Genetic engineering of parthenocarpic plants

Rotino, Giuseppe Leonardo; Perri, E.; Zottini, Michela; Sommer, Hans; Spena, Angelo

doi:10.1038/nbt1297-1398

Cited by 227 publications

(184 citation statements)

References 12 publications

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“…It is well known that pollen produces gibberellins and that application of gibberellins can induce an increase in the content of auxin in the ovaries of unpollinated flowers of the tomato plant, thereby triggering fruit set in the absence of fertilization (Sastry and Muir, 1963;Gorguet et al, 2005). A crucial role for auxin in seedless tomato fruit formation was directly demonstrated by ovule-specific overexpression of bacterial auxin biosynthetic genes, leading to seedless fruit production independent of pollination (Rotino et al, 1997). Furthermore, downregulation of the tomato Aux/IAA transcription factor IAA9 resulted in auxin-hypersensitive tomato plants in which fruit development was triggered before fertilization and independent of pollination, leading to parthenocarpic fruits (Wang et al, 2005).…”

Section: Discussionmentioning

confidence: 99%

RNA Interference Silencing of Chalcone Synthase, the First Step in the Flavonoid Biosynthesis Pathway, Leads to Parthenocarpic Tomato Fruits

Schijlen

Vos²,

Martens³

et al. 2007

Plant Physiol.

263

159

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; and Keygene N.V., 6700 AE Wageningen, The Netherlands (A.J.v.T.)Parthenocarpy, the formation of seedless fruits in the absence of functional fertilization, is a desirable trait for several important crop plants, including tomato (Solanum lycopersicum). Seedless fruits can be of great value for consumers, the processing industry, and breeding companies. In this article, we propose a novel strategy to obtain parthenocarpic tomatoes by downregulation of the flavonoid biosynthesis pathway using RNA interference (RNAi)-mediated suppression of chalcone synthase (CHS), the first gene in the flavonoid pathway. In CHS RNAi plants, total flavonoid levels, transcript levels of both Chs1 and Chs2, as well as CHS enzyme activity were reduced by up to a few percent of the corresponding wild-type values. Surprisingly, all strong Chs-silenced tomato lines developed parthenocarpic fruits. Although a relation between flavonoids and parthenocarpic fruit development has never been described, it is well known that flavonoids are essential for pollen development and pollen tube growth and, hence, play an essential role in plant reproduction. The observed parthenocarpic fruit development appeared to be pollination dependent, and Chs RNAi fruits displayed impaired pollen tube growth. Our results lead to novel insight in the mechanisms underlying parthenocarpic fruit development. The potential of this technology for applications in plant breeding and biotechnology will be discussed.

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Section: Discussionmentioning

confidence: 99%

RNA Interference Silencing of Chalcone Synthase, the First Step in the Flavonoid Biosynthesis Pathway, Leads to Parthenocarpic Tomato Fruits

Schijlen

Vos²,

Martens³

et al. 2007

Plant Physiol.

263

159

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“…There are a number of parthenocarpic tomato mutants, such as pat, pat2 and pat3/4, in which it was shown that the GA content and/or GA biosynthesis were increased signiWcantly (Mazzucato et al 1998;Fos et al 2000Fos et al , 2001Olimpieri et al 2007). Furthermore, overexpression of the iaaM gene, which encodes an enzyme involved in auxin biosynthesis, also induced parthenocarpic fruit development in tomato and many other species (Rotino et al 1997;Mezzetti et al 2004). Changes in both GA and auxin content were thus associated with parthenocarpic phenotypes.…”

