Downregulation of RdDM during strawberry fruit ripening

Background

Recently, DNA methylation was proposed to regulate fleshy fruit ripening. Fleshy fruits can be distinguished by their ripening process as climacteric fruits, such as tomatoes, or non-climacteric fruits, such as strawberries. Tomatoes undergo a global decrease in DNA methylation during ripening, due to increased expression of a DNA demethylase gene. The dynamics and biological relevance of DNA methylation during the ripening of non-climacteric fruits are unknown.

Results

Here, we generate single-base resolution maps of the DNA methylome in immature and ripe strawberry. We observe an overall loss of DNA methylation during strawberry fruit ripening. Thus, ripening-induced DNA hypomethylation occurs not only in climacteric fruit, but also in non-climacteric fruit. Application of a DNA methylation inhibitor causes an early ripening phenotype, suggesting that DNA hypomethylation is important for strawberry fruit ripening. The mechanisms underlying DNA hypomethylation during the ripening of tomato and strawberry are distinct. Unlike in tomatoes, DNA demethylase genes are not upregulated during the ripening of strawberries. Instead, genes involved in RNA-directed DNA methylation are downregulated during strawberry ripening. Further, ripening-induced DNA hypomethylation is associated with decreased siRNA levels, consistent with reduced RdDM activity. Therefore, we propose that a downregulation of RdDM contributes to DNA hypomethylation during strawberry ripening.

Conclusions

Our findings provide new insight into the DNA methylation dynamics during the ripening of non-climacteric fruit and suggest a novel function of RdDM in regulating an important process in plant development.

     

Tissue dependent variations of DNA methylation and endoreduplication levels during tomato fruit development and ripening

Tomato fruit cells are characterized by a strong increase in nuclear ploidy during fruit development. Average ploidy levels increased to similar levels (above 50C) in two distinct fruit tissues, pericarp and locular tissue. However, ploidy profiles differed significantly between these two tissues suggesting a tissue-specific control of endoreduplication in tomato fruit. To determine possible relationships between endoreduplication and epigenetic mechanisms, the methylation status of genomic DNA from pericarp and locular tissue of tomato fruit was analysed. Pericarp genomic DNA was characterized by an increase of CG and/or CNG methylation at the 5S and 18S rDNA loci and at gyspsy-like retrotransposon sequences during fruit growth. A sharp decrease of the global DNA methylation level together with a reduction of methylation at the rDNA loci was also observed in pericarp during fruit ripening. Inversely, no major variation of DNA methylation either global or locus-specific, was observed in locular tissue. Thus, tissue-specific variations of DNA methylation are unlikely to be triggered by the induction of endoreduplication in fruit tissues, but may reflect tissue-specific ploidy profiles. Expression analysis of eight putative tomato DNA methyltransferases encoding genes showed that one chromomethylase (CMT) and two rearranged methyltransferases (DRMs) are preferentially expressed in the pericarp during fruit growth and could be involved in the locus-specific increase of methylation observed at this developmental phase in the pericarp.     

Oxidative DNA damage in humans: comparison between high and low habitual fruit and vegetable consumption

We investigated whether men with a habitual high consumption of vegetables and fruit have a lower excretion of 8 oxo 7,8 dihydro 2 deoxyguanosine 8 oxodG , a urinary marker for oxidative DNA damage, than men with a low consumption of vegetables and fruit. Ten pairs of healthy non smoking males aged between 28 and 59 years, matched for age 10 years and body mass index 2 kg m 2 were selected from a dietary validation study. Habitual food intake was estimated with 12 monthly 24 h recalls. Men in the high vegetable and fruit group consumed an average of 224 g day 1 range 101-330 g day 1 more vegetables and fruit than men in the low vegetable and fruit group. Excretion of 8 oxodG was 95 pmol kg 1 day 1 95 CI-29, 219 higher in the high vegetable and fruit group than in the low vegetable and fruit group paired t test, P = 0.11 . Excretion of 8 oxodG was not correlated with intake of vitamins, energy, fat, nor with blood concentrations of antioxidant pro vitamins, but it was inversely correlated with age. The present findings do not suggest that humans with a habitual high fruit and vegetables consumption have less oxidative DNA damage as measured by 8 oxodG excretion than men with low consumption of fruit and vegetables.     

