Current insights into posttranscriptional regulation of fleshy fruit ripening

Molecular mechanisms driving the unusual pigmentation shift during eggplant fruit development

Fruit pigmentation is a major signal that attracts frugivores to enable seed dispersal. In most fleshy fruit, green chlorophyll typically accumulates early in development and is replaced by a range of pigments during ripening. In species such as grape and strawberry, chlorophyll is replaced by red anthocyanins produced by the flavonoid biosynthetic pathway. Eggplant (Solanum melongena) is unique, as its fruit accumulates anthocyanins beginning from fruit set, and these are later replaced by the yellow flavonoid-pathway intermediate naringenin chalcone. To decipher the genetic regulation of this extraordinary pigmentation shift, we integrated mRNA and microRNA (miRNA) profiling data obtained from developing eggplant fruit. We discovered that SQUAMOSA PROMOTER BINDING-LIKE (i.e., SPL6a, SPL10, and SPL15), MYB1, and MYB2 transcription factors (TFs) regulate anthocyanin biosynthesis in early fruit development, whereas the MYB12 TF controls later accumulation of naringenin chalcone. We further show that miRNA157 and miRNA858 negatively regulate the expression of SPLs and MYB12, respectively. Taken together, our findings suggest that opposing and complementary expression of miRNAs and TFs controls the pigmentation switch in eggplant fruit skin. Intriguingly, despite the distinctive pigmentation pattern in eggplant, fruit development in other species makes use of homologous regulatory factors to control the temporal and spatial production of different pigment classes.

Phosphorylation of the strawberry MADS-box CMB1 regulates ripening via the catabolism of abscisic acid

Research on the ripening of fleshy fruits has relied on techniques that measure transcriptional changes. How ripening is linked to posttranslational modifications such as protein phosphorylation remains less studied. Here, we characterize the MADS-box SEPALLATA 4 (SEP4) subfamily transcription factor FaCMB1, a key negative regulator controlling strawberry ripening, whose transcript and protein abundance decrease progressively with fruit development and are repressed by abscisic acid (ABA). Transient RNAi or overexpression of FaCMB1 significantly altered the fruit ripening process and affected the content of endogenous ABA and ripening-related quality. Transcriptome sequencing (RNA-seq) analysis suggested that manipulation of FaCMB1 expression levels affected the transcription of FaASR (ABA-, stress-, ripening-induced), while FaCMB1 can repress the gene expression of FaASR by directly binding to its promoter. Furthermore, FaASR inhibited the transcriptional activity of FaCYP707A4, a key ABA 8'-hydroxylase enzyme involved in ABA catabolism. We show that FaCMB1 can be phosphorylated by the kinase FaSTPK, and Phos-tag assays indicated that the phosphorylation level of FaCMB1 increases during fruit ripening. This phosphorylation of FaCMB1 affects the binding ability of FaCMB1 to the FaASR promoter and alleviates its transcriptional repression. In conclusion, we elucidated a feedback regulatory path involving FaCMB1-FaASR-FaCYP707A4-ABA. During the fruit ripening process, an increase in ABA content led to a decrease in FaCMB1 transcript and protein levels, which, combined with increased phosphorylation levels, collectively impaired the transcriptional repression of FaASR by FaCMB1. Meanwhile, the increased transcriptional level of FaASR further repressed the expression level of FaCYP707A4, leading to ABA accumulation and fruit ripening.

Identification and Functional Exploration of the ALKBH Gene Family in Oriental Melon Fruit Ripening

N6-methyladenosine (m6A) methylation functions as a vital post-transcriptional and epigenetic modification in higher plants regulated by α-ketoglutarate-dependent dioxygenases (ALKBH). However, the role of ALKBH genes in oriental melon (Cucumis melo L.) fruit ripening has not been explored. Therefore, we treated oriental melon with an exogenous m6A demethylase inhibitor (mechlorfenamic acid) then analyzed endogenous ethylene production and ripening-related indicators to explore the effects of m6A methylation on ripening. Bioinformatics and real-time quantitative PCR analyses were used to determine the impact of ALKBH genes on key ethylene synthesis gene expression. Treatment effectively inhibited endogenous ethylene production, firmness changes, and soluble solid contents, thereby extending fruit ripening. Eight ALKBH gene family members belonging to five major groups were identified in the melon genome. All members were expressed in ripening fruits, with different expression patterns during ripening. CmALKBH6, CmALKBH7, and CmALKBH8 expression was inhibited by an ethylene inhibitor (1-methylcyclopropene). The transient overexpression (OE) of CmALKBH8 in oriental melon led to the increased expression of the ethylene synthesis genes CmACS1, CmACS2, and CmACO1. In summary, the ethylene-regulated gene CmALKBH8 may participate in oriental melon fruit ripening regulation by modulating the methylation levels of ethylene synthesis-related genes. These findings help us better understand how m6A methylation regulates melon ripening.

