Quistad Steven D, Grasis Juris A, Barr Jeremy J, Rohwer Forest L
Department of Biology, San Diego State University, San Diego, CA, USA.
Laboratoire de Colloïdes et Matériaux Divisés (LCMD), Institute of Chemistry, Biology, and Innovation, ESPCI ParisTech/CNRS UMR 8231/PSL Research University, Paris, France.
ISME J. 2017 Apr;11(4):835-840. doi: 10.1038/ismej.2016.182. Epub 2016 Dec 16.
The last common metazoan ancestor (LCMA) emerged over half a billion years ago. These complex metazoans provided newly available niche space for viruses and microbes. Modern day contemporaries, such as cnidarians, suggest that the LCMA consisted of two cell layers: a basal endoderm and a mucus-secreting ectoderm, which formed a surface mucus layer (SML). Here we propose a model for the origin of metazoan immunity based on external and internal microbial selection mechanisms. In this model, the SML concentrated bacteria and their associated viruses (phage) through physical dynamics (that is, the slower flow fields near a diffusive boundary layer), which selected for mucin-binding capabilities. The concentration of phage within the SML provided the LCMA with an external microbial selective described by the bacteriophage adherence to mucus (BAM) model. In the BAM model, phage adhere to mucus protecting the metazoan host against invading, potentially pathogenic bacteria. The same fluid dynamics that concentrated phage and bacteria in the SML also concentrated eukaryotic viruses. As eukaryotic viruses competed for host intracellular niche space, those viruses that provided the LCMA with immune protection were maintained. If a resident virus became pathogenic or if a non-beneficial infection occurred, we propose that tumor necrosis factor (TNF)-mediated programmed cell death, as well as other apoptosis mechanisms, were utilized to remove virally infected cells. The ubiquity of the mucosal environment across metazoan phyla suggest that both BAM and TNF-induced apoptosis emerged during the Precambrian era and continue to drive the evolution of metazoan immunity.
最后的后生动物共同祖先(LCMA)出现在超过5亿年前。这些复杂的后生动物为病毒和微生物提供了新的生态位空间。现代的同类生物,如水母,表明LCMA由两层细胞组成:基部内胚层和分泌黏液的外胚层,它们形成了一个表面黏液层(SML)。在此,我们基于外部和内部微生物选择机制提出了一个后生动物免疫起源的模型。在这个模型中,SML通过物理动力学(即扩散边界层附近较慢的流场)浓缩细菌及其相关病毒(噬菌体),从而选择出黏蛋白结合能力。SML内噬菌体的浓缩为LCMA提供了一种由噬菌体黏附于黏液(BAM)模型描述的外部微生物选择。在BAM模型中,噬菌体黏附于黏液,保护后生动物宿主免受入侵的潜在致病细菌的侵害。在SML中浓缩噬菌体和细菌的相同流体动力学也浓缩了真核病毒。由于真核病毒争夺宿主细胞内的生态位空间,那些为LCMA提供免疫保护的病毒得以保留。如果一种常驻病毒变得具有致病性或发生了非有益感染,我们提出肿瘤坏死因子(TNF)介导的程序性细胞死亡以及其他凋亡机制被用来清除病毒感染的细胞。后生动物各门类中黏膜环境的普遍性表明,BAM和TNF诱导的凋亡均出现在前寒武纪时代,并继续推动后生动物免疫的进化。