Search Results (201)

Anthocyanins, crucial water-soluble pigments in plants, determine coloration in floral and fruit tissues, while fulfilling essential physiological roles in terms of plant growth, development, and stress adaptation. The biosynthesis of anthocyanins is transcriptionally regulated by WRKY factors, one of the largest plant-specific transcription factor families. Euscaphis japonica is an East Asian species, prized for its exceptionally persistent butterfly-shaped fruits that undergo pericarp dehiscence, overturning, and a color transition to scarlet red. This species represents an ideal system for studying anthocyanin regulation. However, the mechanisms by which WRKY transcription factors orchestrate anthocyanin accumulation during this process remain unknown. In this study, we identified 87 WRKY genes (EjaWRKYs) from the E. japonica genome. Phylogenetic analysis was used to classify these genes into three primary groups, with five subgroups, revealing conserved gene structures and motif compositions, supported by collinearity and comparative synteny analyses. Crucially, ten EjaWRKYs exhibited peak expression during the mature fruit stages, showing positive correlations with key anthocyanin biosynthesis genes. Functional validation through the use of transient transactivation assays in Nicotiana benthamiana confirmed that the five selected EjaWRKYs bind W-box elements and strongly activate reporter gene expression. Our results reveal EjaWRKYs’ regulation of anthocyanin accumulation in E. japonica fruit, provide the first comprehensive WRKY family characterization of this species, and establish a foundation for manipulating ornamental traits in horticultural breeding. Full article

B-box (BBX) transcription factors are critical regulators of light-mediated anthocyanin biosynthesis, influencing peel coloration in plants. To explore their role in red mango cultivars, we identified 32 BBX genes (MiBBX1–MiBBX32) in the mango (Mangifera indica L.) genome using a genome-wide analysis. Phylogenetic and structural analyses classified these genes into five subfamilies based on conserved domains. A collinearity analysis revealed segmental duplication as the primary mechanism of MiBBX gene family expansion, with purifying selection shaping their evolution. A promoter analysis identified numerous light- and hormone-responsive cis-elements, indicating regulatory roles in the light and hormonal signaling pathways. Expression profiling in the ‘Sensation’ cultivar revealed organ-specific patterns, with several MiBBX genes showing higher expression in the peel than in the flesh. Many of these genes also consistently exhibited elevated expression in the peel of red-skinned cultivars (‘Sensation’ and ‘Guifei’) compared to yellow and green cultivars, suggesting their role in red peel pigmentation. Furthermore, postharvest light treatment of ‘Hongmang No. 6’ fruit significantly upregulated multiple MiBBX genes, suggesting their involvement in light-induced anthocyanin accumulation in red mango peel. These findings provide valuable insights into the molecular mechanisms governing light-regulated peel coloration in mango and establish a foundation for functional studies of MiBBX genes in fruit pigmentation. Full article

Melanin is a complex natural pigment that imparts a variety of colors to the fruiting bodies of edible fungi, influencing both their nutritional quality and commercial value. Stropharia rugosoannulata is an emerging type of edible fungus that has been widely cultivated in recent years. It can be categorized into red and yellow varieties based on cap color, while its pigment characteristics remain unclear. In this study, the melanins from the two varieties were obtained using an alkaline extraction and acid precipitation method, followed by comprehensive characterization of their chemical properties and ultrastructural features. Both melanins displayed distinct absorption maxima at approximately 211 nm. The melanin extracted from the red variety consisted of 55.63% carbon (C), 7.40% hydrogen (H), 30.23% oxygen (O), 5.99% nitrogen (N), and 0.64% sulfur (S), whereas the yellow variety comprised 52.22% C, 6.74% H, 29.70% O, 5.91% N, and 0.99% S. Both types of melanin included eumelanin and phaeomelanin forms, with eumelanin being the predominant type. Variations in the quantities and relative proportions of eumelanin and phaeomelanin contributed to the observed color differences in the mushroom caps. Ultrastructural micrographs revealed the melanins were primarily localized in the cell wall, consistent with findings in other fungal species. These findings contribute valuable insights into fundamental knowledge and potential applications of mushroom pigments. Full article

