Scaling and structural properties of juvenile bull kelp (Nereocystis luetkeana)

Bull kelp (Nereocystis luetkeana), the only canopy-forming kelp in the Salish Sea, provides primary production in the nearshore subtidal environment and serves as important habitat for economically and ecologically important species. An annual species, each year juvenile bull kelp sporophytes must grow from the hydrodynamically more benign benthos to the water column, where they experience substantial drag at the surface. Because of the differences in morphology and ecology across life stages, and the fact that previous work has focused mainly on adult bull kelp, we tested whether morphology and structural properties change with stipe length, investigating scaling of both juvenile (stipe length < 40 cm) and mature (stipe length > 40cm) kelp, and testing how juvenile stipes fail. Juvenile bull kelp grow proportionally (isometric growth) when young, but lengthen more quickly than would be predicted by bulb size (negative allometry) at maturity. Based on our data, the predicted breakpoint between isometric and allometric growth occurred at about 33 cm, likely ∼ one to two weeks of growth. Cross sectional area of the stipe, Force to failure, Work to failure, and stiffness (Young's Modulus) all grow more slowly than would be predicted based on length, while Maximum Stress and Toughness increase more quickly than predicted. There is no change in extensibility over the size range we tested, suggesting that this material property does not change with stipe length. The differences in biomechanics between juvenile and adult kelp are likely a response to the varied hydrodynamic environments experienced during the annual lifecycle, which highlights the importance of studying organisms across life stages.

Spatial organization of the kelp microbiome at micron scales

Macroalgae are colonized by complex and diverse microbial communities that are distinct from those on inert substrates, suggesting intimate symbioses that likely play key roles in both macroalgal and bacterial biology. Canopy-forming kelp fix teragrams of carbon per year in coastal kelp forest ecosystems, yet little is known about the structure and development of their associated microbial communities. We characterized the spatial organization of bacterial communities on blades of the canopy-forming kelp Nereocystis luetkeana using fluorescence in situ hybridization and spectral imaging with a probe set combining phylum, class and genus-level probes to target >90% of the microbial community. We show that kelp blades host a dense microbial biofilm, generally less than 20 μm thick, in which disparate microbial taxa live in close contact with one another. The biofilm is spatially differentiated, with tightly clustered cells of the dominant symbiont Granulosicoccus sp. (Gammaproteobacteria) close to the kelp surface and filamentous Bacteroidetes and Alphaproteobacteria relatively more abundant near the biofilm-seawater interface. Further, a community rich in Bacteroidetes colonized the interior of kelp tissues. Microbial community structure and cell density increased along the length of the kelp blade, from sparse microbial colonization of newly produced tissues at the meristematic base of the blade to an abundant microbial biofilm on older tissues at the blade tip. Finally, kelp from a declining population hosted fewer microbial cells compared to kelp from a stable population, indicating that biofilms are characteristic of health and that biofilm loss may be related to the condition of the host.ImportanceThe microbial community coating the surfaces of macroalgae may play a key but underexplored role both in the biology of the macroalgal host and in the biogeochemistry of the coastal ocean. We show that photosynthetic blades of the canopy-forming kelp Nereocystis luetkeana host a complex microbial biofilm that is both dense and spatially differentiated. Microbes of different taxa are in intimate cell-to-cell contact with one another; microbial cells invade the interior of kelp cells as well as cover their external surfaces; and a subset of the surface microbiota projects into the water column. These results highlight the potential for metabolic interactions between key members of the kelp microbiome as well as between microbes and their host. The dense layer of microbes coating the surface of the kelp blade is well-positioned to mediate interactions between the host and surrounding organisms and to modulate the chemistry of the surrounding water column.