Tropicalization of temperate ecosystems in North America: The northward range expansion of tropical organisms in response to warming winter temperatures

Osland, Michael J.; Stevens, Philip W.; Lamont, Margaret M.; Brusca, Richard C.; Hart, Kristen M.; Waddle, J. Hardin; Langtimm, Catherine A.; Williams, Carroll M.; Keim, Barry D.; Terando, Adam; Reyier, Eric A.; Marshall, Katie E.; Loik, Michael E.; Boucek, Ross E.; Lewis, Amanda B.; Seminoff, Jeffrey A.

doi:10.1111/gcb.15563

Cited by 150 publications

(91 citation statements)

References 276 publications

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“…Among the grid cells where CTI increased, tropicalization was stronger than deborealization in 68.6% (while deborealization was stronger in 31.4%) (Figure 2C). Hence, while past literature has focused extensively on increases in warmaffinity species and poleward distribution shifts, 3,7,11,13 here, over one-third of CTI increases were attributable to decreases in cold-affinity species. Among the grid cells where CTI decreased, borealization was stronger than detropicalization in 75% (Figure 2D).…”

Section: Resultsmentioning

confidence: 79%

Disentangling tropicalization and deborealization in marine ecosystems under climate change

et al. 2021

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Disentangling tropicalization and deborealization in marine ecosystems under climate changeHighlights d From 1990 to 2015, mean thermal affinity increased in 72% of communities d One-third of these increases were primarily due to decreases in cold-affinity species d This was linked to temperature, depth, human pressure, and community structure d Species responses to warming were shaped by thermal limits and fishing status

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Section: Resultsmentioning

confidence: 79%

Disentangling tropicalization and deborealization in marine ecosystems under climate change

et al. 2021

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“…This twofold effect of climate change, both increasing spillover risk and leading to a northward shift in species ranges (Osland et al, 2021), could have dramatic effect in the High Arctic. Disentangling this risk from actual spillovers and pandemics will be a critical endeavor to pursue in parallel with surveillance activities, in order to mitigate the impact of future major outbreaks.…”

Section: Resultsmentioning

confidence: 99%

Viral spillover risk increases with climate change in High Arctic lake sediments

Lemieux

Colby

Poulain

et al. 2021

Preprint

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While many viruses have a single natural host, host restriction can be incomplete, hereby leading to spillovers to other host species, potentially causing significant diseases as it is the case with the Influenza A, Ebola, or the SARS-CoV-2 viruses. However, such spillover risks are difficult to quantify. As climate change is rapidly transforming environments, it is becoming critical to quantify the potential for spillovers, in an unbiased manner. For this, we resorted to a metagenomics approach, and focused on two environments in the High Arctic, soil and lake sediments from Lake Hazen. We used DNA and RNA sequencing to reconstruct the lake's virosphere and its range of eukaryotic hosts, and show that spillover risk is higher in lake sediments than in soil and increased with runoff from glacier melt - a proxy for climate change. Should climate change also shift species range of potential vectors northwards, the High Arctic could become fertile ground for emerging pandemics.

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“…While range shifts are now understood to be occurring in many species [ 65 ], more nuanced ecological impacts from increasing light and sound pollution have far-reaching effects on both terrestrial and aquatic animals. In extreme instances, pile-driving used for installation of river revetments or other construction can cause physical harm and complex behavioural changes such as avoidance and reduced vocalization [ 54 , 66 , 67 ].…”

Section: The Urban River Syndrome—ecosystems Previously Transformedmentioning

confidence: 99%

The Urban River Syndrome: Achieving Sustainability Against a Backdrop of Accelerating Change

Richardson

Soloviev

2021

IJERPH

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Human activities have been affecting rivers and other natural systems for millennia. Anthropogenic changes to rivers over the last few centuries led to the accelerating state of decline of coastal and estuarine regions globally. Urban rivers are parts of larger catchment ecosystems, which in turn form parts of wider nested, interconnected systems. Accurate modelling of urban rivers may not be possible because of the complex multisystem interactions operating concurrently and over different spatial and temporal scales. This paper overviews urban river syndrome, the accelerating deterioration of urban river ecology, and outlines growing conservation challenges of river restoration projects. This paper also reviews the river Thames, which is a typical urban river that suffers from growing anthropogenic effects and thus represents all urban rivers of similar type. A particular emphasis is made on ecosystem adaptation, widespread extinctions and the proliferation of non-native species in the urban Thames. This research emphasizes the need for a holistic systems approach to urban river restoration.

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Tropicalization of temperate ecosystems in North America: The northward range expansion of tropical organisms in response to warming winter temperatures

Cited by 150 publications

References 276 publications

Disentangling tropicalization and deborealization in marine ecosystems under climate change

Disentangling tropicalization and deborealization in marine ecosystems under climate change

Viral spillover risk increases with climate change in High Arctic lake sediments

The Urban River Syndrome: Achieving Sustainability Against a Backdrop of Accelerating Change

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