Rose is sensitive to high temperature which will make the rose go into a semi-dormancy state. Grafting is an excellent way to enhance rose heat tolerance. Here, heat-tolerant Rosa multiflora ‘Huanong Wuci 1′ (W) and heat-sensitive Rosa chinensis ‘Old Blush′ (X) were selected as experimental materials. The RNA-seq technique was used to investigate the transcriptomes of self-root grafting line (XX0), heterogeneous grafting line (XW0), self-root grafting line under 6 h heat stress (XX6), and heterogeneous grafting line under 6 h heat stress (XW6). Under high temperature stress, multiple signaling pathways were activated, moreover, a large number of transcription factors and functional genes were induced, especially the HSFs and HSPs with remarkably upregulated expression levels. The GO analysis showed that the differences in the expressions of the genes related to fatty acids and carbohydrates were observed between self-root grafting line and heterogeneous grafting line. In addition, 14 P450s were differentially expressed, and one lectin gene was up-regulated in XW0 vs XW6, but down-regulated in XX0 vs XX6. Considering physiological and biochemical traits such as relative electrolyte leakage, SOD activity, proline, and total soluble sugars, DEGs involved in these processes may be key factors to resist high temperature. The present study provides an insight into the complex mechanism underlying grafting in response to heat stress. Our results indicate that grafting is an effective way to improve rose heat resistance.

Osmanthus fragrans is one of the top ten traditional flowers in China. It is divided into three different groups according to its color. α-Carotene and β-carotene are the main determinants to distinguish the color differences between three groups. However, the dominant genes and transcription factors involved in carotenoid metabolism remain unclear. CPTA treatment (0.7 mmol · L⁻¹) remarkably promoted lycopene, α-carotene and β-carotene contents in flowers. Transcriptome sequencing analysis revealed that CPTA treatment could trigger chain reactions in carotenoid metabolism pathway genes. Four up-regulated and 10 down-regulated transcription factors which have close association with carotenoid variation were significantly induced by CPTA treatment. The up-regulated TFs such as MYB43, MYB123, HSF, were further subjected to transcript expression determination in different cultivars with drastic colors. Among them, transcript expression of four up-regulated TFs coincided with the carotenoid accumulation in different cultivars. We selected up-regulated OfMYB43 to verify its function, which is related to stress tolerance and transcriptional regulation. Transient overexpression of OfMYB43 in O. fragrans flowers showed that it could remarkably promote the expression of PDS, ZISO, LCYE and CCD4, leading to increased accumulation of β-branch carotenoids. OfMYB43 was a potential positive regulator of carotenoid biosynthesis in O. fragrans flowers. This study provides insight into the molecular mechanism of carotenoid metabolism in O. fragrans.