Ethylene-Activated E3 Ubiquitin Ligase MdEAEL1 Promotes Apple Fruit Softening by Facilitating the Dissociation of Transcriptional Repressor Complexes

Fruit of most apple varieties soften after harvest, and although the hormone ethylene is known to induce softening, the associated pathway is not well resolved. In this study, it is determined that MdEAEL1 (Ethylene-activated E3 ubiquitin Like 1) is specifically expressed during apple fruit postharvest storage, activated by ethylene, and interacts with the transcription factor MdZFP3 (zinc finger protein3). MdZFP3 is found to rely on an EAR (ethylene-responsive element binding factor-associated amphiphilic repression) motif to form a transcriptional repression complex with MdTPL4 (TOPLESS4)-MdHDA19 (histone deacetylase19), thereby downregulating the histone acetylation levels of the promoters of a range of cell wall degradation-related genes and inhibiting their transcription. MdEAEL1 ubiquitinates and degrades MdZFP3, leading to the disassembly of the MdZFP3-MdTPL4-MdHDA19 transcriptional repression complex. This process promotes the transcription of cell wall degradation-related genes, resulting in fruit softening during storage. Furthermore, the disassembly of the MdZFP3-MdTPL4-MdHDA19 transcriptional repression complex, mediated by MdEAEL1, upregulates the transcription of MdEAEL1 itself, creating a feedback loop that further promotes softening. This study elucidates the interplay between post-translational modifications of a transcription factor and its epigenetic modification to regulate fruit softening, and highlights the complexity of ethylene-induced softening.

The transcription factors AdNAC3 and AdMYB19 regulate kiwifruit ripening through brassinosteroid and ethylene signaling networks

The pivotal role of ethylene (ETH) in fruit ripening has been extensively studied; however, the function of brassinosteroids (BRs) in regulating fruit ripening remains poorly understood. Specifically, the mechanism by which BRs interact with ETH to affect kiwifruit (Actinidia deliciosa) ripening is unclear. Our research showed that 2 genes encoding transcription factors, AdNAC3 and AdMYB19, and the fruit softening gene AdEXP3 (encoding a cell wall expansion protein, expansin 3) were upregulated by ETH and downregulated by BRs. Furthermore, AdNAC3 and AdMYB19 positively regulated the activity of the AdEXP3 promoter, and AdNAC3 positively regulated the promoter activity of AdMYB19. The physical interaction between AdNAC3 and the B-box-type zinc finger protein AdBBX32 affected fruit ripening. Transient overexpression and silencing experiments revealed that ETH upregulated and BRs downregulated the expression of AdNAC3 and AdMYB19, thereby regulating the expression level of AdEXP3 and participating in pectin degradation. Stable transformation of AdNAC3 in tomato fruits accelerated fruit color change and promoted fruit ripening. These results indicate that AdNAC3 and AdMYB19 are involved in the hormone interaction between BRs and ETH in regulating kiwifruit ripening, providing insights into the molecular mechanisms underlying the crosstalk between BRs and ETH.

The transcription factor NnNAC100 positively regulates amylopectin biosynthesis by activating NnSBEII in the rhizome of Nelumbo nucifera Gaertn

