Different mechanisms for Arabidopsis thaliana hybrid necrosis cases inferred from temperature responses.

Temperature is a major determinant of plant growth, development and success. Understanding how plants respond to temperature is particularly relevant in a warming climate. Plant immune responses are often suppressed above species-specific critical temperatures. This is also true for intraspecific hybrids of Arabidopsis thaliana that express hybrid necrosis due to inappropriate activation of the immune system caused by epistatic interactions between alleles from different genomes. The relationship between temperature and defence is unclear, largely due to a lack of studies that assess immune activation over a wide range of temperatures. To test whether the temperature-based suppression of ectopic immune activation in hybrids exhibits a linear or non-linear relationship, we characterised the molecular and morphological phenotypes of two different necrotic A. thaliana hybrids over a range of ecologically relevant temperatures. We found both linear and non-linear responses for expression of immunity markers and for morphological defects depending on the underlying genetic cause. This suggests that the influence of temperature on the trade-off between immunity and growth depends on the specific defence components involved.

MYC activity is negatively regulated by a C-terminal lysine cluster.

The MYC oncogene is not only deregulated in cancer through abnormally high levels of expression, but also through oncogenic lesions in upstream signalling cascades. Modelling MYC deregulation using signalling mutants is a productive research strategy. For example, the MYC threonine-58 to alanine substitution mutant (T58A) within MYC-homology box 1 is more transforming than wild-type (WT) MYC, because of decreased apoptosis and increased protein stability. Understanding the regulatory mechanisms controlling T58 phosphorylation has led to new approaches for the development of MYC inhibitors. In this manuscript, we have extensively characterized a MYC signalling mutant in which six lysine residues near the highly conserved MYC homology box IV and basic region have been substituted to arginines (6KR). Previous literature suggests these lysines can undergo both ubiquitylation and acetylation. We show MYC 6KR is able to fully rescue the slow growth phenotype of HO15.19 MYC-null fibroblasts, and promote cell cycle entry of serum-starved MCF10A cells. Remarkably, 6KR increased anchorage-independent colony growth compared with WT MYC in both SH-EP and MCF10A cells. Moreover, it was also more potent in promoting xenograft tumour growth of Rat1A and SH-EP cells. Combined, our data identify this region and these six lysines as important residues for the negative regulation of MYC-induced transformation. Mechanistically, we demonstrate that, unlike T58A, the increased transformation is not a result of increased protein stability or a reduced capacity for 6KR to induce apoptosis. Through expression analysis and luciferase reporter assays, we show that 6KR has increased transcriptional activity compared with WT MYC. Combined, through a comprehensive evaluation across multiple cell types, we identify an important regulatory region within MYC. A better understanding of the full scope of signalling through these residues will provide further insights into the mechanisms contributing to MYC-induced tumorigenesis and may unveil novel therapeutic strategies to target Myc in cancer.