The green algal genus Ulva includes a speciose group of marine macroalgae inhabiting shallow seas worldwide. Although algal blooms in Asia highlight the opportunistic nature of several "nuisance" species, recent research clearly reveals important positive benefits of Ulva. Applied research requires accurate, reliable, and rapid identification, however, identification of Ulva spp. has met with con-siderable difficulty. Consequently, many have turned to molecular markers to aid in taxonomy. Previous studies of plants and algae have relied heavily on ITS and rbcL. Recently, tufA has been presented as a suitable barcoding gene to facilitate species-level identification of green macroalgae and it is used here to explore the diversity of Ulva spp. in temperate Australia. Ninety Ulva specimens collected from 38 sites across five states were sequenced for this gene region with exemplars from each genetic group also sequenced for rbcL to test for congruence. Collections of Australian Ulva spp. were compared to samples from Asia and North America and exhibited trends consistent with recent studies in terms of species relationships. Results support an overwhelmingly cosmopolitan flora in temperate Australia that contrasts with other Australasian surveys of Ulva that report a greater number of endemics and new species. Four new records, as well as numerous range extensions for taxa already known from the country, are documented. Evidence for three nonindigenous Ulva species in temperate Australia is discussed.
In the last decade, greater than expected levels of genetic structure have been reported for many marine taxa with high dispersal capabilities. Although little-studied to date, it is predicted that taxa with poor dispersal abilities would exhibit even more genetic differentiation than high dispersal taxa. These systems may track biogeographical processes better than more dispersive taxa and, more critically, function as the 'lowest common denominators' in MPA design initiatives. We investigate phylogeographical patterns in the poorly dispersing, yet widely distributed Patelloida profunda group and related congeners across the Indo-west Pacific region. One hundred and twenty-five individuals were sequenced for COI mtDNA [593 base pairs (bp)] and 44 individuals were sequenced for 16S mtDNA (539 bp). Identified P. profunda group lineages are highly geographically structured, with 12 reciprocally monophyletic lineages reported from 13 localities. Divergences within Indian and Pacific basins range from d = 0.013 to 0.127 and between basins from d = 0.147 to 0.197. The latter split is ancient (> 15 Myr) and cannot be related to Plio-Pleistocene sea-level fluctuations, characteristic of previously reported divergences in the same region. Juxtaposed against this structure is genetic connectivity between two widely separated P. profunda populations that share a common haplotype (phiST = 0.001). This finding contrasts with previous work in the same geographical region and cautions strongly against single taxon indicators for designing conservation priorities or marine protected areas (MPAs). Historical and/or biological factors may play more significant roles than oceanography alone in determining the genetic structuring of taxa. In light of these findings, we discuss the difficulty in deriving biogeographical process or directionality from phylogenetic trees in dispersal-driven systems. Even with a well-resolved, highly supported topology, many equally parsimonious scenarios are possible.
The subfamily Fraginae (Cardiidae) is a morphologically diverse group of small-bodied marine clams inhabiting shallow seas worldwide. Like the exclusively photosymbiotic giant clams (Cardiidae: Tridacninae), some fragines are known to host zooxanthellae photosymbionts. However, surveys to widely determine photosymbiotic status and the lack of a comprehensive phylogeny have hindered attempts to track the evolution of photosymbiosis in the group. Worldwide sampling of all fragine genera and subgenera with phylogenetic reconstructions based on four gene regions [nuclear (28S) and mtDNA (16S, cytochrome oxidase I, cytochrome b)] does not support a monophyletic Fraginae. Sampled taxa form four restructured clades: (1) the 'Fragum' group, (2) the 'Trigoniocardia' and 'Ctenocardia' groups, (3) the 'Parvicardium' group and (4) the 'Papillicardium' group. Maximum likelihood analyses strongly support a clade of European cardiids uniting species from three subfamilies. Live examination of > 50% of species reveals that less than half of derived genera and subgenera host photosymbionts, supporting a single and relatively late origin of photosymbiosis in the Fraginae. The evolutionary implications for a small and little modified earliest diverging photosymbiotic lineage are discussed.
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