Your search keyword '"Naoto F. Ishikawa"' showing total 2 results

1. Tracking long‐distance migration of marine fishes using compound‐specific stable isotope analysis of amino acids

Author

Shigeto Nishino, Kazuaki Tadokoro, Naohiko Ohkouchi, Toshi Nagata, Hiroomi Miyamoto, Naoto F. Ishikawa, Chisato Yoshikawa, Yoshiyuki Abe, Atsushi Yamaguchi, Ichiro Tayasu, Kentaro Honda, Yutaka Osada, Kotaro Shirai, Jun Matsubayashi, and Nanako O. Ogawa

Subjects

0106 biological sciences, Fish migration, biology, Isotope, Compound specific, Isoscapes, Ecology, Oceans and Seas, 010604 marine biology & hydrobiology, Fishes, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Food web, Salmon, Animals, Oncorhynchus, Environmental science, Animal Migration, Amino Acids, Ecology, Evolution, Behavior and Systematics, Retrospective Studies, Isotope analysis, Trophic level

Abstract

The long-distance migrations by marine fishes are difficult to track by field observation. Here, we propose a new method to track such migrations using stable nitrogen isotopic composition at the base of the food web (δ15 NBase ), which can be estimated by using compound-specific isotope analysis. δ15 NBase exclusively reflects the δ15 N of nitrate in the ocean at a regional scale and is not affected by the trophic position of sampled organisms. In other words, δ15 NBase allows for direct comparison of isotope ratios between proxy organisms of the isoscape and the target migratory animal. We initially constructed a δ15 NBase isoscape in the northern North Pacific by bulk and compound-specific isotope analyses of copepods (n = 360 and 24, respectively), and then we determined retrospective δ15 NBase values of spawning chum salmon (Oncorhynchus keta) from their vertebral centra (10 sections from each of two salmon). We then estimated the migration routes of chum salmon during their skeletal growth by using a state-space model. Our isotope tracking method successfully reproduced a known chum salmon migration route between the Okhotsk and Bering seas, and our findings suggest the presence of a new migration route to the Bering Sea Shelf during a later growth stage.

Published

2020

2. Using food network unfolding to evaluate food-web complexity in terms of biodiversity: theory and applications

Author

Takeshi Miki, Yoshikazu Kato, Ichiro Tayasu, Yutaka Osada, Naoko Tokuchi, Nobuhito Ohte, Takashi F. Haraguchi, Mayumi Yoshimura, Yukihiro Kohmatsu, Chikage Yoshimizu, Naoto F. Ishikawa, Hiroyuki Togashi, Michio Kondoh, and Noboru Okuda

Subjects

0106 biological sciences, Biomass (ecology), Food Chain, Ecology, 010604 marine biology & hydrobiology, Ecological pyramid, Biodiversity, Species diversity, 010603 evolutionary biology, 01 natural sciences, Food web, Diversity index, Food chain, Geography, Biomass, Ecology, Evolution, Behavior and Systematics, Ecosystem, Trophic level

Abstract

Food-web complexity often hinders disentangling functionally relevant aspects of food-web structure and its relationships to biodiversity. Here, we present a theoretical framework to evaluate food-web complexity in terms of biodiversity. Food network unfolding is a theoretical method to transform a complex food web into a linear food chain based on ecosystem processes. Based on this method, we can define three biodiversity indices, horizontal diversity (DH ), vertical diversity (DV ) and range diversity (DR ), which are associated with the species diversity within each trophic level, diversity of trophic levels, and diversity in resource use, respectively. These indices are related to Shannon's diversity index (H'), where H' = DH + DV - DR . Application of the framework to three riverine macroinvertebrate communities revealed that D indices, calculated from biomass and stable isotope features, captured well the anthropogenic, seasonal, or other within-site changes in food-web structures that could not be captured with H' alone.

Published

2017