KEY MESSAGE

NnNAC100-NnSBEII modules enhance starch content of the rhizome in Nelumbo nucifera Gaertn. Nelumbo nucifera Gaertn. is a popular aquatic vegetable and traditional Chinese medicine whose quality and taste are mainly determined by the starch. Although starch-related genes have been functionally characterized, the regulated mechanism of enzyme (SBE) remains unclear. In this study, we identified and functionally elucidated the functions of NnSBEII and NnNAC100 using transient overexpression of NnSBEII and NnNAC100 in rhizomes of lotus, and it significantly increased the amylopectin content and total starch content. Accordingly, functional complementation assay in defective Arabidopsis also showed that NnSBEII compensated for the low content of starch in the mutant sbe2.2. In addition, overexpression of NnSBEII and NnNAC100 significantly increased the content of starch in transgenic lines. Consistently, opposite results were observed under the background of repressed NnSBEII and NnNAC100 in rhizomes of lotus. Furthermore, yeast one-hybrid and dual-luciferase assays revealed that NnNAC100 could directly bind to the NnSBEII promoter and promote the expression of NnSBEII. Transient overexpression of NnNAC100 upregulated NnSBEII expression significantly, while the expression level of AtSBE2.2 in transgenic Arabidopsis overexpressing NnNAC100 was higher than that of WT, which indicated that NnNAC100 promoted the synthesis of amylopectin by enhancing the expression of NnSBEII. In addition, we found that NnSBEII could form a complex protein by interacting with soluble starch synthase (NnSS2) to increase the activity of the SBEII enzyme. These results reveal a novel mechanism that the NnNAC100-NnSBEII-NnSBEII/NnSS2 module regulates amylopectin biosynthesis and these will provide insights into the broader implications of the regulation mechanism of starch biosynthesis.

The dynamic N1-methyladenosine RNA methylation provides insights into the tomato fruit ripening

N1-methyladenosine (m1A) methylation is an essential mechanism of gene regulation known to impact several biological processes in living organisms. However, little is known about the abundance, distribution, and functional significance of mRNA m1A modification during fruit ripening of tomato the main model species for fleshy fruits. Our study shows that m1A modifications are prevalent in tomato mRNA and are detected in lncRNA and circRNA. The distribution of m1A peaks in mRNA segments indicates that m1A is mainly enriched at the start codon and CDS regions. Assessing changes in global RNA methylation during fruit ripening in wild-type tomatoes and in the ripening-impaired Nr mutant affected in the ethylene receptor gene (SlETR3) revealed a decrease in the overall methylation levels from mature green (MG) stage to 6 days postbreaker (Br + 6). Nr mutant fruits show significantly lower methylation levels than Ailsa Craig (AC) fruits. Notably, differences in m1A methylation are well correlated to the expression levels of a number of key ripening-related genes. The integration of RNA-seq and MeRIP-seq data suggests a potential positive impact of m1A modifications on gene expression. In comparison to the AC fruits, the hypomethylation and reduced expression of ethylene-related genes, ACO3, EBF1, and ERF.D6, in the Nr mutants likely underpin the distinct phenotypic traits observed between the two fruit genotypes at the Br6 stage. Overall, our study brings further arguments supporting the potential significance of m1A methylation modifications in fruit ripening, a developmental process that is instrumental to plant reproduction and to fruit sensory and nutritional qualities.

Effect of histone modifications on fruit ripening

Histone modifications are canonical epigenetic modifications mediating plant growth and development. Specially, histone modifications play important regulatory roles in plant fruit ripening, directly affecting fruit color changes, soluble sugar accumulation, and fruit softening. In this review, we focus on the effects of histone acetylation and methylation during fruit ripening. In particular, histone acetylation at H3 and H4 accelerates fruit ripening, whereas removal of histone acetylation via histone deacetylases (HDACs) inhibits or delays ripening by regulating the expression of carotenoid and anthocyanin production, glycometabolism, cell wall degradation, ethylene synthesis and signalling, and cell expansin-related genes. In addition, histone methylation is also involved in fruit ripening, in which the emergence of H3K27me3 modifications represses fruit ripening and H3K4me3 modifications promote fruit ripening by affecting multiple ripening-related pathways. However, the relationship between other histone modifications and fruit ripening is currently unclear. Here, we point out that accurate and comprehensive studies concerning the regulatory mechanism of histone modifications in fruit ripening are needed to facilitate the design of high-quality and high-yield fruit.

