Abstract
Several types of bacterial appendages, e.g., pili and fimbriae, are known for their role in promoting interactions and aggregation with particles and bacteria in the ocean. First discovered in Bacillus subtilis and Escherichia coli, but novel to marine bacteria, bacterial nanotubes are hollow tubular structures connecting cell pairs that allow for the internal transport of cytoplasmic metabolites across the connecting structure. While the significance of nanotubes in exchange of cytoplasmic content has been established in non-marine bacteria, their occurrence and potential ecological significance in marine bacteria has not been reported. Using multiple high-resolution microscopy methods (atomic force microscopy, scanning, and transmission electron microscopy), we have determined that marine bacteria isolates and natural assemblages from nearshore upper ocean waters can express bacterial nanotubes. In marine isolates Pseudoalteromonas sp. TW7 and Alteromonas sp. ALTSIO, individual bacterial nanotubes measured 50–160 nm in width and extended 100–600 nm between connected cells. The spatial coupling of different cells via nanotubes can last for at least 90 min, extending the duration of interaction events between marine bacteria within natural assemblages. The nanomechanical properties of bacterial nanotubes vary in adhesion and dissipation properties, which has implication for structural and functional variability of these structures in their ability to stick to surfaces and respond to mechanical forces. Nanotube frequency is low among cells in enriched natural assemblages, where nanotubes form short, intimate connections, <200 nm, between certain neighboring cells. Bacterial nanotubes can form the structural basis for a bacterial ensemble and function as a conduit for cytoplasmic exchange (not explicitly studied here) between members for multicellular coordination and expression. The structural measurements and nanomechanical analyses in this study also extends knowledge about the physical properties of bacterial nanotubes and their consequences for marine microenvironments. The discovery of nanotube expression in marine bacteria has significant potential implications regarding intimate bacterial interactions in spatially correlated marine microbial communities.
Highlights
Marine microbial communities are comprised cumulatively of extremely abundant (1029 estimated bacteria in the global ocean) and diverse cells that shape the biological and biogeochemical landscapes of the oceans through interactions with their biotic and abiotic environments (Azam et al, 1994; Azam and Malfatti, 2007; Flemming and Wuertz, 2019)
We report first observations of intercellular nanotubes in marine bacterial isolates and within natural marine assemblages using atomic force microscopy (AFM)
We observed during nanoscale imaging in native-like conditions with AFM numerous instances of bacterial nanotubes connecting cell pairs within surface populations of Pseudoalteromonas sp
Summary
Marine microbial communities are comprised cumulatively of extremely abundant (1029 estimated bacteria in the global ocean) and diverse cells that shape the biological and biogeochemical landscapes of the oceans through interactions with their biotic and abiotic environments (Azam et al, 1994; Azam and Malfatti, 2007; Flemming and Wuertz, 2019). A fundamental goal in microbial oceanography is to understand how microbes interact with their organic matter field, including other microbes, and larger organisms – and with what ecosystem consequences This is a formidable challenge given the enormous complexity of the organic matter pool in the ocean, the diversity of potential interactions, and the range of spatial scales of influence – from nanometers to the ocean basins. The challenge for pelagic marine bacteria is to grow and persist at the expense of such vanishingly low concentrations of DOM. This has raised the question whether pelagic bacteria gain metabolic and growth advantage by interacting with colloids and particulate detritus to solubilize them, generating microscale loci of high DOM. Submicron-sized colloids, present at ∼108 particles mL−1 in ambient seawater (Wells and Goldberg, 1991) and likely even greater in phycospheres and detritospheres, might attach to bacterial surface and appendages, generating nanoscale hotspots of organic matter directly on cell surface
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