Department of Biological Sciences, Graduate School of Science, The University of Tokyo, Tokyo, Japan.
Bioproduction Research Institute, National Institute of Advanced Industrial Science and Technology, Tsukuba, Japan.
mBio. 2023 Apr 25;14(2):e0052223. doi: 10.1128/mbio.00522-23. Epub 2023 Apr 5.
Microbial mutualists are pivotal for insect adaptation, which often entails the evolution of elaborate organs for symbiosis. Addressing what mechanisms underpin the development of such organs is of evolutionary interest. Here, we investigated the stinkbug Plautia stali, whose posterior midgut is transformed into a specialized symbiotic organ. Despite being a simple tube in newborns, it developed numerous crypts in four rows, whose inner cavity hosts a specific bacterial symbiont, during the 1st to 2nd nymphal instar stages. Visualization of dividing cells revealed that active cell proliferation was coincident with the crypt formation, although spatial patterns of the proliferating cells did not reflect the crypt arrangement. Visualization of visceral muscles in the midgut, consisting of circular muscles and longitudinal muscles, uncovered that, strikingly, circular muscles exhibited a characteristic arrangement running between the crypts specifically in the symbiotic organ. Even in the early 1st instar stage, when no crypts were seen, two rows of epithelial areas delineated by bifurcated circular muscles were identified. In the 2nd instar stage, crossing muscle fibers appeared and connected the adjacent circular muscles, whereby the midgut epithelium was divided into four rows of crypt-to-be areas. The crypt formation proceeded even in aposymbiotic nymphs, revealing the autonomous nature of the crypt development. We propose a mechanistic model of crypt formation wherein the spatial arrangement of muscle fibers and the proliferation of epithelial cells underpin the formation of crypts as midgut evaginations. Diverse organisms are associated with microbial mutualists, in which specialized host organs often develop for retaining the microbial partners. In light of the origin of evolutionary novelties, it is important to understand what mechanisms underpin the elaborate morphogenesis of such symbiotic organs, which must have been shaped through interactions with the microbial symbionts. Using the stinkbug as a model, we demonstrated that visceral muscular patterning and proliferation of intestinal epithelial cells during the early nymphal stages are involved in the formation of numerous symbiont-harboring crypts arranged in four rows in the posterior midgut to constitute the symbiotic organ. Strikingly, the crypt formation occurred normally even in symbiont-free nymphs, revealing that the crypt development proceeds autonomously. These findings suggest that the crypt formation is deeply implemented into the normal development of , which must reflect the considerably ancient evolutionary origin of the midgut symbiotic organ in stinkbugs.
微生物共生体是昆虫适应的关键,这通常需要共生的精细器官的进化。研究支持这些器官发育的机制是进化上的兴趣所在。在这里,我们研究了斑蝥 Plautia stali,其后中肠转化为专门的共生器官。尽管在新生儿中是一个简单的管,但在 1 到 2 龄若虫阶段,它在四排中发育出许多隐窝,其内腔容纳特定的细菌共生体。分裂细胞的可视化显示,尽管增殖细胞的空间模式与隐窝的排列无关,但活跃的细胞增殖与隐窝的形成同时发生。对中肠内脏肌肉(包括环肌和纵肌)的可视化显示,令人惊讶的是,在共生器官中,特别在隐窝之间,环肌呈现出一种特征性的排列。即使在早期的 1 龄若虫阶段,当没有隐窝时,也可以识别出由分叉环肌界定的两排上皮区域。在 2 龄若虫阶段,交叉肌纤维出现并连接相邻的环肌,从而将中肠上皮分为四排隐窝区域。即使在无共生的若虫中,隐窝的形成也在继续,揭示了隐窝发育的自主性。我们提出了隐窝形成的机制模型,其中肌肉纤维的空间排列和上皮细胞的增殖为隐窝作为中肠外生的形成提供了基础。 多种生物体与微生物共生体相关联,其中通常为保留微生物伙伴而开发专门的宿主器官。鉴于进化新颖性的起源,了解支撑这种共生器官复杂形态发生的机制是很重要的,这种形态发生必须通过与微生物共生体的相互作用来塑造。使用臭虫作为模型,我们证明了内脏肌肉模式形成和早期若虫阶段肠上皮细胞的增殖参与了在后中肠中排列成四排的大量共生体栖息隐窝的形成,构成共生器官。引人注目的是,即使在没有共生体的若虫中,隐窝的形成也正常进行,这表明隐窝的发育是自主进行的。这些发现表明,隐窝的形成深深地融入了斑蝥的正常发育中,这反映了中肠共生器官在臭虫中相当古老的进化起源。
