Thermal preference increases during larval development of pure and hybrid abalone

Temperature is one of the main factors influencing biological processes of ectothermic species. An optimum temperature of 16–18°C has been suggested for the development of early life stages of temperate Australian abalone, yet there are little physiological or behavioral data to support this suggestion. This study examines the acute thermal preferences (Tpref), swimming speeds (U), and oxygen consumption rates (ṀO2) of veliger larvae of blacklip abalone [Haliotis rubra (Leach, 1814)], greenlip abalone [Haliotis laevigata (Donovan, 1808)], and their interspecies hybrid. Thermal preference and U were measured in a thermal gradient with temperatures ranging from 12°C to 25°C, and ṀO2 was measured at 4–7 temperatures between 12°C and 32°C. Thermal preference increased in all three groups of abalone during development from a Tpref of 16°C in 1-day-old early veligers to a Tpref of 20°C in 3-day-old late veligers. Swimming speed increased with temperature in all three groups of abalone and increased with age in H. rubra and hybrids but not in H. laevigata. Veliger ṀO2 increased throughout the ecologically relevant temperature range in all three abalone groups. Higher temperatures were examined in hybrids, and it was found that ṀO2 reached a peak at 25°C and declined thereafter. These results align with the temperatures that veligers may experience in their natural habitat and provide support that current temperatures maintained at Australian aquaculture hatcheries are within optimal ranges for larval performance

Testing Ecological Theory with Lianas

Lianas constitute a diverse polyphyletic plant group that is advancing our understanding of ecological theory. Specifically, lianas are providing new insights into the mechanisms that control plant distribution and diversity maintenance. For example, there is now evidence that a single, scalable mechanism may explain local, regional, and pan‐tropical distribution of lianas, as well as the maintenance of liana species diversity. The ability to outcompete trees under dry, stressful conditions in seasonal forests provides lianas a growth advantage that, over time, results in relatively high abundance in seasonal forests and low abundance in aseasonal forests. Lianas may also gain a similar growth advantage following disturbance, thus explaining why liana density and diversity peak following disturbance at the local, forest scale. The study of ecology, however, is more than the effect of the environment on organisms; it also includes the effects of organisms on the environment. Considerable empirical evidence now indicates that lianas substantially alter their environment by consuming resources, suppressing tree performance, and influencing emergent properties of forests, such as ecosystem functioning, plant and animal diversity, and community composition. These recent studies using lianas are transcending classical tropical ecology research and are now providing novel insights into fundamental ecological theory

Developmental hypoxia has negligible effects on long-term hypoxia tolerance and aerobic metabolism of Atlantic salmon (Salmo salar)

Exposure to developmental hypoxia can have long-term impacts on the physiological performance of fish because of irreversible plasticity. Wild and captive-reared Atlantic salmon (Salmo salar) can be exposed to hypoxic conditions during development and continue to experience fluctuating oxygen levels as juveniles and adults.Here,we examine whether developmental hypoxia impacts subsequent hypoxia tolerance and aerobic performance of Atlantic salmon. Individuals at 8°C were exposed to 50% (hypoxia) or 100% (normoxia) dissolved oxygen (DO) saturation (as percent of air saturation) from fertilization for ∼100 d (800 degree days) and then raised in normoxic conditions for a further 15mo. At 18mo after fertilization, aerobic scope was calculated in normoxia (100% DO) and acute (18 h) hypoxia (50% DO) from the difference between the minimum and maximum oxygen consumption rates (ṀO2 min and ṀO2 max, respectively) at 107°C. Hypoxia tolerance was determined as the DO at which loss of equilibrium (LOE) occurred in a constantly decreasing DO environment. There was no difference in ṀO2 min, ṀO2 max, or aerobic scope between fish raised in hypoxia or normoxia. There was some evidence that hypoxia tolerance was lower (higher DO at LOE) in hypoxiaraised fish compared with those raised in normoxia, but the magnitude of the effect was small (12.52% DO vs. 11.73% DO at LOE). Acute hypoxia significantly reduced aerobic scope by reducing ṀO2 max, while ṀO2 min remained unchanged. Interestingly, acute hypoxia uncovered individual-level relationships between DO at LOE and ṀO2 min, ṀO2 max, and aerobic scope. We discuss our findings in the context of developmental trajectories and the role of aerobic performance in hypoxia tolerance

