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PubMed Publications| Keyword search (4,163 papers available) |  |
"Walsh DA" Authored Publications:
| Title | Authors | PubMed ID | |
|---|---|---|---|
| 1 | Eutrophication and Warming Drive Algal Community Shifts in Synchronised Time Series of Experimental Lakes | Garner RE; Taranu ZE; Higgins SN; Paterson MJ; Gregory-Eaves I; Walsh DA; | 40704779 BIOLOGY |
| 2 | Water Quality and Land Use Shape Bacterial Communities Across 621 Canadian Lakes | Onana VE; Beisner BE; Walsh DA; | 39868666 BIOLOGY |
| 3 | Vulnerability of Arctic Ocean microbial eukaryotes to sea ice loss | Jackson VLN; Grevesse T; Kilias ES; Onda DFL; Young KF; Allen MJ; Walsh DA; Lovejoy C; Monier A; | 39572565 BIOLOGY |
| 4 | A genome catalogue of mercury-methylating bacteria and archaea from sediments of a boreal river facing human disturbances | Lawruk-Desjardins C; Storck V; Ponton DE; Amyot M; Walsh DA; | 38922750 BIOLOGY |
| 5 | 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 |
| 6 | Publisher Correction: A genome catalogue of lake bacterial diversity and its drivers at continental scale | Garner RE; Kraemer SA; Onana VE; Fradette M; Varin MP; Huot Y; Walsh DA; | 37821571 BIOLOGY |
| 7 | A genome catalogue of lake bacterial diversity and its drivers at continental scale | Garner RE; Kraemer SA; Onana VE; Fradette M; Varin MP; Huot Y; Walsh DA; | 37524802 BIOLOGY |
| 8 | Geospatial analysis reveals a hotspot of fecal bacteria in Canadian prairie lakes linked to agricultural non-point sources | Oliva A; Onana VE; Garner RE; Kraemer SA; Fradette M; Walsh DA; Huot Y; | 36653256 BIOLOGY |
| 9 | Degradation pathways for organic matter of terrestrial origin are widespread and expressed in Arctic Ocean microbiomes | Grevesse T; Guéguen C; Onana VE; Walsh DA; | 36566218 BIOLOGY |
| 10 | A resistome survey across hundreds of freshwater bacterial communities reveals the impacts of veterinary and human antibiotics use | Kraemer SA; Barbosa da Costa N; Oliva A; Huot Y; Walsh DA; | 36338036 BIOLOGY |
| 11 | Comparing microscopy and DNA metabarcoding techniques for identifying cyanobacteria assemblages across hundreds of lakes | MacKeigan PW; Garner RE; Monchamp MÈ; Walsh DA; Onana VE; Kraemer SA; Pick FR; Beisner BE; Agbeti MD; da Costa NB; Shapiro BJ; Gregory-Eaves I; | 35287928 BIOLOGY |
| 12 | Rethinking microbial infallibility in the metagenomics era | O' Malley MA; Walsh DA; | 34160589 BIOLOGY |
| 13 | A Novel Freshwater to Marine Evolutionary Transition Revealed within Methylophilaceae Bacteria from the Arctic Ocean | Ramachandran A; McLatchie S; Walsh DA; | 34154421 BIOLOGY |
| 14 | Role of organic matter and microbial communities in mercury retention and methylation in sediments near run-of-river hydroelectric dams. | Millera Ferriz L, Ponton DE, Storck V, Leclerc M, Bilodeau F, Walsh DA, Amyot M | 33609815 BIOLOGY |
| 15 | Sediment Metagenomes as Time Capsules of Lake Microbiomes. | Garner RE; Gregory-Eaves I; Walsh DA; | 33148818 BIOLOGY |
| 16 | A large-scale assessment of lakes reveals a pervasive signal of land use on bacterial communities. | Kraemer SA, Barbosa da Costa N, Shapiro BJ, Fradette M, Huot Y, Walsh DA | 32770118 BIOLOGY |
| 17 | Modelling Free-Living and Particle-Associated Bacterial Assemblages across the Deep and Hypoxic Lower St. Lawrence Estuary. | Cui TT, Dawson TJ, McLatchie S, Dunn K, Bielawski J, Walsh DA | 32434843 BIOLOGY |
| 18 | Diversity and biogeography of SAR11 bacteria from the Arctic Ocean. | Kraemer S, Ramachandran A, Colatriano D, Lovejoy C, Walsh DA | 31501503 BIOLOGY |
| 19 | 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 |
| 20 | Genomic evidence for the degradation of terrestrial organic matter by pelagic Arctic Ocean Chloroflexi bacteria. | Colatriano D, Tran PQ, Guéguen C, Williams WJ, Lovejoy C, Walsh DA | 30271971 BIOLOGY |
| 21 | BioMiCo: a supervised Bayesian model for inference of microbial community structure. | Shafiei M, Dunn KA, Boon E, MacDonald SM, Walsh DA, Gu H, Bielawski JP | 25774293 BIOLOGY |
| 22 | A compendium of multi-omic sequence information from the Saanich Inlet water column. | Hawley AK, Torres-Beltrán M, Zaikova E, Walsh DA, Mueller A, Scofield M, Kheirandish S, Payne C, Pakhomova L, Bhatia M, Shevchuk O, Gies EA, Fairley D, Malfatti SA, Norbeck AD, Brewer HM, Pasa-Tolic L, Del Rio TG, Suttle CA, Tringe S, Hallam SJ | 29087368 BIOLOGY |
| 23 | A compendium of geochemical information from the Saanich Inlet water column. | Torres-Beltrán M, Hawley AK, Capelle D, Zaikova E, Walsh DA, Mueller A, Scofield M, Payne C, Pakhomova L, Kheirandish S, Finke J, Bhatia M, Shevchuk O, Gies EA, Fairley D, Michiels C, Suttle CA, Whitney F, Crowe SA, Tortell PD, Hallam SJ | 29087371 BIOLOGY |
