Stable isotopic characterization of carbon, nitrogen and sulfur uptake of Acharax japonica from central Japan

A unique community of Acharax japonica has been found in the reductive bottom sediments in two natural seawater sinks, where a number of the clams can easily be collected and successfully maintained for over a year in laboratory conditions. Stable isotopic signature of their soft body parts shows ty...

Full description

Saved in:
Bibliographic Details
Published in:Plankton & benthos research 2008/02/25, Vol.3(1), pp.36-41
Main Authors: Yamanaka, T.(Kyushu Univ., Fukuoka (Japan)), Mizota, C, Matsuyama Serisawa, K, Kakegawa, T, Miyazaki, J, Mampuku, M, Tsutsumi, H, Fujiwara, Y
Format: Article
Language:English
Subjects:
ABSORCION DE SUSTANCIAS NUTRITIVAS
ABSORPTION DE SUBSTANCES NUTRITIVES
Acharax
Acharax japonica
acquisition of nutrients
AZOTE
AZUFRE
Bivalvia
CARBON
CARBONE
CARBONO
CHEMICAL SYNTHESIS
chemosynthesis-based animal
CONCHA
COQUILLE
ISOTOPE
ISOTOPES
ISOTOPOS
laboratory culture
Marine
NITROGEN
NITROGENO
NUTRIENT UPTAKE
SHELL
SIMBIONTICO
SINTESIS QUIMICA
SOLEMYIDAE
SOUFRE
stable isotopes
SULPHUR
SYMBIONTS
SYMBIOTE
SYNTHESE CHIMIQUE
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:A unique community of Acharax japonica has been found in the reductive bottom sediments in two natural seawater sinks, where a number of the clams can easily be collected and successfully maintained for over a year in laboratory conditions. Stable isotopic signature of their soft body parts shows typical range for chemosynthesis-based bivalves, indicating that the clams rely on sulfur-oxidizing bacteria in their gill. Deltasup(15)N values of substrate ammonia have been measured together with those of the clam soft body parts. These results confirm that the characteristic negative deltasup(15)N values of the clam soft-body parts were caused by a large isotope fractionation during ammonia assimilation as previously documented for those from various locations. In addition, sulfur isotopic ratios of each organ show significant variation. Such trend is observed for some thiotrophic chemosynthesis-based bivalves inhabited on a cold-seep environment, suggesting that it is a common feature for thiotrophic bivalve communities depended on bacterial derived sulfide. Heterogeneity of sulfur isotopic signature among different organs from one specimen was considered due to primary heterogeneity of deltasup(34)S values for source sulfide in their habitat. In addition a different turnover rate of the sulfur nutrition in each organ was conspicuous for the sulfur isotopic variation. This was confirmed by long-term maintenance using an external sulfur budget under laboratory conditions. The estimated turnover rates among three organs were the highest for gill (shorter than three months), the lowest for viscera (longer than a year), and intermediate for foot.
ISSN:1880-8247
1882-627X
DOI:10.3800/pbr.3.36