Flavonoids play a crucial role in plant development, resistance, and the pigmentation of fruits and flowers. This study aimed to uncover the mechanism of flavonoid biosynthesis and fruit coloring in muscadine grapes. Two muscadine genotypes (Paulk and Supreme) were investigated via metabolomic and transcriptomic analysis during three developmental stages (bunch closure, veraison stage, and ripening stage). A total of 314 flavonoids were identified, with flavones and flavonols being the primary constituents. The contents of many differentially accumulated metabolites (DAMs) were higher at the veraison stage. The total anthocyanin content was upregulated during berry development, with the dominant type of anthocyanidin-3,5-O-diglucoside. Proanthocyanins accumulated higher levels in the ripening stage of Paulk than Supreme. Transcriptomic analyses revealed that over 46% of the DEGs exhibited higher expression levels in the bunch closure stage. Moreover, phenylalanine ammonia-lyase (PAL), cinnamyl 4-hydroxylase (C4H), and coumaryl CoA ligase (4CL) genes were upregulated during berry development, suggesting they promote second metabolites biosynthesis. The upregulation of dihydroflavonol 4-reductase (DFR) and leucoanthocyanin reductase (LAR) may related to the higher levels of PA in Paulk. Anthocyanidin synthase (ANS) and UDP-glucose:flavonoid-3-O-glucosyltransferase (UFGT) showed higher expression levels in the ripening stage, which may relate to the accumulation of anthocyanidins. This study provides comprehensive insights into flavonoid metabolism and berry coloration in Vitis rotundifolia. Full article

Global fruit production is excessive, and fruit wine is a significant outcome of fruit processing. The pigment in fruit wine gives it a vibrant color and affects its quality, taste, and marketing. The pigments in fruit wines are commonly divided into three categories: anthocyanins, carotenoids, and chlorophylls. They are naturally synthesized pigments in plants that undergo complex biochemical changes that eventually tend to be stable in mature fruit wine, showing the color properties desired by consumers. Under normal circumstances, pigment molecules are unstable and have isomers, which makes it difficult to accurately identify and control them. In addition, biochemical changes produce a series of chemical derivatives that affect bioavailability and biological functions. This review summarizes the chemical basis, formation process, influencing factors, identification techniques, bioavailability, and bioactivity of fruit wine pigments, providing an important reference for the utilization of fruit resources and the development of high-quality fruit wine products. Full article

The transition to ripening in non-climacteric species is governed by several signals, including hormones that enhance or counteract the abscisic acid (ABA)-promoting effect. The SQUAMOSA Promoter-binding protein-Like (SPL) transcription factors are involved in ripening through the modulation of anthocyanin biosynthesis. In sweet cherry fruits, several miR156-targeted PavSPLs are expressed before and during ripening. Recently, some PavSPLs were found in the transition from development to ripening in cultivars contrasting in maturity time. Additionally, several forms of miR156 were expressed in sweet cherry seeds of an early-season cultivar. In this work, we addressed the relevance of endocarp lignification and PavSPLs expression for the transition to ripening. First, we characterized early- and late-season sweet cherry cultivars, ‘Celeste’ and ‘Regina’, focusing on fruit and seed development, endocarp lignification, and PavSPL expression profile. Fruit growth dynamics revealed an earlier onset of color development and lignification in ‘Celeste’, while ‘Regina’ exhibited a prolonged lag phase and delayed embryo development. Transcript profiling at the light green stage showed a higher expression of PavSPL genes in fruits and identified cultivar-specific expressions, especially between ‘Regina’ and ‘Celeste’ seeds. Co-expression networks linked PavSPLs to genes involved in lignin and anthocyanin biosynthesis. We focused on PavSPL2 and PavSPL9, which were targeted by mtr-miR156a and gma-miR156f. Both PavSPLs and miRNAs were expressed in fruits and seeds at the yellow stage, an advanced point in the transition to ripening in sweet cherry. Exogenous application of auxin-related compounds in the mid-season cultivar ‘Lapins’ modulated endocarp lignification and pigmentation. Notably, p-IBA treatment, which enzymatically targets the lignin pathway, transiently increased anthocyanin accumulation and reduced lignin deposition, effects that correlated with the downregulation of PavSPL gene expression. These findings highlight the interplay between lignification, color evolution, and pigment biosynthesis during the transition from development to ripening in sweet cherry fruits, and suggest a role for PavSPL genes in this transition. Full article