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confidence: 99%

Abscisic acid levels in tomato ovaries are regulated by LeNCED1 and SlCYP707A1

Nitsch

Oplaat

Feron

et al. 2009

Planta

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Although the hormones, gibberellin and auxin, are known to play a role in the initiation of fruits, no such function has yet been demonstrated for abscisic acid (ABA). However, ABA signaling and ABA responses are high in tomato (Solanum lycopersicum L.) ovaries before pollination and decrease thereafter (Vriezen et al. in New Phytol 177:60-76, 2008). As a Wrst step to understanding the role of ABA in ovary development and fruit set in tomato, we analyzed ABA content and the expression of genes involved in its metabolism in relation to pollination. We show that ABA levels are relatively high in mature ovaries and decrease directly after pollination, while an increase in the ABA metabolite dihydrophaseic acid was measured. An important regulator of ABA biosynthesis in tomato is 9-cis-epoxy-carotenoid dioxygenase (LeNCED1), whose mRNA level in ovaries is reduced after pollination. The increased catabolism is likely caused by strong induction of one of four newly identiWed putative (+)ABA 8Ј-hydroxylase genes. This gene was named SlCYP707A1 and is expressed speciWcally in ovules and placenta. Transgenic plants, overexpressing SlCYP707A1, have reduced ABA levels and exhibit ABA-deWcient phenotypes suggesting that this gene encodes a functional ABA 8Ј-hydroxylase. Gibberellin and auxin application have diVerent eVects on the LeNCED1 and SlCYP707A1 gene expression. The crosstalk between auxins, gibberellins and ABA during fruit set is discussed.

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“…Genetically controlled parthenocarpy has been observed in tomato (Vardy et al, 1989), banana (Qrtiz and Vuylsteke, 1995) and cucumber (Rudich et al, 1977). A transgenic approach has been successfully applied for obtaining parthenocarpic fruits in eggplant and tobacco (Rotino et al, 1997). Parthenocarpy is a highly appreciated trait by consumers and process companies, not only because of easy processing (e.g.…”

Section: Introductionmentioning

confidence: 99%

Selection of Sweet Pepper (Capsicum Annuum L.) Genotypes for Parthenocarpic Fruit Growth

Tiwari¹,

Dassen

Heuvelink³

2007

Acta Hortic.

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Yield irregularity and blossom-end-rot are major problems in sweet pepper production, which can be reduced by parthenocarpy. However no commercial parthenocarpic cultivars are available. The purpose of this study was to find parthenocarpic genotype(s) of sweet pepper with the ability to produce good quality fruits without seeds. Eleven genotypes of sweet pepper were studied at normal (20/20°C D/N) and at low night temperature (20/10°C D/N), in two greenhouse compartments from January till May. Fruit length, diameter, fresh and dry weight and number of seeds per fruit were measured. A higher percentage of parthenocarpic fruits was observed for all genotypes at low night temperature compared to normal temperature. Within the genotypes which showed at least 60% parthencarpic fruit growth at low night temperature, two groups were distinguished, which showed a different expression of parthenocarpy in response to the environment. In one set of genotypes (Line 1 and Line 3) high expressivity for parthenocarpy was found irrespective of night temperature. In another set of genotypes (Gen A, Gen B, Gen C, Lamuyo A, Lamuyo B and Bruinsma Wonder), a high level of parthenocarpy was expressed at low night temperature only, which may be due to non-viable pollen at low night temperature. Further evaluation of the latter six genotypes resulted in one genotype (Bruinsma Wonder) for which the absence of seeds only marginally influenced shape and size of fruits. These selected genotypes may eventually lead to an exploitation of parthenocarpy in sweet pepper breeding.

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Genetic engineering of parthenocarpic plants

Cited by 227 publications

References 12 publications

RNA Interference Silencing of Chalcone Synthase, the First Step in the Flavonoid Biosynthesis Pathway, Leads to Parthenocarpic Tomato Fruits

RNA Interference Silencing of Chalcone Synthase, the First Step in the Flavonoid Biosynthesis Pathway, Leads to Parthenocarpic Tomato Fruits

Abscisic acid levels in tomato ovaries are regulated by LeNCED1 and SlCYP707A1

Selection of Sweet Pepper (Capsicum Annuum L.) Genotypes for Parthenocarpic Fruit Growth

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