JpGU-AGU Joint Meeting 2017

講演情報

[JJ] 口頭発表

セッション記号 M (領域外・複数領域) » M-IS ジョイント

[M-IS19] [JJ] 生物地球化学

2017年5月24日(水) 10:45 〜 12:15 302 (国際会議場 3F)

コンビーナ:楊 宗興(東京農工大学)、柴田 英昭(北海道大学北方生物圏フィールド科学センター)、大河内 直彦(海洋研究開発機構)、山下 洋平(北海道大学 大学院地球環境科学研究院)、座長:木庭 啓介(京都大学生態学研究センター)、座長:砂村 倫成(東京大学大学院理学系研究科地球惑星科学専攻)、座長:和穎 朗太(農研機構 農業環境変動研究センター)、座長:仁科 一哉(国立環境研究所)

11:00 〜 11:15

[MIS19-08] ゲノム科学から見えてくる微生物によるヒ素循環

*天知 誠吾1土屋 達哉1笠原 康裕3濱村 奈津子2 (1.千葉大学大学院園芸学研究科、2.九州大学理学研究院、3.北海道大低温科学研究所)

キーワード:ヒ素、微生物、ゲノム解析、ヒ酸還元、転写解析、プロテオーム解析

Arsenic is released from anaerobic sediments into groundwater as As(III) (arsenite), which threatens the health of millions of people in southern Asia. It is widely accepted that certain anaerobic bacteria, such as dissimilatory iron-reducing bacteria and dissimilatory As(V) (arsenate)-reducing bacteria, play important roles in arsenic release in nature. Although respiratory arsenate reductase genes (arrA) closely related with Geobacter species have been detected frequently in arsenic-rich sediments, it is still unclear whether they directly participate in arsenic release, mainly due to lack of pure cultures capable of arsenate reduction. Previously, we isolated Geobacter sp. OR-1 from Japanese paddy soil. Strain OR-1 also utilized soluble Fe(III) and ferrihydrite as electron acceptors, and catalyzed dissolution of arsenic from arsenate-adsorbed ferrihydrite. Furthermore, inoculation of strain OR-1 into sterilized paddy soil successfully restored arsenic release. In this study, we analyzed draft genome sequence of strain OR-1, and found two distinct “arsenic islands”, the genomic regions highly enriched with arsenic-metabolizing genes. One consisted of arrAB, and they are also flanked with genes for arsenic resistance (arsADR and acr3) Another island consisted mainly of genes for arsenic resistance including that for a detoxifying arsenate reductase ArsC. Transcriptional analysis revealed that most of these genes were expressed specifically in the presence of arsenic, and that the expression of arrA was more than 30 times higher in the presence of arsenic. Comprehensive proteomic analysis by means of 1D SDS-PAGE and LC-MS/MS showed that not only arsenic-metabolizing proteins but also those involved in oxidative stress response, protein folding, molecular chaperones, phosphate uptake, and sulfur metabolism were expressed cooperatively in the presence of arsenic. Our results shed light on how microbes cope with this toxic metalloid, and play an important role in the biogeochemical cycling of arsenic.