Oxidative DNA damage in humans: comparison between high and low habitual fruit and vegetable consumption

We investigated whether men with a habitual high consumption of vegetables and fruit have a lower excretion of 8 oxo 7,8 dihydro 2 deoxyguanosine 8 oxodG, a urinary marker for oxidative DNA damage, than men with a low consumption of vegetables and fruit. Ten pairs of healthy non smoking males aged between 28 and 59 years, matched for age 10 years and body mass index 2 kg m 2 were selected from a dietary validation study. Habitual food intake was estimated with 12 monthly 24 h recalls. Men in the high vegetable and fruit group consumed an average of 224 g day 1 range 101-330 g day 1 more vegetables and fruit than men in the low vegetable and fruit group. Excretion of 8 oxodG was 95 pmol kg 1 day 1 95 CI-29, 219 higher in the high vegetable and fruit group than in the low vegetable and fruit group paired t test, P = 0.11 . Excretion of 8 oxodG was not correlated with intake of vitamins, energy, fat, nor with blood concentrations of antioxidant pro vitamins, but it was inversely correlated with age. The present findings do not suggest that humans with a habitual high fruit and vegetables consumption have less oxidative DNA damage as measured by 8 oxodG excretion than men with low consumption of fruit and vegetables.     

Novel promoters that induce specific transgene expression during the green to ripening stages of tomato fruit development

Fruit-specific promoters have been used as genetic engineering tools for studies on molecular mechanism of fruit development and advance in fruit quality and additional value by increasing functional component. Especially fruit-ripening specific promoters have been well utilized and studied in tomato; however, few studies have reported the development of promoters that act at fruit developing stages such as immature green and mature green periods. In this study, we report novel promoters for gene expression during the green to ripening stages of tomato fruit development. Genes specifically expressed at tomato fruit were selected using microarray data. Subsequent to confirmation of the expression of the selected 12 genes, upstream DNA fragments of the genes LA22CD07, Les.3122.2.A1_a_at and LesAffx.6852.1.S1_at which specifically expressed at fruit were isolated from tomato genomic DNA as promoter regions. Isolated promoter regions were fused with the GUS gene and the resultant constructs were introduced into tomato by agrobacterium-mediated transformation for evaluation of promoter activity in tomato fruit. The two promoters of LA22CD07, and LesAffx.6852.1.S1_at showed strong activity in the fruit, weak activity in the flower and undetectable activity in other tissues. Unlike well-known fruit-ripening specific promoters, such as the E8 promoter, these promoters exhibited strong activity in green fruit in addition to red-ripening fruit, indicating that the promoters are suitable for transgene expression during green to ripening stages of tomato fruit development. KEY MESSAGE: Novel fruit-specific promoters have been identified and are suitable for transgene expression during green to ripening stages of tomato fruit development.     

cDNA cloning and characterisation of novel ripening-related mRNAs with altered patterns of accumulation in the ripening inhibitor (rin) tomato ripening mutant

A cDNA library produced from mRNA isolated from the pericarp of wild-type tomato fruit (Lycopersicon esculentum Mill. cv Ailsa Craig) at the first visible sign of fruit ripening was differentially screened to identify clones whose homologous mRNAs were present at reduced levels in fruit of the tomato ripening mutant, ripening inhibitor,rin. Five clones were isolated (pERT 1, 10, 13, 14, 15). Accumulation of mRNA homologous to each of these clones increased during the ripening of wild-type fruit and showed reduced accumulation in ripening rin fruit. The levels of three of them (homologous to ERT 1, 13 and 14) were increased by ethylene treatment of the mutant fruit. A further clone, ERT 16 was identified for a mRNA present at a high level in both normal and mutant fruit at early stages of ripening. Database searches revealed no significant homology to the DNA sequence of ERT 14 and 15; however, DNA and derived amino acid sequence of ERT 1 both contain regions of homology with several reported UDP-glucosyl and glucuronosyl transferases (UDPGT) and with a conserved UDPGT motif. A derived amino acid sequence from the ERT 10 cDNA contains a perfect match to a consensus sequence present in a number of dehydrogenases. The ERT 13 DNA sequence has homology with an mRNA present during potato tuberisation. The presence of these mRNAs in tomato fruit is unreported and their role in ripening is unknown. The ERT 16 DNA sequence has homology with a ripening/stress-related cDNA isolated from tomato fruit pericarp.     

A DNA test for routine prediction in breeding of sweet cherry fruit color,Pav-R<Subscript>f</Subscript>-SSR

Sweet cherry fruit color is a market class-defining trait. The two main market classes in the USA are mahogany, consisting fruit with red skin and flesh, and blush, consisting clear-fleshed fruit with yellow skin and a red overcolor on less than the entire skin surface. Fruit color is a major consideration in sweet cherry breeding as resources and selection thresholds are often differentially applied to each market class. The use of DNA-based information could improve breeding efficiency and accuracy for fruit color, but a predictive DNA test is required. The objective of this study was to develop a reliable, simple DNA test for the prediction of sweet cherry color-based market classes, targeting the major locus, termed here as R _f , associated with fruit color variation. Haplotypes were developed based on 14 SNP markers from the RosBREED cherry 6K SNP array v1 that were associated with the two market classes. To convert the multiple SNP markers to a single, simple PCR-based assay, 11 PCR-based assays targeting microsatellite motifs were designed, using the peach reference genome sequence, and used to screen 20 individuals representing the most common SNP haplotypes. One assay, subsequently named Pav-R_f-SSR, was used to screen 221 phenotyped individuals of the RosBREED sweet cherry reference germplasm set and accurately differentiated individuals with mahogany and blush fruits. Pav-R_f-SSR can be used in DNA-informed breeding schemes to efficiently and accurately predict genetic potential for fruit color and is one of the first DNA tests publicly available for a sweet cherry fruit quality trait.     

