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Plants from the eudicot Celastraceae family are primarily cultivated for ornamental use due to their colourful autumn foliage, and, as such, their chemical composition is rarely investigated. In total, 125 samples from, altogether, 40 shrub, vine and tree species (Catha, Celastrus, Euonymus, Gymnosporia, Maytenus, Parnassia, and Tripterygium) were investigated to confirm tocotrienol dominance in the family, which was observed in the initial screenings. The tocochromanol–tocopherol (T) and tocotrienol (T3) contents ranged from 3.04 to 66.22 mg 100 g⁻¹ dw. Almost all the samples were tocotrienol-dominated (50.1–98.5% of total tocochromanols), except for Parnassia. The two most prevalent compounds were γ-T3 and α-T3. Most Euonymus species’ seeds contained primarily α-T3 (16.2–86.0% of total tocochromanols) and tocopherol (up to 35.0%), while the other species had higher γ-T3 (36.0–87.2%) and tocopherol (up to 29.9%) contents, except the Parnassia samples, which contained primarily γ-T and δ-T. The highest total tocochromanol content was observed in E. scandens, but it was highly variable. The content of α-T3 was less variable than γ-T3 (coefficients of variation of 0.74 and 1.46, respectively). This study shows that tocotrienols are predominant in the Celastraceae family. A streamlined ethanolic extraction protocol was evaluated and deemed suitable for routine screening and, potentially, bioactive extraction. Full article

Hippophae rhamnoides subsp. sinensis is extensively found in China, where the annual precipitation ranges from 400 to 800 mm. It is the most dominant species in natural sea buckthorn forests and the primary cultivar for artificial ecological plantations. Additionally, it exhibits significant nutritional and medicinal value, making it a renowned eco-economic tree species. Despite extensive research into its ecological functions and health benefits, the mitochondrial genome of this widespread species has not yet been published, and knowledge of the mitochondrial genome is crucial for understanding plant environmental adaptation, evolution, and maternal inheritance. Therefore, the complete mitochondrial genome was successfully assembled by aligning third-generation sequencing data to the reference genome sequence using the Illumina NovaSeq 6000 platform and Nanopore Prometh ION technologies. Additionally, the gene structure, composition, repeat sequences, codon usage bias, homologous fragments, and phylogeny-related indicators were also analyzed. The results showed that the length of the mitochondrial genome is 454,489 bp, containing 30 tRNA genes, three rRNA genes, 40 PCGs, and two pseudogenes. A total of 411 C-to-U RNA editing sites were identified in 33 protein-coding genes (PCGs), with higher frequencies observed in ccmFn, ccmB, nad5, ccmC, nad2, and nad7 genes. Moreover, 31 chloroplast-derived fragments were detected, accounting for 11.86% of the mitochondrial genome length. The ccmB, nad4L, and nad7 genes related to energy metabolism exhibited positive selection pressure. The mitochondrial genome sequence similarity between H. rhamnoides subsp. sinensis and H. tibetana or H. salicifolia was 99.34% and 99.40%, respectively. Fifteen shared gene clusters were identified between H. rhamnoides subsp. sinensis and H. tibetana. Phylogenetically, the Rosales order showed close relationships with Fagales, Fabales, Malpighiales, and Celastrales. These findings provide fundamental data for exploring the widespread distribution of H. rhamnoides subsp. sinensis and offer theoretical support for understanding the evolutionary mechanisms within the Hippophae genus and the selection of molecular breeding targets. Full article