Anthocyanins, as natural pigments belonging to the flavonoid group, play a crucial role in plant reproduction, stress resistance and human fitness. Kiwifruit, which is rich in anthocyanins, demonstrates significant potential for promoting health benefits. Although light is widely recognized as an inducer of anthocyanin accumulation, we observed that kiwifruit accumulates more anthocyanin after bagging treatment. This unexpected finding suggests that anthocyanin biosynthesis in kiwifruit may also be regulated by other environmental or physiological factors influenced by bagging, such as humidity, temperature, or gas exchange. This implies that bagging may trigger specific regulatory pathways that promote anthocyanin accumulation through multiple environmental cues beyond light. Therefore, RNA-seq was performed to find the potential pathway. A total of 260 differentially expressed genes were found, including 8 transcription factors and 1 anthocyanin biosynthesis gene F3GT1 (glucosyltransferase). Dual-luciferase reporter assays revealed that bHLH transcription factors could activate the promoter of F3GT1 by 2.45-fold. We infer that bagging treatment increases the kiwifruit anthocyanin content through the bHLH291-F3GT1 pathway. This study not only highlights the potential agricultural applications and commercial value of bagging treatment but also provides new theoretical support for improving fruit coloration and optimizing breeding strategies. Full article

Fruit color serves as a crucial visual indicator in chili peppers and is closely linked to the bioactive components that determine their economic and nutritional value. However, the specific components and potential molecular mechanisms that impact fruits’ development and color changes are less thoroughly understood. Here, we utilized three chili pepper varieties (CS03, CS29, and L816) at different developmental stages (young fruit stage, turning color stage, and mature stage) as research materials and integrated transcriptome and non-targeted metabolome analyses to explore the variation in bioactive components and color to explain the molecular regulatory mechanisms underlying different colors of chili peppers during the young fruit stage. Our results showed that flavonoids were the most enriched differential metabolites; aromadendrin 4′-glucoside, diospyrin, precarthamin, kaempferol-3-O-rutinoside, and kaempferol-3-O-Glucoside were significantly enriched in the young fruit stage of pepper CS03; and cyanidin, delphinidin, and cyanidin 3-glucoside were major contributors to the color formation. The upregulation of anthocyanin was related to the structural genes CaC4H, Ca4CL, CaCHS, CaF3H, CaANS, and CaUFGT, and key transcription factors such as CaMYBs and CabHLHs may have contributed to the differential accumulation of anthocyanins in CS03; in addition, RT-qPCR validation was correlated with anthocyanins, but also with flavonoids. This article mainly focuses on the changes in chili pigments, particularly anthocyanins, and explores the molecular mechanisms involved. This provides a reference for research on color in solanaceae vegetables and lays a theoretical foundation for further research on the bioactive components of chili peppers, as well as for optimizing harvesting practices and dietary recommendations. Full article

The WRKY gene family is essential for controlling a variety of plant physiological functions, yet the involvement of specific WRKY members in pigment biosynthesis and accumulation in Camellia chekiangoleosa remains unexplored, particularly in anthocyanins and carotenoids, which play crucial roles in the pigmentation of C. chekiangoleosa. This study systematically identified 87 WRKY genes across 15 chromosomes in C. chekiangoleosa through bioinformatic approaches. Further structural and phylogenetic analyses of these TFs enabled their classification into six different subgroups. WRKY family expansion was shown to be mostly driven by tandem duplication. W-box elements, which can be binding sites for WRKY transcription factors, were present in a number of biosynthetic genes in the pigment production pathway. Yeast one-hybrid assay confirmed that five WRKY transcription factors (CchWRKY15/24/33/47/76) directly bind to the promoter regions of two key biosynthetic genes, CchPSY1 and Cch4CL1. Intriguingly, among the five WRKYs tested, the expression levels of CchWRKY15, CchWRKY33, and CchWRKY47 showed the strongest positive associations with flavonoid accumulation (p < 0.05, Pearson correlation analysis).These findings provide novel insights into the evolutionary patterns, transcriptional regulation, and functional characteristics of CchWRKYs, while elucidating their possible regulatory mechanisms in the fruit coloration of C. chekiangoleosa. Full article