Recovering full DNA barcodes from natural history collections of Tephritid fruitflies (Tephritidae, Diptera) using mini barcodes

The family of Tephritid fruit flies (Tephritidae, Diptera) is composed of more than 4000 species and more than 350 are of economic importance (EI). The Tephritid Barcoding Initiative (TBI) aims at obtaining DNA barcodes for all EI species and the majority of their congeners. Dry pinned specimens from natural history collections are an important resource for reference material, but were often collected decades ago. We observed a strong decrease in the success rate of obtaining a full COX1 DNA barcode (658 bp), with an increasing age of the specimens. Obtaining full barcodes is often not possible using standard protocols. We developed a universal Tephritid primer set for multiple overlapping mini-barcodes that allows reconstructing the full COX1 DNA barcode. These newly developed primers and the corresponding protocol will facilitate the utilization of the extensive natural history collection by the TBI consortium.     

DNA分子标记在果树遗传育种研究中的应用

DNA分子标记是随着分子生物学技术的发展出现的一类重要的遗传标记,近年来发展非常迅速,已在果树遗传育种研究的各个方面得到广泛的应用。介绍了几种DNA分子标记技术的原理,综述了DNA分子标记在果树种质资源研究、分子遗传图谱构建、基因定位、分子辅助选择等方面的应用,并对其在果树上的应用前景和存在问题进行了评述。     

Changes in the activities of some cell wall-degrading enzymes during development and ripening of Japanese pear fruit (Pyrus serotina Rehder var. culta Rehder)

1. Based on changes in DNA content per whole fruit and wholefruit weight during development, the development of Japanesepear fruit (cultivars Hosui and 93-3) was divided into celldivision, pre-enlargement, enlargement and ripening stages. 2. A climacteric rise in respiration with ethylene evolutionwas recognized although it was not very marked. 3. The ratio of pectinic acid to total pectin content increasedwith ripening. Total pectin content on a DNA content basis increasedclearly in the pre-enlargement and ripening stages, but roughlyremained constant in the cell division and enlargement stages. 4. Changes in the activities of cell wall-degrading enzymes,i.e. endocellulase, exocellulase, polygalacturonase, pectinmethylesterase and ß-galactosidase, were investigatedduring fruit growth. The activities per fresh weight of allenzymes, except exocellulase, were fairly high in the cell divisionand pre-enlargement stages, decreased in the enlargement stage,and increased remarkably with ripening or overripening, exceptfor pectin methylesterase. Endocellulase was present as an acidtype and neutral types. The former was more active than thelatter in the cell division and pre-enlargement stages, butwith ripening the reverse was found. On the other hand, theactivities, on a DNA content basis, in all the enzymes wereroughly constant, not decreasing during cell division, pre-enlargementand enlargement stages, but increasing extensively with ripening.That is, the lowering of these enzyme activities per g freshweight in the enlargement stage seemed not to be due to inactivationor stimulation of enzyme degeneration. The extensive enhancementsof cell wall-degrading enzyme activities with ripening or overripeningseem to be closely related to the softening or pithiness ofthe fruit. ¹ This paper is Contribution A-63, Fruit Tree Res. Sta. (Received June 11, 1976; )     

Isolation of cDNA clones corresponding to genes differentially expressed in pericarp of mume (Prunus mume) in response to ripening, ethylene and wounding signals