Mutation of YFT3, an isomerase in the isoprenoid biosynthetic pathway, impairs its catalytic activity and carotenoid accumulation in tomato fruit

Tomato fruit colors are directly associated with their appearance quality and nutritional value. However, tomato fruit color formation is an intricate biological process that remains elusive. In this work we characterized a tomato yellow fruited tomato 3 (yft3, e9292, Solanum lycopersicum) mutant with yellow fruits. By the map-based cloning approach, we identified a transversion mutation (A2117C) in the YFT3 gene encoding a putative isopentenyl diphosphate isomerase (SlIDI1) enzyme, which may function in the isoprenoid biosynthetic pathway by catalyzing conversion between isopentenyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP). The mutated YFT3 (A2117C) (designated YFT3 allele) and the YFT3 genes did not show expression difference at protein level, and their encoded YFT3 allelic (S126R) and YFT3 proteins were both localized in plastids. However, the transcript levels of eight genes (DXR, DXS, HDR, PSY1, CRTISO, CYCB, CYP97A, and NCED) associated with carotenoid synthesis were upregulated in fruits of both yft3 and YFT3 knockout (YFT3-KO) lines at 35 and 47 days post-anthesis compared with the red-fruit tomato cultivar (M82). In vitro and in vivo biochemical analyses indicated that YFT3 (S126R) possessed much lower enzymatic activities than the YFT3 protein, indicating that the S126R mutation can impair YFT3 activity. Molecular docking analysis showed that the YFT3 allele has higher ability to recruit isopentenyl pyrophosphate (IPP), but abolishes attachment of the Mg2+ cofactor to IPP, suggesting that Ser126 is a critical residue for YTF3 biochemical and physiological functions. As a result, the yft3 mutant tomato line has low carotenoid accumulation and abnormal chromoplast development, which results in yellow ripe fruits. This study provides new insights into molecular mechanisms of tomato fruit color formation and development.

Transcriptomics reveal useful resources for examining fruit development and variation in fruit size in Coccinia grandis

Introduction

The Cucurbitaceae family comprises many agronomically important members, that bear nutritious fruits and vegetables of great economic importance. Coccinia grandis, commonly known as Ivy gourd, belongs to this family and is widely consumed as a vegetable. Members of this family are known to display an impressive range of variation in fruit morphology. Although there have been studies on flower development in Ivy gourd, fruit development remains unexplored in this crop.

Methods

In this study, comparative transcriptomics of two Ivy gourd cultivars namely "Arka Neelachal Kunkhi" (larger fruit size) and "Arka Neelachal Sabuja" (smaller fruit size) differing in their average fruit size was performed. A de novo transcriptome assembly for Ivy gourd was developed by collecting fruits at different stages of development (5, 10, 15, and 20 days after anthesis i.e. DAA) from these two varieties. The transcriptome was analyzed to identify differentially expressed genes, transcription factors, and molecular markers.

Results

The transcriptome of Ivy gourd consisted of 155205 unigenes having an average contig size of 1472bp. Unigenes were annotated on publicly available databases to categorize them into different biological functions. Out of these, 7635 unigenes were classified into 38 transcription factor (TF) families, of which Trihelix TFs were most abundant. A total of 11,165 unigenes were found to be differentially expressed in both the varieties and the in silico expression results were validated through real-time PCR. Also, 98768 simple sequence repeats (SSRs) were identified in the transcriptome of Ivy gourd.

Discussion

This study has identified a number of genes, including transcription factors, that could play a crucial role in the determination of fruit shape and size in Ivy gourd. The presence of polymorphic SSRs indicated a possibility for marker-assisted selection for crop breeding in Ivy gourd. The information obtained can help select candidate genes that may be implicated in regulating fruit development and size in other fruit crops.

Transcriptomic Analysis of Alternative Splicing Events during Different Fruit Ripening Stages of Coffea arabica L

To date, genomic and transcriptomic data on Coffea arabica L. in public databases are very limited, and there has been no comprehensive integrated investigation conducted on alternative splicing (AS). Previously, we have constructed and sequenced eighteen RNA-seq libraries of C. arabica at different ripening stages of fruit development. From this dataset, a total of 3824, 2445, 2564, 2990, and 3162 DSGs were identified in a comparison of different fruit ripening stages. The largest proportion of DSGs, approximately 65%, were of the skipped exon (SE) type. Biologically, 9 and 29 differentially expressed DSGs in the spliceosome pathway and carbon metabolism pathway, respectively, were identified. These DSGs exhibited significant variations, primarily in S1 vs. S2 and S5 vs. S6, and they involve many aspects of organ development, hormone transduction, and the synthesis of flavor components. Through the examination of research findings regarding the biological functions and biochemical pathways associated with DSGs and DEGs, it was observed that six DSGs significantly enriched in ABC transporters, namely, LOC113712394, LOC113726618, LOC113739972, LOC113725240, LOC113730214, and LOC113707447, were continually down-regulated at the fruit ripening stage. In contrast, a total of four genes, which were LOC113732777, LOC113727880, LOC113690566, and LOC113711936, including those enriched in the cysteine and methionine metabolism, were continually up-regulated. Collectively, our findings may contribute to the exploration of alternative splicing mechanisms for focused investigations of potential genes associated with the ripening of fruits in C. arabica.

