Copepods are one of the most abundant invertebrate groups in the seas and oceans and are a significant food source for marine animals. Copepods are also particularly sensitive to elevated temperatures. However, it is relatively unknown the role of the internal microbiome in shaping copepod susceptibility to warming. We addressed this fundamental knowledge gap by assessing key life history traits (survival, development, reproduction), and changes in the internal microbiome in the tropical calanoid copepod Acartia sp. in response to warming (26, 30, and 34°C). Copepod microbiomes were analyzed using high throughput DNA sequencing of V1–V9 of 16S rRNA hypervariable regions. Copepod performance was better at 30°C than at 26°C as indicated by higher survival, faster growth rate and development, and higher fecundity. However, these parameters strongly decreased at 34°C. We recorded 1,262,987 amplicon sequence reads, corresponding to 392 total operational taxonomic units at 97% similarity. The copepod microbiomes contained Proteobacteria, Bacteroidetes, Planctomycetes, Actinobacteria, and Acidobacteria. Importantly, the internal microbiota biodiversity was strongly reduced at higher temperatures. The highest number of OTUs was obtained at 26°C (126/392 OTUs), and the lowest was at 34°C (31/392 OTUs). The thermophilic Proteobacteria was dominant under elevated temperatures (30°C and 34°C). At 34°C, Vibrio accounted for 70% of bacterial species in copepods. The reduced OTUs number with an increased relative abundance of Vibrio seemed to be related to the reduced copepod growth and survival. Profiling the functional role of all internal bacterial groups as a function of the temperature change will fundamentally advance our mechanistic understanding of the performance of tropical copepods and, more generally, marine invertebrates to a warming climate.

A document by Quyen Vu. Click on the document to view its contents.

Marine heatwaves (MHWs) emerge as a severe stressor in marine ecosystems. Extreme warm sea surface temperatures during MHWs are often beyond the optimal thermal range and beyond one generation of tropical coastal zooplankton. However, it is relatively unknown whether transgenerational MHW effect may shape the offspring fitness, particularly in an ecologically relevant context with biotic interactions such as predation stress. We addressed these novel research questions by quantifying the reproductive success, grazing, and survival of copepod Pseudodiaptomus incisus exposed to MHW and fish predator cues (FPC) for two generations (F1 and F2). There were four F1 treatments [(control or F1-MHW) × (no FPC or F1-FPC)] and 16 F2 treatments [(control or F1-MHW) × (no F1-FPC or F1-FPC)] × [(control or F2-MHW × no F2-FPC or F2-FPC)]. In both generations, P. incisus performance was substantially lowered in MHW, but slightly higher in FPC, particularly in control temperature. F2 reproductive success and cumulative faecals were reduced by 20-30% in F1-MHW, but increased by ~2% in F1-FPC. Strikingly, direct MHW exposure strongly reduced survival, but transgenerational MHW exposure ameliorated its lethal effect and was independent of FPC. The increased survival came with a cost of reduced reproductive success, constrained by reduced grazing. The rapid transgenerational MHW acclimation and its associated costs are likely widespread and crucial mechanisms underlying the resilience of coastal tropical zooplankton to MHWs under high predation pressure in the tropical coastal marine ecosystems.