Our multi-omics investigation of pepper fruit coloration dynamics demonstrates that the coordinated regulation of flavonoid accumulation and chlorophyll retention underpins the distinct pigmentation patterns between dark green (XHB) and light green (QL2017) cultivars. Through the integrated analysis of three developmental stages (10–30 DPA), we identified 989 differentially accumulated metabolites (DAMs) and 810 differentially expressed genes (DEGs), with flavonoid biosynthesis, phenylpropanoid metabolism, and chlorophyll turnover pathways pinpointed as central regulatory hubs. Notably, key metabolites such as quercitrin, kaempferol-3-O-rhamnoside, and cinnamic acid were significantly enriched in dark green fruits (XHB), coinciding with enhanced antioxidant activity and delayed chlorophyll degradation. Transcriptomic data revealed the coordinated upregulation of chlorophyll biosynthesis genes (COX15, POR) and light-harvesting complex components (Lhcb1, Lhcb2), while PAO—a pivotal chlorophyll catabolism gene—also exhibited elevated expression. Co-expression network analysis highlighted scopoletin GTase, F5H, CCR, and CAD as hub genes regulating flavonoid biosynthesis. qRT-PCR validation confirmed high consistency with transcriptomic trends (r > 0.85, p < 0.01). Our findings propose a synergistic model wherein flavonoid accumulation and chlorophyll metabolic dynamics jointly orchestrate green fruit pigmentation, offering novel insights and molecular targets for the precision breeding of pepper fruit coloration. Full article

Anthocyanins are key metabolites that determine red pigmentation in pear skin (Pyrus spp.) and their biosynthesis is controlled by multiple transcription factors. Although phytochrome-interacting factors (PIFs) of the bHLH family have been shown to regulate anthocyanin biosynthesis in Arabidopsis thaliana, their genome-wide identification and regulatory mechanisms in pear (Pyrus spp.) anthocyanin synthesis remain unclear. Here, we characterized PIFs family in pear, identifying eight PbPIF proteins. Promoter cis-elements and expression patterns analysis suggested that PbPIF3a and PbPIF4 might be involved in anthocyanin biosynthesis. Subcellular localization confirmed nuclear enrichment of PbPIF3a and PbPIF4. Functional studies demonstrated that overexpression of PbPIF3a and PbPIF4 significantly suppressed anthocyanin accumulation in fruit skins, downregulating key biosynthetic genes such as PbDFR and PbUFGT. In contrast, the silencing of related genes led to an enhancement of anthocyanin accumulation. Dual-luciferase reporter assays and yeast one-hybrid assays confirmed that PbPIF3a directly bound to the promoters of PbDFR and PbUFGT and repressed their transcriptional activation, while PbPIF4 specifically inhibited the activity of the PbDFR promoter. Taken together, we demonstrated that PbPIF3a and PbPIF4 negatively regulated pear fruit coloration by directly repressing the transcriptional activity of key anthocyanin biosynthesis genes, providing novel insights into PIF-mediated regulation of anthocyanin biosynthesis. Full article

The present study examined the effect of different cap management techniques, maceration length, and ethanol levels through chaptalization on the chemical and sensory composition of Syrah wines from the Edna Valley AVA in California. Punch down wines had significantly higher anthocyanins, tannins, and total polymeric pigments compared to all other treatments. In terms of volatile chemistry, the submerged cap wines tended to have a higher concentration of esters and terpenes compared to the other treatments. Additionally, ethanol levels were more impactful on the chemical composition of the wines. As expected, chaptalized wines had significantly higher ethanol and glucose + fructose levels but also tended to have higher concentrations of esters and terpenes. Sensory evaluation was done through a modification of the Pivot© Profile method using an expert panel of winemakers (n = 15). The results suggested that cap management and the maceration length were more impactful on the sensory profile than the ethanol level whereby each cap management and maceration length treatment had a distinctive profile. As such, the punch down, chaptalized wines showed higher purple hue and color saturation attributes, blueberry orthonasal aromas as well as jammy and black fruit retronasal aromas. Submerged cap wines were associated with significantly meatier orthonasal aromas and reductive retronasal aromas. Extended maceration wines were characterized by more jammy orthonasal aromas and dried fruit retronasal aromas. However, within the extended maceration wines, the effect of chaptalization was apparent whereby the chaptalized wines showed more acetaldehyde aromas while the non-chaptalized wines were characterized by more herbal aromas. Full article

