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Understanding connectivity between populations is key to identifying hotspots of diversity, dispersal sinks and sources, and effective management units for natural resources. Multi-species connectivity seeks to overcome species-specific idiosyncrasies to identify shared patterns that are most critical to spatial management. The linear Hawaiian archipelago provides an excellent platform to assess multi-species connectivity patterns, with shared boundaries to gene flow identified across a majority of the 41 coral reef species surveyed to date. Here, we evaluate genome-scale data by comparing consistency and resolution to previous connectivity studies using far fewer loci. We used pool-seq to genotype 22,503–232,730 single nucleotide polymorphisms per species (625,215 SNPs total) from the same individuals published in previous studies of two fishes, two corals, and two lobsters. Additionally, one coral species (Pocillopora meandrina) without previous archipelago-wide population genetic data was included. With greater statistical power, most genetic differences between pairwise comparisons of islands were significant (250 of 308), consistent with the most recent larval dispersal models for the Hawaiian Archipelago. These data reveal significant differentiation at a finer scale than previously reported using single-marker studies, yet did not overturn any of the conclusions or management implications drawn from previous studies. We confirm that population genomic datasets are consistent with previously reported patterns of multispecies connectivity but add a finer layer of population resolution that is pertinent to management. 

Abstract The bacterial orderPelagibacterales(SAR11) is among the most abundant and widely distributed microbial lineages across the global surface ocean, where it forms an integral component of the marine carbon cycle. However, the limited availability of high-quality genomes has hampered comprehensive insights into the ecology and evolutionary history of this critical group. Here, we increase the number of complete SAR11 isolate genomes fourfold by describing 81 new SAR11 strains from seven distinct lineages isolated from coastal and offshore surface seawater of the tropical Pacific Ocean. We leveraged comprehensive phylogenomic insights afforded by these isolates to characterize 24 monophyletic, discrete ecotypes with unique spatiotemporal patterns of distribution across the global ocean, which we define as genera. Our data illustrate fine-scale differentiation in patterns of detection with ecologically-relevant gene content variation for some closely related genomes, demonstrating instances of ecological speciation within SAR11 genera. Our study provides unique insight into complex environmental SAR11 populations, and proposes an ecology-informed hierarchy to pave a path forward for the systematic nomenclature for this clade.