Thermal plasticity of growth and chain formation of the dinoflagellates Alexandrium affine and Alexandrium pacificum with respect to ocean acidification

The amount of CO2 absorbed by the oceans continues to rise, resulting in further acidification, altering some functional traits of phytoplankton. To understand the effect of elevated partial pressures of CO2 (pCO2) on functional traits of dinoflagellates Alexandrium affine and A. pacificum, the cardinal temperatures and chain formation extent were examined under two pCO2 (400 and 1,000 μatm) over the range of temperature expected to be associated with growth. The growth rate and chain formation extent of A. affine increased with higher pCO2, showing significant changes in cardinal temperatures and a substantial increase in middle chain-length (4‒8 cells) fractionation under elevated pCO2 condition. By contrast, there were no significant differences in specific growth rate and any chain-length fractionation of A. pacificum between ambient and elevated pCO2 conditions. The observed interspecies variation in the functional traits may reflect differences in ability of species to respond to environmental change with plasticity. Moreover, it allows us to understand the shifting biogeography of marine phytoplankton and predict their phenology in the Korea Strait.

Limited thermal plasticity may constrain ecosystem function in a basally heat tolerant tropical telecoprid dung beetle, Allogymnopleurus thalassinus (Klug, 1855)

Tropical organisms are more vulnerable to climate change and associated heat stress as they live close to their upper thermal limits (UTLs). UTLs do not only vary little across tropical species according to the basal versus plasticity ‘trade-off’ theory but may also be further constrained by low genetic variation. We tested this hypothesis, and its effects on ecosystem function using a diurnally active dung rolling beetle (telecoprid), Allogymnopleurus thalassinus (Klug, 1855) that inhabits arid environments. Specifically, (i) we tested basal heat tolerance (critical thermal maxima [CTmax] and heat knockdown time [HKDT]), and (ii) ecological functioning (dung removal) efficiency following dynamic chronic acclimation temperatures of variable high (VT-H) (28–45 °C) and variable low (VT-L) (28–16 °C). Results showed that A. thalassinus had extremely high basal heat tolerance (> 50 °C CTmax and high HKDT). Effects of acclimation were significant for heat tolerance, significantly increasing and reducing CTmax values for variable temperature high and variable temperature low respectively. Similarly, effects of acclimation on HKDT were significant, with variable temperature high significantly increasing HKDT, while variable temperature low reduced HKDT. Effects of acclimation on ecological traits showed that beetles acclimated to variable high temperatures were ecologically more efficient in their ecosystem function (dung removal) compared to those acclimated at variable low temperatures. Allogymnopleurus thalassinus nevertheless, had low acclimation response ratios, signifying limited scope for complete plasticity for UTLs tested here. This result supports the ‘trade-off’ theory, and that observed limited plasticity may unlikely buffer A. thalassinus against effects of climate change, and by extension, albeit with caveats to other tropical ecological service providing insect species. This work provides insights on the survival mechanisms of tropical species against heat and provides a framework for the conservation of these natural capital species that inhabit arid environments under rapidly changing environmental climate.

Divergent phenotypic plasticity of a convergent Mendelian trait in Drosophila

In Drosophila, comparisons of the thermal plasticity of pigmentation across serially homologous abdominal segments have been conducted in two species, namely Drosophila melanogaster and D. kikkawai. Pigmentation variation has different genetic architecture in the two species, being oligogenic in the former and monogenic in the later. Here, we analyze the thermal plasticity of abdominal pigmentation in a third species, D. erecta, which is phylogenetically close to D. melanogaster but like D. kikkawai has a monogenic basis for pigmentation variation. However, the underlying locus differs between D. erecta and D. kikkawai, being the X-linked melanin-synthesis gene tan in the former and the autosomal transcription factor pdm3 in the later. We found that in spite of a low overall plasticity in monogenic species compared to D. melanogaster, the two monogenic species showed divergent plasticity patterns in respect to the response to temperature and to the degree of dominance in heterozygotes. Those results provide new insights on the dependence of the degree of plasticity on the genetic architecture as well as on the extent of phenotypic convergence.

Thermal plasticity in behavioural traits mediates mating and reproductive dynamics in an ectotherm

Global changes in temperature potentially influence sexual selection by restricting opportunities for activity. However, explicit tests of the behavioural mechanisms linking thermal variation to mating and reproductive performance are rare. We address this gap in a temperate lizard by combining social network analysis with molecular pedigree reconstruction in a large-scale thermal manipulation experiment. Populations exposed to a more restrictive (cooler) thermal regime presented fewer high activity days compared to populations exposed to a warmer regime. While plasticity in thermal activity responses masked overall differences in activity levels, prolonged restriction nevertheless affected the timing and consistency of male-female interactions. Less active females in the cool thermal regime were significantly less likely to reproduce, which subsequently limited male mating. Surprisingly, this did not correspond to a heightened intensity of sexual selection or shifts in the targets of sexual selection. Thus, populations facing thermal activity restriction may possess limited potential for evolutionary response.

Jack, Master or Both? The Invasive Ladybird Harmonia Axyridis Outperforms Its Native Counterpart Despite Similar Levels of Plasticity

The plasticity of performance traits is expected to promote the successful invasion of species. Therefore, the comparison of reaction norms of invasive species with native competitors should enhance predictions of alien species establishment. Yet, most studies focus on a reduced set of traits, rarely in combination, or do not include trait variability to make predictions of establishment success. Here, we acclimated individuals to a cold, medium or warm temperature regime and measured critical thermal limits, life-history traits, and starvation resistance of the globally invasive Harmonia axyridis and its native counterpart Cheilomenes lunata. The native C. lunata had higher thermal plasticity of starvation resistance and higher upper thermal tolerance than H. axyridis. By contrast, H. axyridis outperformed C. lunata in most life-history traits. We combined trait responses, transport duration and propagule pressure to simulate the final number of beetles established in the introduced site in cold, medium and warm scenarios, where beetles also experienced a heatwave once established. Although C. lunata initially outcompeted the invasive species during transport, more H. axyridis survived in all environments because of higher life-history trait responses, in particular, higher fecundity. Despite increased starvation mortality in the warm scenario, H. axyridis established successfully given sufficient propagule size. By contrast, in the event of a heatwave, H. axyridis numbers plummeted and higher numbers of the native species established in the cold scenario. This study underscores the importance of considering a combination of traits and respective cascading effects when estimating the establishment potential of species and responses to climate warming.

Plasma Membrane Fluidity: An Environment Thermal Detector in Plants

The lipid matrix in cell membranes is a dynamic, bidimensional array of amphipathic molecules exhibiting mesomorphism, which contributes to the membrane fluidity changes in response to temperature fluctuation. As sessile organisms, plants must rapidly and accurately respond to environmental thermal variations. However, mechanisms underlying temperature perception in plants are poorly understood. We studied the thermal plasticity of membrane fluidity using three fluorescent probes across a temperature range of −5 to 41 °C in isolated microsomal fraction (MF), vacuolar membrane (VM), and plasma membrane (PM) vesicles from Arabidopsis plants. Results showed that PM were highly fluid and exhibited more phase transitions and hysteresis, while VM and MF lacked such attributes. These findings suggest that PM is an important cell hub with the capacity to rapidly undergo fluidity modifications in response to small changes of temperatures in ranges spanning those experienced in natural habitats. PM fluidity behaves as an ideal temperature detector: it is always present, covers the whole cell, responds quickly and with sensitivity to temperature variations, functions with a cell free-energy cost, and it is physically connected with potential thermal signal transducers to elicit a cell response. It is an optimal alternative for temperature detection selected for the plant kingdom.