Anthocyanins play a pivotal role in determining the color diversity in the flowers and fruits of Cerasus humilis (Bge.) Sok. This study performed a metabolomic analysis of the flowers and fruits of two varieties differing in pigmentation phenotypes (‘Jinou 1’ and ‘Nongda 5’), and the results indicated that the cyanidin, pelargonidin, paeonidin, and delphinidin were the main substances serving as the primary pigments contributing to their striking chromatic divergence between two varieties. Transcriptome profiling revealed that several key structural genes (ChCHS1, ChDFR, ChF3H, and ChF3’H) in the anthocyanin biosynthesis pathway exhibited significantly elevated expression levels in ’Jinou 1’ compared to ’Nongda 5’. Further metabolomic and transcriptomic correlation analyses identified that ChMYB9 and ChMYB12 exhibited strong positive associations with anthocyanin pathway metabolites in both floral and fruit tissues. Notably, ChMYB9 displayed the strongest correlation with the metabolite profiles, suggesting it may serve as a core regulatory component of the anthocyanin biosynthesis. This research provides new insights into the regulatory mechanisms of anthocyanin biosynthesis in C. humilis. Full article

Pigments in plants not only determine their visual characteristics but also play crucial roles in photosynthesis, pollinator attraction, and disease resistance. The diverse colors of chili peppers arise from various pigments. However, detailed reports on the genetic and metabolic changes of these pigments in the developmental stages of colorful chili peppers are limited. In this study, we analyzed the content of anthocyanins and carotenoids in the fruits of the cultivated pepper variety H18 at different growth and development stages. Our findings revealed that, as the fruits mature, the anthocyanin content gradually decreases while the carotenoid content increases. Using the transcriptomic and metabolomic sequencing of pepper fruits at various developmental stages, we identified four types of anthocyanins: pelargonidin, cyanidin, delphinidin, and peonidin, as well as a small amount of proanthocyanidins. The concentrations of these anthocyanins generally showed a decreasing trend, and the expression patterns of anthocyanin biosynthesis genes were consistent with the metabolic data. In the analysis of carotenoids, we found that, apart from Lutein, the concentrations of all other detected carotenoids increased during fruit development. Most carotenoids began to accumulate significantly at the orange fruit stage (H18-O) and peaked at the red fruit stage (H18-R). Transcriptomic and RT-qPCR data indicated that the expression of carotenoid biosynthesis genes also increased progressively. Furthermore, we investigated the degradation of anthocyanins and identified potential degradation genes, including BGLU, POD, and PPO. This study provides deep insights into the mechanisms underlying pigment changes in colorful peppers, which may contribute to the improvement of pepper varieties and future research on pigment regulatory mechanisms. Full article

In this research, the impact of the pulsed electric fields (PEF) pretreatment on the infrared–convective drying (IR-CD) of apples and selected quality indicators (antioxidant capacity, color, and total phenolic content) of dried apples was evaluated. PEF pretreatment was carried out at the following parameters: electric field strength of 1 kV/cm, specific energy inputs of 1, 3.5, and 6 kJ/kg. Moreover, variable IR-CD process parameters were also assessed (peak wavelength of 1.2 µm, distance between the infrared lamps and the apple slices of 10, 20, and 30 cm). PEF pretreatment, by disintegrating apple cells, reduced the drying time of that fruit by 11–20%. The IR-CD of apples was the most effective at the shortest distance (10 cm) between the infrared source and the apple slices; it was associated with the intense heating of its surface. PEF-pretreated samples exhibited lower retention of antioxidants and were darker and redder than untreated ones. PEF could increase the activity of enzymes responsible for oxidizing phenolic compounds to brown pigments. The use of a medium distance (20 cm) during IR-CD promoted the highest retention of antioxidant compounds (relatively prompt drying with moderate heating of the sample surface). Full article