Department of Plant Sciences, University of Arizona, Tucson, AZ, USA.
Mol Plant Microbe Interact. 2011 Mar;24(3):368-76. doi: 10.1094/MPMI-09-10-0198.
The fungal plant pathogen Nectria haematococca MPVI produces a cytochrome P450 that is responsible for detoxifying the phytoalexin pisatin, produced as a defense mechanism by its host, garden pea. In this study, we demonstrate that this fungus also produces a specific ATP-binding cassette (ABC) transporter, NhABC1, that enhances its tolerance to pisatin. In addition, although both mechanisms individually contribute to the tolerance of pisatin and act as host-specific virulence factors, mutations in both genes render the fungus even more sensitive to pisatin and essentially nonpathogenic on pea. NhABC1 is rapidly induced after treatment with pisatin in vitro and during infection of pea plants. Furthermore, NhABC1 was able to confer tolerance to the phytoalexin rishitin, produced by potato. NhABC1 appears to be orthologous to GpABC1 of the potato pathogen Gibberella pulicaris and, along with MoABC1 from Magnaporthe oryzae, resides in a phylogenetically related clade enriched with ABC transorters involved in virulence. We propose that NhABC1 and the cytochrome P450 may function in a sequential manner in which the energy expense from pisatin efflux by NhABC1 releases the repression of the cytochrome P450, ultimately allowing pisatin tolerance by two mechanisms. These results demonstrate that a successful pathogen has evolved multiple mechanisms to overcome these plant antimicrobial compounds.
真菌病原体血痂壳孢菌 MPVI 产生一种细胞色素 P450,负责解毒其宿主豌豆产生的防御机制物质豌豆素。在这项研究中,我们证明该真菌还产生了一种特定的三磷酸腺苷结合盒(ABC)转运蛋白 NhABC1,该蛋白增强了其对豌豆素的耐受性。此外,尽管这两种机制都有助于耐受豌豆素,并作为宿主特异性毒力因子起作用,但这两个基因的突变使真菌对豌豆素更加敏感,基本上对豌豆没有致病性。NhABC1 在体外用豌豆素处理和感染豌豆植物后迅速诱导。此外,NhABC1 能够赋予对由马铃薯产生的植物抗毒素麦角硫因的耐受性。NhABC1 似乎与马铃薯病原体茄病镰刀菌的 GpABC1 同源,并且与稻瘟病菌的 MoABC1 一起,位于一个与毒力相关的系统发育上相关的分支中,其中富含涉及毒力的 ABC 转运蛋白。我们提出 NhABC1 和细胞色素 P450 可能以顺序方式发挥作用,其中 NhABC1 将豌豆素排出的能量消耗释放了对细胞色素 P450 的抑制,最终通过两种机制允许豌豆素耐受性。这些结果表明,成功的病原体已经进化出多种机制来克服这些植物抗菌化合物。
