Analysis of tomato polygalacturonase expression in transgenic tobacco.

Osteryoung, Katherine W.; Toenjes, Kurt A.; Hall, Bonnie L.; Winkler, Vickie; Bennett, A. B.

doi:10.1105/tpc.2.12.1239

Cited by 42 publications

(18 citation statements)

References 36 publications

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“…The results are similar to the findings of scientists who worked on the role of PG during fruit development in various kinds of fruits and found a correlation, as PG activity and softening occurs simultaneously in cherry (Barrett and Gonzalez, 1994), date (Hasegawa et al, 1969), durian (Ketsa and Daengkanit, 1999), kiwifruit (Wang et al, 2000), mango (Ketsa et al, 1998), papaya (Paull and Chen, 1983), pear (Ahmed and Labavitch, 1980), pepper (Rao and Paran, 2003;Arancibia and Motsenbocker, 2006), tobacco (Osteryoung et al, 1990), and tomato (Hobson, 1965;Crookes and Grierson, 1983;Huber, 1983;DellaPenna et al, 1987;Bird et al, 1988;Biggs and Handa, 1989;Smith et al, 1990;Fenwick et al, 1996).…”

Section: Discussionsupporting

confidence: 78%

“…It is believed that transition of fruit ripening is the result of a complex developmental program influencing metabolic processes in each compartment of the cell. Primarily, this developmental program occurs due to the degradation of pectic polymers in the cell wall, which is brought about by the action of ripening-induced enzymes, such as polygalacturonase (PG) (Themmen et al, 1982;Crookes and Grierson, 1983;Huber, 1983;Giovannoni et al, 1989;Osteryoung et al, 1990). Although the ripening mechanism has been widely studied and reviewed, it is still far from being clearly understood (Brady, 1987).…”

Section: Introductionmentioning

confidence: 99%

“…The softening phenomenon influenced by PG in fruits like apples, cherries, dates, durians, grapes, kiwis, melons, peaches, pears, pineapples, tobacco, and tomatoes during ripening has been studied during the past two decades and substantial evidence has been collected, suggesting that the cell wall enzyme PG plays a major role in the entire ripening process (Hobson, 1965;Hasegawa et al, 1969;Ahmed and Labavitch, 1980;Paull and Chen, 1983;Osteryoung et al, 1990;Barrett and Gonzalez, 1994;Ketsa et al, 1998;Ketsa and Daengkanit, 1999).…”

Section: Introductionmentioning

confidence: 99%

“…Although the ripening mechanism has been widely studied and reviewed, it is still far from being clearly understood (Brady, 1987). Some authors have reported that the fruit softening is largely associated with breakdown of the fruit cell wall (Crookes and Grierson, 1983;Osteryoung et al, 1990;Rao and Paran, 2003). The primary cell wall is composed of several polymers, including cellulose, glycans and pectins that are modified during fruit ripening (Brummell and Harpster, 2001;Giovannoni, 2001).…”

Section: Introductionmentioning

confidence: 99%

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Activity and expression of polygalacturonase vary at different fruit ripening stages of sweet pepper cultivars

Ahmed

Gong²,

Khan³

et al. 2011

Genet. Mol. Res.

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Section: Discussionsupporting

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Activity and expression of polygalacturonase vary at different fruit ripening stages of sweet pepper cultivars

Ahmed

Gong²,

Khan³

et al. 2011

Genet. Mol. Res.

