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Microalgal interactions within microbial communities across different environmental gradients and physical scales are widely acknowledged to play essential roles in microbial evolution and ecosystem functions, and are further recognized as key drivers of productivity, resilience, and functionality in microalgae-based biotechnological systems. These interactions -spanning molecular to population levels -influence the production and transport of key molecular cargoes with broader ecological and engineering implications, and biogeochemical cycling on a global scale.Recent advancements in multi-omics approaches and synthetic biology have significantly expanded our understanding of metabolic versatility and the interactive mechanisms underlying diverse microalgae-microbe consortia. Nevertheless, the wide spectrum of possible interactions in these consortia urgently calls for further systematic investigations to unravel novel biological insights and create opportunities for advancing microalgal synthetic biology, nature-based solutions for bioremediation and carbon sequestration, and the commercialization of biofuels and high-value bioproducts.Acknowledging the vital importance of microalgae-microbe interactions, this Research Topic was established to present a collection of recent advances in the field. Seven articles in this collection cover a broad range of topics -from reports on novel microbes influencing bloomforming algae and elusive predatory bacteria in outdoor microalgal cultivation systems to a deep learning-based predictive model for chloroplast-targeting peptides and a timely review on microbiome engineering approaches for algal biotechnology.Mankiewicz-Boczek et al. investigated the bacterial consortia associated with morphologically distinct cyanobacteria that can influence the ecological threat of harmful algal blooms across freshwater bodies globally. The results of 16S rRNA amplicon sequencing and shotgun metagenomics supported that phycosphere composition and nutrient-cycling capacity depended on the dominant cyanobacterial strain, with Microcystis supporting more complex bacterial associations than Aphanizomenon and Planktothrix. Interestingly, non-diazotrophic blooms exhibited greater abundances of nitrogen-and phosphorus-cycling genes, indicating their importance in bloom's ecological impact possibly via nutrient transformations.Resonating with these findings, Li et al. reported bacterial strains isolated from blooms of Phaeocystis globosa in marine ecosystems and highlighted the role of ammonifying and phosphorus-solubilizing functions in supporting the growth of this bloom-forming alga. A particular isolate, GXAS306 T , was identified as belonging to the genus Aliikangiella, and its growth-promoting activity reiterates that the fate of bloom-forming algae is closely influenced by associated bacterial communities.While bloom-forming algae also include macroalgae, such as seaweeds that form largescale green tides, Liu et al. investigated the impacts of decaying Ulva green tides on the phycospheric microbiome. Shotgun metagenomic analysis suggested that the demise of Ulva prolifera green tides substantially altered phycospheric microbial community structure. Many chloroplast proteins are nuclear encoded and imported into chloroplasts after translation; therefore, predicting cTPs is critical for chloroplast-targeted engineering as well as for elucidating evolutionary histories. Dubbed Chlamy_ChloroPred, the proposed classifier achieved substantially higher prediction accuracy than the previously reported TargetP 2.0.Nevertheless, the remaining room for improvement in model performance aligns with Koneru et al., underscoring the need for larger, higher-quality biological datasets to further advance predictive models and better understand -and ultimately exploit -microalgae-microbe interactions.Although no single collection can cover the full breadth of our topic, the seven articles disseminated herein represent its transdisciplinary nature. With growing excitement around new tools and approaches, we remain optimistic that our collective understanding of the intricate tapestry of microalgae-microbe interactions will only deepen, as the articles in this collection demonstrate. With seemingly intractable yet intriguing challenges remaining, we strongly encourage researchers with fresh perspectives and ideas to further explore this exciting area.