Abstract
Microbes spontaneously release membrane vesicles (MVs), which play roles in nutrient acquisition and microbial interactions. Iron is indispensable for microbes, but is a difficult nutrient to acquire. However, whether MVs are also responsible for efficient iron uptake and therefore involved in microbial interaction remains to be elucidated. Here, we used a Gram-positive strain, Dietzia sp. DQ12-45-1b, to analyze the function of its MVs in heme-iron recycling and sharing between species. We determined the structure and constituent of MVs and showed that DQ12-45-1b releases MVs originating from the mycomembrane. When comparing proteomes of MVs between iron-limiting and iron-rich conditions, we found that under iron-limiting conditions, heme-binding proteins are enriched. Next, we proved that MVs participate in extracellular heme capture and transport, especially in heme recycling from environmental hemoproteins. Finally, we found that the heme carried in MVs is utilized by multiple species, and we further verified that membrane fusion efficiency and species evolutionary distance determine heme delivery. Together, our findings strongly suggest that MVs act as a newly identified pathway for heme recycling, and represent a public good shared between phylogenetically closely related species.
Highlights
Microorganisms naturally live in large communities, and are constantly challenged by lack of resources or environmental stimuli
In order to evaluate whether DQ12-45-1b generates membrane vesicles (MVs), we analyzed the morphology of DQ12-45-1b cells from late-exponential phase in iron-limiting medium using Transmission electron microscope (TEM)
We showed that mycomembrane vesicles (mMVs) of a Gram-positive bacterium deliver heme-iron directly into cells and acts as public goods under iron-depleted conditions
Summary
Microorganisms naturally live in large communities, and are constantly challenged by lack of resources or environmental stimuli. To overcome this predicament, microbes form complex webs of ecological interactions with their neighbors, primarily via metabolic secretion and exchange [1, 2]. Proteases, hydrolases, and quorum-sensing signal molecules are secreted through various secretion systems, assisting microbes to acquire nutrient and regulate community structures [3, 4].
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