The Lesser Known Challenge of Climate Change: Thermal Variance and Sex-Reversal in Vertebrates with Temperature-Dependent Sex Determination

Climate change is expected to disrupt biological systems. Particularly susceptible are species with temperature-dependent sex determination (TSD), as in many reptiles. While the potentially devastating effect of rising mean temperatures on sex ratios in TSD species is appreciated, the consequences of increased thermal variance predicted to accompany climate change remain obscure. Surprisingly, no study has tested if the effect of thermal variance around high-temperatures (which are particularly relevant given climate change predictions) has the same or opposite effects as around lower temperatures. Here we show that sex ratios of the painted turtle (Chrysemys picta) were reversed as fluctuations increased around low and high unisexual mean-temperatures. Unexpectedly, the developmental and sexual responses around female-producing temperatures were decoupled in a more complex manner than around male-producing values. Our novel observations are not fully explained by existing ecological models of development and sex determination, and provide strong evidence that thermal fluctuations are critical for shaping the biological outcomes of climate change

The effects of constant and cyclical hypoxia on the survival, growth and metabolic physiology of incubating Atlantic salmon (Salmo salar)

Salmonids reared in aquaculture incubation systems are susceptible to periods of cyclical or fluctuating hypoxia caused by embryo crowding, water flow rates and management protocols. Hypoxia during early development can reduce salmon growth, development and survival, and delay hatching, potentially impacting future performance and survival in subsequent phases of life. However, salmon embryos can also limit the effects of hypoxia by metabolic depression, premature hatching or physiological modifications to improve oxygen delivery. Here, we investigated the effects of constant and cyclical hypoxia on the growth, development, hatching, survival, oxygen uptake rate (ṀO2) and hypoxia tolerance (O2crit) of Atlantic salmon (Salmo salar) from fertilisation, through hatching, until 113 days post-fertilisation (DPF). We incubated salmon in either normoxia (100% dissolved oxygen [DO; as percent air saturation]), moderate hypoxia (∼63% DO), severe hypoxia (∼27% DO) or cyclical hypoxia (∼100-25% DO daily). At the eyed-egg stage routine oxygen uptake (ṀO2rout) was reduced by ~20% in salmon from the cyclical and moderate hypoxia treatments, although reduced ṀO2rout was not associated with a reduction in O2crit. Moderate hypoxia did not affect growth, development, survival or hatching. However, at 113 DPF cyclical hypoxia-incubated salmon were ∼12% smaller and developmentally delayed by ∼5 days compared to normoxia-incubated salmon as a result of reduced growth and development prior to the eyed-egg stage (∼39 DPF). Survival was unaffected by moderate or cyclical hypoxia, but hatching was delayed by ∼2-3 days in cyclical hypoxia incubated salmon. Severe hypoxia produced deformed embryos, greatly decreased growth and development and resulted in 99.3% mortality by 113 DPF. This study demonstrates that Atlantic salmon have a considerable capacity to survive daily bouts of extreme hypoxia, however, the consequent reductions in growth, development and hatching may still have implications in aquaculture systems

Living on the Edge of Two Changing Worlds: Forecasting the Responses of Rocky Intertidal Ecosystems to Climate Change

Long-term monitoring shows that the poleward range edges of intertidal biota have shifted by as much as 50 km per decade, faster than most recorded shifts of terrestrial species. Although most studies have concentrated on species-range edges, recent work emphasizes how modifying factors such as regional differences in the timing of low tide can overwhelm large-scale climatic gradients, leading to a mosaic of environmental stress. We discuss how changes in the mean and variability in climatic regimes, as modified by local and regional factors, can lead to complex patterns of species distribution rather than simple range shifts. We describe how ecological forecasting may be used to generate explicit hypotheses regarding the likely impacts of different climatic change scenarios on the distribution of intertidal species and how related hindcasting methods can be used to evaluate changes that have already been detected. These hypotheses can then be tested over a hierarchy of temporal and spatial scales using coupled field and laboratory-based approaches