Dissection of mRNA ac4C acetylation modifications in AC and Nr fruits: insights into the regulation of fruit ripening by ethylene

N4-acetylcytidine (ac4C) modification of mRNA has been shown to be present in plant RNAs, but its regulatory function in plant remains largely unexplored. In this study, we investigated the differentially expressed mRNAs, lncRNAs and acetylation modifications of mRNAs in tomato fruits from both genotypes. By comparing wild-type (AC) tomato and the ethylene receptor-mutant (Nr) tomato from mature green (MG) to six days after the breaker (Br6) stage, we identified differences in numerous key genes related to fruit ripening and observed the corresponding lncRNAs positively regulated the target genes expression. At the post-transcriptional level, the acetylation level decreased and increased in AC and Nr tomatoes from MG to Br6 stage, respectively. The integrated analysis of RNA-seq and ac4C-seq data revealed the potential positive role of acetylation modification in regulating gene expression. Furthermore, we found differential acetylation modifications of certain transcripts (ACO, ETR, ERF, PG, CesA, β-Gal, GAD, AMY, and SUS) in AC and Nr fruits which may explain the differences in ethylene production, fruit texture, and flavor during their ripening processes. The present study provides new insights into the molecular mechanisms by which acetylation modification differentially regulates the ripening process of wild-type and mutant tomato fruits deficient in ethylene signaling.

Integrative transcriptomics and proteomics profiling of Arabidopsis thaliana elucidates novel mechanisms underlying spaceflight adaptation

Spaceflight presents a unique environment with complex stressors, including microgravity and radiation, that can influence plant physiology at molecular levels. Combining transcriptomics and proteomics approaches, this research gives insights into the coordination of transcriptome and proteome in Arabidopsis' molecular and physiological responses to Spaceflight environmental stress. Arabidopsis seedlings were germinated and grown in microgravity (µg) aboard the International Space Station (ISS) in NASA Biological Research in Canisters - Light Emitting Diode (BRIC LED) hardware, with the ground control established on Earth. At 10 days old, seedlings were frozen in RNA-later and returned to Earth. RNA-seq transcriptomics and TMT-labeled LC-MS/MS proteomic analysis of cellular fractionates from the plant tissues suggest the alteration of the photosynthetic machinery (PSII and PSI) in spaceflight, with the plant shifting photosystem core-regulatory proteins in an organ-specific manner to adapt to the microgravity environment. An overview of the ribosome, spliceosome, and proteasome activities in spaceflight revealed a significant abundance of transcripts and proteins involved in protease binding, nuclease activities, and mRNA binding in spaceflight, while those involved in tRNA binding, exoribonuclease activity, and RNA helicase activity were less abundant in spaceflight. CELLULOSE SYNTHASES (CESA1, CESA3, CESA5, CESA7) and CELLULOSE-LIKE PROTEINS (CSLE1, CSLG3), involved in cellulose deposition and TUBULIN COFACTOR B (TFCB) had reduced abundance in spaceflight. This contrasts with the increased expression of UDP-ARABINOPYRANOSE MUTASEs, involved in the biosynthesis of cell wall non-cellulosic polysaccharides, in spaceflight. Both transcripts and proteome suggested an altered polar auxin redistribution, lipid, and ionic intracellular transportation in spaceflight. Analyses also suggest an increased metabolic energy requirement for plants in Space than on Earth, hence, the activation of several shunt metabolic pathways. This study provides novel insights, based on integrated RNA and protein data, on how plants adapt to the spaceflight environment and it is a step further at achieving sustainable crop production in Space.

