JpGU-AGU Joint Meeting 2017

講演情報

[EJ] 口頭発表

セッション記号 B (地球生命科学) » B-PT 古生物学・古生態学

[B-PT04] [EJ] 化学合成生態系の進化をめぐって

2017年5月21日(日) 09:00 〜 10:30 106 (国際会議場 1F)

コンビーナ:ジェンキンズ ロバート(金沢大学理工研究域自然システム学系)、渡部 裕美(海洋研究開発機構)、延原 尊美(静岡大学教育学部理科教育講座地学教室)、間嶋 隆一(国立大学法人横浜国立大学教育人間科学部)、座長:ジェンキンズ ロバート(金沢大学理工研究域自然システム学系)、座長:渡部 裕美(海洋研究開発機構)

10:15 〜 10:30

[BPT04-06] Locomotion and move tracking of "Calytogena" clams in situ and in patented H2S controlling tanks

*太田 未来1延原 尊美1土井 佑太1早瀬 磨菜1杉村 誠2長井 裕季子3,4豊福 高志3岩瀬 良一3 (1.静岡大学教育学部、2.新江ノ島水族館、3.独立行政法人海洋研究開発機構、4.横浜国立大学)

キーワード:化学合成、メタン湧水、オトヒメハマグリ科、ロコモーション

Vesicomyid clams are one of the representative chemosynthetic animals, which have flourished in seep and vent sites during the Cenozoic. We report locomotion and behavior patterns of “Calytogena” clams to examine their adaptability to fluctuation of seep activity and disturbance of rapid burial. We analyzed time-lapse image data of in situ Real-time Deep Seafloor Observatory off Hatsushima Island in Sagami Bay, 1174 m in depth (3 min. interval) and patented H2S controlling tanks in JAMSTEC (30 sec. interval) and Enoshima Aquarium (3 min. interval).
The “Calytogena” clams usually show semi-infaunal standing position with anterior side down and foot penetrating into underground sulfide layer, but sometimes crawl laying their shells with ventral side down. In standing position, the clams rearrange their postures swaying and obliquely rotating shells with foot as an axis. The clams sometimes push one another maybe quarreling over their favorite seep spots.
In crawling mode, they move forward by repeating the following steps: 1) laying shell down, 2) extending and penetrating foot in anterior direction, 3) maybe forming an anchor by foot expansion, and 4) pulling shell forward by foot contraction. In cases, the clams gathered into one spot and stranded one another, but could restore their postures into normal semi-infaunal position by extending and bending foot, which has wide movable range and high flexibility. During foot re-penetrating into the sediment, we observed that mass of sediment particles travels on whole surface of foot from its tip to root. Our SEM observation confirmed that the foot surface is densely covered by mucous cilia. The ciliary movement maybe enables the sediment conveying backward, which helps foot penetration.
In patented H2S controlling tanks of Enoshima Aquarium, the “Calytogena” clams migrated keeping their track along the outer margin of bacteria mat. The average time and distance of one move action is about 15 min and 3.22 cm, so the average speed is about 0.38 cm/min. “Calyptogena” clams have been reported to form a ring colony surrounding bacteria mat, and this ring colony is a result guided by best condition of chemical subbottom profile. The positions and areas of bacteria mats in the Enoshima Aquarium tank have been rather stable but the margin fluctuated. The Enoshima clam tracks seem to be a result of tracing the best spot for getting subbottom hydrogen sulfide. In contrast, the “Calyptogena” clams of in situ the Hatsushima observation seem to move breaking bacteria mats, which were newly formed just after turbiditic rapid burial. In emergency where they lost their favorite seep spots just after such physical disturbance, the clams also repeated round trips from one position, back and forth in various directions, with maximum speed about 12 to 14 cm/min.
Calytogena” clams have high ability of moving and restoring of their postures, as noted above. This ability is one of the keys of their adaptability to fluctuation of seep activity and disturbance of rapid burial, leading to their flourishing since the Cenozic.