James E. Palardy

Heterotrophic plasticity and resilience in bleached corals

Mass coral bleaching events caused by elevated seawater temperatures have resulted in extensive coral mortality throughout the tropics over the past few decades. With continued global warming, bleaching events are predicted to increase in frequency and severity, causing up to 60% coral mortality globally within the next few decades. Although some corals are able to recover and to survive bleaching, the mechanisms underlying such resilience are poorly understood. Here we show that the coral host has a significant role in recovery and resilience. Bleached and recovering Montipora capitata (branching) corals met more than 100% of their daily metabolic energy requirements by markedly increasing their feeding rates and CHAR (per cent contribution of heterotrophically acquired carbon to daily animal respiration), whereas Porites compressa (branching) and Porites lobata (mounding) corals did not. These findings suggest that coral species with high-CHAR capability during bleaching and recovery, irrespective of morphology, will be more resilient to bleaching events over the long term, could become the dominant coral species on reefs, and may help to safeguard affected reefs from potential local and global extinction.

Water flow drives biodiversity by mediating rarity in marine benthic communities.

In aquatic ecosystems, water flow mediates the delivery of reproductive propagules, competition and predation, each of which may have contrasting effects on biodiversity. Here, we show that water flow has a net positive effect on the biodiversity of benthic invertebrate communities in three biogeographic regions. In Palau and Alaska, flow velocity predicted 55-91% of the variance in species richness in natural communities. In experimental communities in Alaska and Maine, enhanced water flow treatments resulted in higher levels of species density (+56%) and richness (+74%), which were predicted by the abundance of locally rare species. Additionally, the richness of recruitment was higher in experimentally enhanced flows (+46%). Thus, the data suggest that flow drives diversity by mediating the delivery of rare species in multiple biogeographic regions. Consequently, flow velocity should be included in future developments of diversity theory and conservation strategy.

Flow, recruitment limitation, and the maintenance of diversity in marine benthic communities.

Many terrestrial and marine systems are open to immigration. As such, the delivery of reproductive propagules should play a substantial role in determining local diversity in many systems. Here we present the results of a two-year experimental manipulation of subtidal flow regimes and show that flow has a strong positive effect on the assembly and maintenance of epifaunal invertebrate diversity by reducing recruitment limitation in two biogeographic regions. At two sites each in Alaska and Maine, USA, we experimentally manipulated flow speeds and measured the diversity of communities assembling through time and on recruitment panels scraped clean regularly. At all sites, the species richness of established communities, and the richness of recruitment into established communities and onto empty plates was >25% higher in enhanced flow than in control flow treatments. These effects were consistent for two years, and community diversity remained higher despite 30% higher species loss in enhanced flow treatments. Because communities remained open to immigration throughout the experiment, the data suggest that the diversity of epifaunal communities is strongly limited by recruitment and that supply-side effects on diversity in natural communities are strong. The positive effect of flow on diversity through a decrease in recruitment limitation was robust across scale, biogeographic region, and flow velocities and was consistent in magnitude in communities and on recruitment plates. Consequently, the data strongly suggest that the positive effects of flow on epifaunal diversity are persistent, can operate without diversity-enhancing positive feedback mechanisms, and are driven by increases in propagule delivery. Thus flow plays a large role in establishing and maintaining epifaunal diversity by mediating the delivery of propagules necessary to colonize a patch or to replace species within communities. Although our data do not preclude effects of interspecific interactions, they strongly suggest that flow plays a large and essentially untested role in determining the diversity of benthic marine communities, and they imply that flow is a key mechanism driving recruitment limitation in diverse aquatic systems.