Capacity for protein synthesis following heat stimulus of Drosophila associates with heat tolerance but does not underlie the latitudinal tolerance cline

Across populations of Drosophila melanogaster along the Australian eastern coastline latitudinal clines occur in both heat-knockdown tolerance and hardened heat-knockdown tolerance – low latitude tropical populations being more tolerant. A latitudinal cline also occurs for rates of total protein synthesis following a mild heat stress, with tropical populations having higher rates. Since the control of protein synthesis following heat stress is an important component of the cellular heat-shock response, we hypothesised that the higher rates of synthesis that follow a heat stimulus lead to higher knockdown tolerance and underpins the cline. However, levels of heat-stimulated total protein synthesis have been negatively related to heat-hardening capacity, a somewhat conflicting result. Here we examine the relationship between these physiological and adaptive traits in a set of 40 family lines derived from a hybrid laboratory population established by crossing populations from either end of the latitudinal transect. Among these lines high levels of heat-stimulated total protein synthesis were associated with both low basal and low heat-hardened adult knockdown time, confirming the importance of a negative relationship between protein synthesis and thermal tolerance. This result, when considered along with the directions of the latitudinal clines in protein synthesis and tolerance, suggests that variation in rates of heat-stimulated total protein synthesis is not a factor contributing to the latitudinal cline in heat tolerance. Given the robustness of this negative relationship we discuss possible explanations and future experiments to elucidate how the cellular heat stress response might facilitate increased knockdown tolerance.     

Heritable variation in heat shock gene expression: a potential mechanism for adaptation to thermal stress in embryos of sea turtles

The capacity of species to respond adaptively to warming temperatures will be key to their survival in the Anthropocene. The embryos of egg-laying species such as sea turtles have limited behavioural means for avoiding high nest temperatures, and responses at the physiological level may be critical to coping with predicted global temperature increases. Using the loggerhead sea turtle (Caretta caretta) as a model, we used quantitative PCR to characterise variation in the expression response of heat-shock genes (hsp60, hsp70 and hsp90; molecular chaperones involved in cellular stress response) to an acute non-lethal heat shock. We show significant variation in gene expression at the clutch and population levels for some, but not all hsp genes. Using pedigree information, we estimated heritabilities of the expression response of hsp genes to heat shock and demonstrated both maternal and additive genetic effects. This is the first evidence that the heat-shock response is heritable in sea turtles and operates at the embryonic stage in any reptile. The presence of heritable variation in the expression of key thermotolerance genes is necessary for sea turtles to adapt at a molecular level to warming incubation environments.     

Genome-wide analysis of alternative splicing of pre-mRNA under salt stress in Arabidopsis

Background

Alternative splicing (AS) of precursor mRNA (pre-mRNA) is an important gene regulation process that potentially regulates many physiological processes in plants, including the response to abiotic stresses such as salt stress.

Results

To analyze global changes in AS under salt stress, we obtained high-coverage (~200 times) RNA sequencing data from Arabidopsis thaliana seedlings that were treated with different concentrations of NaCl. We detected that ~49% of all intron-containing genes were alternatively spliced under salt stress, 10% of which experienced significant differential alternative splicing (DAS). Furthermore, AS increased significantly under salt stress compared with under unstressed conditions. We demonstrated that most DAS genes were not differentially regulated by salt stress, suggesting that AS may represent an independent layer of gene regulation in response to stress. Our analysis of functional categories suggested that DAS genes were associated with specific functional pathways, such as the pathways for the responses to stresses and RNA splicing. We revealed that serine/arginine-rich (SR) splicing factors were frequently and specifically regulated in AS under salt stresses, suggesting a complex loop in AS regulation for stress adaptation. We also showed that alternative splicing site selection (SS) occurred most frequently at 4 nucleotides upstream or downstream of the dominant sites and that exon skipping tended to link with alternative SS.

Conclusions

Our study provided a comprehensive view of AS under salt stress and revealed novel insights into the potential roles of AS in plant response to salt stress.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-431) contains supplementary material, which is available to authorized users.     

Alternative splicing of Myb-related genes MYR1 and MYR2 may modulate activities through changes in dimerization,localization, or protein folding

Arabidopsis genes MYR1 and MYR2 are regulators of flowering time under low light intensity. These Myb-related genes are expressed as alternative splice variants affected in their coiled-coil and DNA-binding domains. We tested whether alternative splicing could affect dimerization and localization of MYR1 and MYR2, thereby potentially affecting their activity. Using MYR1 as a model for variants within the coiled-coil region, we detected 2 types of homodimers. For MYR2, alternative splicing in the DNA-binding Myb-like domain abolished the ability of MYR2 to dimerize. Alternative splicing in the coiled-coil domain did not affect nuclear localization, as determined by transient expression in tobacco, while alternative splicing in the DNA-binding domain of MYR2 yielded a distinct intranuclear localization pattern that may reflect changes in phosphorylation-dependent protein folding. Thus alternative splicing of these genes may result in changes in dimerization or protein folding resulting in changes in activity and abundance of MYR1 or MYR2 protein.     

The capacity of Drosophila to heat harden associates with low rates of heat-shocked protein synthesis

The thermotolerance of a species or of an ecotype is important for determining its habitat range and vigour, and considerable research has focused on identifying underlying physiological, biochemical and genetic bases of thermotolerance traits. Rates of protein synthesis in tissues when organisms experience a sudden heat stress as occurs on rare hot days may be important to avoid heat-induced paralysis and to survive. While natural variation in Drosophila melanogaster thermotolerance has been associated with heat-shock gene expression, little attention has been given to examining the thermo-protective role of protein synthesis generally. Using two independently derived sets of single-pair mating lines, we characterised variation in rates of protein synthesis in dissected ovarian tissues, both before and after a heat shock applied at different severities in the two sets. In both sets of lines heat-shocked protein synthesis rates were negatively associated with the increase in heat knockdown tolerance after hardening. These associations occurred in a different sex in each set. Variation in rates of Hsp70 synthesis failed to associate with levels of heat tolerance or general protein synthesis. Our results suggest heritable variation in the rate of protein synthesis following heat stress, independently of Hsp70 variation, contributes to heat tolerance variation in this species.