Summary
Earths nitrogen cycle is central to sustaining ecosystem productivity and global biogeochemical balance. Although biological N2-fixation is well characterized in prokaryotes and plant symbioses, in other eukaryotic lineages it remains poorly understood. Diatoms of the family Rhopalodiacea harbor diazoplasts, endosymbiotic spheroid bodies specialized for N2-fixation. This makes these diatoms genuine N2-fixing eukaryotes that represent a unique model for organelle evolution, parallel but distinct from haptophyte nitroplasts. Here, we report the isolation and stable cultivation of an Epithemia adnata strain, the sequencing of its diazoplast genome and its proteomic profile when growing diazotrophically in the light or darkness, or upon exposure to ammonium. Our analyses reveal that ammonium induced broad down-regulation of diazoplast proteins, particularly those linked to N2-fixation, ATP synthesis, and central carbon metabolism underscoring a general regulatory commitment toward diazotrophic metabolism tightly coupled to host carbon and nitrogen status. The pentose phosphate pathway and ferredoxin-NADP oxidoreductase appear as likely source of reductant to nitrogenase. A striking enrichment of chaperones, peroxiredoxins, bacterioferritin-like proteins, and DpsA might stabilize nitrogenase and buffer against oxidative stress during light-driven diazotrophy. Importantly, we identified a plasmid-encoded GlpF as a putative glycerol transporter, pointing to glycerol-mediated host-symbiont metabolic integration in the extant symbiosis and possibly a crucial innovation during the early evolutionary stages of its establishment. Thus, diazoplast activity is not autonomous but requires integration with host carbon and nitrogen status, establishing glycerol transport, reductant supply, stress mitigation, and nutrient-responsive regulation as pivotal mechanisms of nitrogenase activity and host integration. These findings have broad implications for biogeochemical cycling, organellogenesis, and synthetic biology strategies aimed at engineering N2-fixation in crop plants. SignificanceN2-fixing eukaryotes are increasingly recognized as abundant algae containing bacterial-derived diazotrophic endosymbionts, representing an underappreciated component of global N cycling. Diazoplasts in rhopalodiacean diatoms represent a compelling example of such endosymbionts specialized for N2-fixation. By combining genomic sequencing and proteomic analysis, we demonstrate their metabolic specialization, host integration, and regulatory commitment to diazotrophy. These findings reinforce the emerging view that diazoplasts function as organelle-like entities dedicated to N2-fixation, dependent on host-supplied carbon while contributing fixed N in return. Beyond giving evolutionary insights into organellogenesis, this work establishes a framework for translational applications, such as engineering N2-fixation into agricultural plants. Such advances could reduce reliance on synthe
Outcomes reported
Earths nitrogen cycle is central to sustaining ecosystem productivity and global biogeochemical balance. Although biological N2-fixation is well characterized in prokaryotes and plant symbioses, in other eukaryotic lineages it remains poorly understood. Diatoms of the family Rhopalodiacea harbor diazoplasts, endosymbiotic spheroid bodies specialized for N2-fixation. This makes these diatoms genuine N2-fixing eukaryotes that represent a unique model for organelle evolution, parallel but distinct from haptophyte nitroplasts. Here, we report the isolation and stable cultivation of an Epithemia adnata strain, the sequencing of its diazoplast genome and its proteomic profile when growing diazotrophically in the light or darkness, or upon exposure to ammonium. Our analyses reveal that ammonium induced broad down-regulation of diazoplast proteins, particularly those linked to N2-fixation, ATP synthesis, and central carbon metabolism underscoring a general regulatory commitment toward diazotrophic metabolism tightly coupled to host carbon and nitrogen status. The pentose phosphate pathway and ferredoxin-NADP oxidoreductase appear as likely source of reductant to nitrogenase. A striking enrichment of chaperones, peroxiredoxins, bacterioferritin-like proteins, and DpsA might stabilize nitrogenase and buffer against oxidative stress during light-driven diazotrophy. Importantly, we identified a plasmid-encoded GlpF as a putative glycerol transporter, pointing to glycerol-mediated host-symbiont metabolic integration in the extant symbiosis and possibly a crucial innovation during the early evolutionary stages of its establishment. Thus, diazoplast activity is not autonomous but requires integration with host carbon and nitrogen status, establishing glycerol transport, reductant supply, stress mitigation, and nutrient-responsive regulation as pivotal mechanisms of nitrogenase activity and host integration. These findings have broad implications for biogeochemical cycling, organellogenesis, and synthetic biology strategies aimed at engineering N2-fixation in crop plants. SignificanceN2-fixing eukaryotes are increasingly recognized as abundant algae containing bacterial-derived diazotrophic endosymbionts, representing an underappreciated component of global N cycling. Diazoplasts in rhopalodiacean diatoms represent a compelling example of such endosymbionts specialized for N2-fixation. By combining genomic sequencing and proteomic analysis, we demonstrate their metabolic specialization, host integration, and regulatory commitment to diazotrophy. These findings reinforce the emerging view that diazoplasts function as organelle-like entities dedicated to N2-fixation, dependent on host-supplied carbon while contributing fixed N in return. Beyond giving evolutionary insights into organellogenesis, this work establishes a framework for translational applications, such as engineering N2-fixation into agricultural plants. Such advances could reduce reliance on synthe
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