | Valois P; Tessier M; Bouchard D; Talbot D; Morin AJS; Anctil F; Cloutier G; | 33143677 PSYCHOLOGY |
| 17 | Late-spring frost risk between 1959 and 2017 decreased in North America but increased in Europe and Asia. | Zohner CM, Mo L, Renner SS, Svenning JC, Vitasse Y, Benito BM, Ordonez A, Baumgarten F, Bastin JF, Sebald V, Reich PB, Liang J, Nabuurs GJ, de-Miguel S, Alberti G, Antón-Fernández C, Balazy R, Brändli UB, Chen HYH, Chisholm C, Cienciala E, Dayanandan S, Fayle TM, Frizzera L, Gianelle D, Jagodzinski AM, Jaroszewicz B, Jucker T, Kepfer-Rojas S, Khan ML, Kim HS, Korjus H, Johannsen VK, Laarmann D, Lang M, Zawila-Niedzwiecki T, Niklaus PA, Paquette A, Pretzsch H, Saikia P, Schall P, Šeben V, Svoboda M, Tikhonova E, Viana H, Zhang C, Zhao X, Crowther TW | 32393624 BIOLOGY |
| 18 | Assessment of regional greenhouse gas emission from beef cattle production: A case study of Saskatchewan in Canada. | Chen Z, An C, Fang H, Zhang Y, Zhou Z, Zhou Y, Zhao S | 32217321 ENCS |
| 19 | How does synchrony with host plant affect the performance of an outbreaking insect defoliator? | Fuentealba A, Pureswaran D, Bauce É, Despland E | 28756489 BIOLOGY |
| 20 | The NSERC Canadian Lake Pulse Network: A national assessment of lake health providing science for water management in a changing climate. | Huot Y, Brown CA, Potvin G, Antoniades D, Baulch HM, Beisner BE, Bélanger S, Brazeau S, Cabana H, Cardille JA, Del Giorgio PA, Gregory-Eaves I, Fortin MJ, Lang AS, Laurion I, Maranger R, Prairie YT, Rusak JA, Segura PA, Siron R, Smol JP, Vinebrooke RD, Walsh DA | 31419692 BIOLOGY |
| Title: | A Novel Freshwater to Marine Evolutionary Transition Revealed within Methylophilaceae Bacteria from the Arctic Ocean | ||||
| Authors: | Ramachandran A, McLatchie S, Walsh DA | ||||
| Link: | https://pubmed.ncbi.nlm.nih.gov/34154421/ | ||||
| DOI: | 10.1128/mBio.01306-21 | ||||
| Publication: | mBio | ||||
| Keywords: | climate change; genome evolution; marine microbiology; metagenomics; methanol; | ||||
| PMID: | 34154421 | Category: | Date Added: | 2021-06-22 | |
| Dept Affiliation: |
BIOLOGY
1 Department of Biology, Concordia University, Montreal, Quebec, Canada. |
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Description: |
Bacteria inhabiting polar oceans, particularly the Arctic Ocean, are less studied than those at lower latitudes. Discovering bacterial adaptations to Arctic Ocean conditions is essential for understanding responses to the accelerated environmental changes occurring in the North. The Methylophilaceae are emerging as a model for investigating the genomic basis of habitat adaptation, because related lineages are widely distributed across both freshwater and marine ecosystems. Here, we investigated Methylophilaceae diversity in the salinity-stratified surface waters of the Canada Basin, Arctic Ocean. In addition to a diversity of marine OM43 lineages, we report on the genomic characteristics and evolution of a previously undescribed Methylophilaceae clade (BS01) common to polar surface waters yet related to freshwater sediment Methylotenera species. BS01 is restricted to the lower-salinity surface waters, while OM43 is found throughout the halocline. An acidic proteome supports a marine lifestyle for BS01, but gene content shows increased metabolic versatility compared to OM43 and evidence for ongoing genome-streamlining. Phylogenetic reconstruction shows that BS01 colonized the pelagic ocean independently of OM43 via convergent evolution. Salinity adaptation and differences in one-carbon and nitrogen metabolism may play a role in niche differentiation between BS01 and OM43. In particular, urea utilization by BS01 is predicted to provide an ecological advantage over OM43 given the limited amount of inorganic nitrogen in the Canada Basin. These observations provide further evidence that the Arctic Ocean is inhabited by distinct bacterial groups and that at least one group (BS01) evolved via a freshwater to marine environmental transition. IMPORTANCE Global warming is profoundly influencing the Arctic Ocean. Rapid ice melt and increased freshwater input is increasing ocean stratification, driving shifts in nutrient availability and the primary production that supports marine food webs. Determining bacterial responses to Arctic Ocean change is challenging because of limited knowledge on the specific adaptations of Arctic Ocean bacteria. In this study, we investigated the diversity and genomic adaptations of a globally distributed group of marine bacteria, the Methylophilaceae, in the surface waters of the Arctic Ocean. We discovered a novel lineage of marine Methylophilaceae inhabiting the Arctic Ocean whose evolutionary origin involved a freshwater to marine environmental transition. Crossing the salinity barrier is thought to rarely occur in bacterial evolution. However, given the ongoing freshening of the Arctic Ocean, our results suggest that these relative newcomers to the ocean microbiome increase in abundance and, therefore, ecological significance in a near-future Arctic Ocean. |