The transcription factor EMB1444-like affects tomato fruit ripening by regulating YELLOW-FRUITED TOMATO 1, a core component of ethylene signaling transduction

The fleshy fruit of tomato (Solanum lycopersicum) are climacteric and, as such, ethylene plays a pivotal role in their ripening and quality traits. In this study, a basic helix-loop-helix transcription factor, EMB1444-like, was found to induce the expression of YELLOW-FRUITED TOMATO 1 (YFT1), which encodes the SlEIN2 protein, a key element in the ethylene signaling pathway. Yeast one-hybrid and EMSA analyses revealed that EMB1444-like binds to the E-box motif (CACTTG, -1295 bp to -1290 bp upstream of the ATG start codon) of the YFT1 promoter (pYFT1). Suppression of EMB1444-like expression in tomato lines (sledl) using RNAi reduced ethylene production by lowering the expression of 1-AMINOCYCLOPROPANE-1-CARBOXYLATE SYNTHASE 2/4 (ACS2/4) and ACC OXIDASE1 (ACO1) in a positive feedback loop. sledl tomato also showed differences in numerous quality traits related to fruit ripening, compared with the wild type, such as delayed chromoplast differentiation, a decrease in carotenoid accumulation, and delayed fruit ripening in an ethylene-independent manner, or at least upstream of ripening mediated by YFT1/SlEIN2. This study elucidates the regulatory framework of fruit ripening in tomato, providing information that may be used to breed tomato hybrid cultivars with an optimal balance of shelf-life, durability, and high quality.

Comprehensive Profiling of Alternative Splicing and Alternative Polyadenylation during Fruit Ripening in Watermelon (Citrullus lanatus)

Fruit ripening is a highly complicated process that is accompanied by the formation of fruit quality. In recent years, a series of studies have demonstrated post-transcriptional control play important roles in fruit ripening and fruit quality formation. Till now, the post-transcriptional mechanisms for watermelon fruit ripening have not been comprehensively studied. In this study, we conducted PacBio single-molecule long-read sequencing to identify genome-wide alternative splicing (AS), alternative polyadenylation (APA) and long non-coding RNAs (lncRNAs) in watermelon fruit. In total, 6,921,295 error-corrected and mapped full-length non-chimeric (FLNC) reads were obtained. Notably, more than 42,285 distinct splicing isoforms were derived from 5,891,183 intron-containing full-length FLNC reads, including a large number of AS events associated with fruit ripening. In addition, we characterized 21,506 polyadenylation sites from 11,611 genes, 8703 of which have APA sites. Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis showed that fructose and mannose metabolism, starch and sucrose metabolism and carotenoid biosynthesis were both enriched in genes undergoing AS and APA. These results suggest that post-transcriptional regulation might potentially have a key role in regulation of fruit ripening in watermelon. Taken together, our comprehensive PacBio long-read sequencing results offer a valuable resource for watermelon research, and provide new insights into the molecular mechanisms underlying the complex regulatory networks of watermelon fruit ripening.

Recent advances in epigenetic triggering of climacteric fruit ripening

During ripening, fleshy fruits undergo irreversible changes in color, texture, sugar content, aroma, and flavor to appeal to seed-dispersal vectors. The onset of climacteric fruit ripening is accompanied by an ethylene burst. Understanding the factors triggering this ethylene burst is important for manipulating climacteric fruit ripening. Here, we review the current understanding and recent insights into the possible factors triggering climacteric fruit ripening: DNA methylation and histone modification, including methylation and acetylation. Understanding the initiation factors of fruit ripening is important for exploring and accurately regulating the mechanisms of fruit ripening. Lastly, we discuss the potential mechanisms responsible for climacteric fruit ripening.

Anthocyanins distribution, transcriptional regulation, epigenetic and post-translational modification in fruits

Anthocyanins have indispensable functions in plant resistance, human health, and fruit coloring, which arouse people's favorite. It has been reported that anthocyanins are widely found in fruits, and can be affected by numerous factors. In this review, we systematically summarize anthocyanin functions, classifications, distributions, biosynthesis, decoration, transportation, transcriptional regulation, DNA methylation, and post-translational regulation in fruits.

