AI Article Synopsis
- Tuna are important commercial species that serve as a key protein source worldwide and are affected by climate change, with their distribution patterns shifting in response to environmental conditions.
- A study examined the distribution of six tuna species from 1958 to 2004, revealing that suitable habitats have moved poleward, averaging 6.5 km per decade in the northern hemisphere and 5.5 km in the southern hemisphere.
- Future projections predict declines in temperate tunas in tropical regions while indicating increased abundance of skipjack and yellowfin tunas in the tropics and coastal economic zones, highlighting the need for adaptive management to address climate change impacts.
Article Abstract
Tuna are globally distributed species of major commercial importance and some tuna species are a major source of protein in many countries. Tuna are characterized by dynamic distribution patterns that respond to climate variability and long-term change. Here, we investigated the effect of environmental conditions on the worldwide distribution and relative abundance of six tuna species between 1958 and 2004 and estimated the expected end-of-the-century changes based on a high-greenhouse gas concentration scenario (RCP8.5). We created species distribution models using a long-term Japanese longline fishery dataset and two-step generalized additive models. Over the historical period, suitable habitats shifted poleward for 20 out of 22 tuna stocks, based on their gravity centre (GC) and/or one of their distribution limits. On average, tuna habitat distribution limits have shifted poleward 6.5 km per decade in the northern hemisphere and 5.5 km per decade in the southern hemisphere. Larger tuna distribution shifts and changes in abundance are expected in the future, especially by the end-of-the-century (2080-2099). Temperate tunas (albacore, Atlantic bluefin, and southern bluefin) and the tropical bigeye tuna are expected to decline in the tropics and shift poleward. In contrast, skipjack and yellowfin tunas are projected to become more abundant in tropical areas as well as in most coastal countries' exclusive economic zones (EEZ). These results provide global information on the potential effects of climate change in tuna populations and can assist countries seeking to minimize these effects via adaptive management.
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| http://dx.doi.org/10.1111/gcb.14630 | DOI Listing |
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