| 24 | Microbial life under ice: Metagenome diversity and in situ activity of Verrucomicrobia in seasonally ice-covered Lakes. | Tran P, Ramachandran A, Khawasik O, Beisner BE, Rautio M, Huot Y, Walsh DA | 29921005 BIOLOGY |
| 25 | Progress and Challenges in Ocean Metaproteomics and Proposed Best Practices for Data Sharing. | Saito MA, Bertrand EM, Duffy ME, Gaylord DA, Held NA, Hervey WJ, Hettich RL, Jagtap PD, Janech MG, Kinkade DB, Leary DH, McIlvin MR, Moore EK, Morris RM, Neely BA, Nunn BL, Saunders JK, Shepherd AI, Symmonds NI, Walsh DA | 30702898 BIOLOGY |
| 26 | Annual nitrification dynamics in a seasonally ice-covered lake. | Massé S, Botrel M, Walsh DA, Maranger R | 30893339 BIOLOGY |
| 27 | Author Correction: A compendium of geochemical information from the Saanich Inlet water column. | Torres-Beltrán M, Hawley AK, Capelle D, Zaikova E, Walsh DA, Mueller A, Scofield M, Payne C, Pakhomova L, Kheirandish S, Finke J, Bhatia M, Shevchuk O, Gies EA, Fairley D, Michiels C, Suttle CA, Whitney F, Crowe SA, Tortell PD, Hallam SJ | 30647409 BIOLOGY |
| Title: | Comparing microscopy and DNA metabarcoding techniques for identifying cyanobacteria assemblages across hundreds of lakes | ||||
| Authors: | MacKeigan PW, Garner RE, Monchamp MÈ, Walsh DA, Onana VE, Kraemer SA, Pick FR, Beisner BE, Agbeti MD, da Costa NB, Shapiro BJ, Gregory-Eaves I | ||||
| Link: | https://pubmed.ncbi.nlm.nih.gov/35287928/ | ||||
| DOI: | 10.1016/j.hal.2022.102187 | ||||
| Publication: | Harmful algae | ||||
| Keywords: | 16s rRNA gene metabarcoding; Cyanobacteria; Freshwater lakes; Microcystis genotypes; Microscopy; Trophic status; eDNA; | ||||
| PMID: | 35287928 | Category: | Date Added: | 2022-03-15 | |
| Dept Affiliation: |
BIOLOGY
1 Department of Biology, McGill University, Montreal, Quebec, Canada; Interuniversity Research Group in Limnology (GRIL), Quebec, Canada. Electronic address: paul.mackeigan@mail.mcgill.ca. 2 Interuniversity Research Group in Limnology (GRIL), Quebec, Canada; Department of Biology, Concordia University, Montreal, Quebec, Canada. 3 Department of Biology, McGill University, Montreal, Quebec, Canada; Interuniversity Research Group in Limnology (GRIL), Quebec, Canada. 4 Department of Biology, University of Ottawa, Ottawa, Ontario, Canada. 5 Interuniversity Research Group in Limnology (GRIL), Quebec, Canada; Department of Biological Sciences, University of Quebec at Montreal, Montreal, Quebec, Canada. 6 Bio-Limno Research & Consulting, Halifax, Nova Scotia, Canada. 7 Interuniversity Research Group in Limnology (GRIL), Quebec, Canada; Department of Biological Sciences, University of |
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Description: |
Accurately identifying the species present in an ecosystem is vital to lake managers and successful bioassessment programs. This is particularly important when monitoring cyanobacteria, as numerous taxa produce toxins and can have major negative impacts on aquatic ecosystems. Increasingly, DNA-based techniques such as metabarcoding are being used for measuring aquatic biodiversity, as they could accelerate processing time, decrease costs and reduce some of the biases associated with traditional light microscopy. Despite the continuing use of traditional microscopy and the growing use of DNA metabarcoding to identify cyanobacteria assemblages, methodological comparisons between the two approaches have rarely been reported from a wide suite of lake types. Here, we compare planktonic cyanobacteria assemblages generated by inverted light microscopy and DNA metabarcoding from a 379-lake dataset spanning a longitudinal and trophic gradient. We found moderate levels of congruence between methods at the broadest taxonomic levels (i.e., Order, RV=0.40, p < 0.0001). This comparison revealed distinct cyanobacteria communities from lakes of different trophic states, with Microcystis, Aphanizomenon and Dolichospermum dominating with both methods in eutrophic and hypereutrophic sites. This finding supports the use of either method when monitoring eutrophication in lake surface waters. The biggest difference between the two methods was the detection of picocyanobacteria, which are typically underestimated by light microscopy. This reveals that the communities generated by each method currently are complementary as opposed to identical and promotes a combined-method strategy when monitoring a range of trophic systems. For example, microscopy can provide measures of cyanobacteria biomass, which are critical data in managing lakes. Going forward, we believe that molecular genetic methods will be increasingly adopted as reference databases are routinely updated with more representative sequences and will improve as cyanobacteria taxonomy is resolved with the increase in available genetic information. |