The mechanisms underpinning anthocyanin accumulation in a red-skinned bud sport in pear (Pyrus ussuriensis)

KEY MESSAGE

In our study, we demonstrated that histone acetylation promotes anthocyanin accumulation in pears by affecting the expression of key genes. Color is an important trait of horticultural plants, and the anthocyanin content directly affects the nutritional value and commercial value of colored fruits. Therefore, it is important for fruit breeding to cultivate new varieties with bright colors. 'Nanhong' (NH) pear (Pyrus ussuriensis) is a bud sport cultivar of 'Nanguo' (NG) pear. The anthocyanin content in NH pear is significantly higher than that in NG pear, but the underlying molecular mechanism remains unclear. Here, we observed that the anthocyanin biosynthesis structural gene PuUFGT (UDP-glucose: flavonoids 3-O-glucosyltransferase) and an anthocyanin transporter gene PuGSTF6 (glutathione S-transferase) had significantly higher expression levels in NH than in NG pears during the late stages of fruit development. Meanwhile, the R2R3-MYB transcription factor PuMYB110a was also highly expressed in NH pears and could positively regulate the transcription of PuUFGT and PuGSTF6. Overexpression of PuMYB110a in pear increased the fruit anthocyanin content. In addition, despite no significant differences in methylation levels being found in the promoters of PuMYB110a, PuUFGT, and PuGSTF6 when comparing the two varieties, the histone acetylation levels of PuMYB110a were significantly higher in NH pear compared with those in NG pear. Our findings suggest a mechanism for anthocyanin accumulation in NH fruit.

Abscisic acid plays a key role in the regulation of date palm fruit ripening

The date palm (Phoenix dactylifera L.) fruit is of major importance for the nutrition of broad populations in the world's desert strip; yet it is sorely understudied. Understanding the mechanism regulating date fruit development and ripening is essential to customise date crop to the climatic change, which elaborates yield losses due to often too early occurring wet season. This study aimed to uncover the mechanism regulating date fruit ripening. To that end, we followed the natural process of date fruit development and the effects of exogenous hormone application on fruit ripening in the elite cultivar 'Medjool'. The results of the current study indicate that the onset of fruit ripening occurre once the seed had reached maximum dry weight. From this point, fruit pericarp endogenous abscisic acid (ABA) levels consistently increased until fruit harvest. The final stage in fruit ripening, the yellow-to-brown transition, was preceded by an arrest of xylem-mediated water transport into the fruit. Exogenous ABA application enhanced fruit ripening when applied just before the green-to-yellow fruit color transition. Repeated ABA applications hastened various fruit ripening processes, resulting in earlier fruit harvest. The data presented supports a pivotal role for ABA in the regulation of date fruit ripening.

Transcriptomic analysis of effects of 1-methylcyclopropene (1-MCP) and ethylene treatment on kiwifruit (Actinidia chinensis) ripening

Ethylene (ET) is a gaseous phytohormone with a crucial role in the ripening of many fruits, including kiwifruit (Actinidia spp.). Meanwhile, treatment with 1-methylcyclopropene (1-MCP), an artificial ET inhibitor delays the ripening of kiwifruit. The objective of this study was to determine the effect of ET and 1-MCP application during time-course storage of kiwifruit. In addition, we aimed to elucidate the molecular details underlying ET-mediated ripening process in kiwifruit. For this purpose, we conducted a time-course transcriptomic analysis to determine target genes of the ET-mediated maturation process in kiwifruit during storage. Thousands of genes were identified to be dynamically changed during storage and clustered into 20 groups based on the similarity of their expression patterns. Gene ontology analysis using the list of differentially expressed genes (DEGs) in 1-MCP-treated kiwifruit revealed that the identified DEGs were significantly enriched in the processes of photosynthesis metabolism and cell wall composition throughout the ripening process. Meanwhile, ET treatment rapidly triggered secondary metabolisms related to the ripening process, phenylpropanoid (e.g. lignin) metabolism, and the biosynthesis of amino acids (e.g. Phe, Cys) in kiwifruit. It was demonstrated that ET biosynthesis and signaling genes were oppositely affected by ET and 1-MCP treatment during ripening. Furthermore, we identified a ET transcription factor, AcEIL (Acc32482) which is oppositely responsive by ET and 1-MCP treatment during early ripening, potentially one of key signaling factor of ET- or 1-MCP-mediated physiological changes. Therefore, this transcriptomic study unveiled the molecular targets of ET and its antagonist, 1-MCP, in kiwifruit during ripening. Our results provide a useful foundation for understanding the molecular details underlying the ripening process in kiwifruit.