Ripening of climacteric fruit is a complex developmental process that includes many changes in gene expression. Some ripening-regulated genes are responsive to ethylene and/or wounding signals. Wounding increased Pm-ACS1 expression in Prunus mume (Japanese apricot), but was negatively regulated by ethylene. However, exposure of freshly harvested mature green mume fruit to ethylene induced PmACS1 . Fifteen complementary DNA clones corresponding to messenger RNAs differentially expressed in the pericarp of P. mume fruit in response to ripening, ethylene and wounding signals were isolated by differential display. Quantitative real-time PCR analysis distinctly showed that these genes are differentially regulated. Genes that were upregulated during fruit ripening include Pm15 (cinnamyl-alcohol dehydrogenase), Pm21 (2-oxoacid-dependent dioxygenase), Pm22 (1-acyl- sn -glycerol-3-phosphate acyltransferase), Pm27 (unknown function), Pm38 (alcohol dehydrogenase), Pm41 (no homology), Pm52 (no homology), Pm65 (pectate lyase), Pm68 (expansin), Pm69 (serine carboxypeptidase) and Pm94 (alcohol acyltransferase). Expression of most of these genes was also inducible by ethylene and some of them were inducible by wounding. Pm3 (water channel protein, MIP) and Pm8 (unknown function) were downregulated during ripening. Expression of Pm71 (no homology) and Pm74 (NAC family protein) did not increase during ripening or in response to ethylene, but was upregulated in response to wounding. The possible physiological roles of these genes during ripening and in response to ethylene and wounding are discussed.     

Characterisation of alleles of tomato light signalling genes generated by TILLING

Targeting Induced Local Lesions IN Genomes (TILLING) combines chemical mutagenesis with high throughput screening to allow the generation of alleles of selected genes. In this study, TILLING has been applied to produce a series of mutations in genes encoding essential components of the tomato light signal transduction pathway in an attempt to enhance fruit nutritional quality. Point mutations to DEETIOLATED1 (DET1), which is responsible for the high pigment2 (hp2) tomato mutant, resulted in elevated levels of both carotenoid and phenylpropanoid phytonutrients in ripe fruit, whilst immature fruit showed increased chlorophyll content, photosynthetic capacity and altered fruit morphology. Furthermore, genotypes with mutations to the UV-DAMAGED DNA BINDING PROTEIN 1 (DDB1), COP1 and COP1like were also characterised. These genotypes largely did not display phenotypes characteristic of mutation to light signalling components but their characterisation has enabled interrogation of structure function relationships of the mutated genes.     

Elucidating the functional role of endoreduplication in tomato fruit development

Background

Endoreduplication is the major source of endopolyploidy in higher plants. The process of endoreduplication results from the ability of cells to modify their classical cell cycle into a partial cell cycle where DNA synthesis occurs independently from mitosis. Despite the ubiquitous occurrence of the phenomenon in eukaryotic cells, the physiological meaning of endoreduplication remains vague,although several roles during plant development have been proposed, mostly related to cell differentiation and cell size determination.

Scope

Here recent advances in the knowledge of endoreduplication and fruit organogenesis are reviewed, focusing on tomato (Solanum lycopersicum) as a model, and the functional analyses of endoreduplication-associated regulatory genes in tomato fruit are described.

Conclusions

The cyclin-dependent kinase inhibitory kinase WEE1 and the anaphase promoting complex activator CCS52A both participate in the control of cell size and the endoreduplication process driving cell expansion during early fruit development in tomato. Moreover the fruit-specific functional analysis of the tomato CDK inhibitor KRP1 reveals that cell size and fruit size determination can be uncoupled from DNA ploidy levels, indicating that endoreduplication acts rather as a limiting factor for cell growth. The overall functional data contribute to unravelling the physiological role of endoreduplication in growth induction of fleshy fruits.     

Induced polyploidy dramatically increases the size and alters the shape of fruit in Actinidia chinensis

Background and Aims

Some otherwise promising selections of Actinidia chinensis (kiwifruit) have fruit that are too small for successful commercialization. We have therefore made the first detailed study in diploid kiwifruit of the effects of chromosome doubling induced by colchicine on fruit size, shape and crop loading.

Methods

Flow cytometric analysis of young leaves and chromosome analysis of flower buds and root tips was used to confirm the stability of induced autotetraploids. Fruit weight, size and crop load were measured in the third year after planting in the field and for three consecutive years. DNA fingerprinting was used to confirm the origin of the material.

Key Results

There was a very significant increase in fruit size in induced autotetraploids of different genotypes of A. chinensis. With the commercially important diploid cultivar ‘Hort16A’, most regenerants, Type A plants, had fruit which were much the same shape as fruit of the diploid but, at the same fruit load, were much larger and heavier. Some regenerants, Type B plants, produced fruit similar to ‘fasciated’ fruit. Fruit of the autotetraploids induced from three female red-fleshed A. chinensis selections were also 50–60 % larger than fruit of their diploid progenitors. The main increase in fruit dimensions was in their diameters. These improved fruit characteristics were stable over several seasons.

Conclusions

Chromosome doubling has been shown to increase significantly fruit size in autotetraploid A. chinensis, highlighting the considerable potential of this technique to produce new cultivars with fruit of adequate size. Other variants with differently shaped fruit were also produced but the genetic basis of this variation remains to be elucidated. Autoploids of other Actinidia species with commercial potential may also show improved fruit characteristics, opening up many new possibilities for commercial development.