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“…Either up-and down-regulation in tomato of an endogenous gene encoding an endopolygalacturonase involved in fruit softening had no apparent effect on growth and development (Giovannoni et al, 1989;Smith et al, 1990). The expression of a tomato PG in tobacco (Nicotiana tabacum) resulted in no phenotype (Osteryoung et al, 1990), whereas the overexpression of an apple (Malus domestica) fruit PG in apple resulted in novel phenotypes involving changes in cell adhesion (Atkinson et al, 2002).…”

mentioning

confidence: 99%

Targeted Modification of Homogalacturonan by Transgenic Expression of a Fungal Polygalacturonase Alters Plant Growth

et al. 2004

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Pectins are a highly complex family of cell wall polysaccharides comprised of homogalacturonan (HGA), rhamnogalacturonan I and rhamnogalacturonan II. We have specifically modified HGA in both tobacco (Nicotiana tabacum) and Arabidopsis by expressing the endopolygalacturonase II of Aspergillus niger (AnPGII). Cell walls of transgenic tobacco plants showed a 25% reduction in GalUA content as compared with the wild type and a reduced content of deesterified HGA as detected by antibody labeling. Neutral sugars remained unchanged apart from a slight increase of Rha, Ara, and Gal. Both transgenic tobacco and Arabidopsis were dwarfed, indicating that unesterified HGA is a critical factor for plant cell growth. The dwarf phenotypes were associated with AnPGII activity as demonstrated by the observation that the mutant phenotype of tobacco was completely reverted by crossing the dwarfed plants with plants expressing PGIP2, a strong inhibitor of AnPGII. The mutant phenotype in Arabidopsis did not appear when transformation was performed with a gene encoding AnPGII inactivated by site directed mutagenesis.Although biochemical events causing structural changes of cell walls are expected to influence plant growth and development (Pilling et al., 2000;Bouton et al., 2002), the degradation and remodeling of cell wall constituents during development appear to be of considerable complexity and far from being fully understood. For example, the remodeling of pectin, which is thought to impact upon processes such as adhesion between cells and plant growth, requires the action of several different enzyme classes (Ridley et al., 2001). The complex role of pectin in the dynamics of cell walls is further indicated by the presence of large families of these pectic enzymes in plant genomes. For example, more than 50 genes encoding putative polygalacturonases (PGs) have been identified in Arabidopsis (Arabidopsis Genome Initiative, 2000).Indications that the pectic polymers homogalacturonan (HGA), rhamnogalacturonan-I (RG-I), and rhamnogalacturonan-II (RG-II) play an important role in plant development have been obtained by analyzing several cell wall mutants, most of which have been obtained by mutagenesis of Arabidopsis. Among these, Arabidopsis emb30 mutants, having a mutation in a gene putatively involved in the secretory pathway, show an abnormal localization and accumulation of pectin in intercellular/interstitial spaces rather than in the corners. Cells of emb30 mutants are larger than those of the wild type and do not adhere well to each other; the seeds are impaired in the control of cell division, expansion, and polarity and do not develop as wild type (Shevell et al., 2000). The Arabidopsis quartet mutants have microspores that fail to separate during pollen development as a result of the persistence of pectin in the pollen mother cell wall (Rhee and Somerville, 1998). The Arabidopsis mur1 mutation, leading to a deficiency in fucosyl residues, affects RG-II, reducing its capacity to dimerize through the formation of boron diest...

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The Composition and Structure of Plant Primary Cell Walls

O’Neill

York

2018

Annual Plant Reviews Online

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The sections in this article areIntroductionDefinition of the WallThe Composition of the Primary Cell WallThe Macromolecular Components of Primary WallsDetermination of the Structures of Primary Wall PolysaccharidesOligosaccharide Profiling of Cell Wall PolysaccharidesThe Structures of the Polysaccharide Components of Primary WallsThe Pectic PolysaccharidesOther Primary Wall ComponentsGeneral Features of Wall Ultrastructural ModelsConclusionsAcknowledgements

show abstract

Analysis of tomato polygalacturonase expression in transgenic tobacco.

Cited by 42 publications

References 36 publications

Activity and expression of polygalacturonase vary at different fruit ripening stages of sweet pepper cultivars

Activity and expression of polygalacturonase vary at different fruit ripening stages of sweet pepper cultivars

Targeted Modification of Homogalacturonan by Transgenic Expression of a Fungal Polygalacturonase Alters Plant Growth

The Composition and Structure of Plant Primary Cell Walls

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