Abstract
Global scale analyses have recently revealed that the latitudinal gradient in marine species richness is bimodal, peaking at low-mid latitudes but with a dip at the equator; and that marine species richness decreases with depth in many taxa. However, these overall and independently studied patterns may conceal regional differences that help support or qualify the causes in these gradients. Here, we analysed both latitudinal and depth gradients of species richness in the NW Pacific and its adjacent Arctic Ocean. We analysed 324,916 distribution records of 17,414 species from 0 to 10,900 m depth, latitude 0 to 90°N, and longitude 100 to 180°N. Species richness per c. 50 000 km2 hexagonal cells was calculated as alpha (local average), gamma (regional total) and ES50 (estimated species for 50 records) per latitudinal band and depth interval. We found that average ES50 and gamma species richness decreased per 5° latitudinal bands and 100 m depth intervals. However, average ES50 per hexagon showed that the highest species richness peaked around depth 2,000 m where the highest total number of species recorded. Most (83%) species occurred in shallow depths (0 to 500 m). The area around Bohol Island in the Philippines had the highest alpha species richness (more than 8,000 species per 50,000 km2). Both alpha and gamma diversity trends increased from the equator to latitude 10°N, then further decreased, but reached another peak at higher latitudes. The latitudes 60–70°N had the lowest gamma and alpha diversity where there is almost no ocean in our study area. Model selection on Generalized Additive Models (GAMs) showed that the combined effects of all environmental predictors produced the best model driving species richness in both shallow and deep sea. The results thus support recent hypotheses that biodiversity, while highest in the tropics and coastal depths, is decreasing at the equator and decreases with depth below ~2000 m. While we do find the declines of species richness with latitude and depth that reflect temperature gradients, local scale richness proved poorly correlated with many environmental variables. This demonstrates that while regional scale patterns in species richness may be related to temperature, that local scale richness depends on a greater variety of variables.
Highlights
The latitudinal and bathymetrical gradients of marine species richness have been widely studied at both regional[1,2,3,4,5] and global scales[6,7,8,9,10]
The highest ES50 (48) in the deep sea was recorded around Luzon Island (16.14°N, 122.40°E; ocean area: ~1,250 km2) in the Philippines
The data still showed a decline in species richness with depth when adjusted for sampling effort (ES50)
Summary
The latitudinal and bathymetrical gradients of marine species richness have been widely studied at both regional[1,2,3,4,5] and global scales[6,7,8,9,10]. Last 36 million years, but were weakened or absent during glacial periods[24] Considering both latitude and deep-sea gradients of marine species richness together in the same geographic region seems overdue. Tropical warmer climates have increased metabolic scope and biodiversity by fostering greater population size and extinction resistance[29] This allows more species to inhabit specialized niches as a result of greater available energy, and generates faster speciation and/or lower extinction rates[29,35]. We considered the adjacent Arctic Ocean of the NW Pacific to discover how these patterns change towards the highest latitudes If these latitudinal and depth gradients are largely temperature correlated it would suggest that other variables, including topographic complexity, had negligible influence on the evolution of the fauna
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