University of Georgia Marine Institute, Sapelo Island, Georgia 31327, and Division of Marine and Atmospheric Chemistry, Rosenstiel School of Marine and Atmospheric Science, University of Miami, Miami, Florida 33149-1098.
Appl Environ Microbiol. 1988 Sep;54(9):2208-12. doi: 10.1128/aem.54.9.2208-2212.1988.
Dimethylsulfoniopropionate (DMSP) is a natural product of algae and aquatic plants, particularly those from saline environments. We investigated whether DMSP could serve as a precursor of thiols in anoxic coastal marine sediments. The addition of 10 or 60 muM DMSP to anoxic sediment slurries caused the concentrations of 3-mercaptopropionate (3-MPA) and methanethiol (MSH) to increase. Antibiotics prevented the appearance of these thiols, indicating biological formation. Dimethyl sulfide (DMS) and acrylate also accumulated after the addition of DMSP, but these compounds were rapidly metabolized by microbes and did not reach high levels. Acrylate and DMS were probably generated by the enzymatic cleavage of DMSP. MSH arose from the microbial metabolism of DMS, since the direct addition of DMS greatly increased MSH production. Additions of 3-methiolpropionate gave rise to 3-MPA at rates similar to those with DMSP, suggesting that sequential demethylation of DMSP leads to 3-MPA formation. Only small amounts of MSH were liberated from 3-methiolpropionate, indicating that demethiolation was not a major transformation for 3-methiolpropionate. We conclude that DMSP was degraded in anoxic sediments by two different pathways. One involved the well-known enzymatic cleavage to acrylate and DMS, with DMS subsequently serving as a precursor of MSH. In the other pathway, successive demethylations of the sulfur atom proceeded via 3-methiolpropionate to 3-MPA.
二甲亚砜(DMSP)是藻类和水生植物的天然产物,尤其是那些来自盐环境的植物。我们研究了 DMSP 是否可以作为缺氧沿海海洋沉积物中硫醇的前体。向缺氧沉积物悬浮液中添加 10 或 60 μM 的 DMSP 会导致 3-巯基丙酸(3-MPA)和甲硫醇(MSH)的浓度增加。抗生素阻止了这些硫醇的出现,表明其为生物形成。添加 DMSP 后还会积累二甲基硫(DMS)和丙烯酸盐,但这些化合物会被微生物迅速代谢,不会达到高水平。丙烯酸盐和 DMS 可能是通过 DMSP 的酶促裂解产生的。MSH 是由 DMS 的微生物代谢产生的,因为直接添加 DMS 会大大增加 MSH 的产生。添加 3-巯基丙酸会以与 DMSP 相似的速率产生 3-MPA,这表明 DMSP 的顺序脱甲基导致 3-MPA 的形成。只有少量的 MSH 从 3-巯基丙酸中释放出来,表明脱巯基不是 3-巯基丙酸的主要转化途径。我们得出结论,DMSP 在缺氧沉积物中通过两种不同的途径降解。一种涉及众所周知的酶促裂解生成丙烯酸盐和 DMS,随后 DMS 作为 MSH 的前体。在另一种途径中,硫原子的连续脱甲基通过 3-巯基丙酸进行,生成 3-MPA。