Glycosyl-linkage composition of tomato fruit cell wall hemicellulosic fractions during ripening

Hemicelluloses were extracted from isolated tomato ( Lycopersicon esculentum Mill. cv. Rutgers) pericarp cell wall material at 3 different stages of ripeness with 4 M and 8 M KOH. Little change in molecular weight or composition of 4 M KOH-extracted material was observed during ripening. However, the composition of 8 M KOH-extracted material changed, and a relative increase in polymers of < 40 kDa was observed during ripening. Changes in glycosyl linkage composition of the 8 M KOH hemicellulosic material were detected, including increases in 4-linked mannosyl, 4,6-linked mannosyl, and 4-linked glucosyl, and decreases in 5-linked arabinosyl residues in polymers of < 40 kDa, and decreases in terminal glocosyl residues in polymers of > 40 kDa. These data may indicate that de novo hemicellulose synthesis occurs throughout tomato fruit ripening, even at the red ripe stage.     

Function of the polygalacturonase convertor in ripening tomato fruit

In extracts from pericarp tissue of ripening tomato ( Lycopersicon esculentum Mill. cv, Sonato) fruits, two isoenzymes of polygalacturonase (E.C. 3.2.1.15), PG1 and PG2, are usually found. Also in such extracts, or as part of PG1, a convertor (CV) occurs. Incubation of PG2 with this CV gives rise to PG1 or a different isoenzyme, PGx, that is also stable at 65°C but differs in _pH optimum and size from PG1. It appears that CV has two affinity sites that can bind with PG2 or with a polydextran. PG1 is an extraction artifact, consisting of one molecule of CV and two molecules of PG2. PGx is made up of one molecule of CV and one molecule of PG2. It is the CV part of PGx that binds to polydextrans such as Blue Dextran 2000, Sephadex G-100, and cell wall preparations. In this last form PGx is the physiologically active form of the enzyme, solubilizing demethylated pectin.
On Sephacryl S-300, CV appears to have a molecular weight of 81 kDa, but because of its heat stability and partial leakage through a 10 kDa cut-off membrane, it might be a much smaller, rod-like molecule. The polygalacturonase convertor might be a lectin without intrinsic enzyme activity, with a function to immobilize, stabilize and activate enzymic proteins in the cell wall.     

Sugar uptake by protoplasts isolated from tomato fruit tissues during various stages of fruit growth

The uptake of radioactive glucose and sucrose by protoplasts isolated from pericarp and placenta tissues of tomato ( Lycopersicon esculentum cv. Counter) fruit was investigated in relation to the dry matter accumulation rates of these tissues. Uptake of glucose by protoplasts isolated from pericarp tissue was highest in fruit of around 20 g fresh weight or 25 days after anthesis. Sucrose uptake by pericarp protoplasts was lower than that of glucose and did not show a peak of uptake. The maximum rate of glucose uptake by protoplasts from the pericarp was at the time when the tomato fruit was accumulating dry matter at the highest rate. Glucose uptake by placenta protoplasts was lower and at a similar level as sucrose.
Protoplast uptake of glucose, but not of sucrose, was partially inhibited by (1) p -chloromercuribenzene sulphonic acid, a sulphydryl group modifier; (2) erythrosin B, an H⁺-ATPase inhibitor; and (3) valinomycin, a K⁺-ionophore, suggesting that membrane transport of glucose by tomato fruit sink cells may be a carrier-mediated, energy-dependent process.
The main route of carbohydrate accumulation by tomato fruit during the period of rapid fruit growth may be by cleavage of sucrose by apoplastic acid invertase prior to hexose transport across the plasma membrane.     

Regulation of tomato fruit growth by epidermal cell wall enzymes

Water relations of tomato fruit and the epidermal and pericarp activities of the putative cell wall loosening and tightening enzymes Xyloglucan endotransglycosylase (XET) and peroxidase were investigated, to determine whether tomato fruit growth is principally regulated in the epidermis or pericarp. Analysis of the fruit water relations and observation of the pattern of expansion of tomato fruit slices in vitro , has shown that the pericarp exerts tissue pressure on the epidermis in tomato fruit, suggesting that the rate of growth of tomato fruit is determined by the physical properties of the epidermal cell walls. The epidermal activities of XET and peroxidase were assayed throughout fruit development. Temporal changes in these enzyme activities were found to correspond well with putative cell wall loosening and stiffening during fruit development. XET activity was found to be proportional to the relative expansion rate of the fruit until growth ceased, and a peroxidase activity weakly bound to the epidermal cell wall appeared shortly before cessation of fruit expansion. No equivalent peroxidase activity was detected in pericarp tissue of any age. It is therefore plausible that the expansion of tomato fruit is regulated by the combined action of these enzyme activities in the fruit epidermis.     

Water relations and growth of tomato fruit pericarp tissue

The water relations of young tomato fruit pericarp tissue were examined and related to tissue expansion. The relationship between bulk turgor pressure and tissue expansion (as change in fresh mass or length of tissue) was determined in slices of pericarp cut from young, growing fruit by incubation in different osmotic concentrations of polyethylene glycol 6000 or mannitol. The bulk turgor of this tissue was low (about 0.2 MPa), even in fruit from plants that were otherwise fully turgid, whether measured psychrometrically or by length change in osmotic solutions. The rate of tissue growth at maximum turgor was less than that at moderate turgor unless calcium was added to the incubation medium. However, added calcium also decreased the rate of growth at lower turgor pressures. Yield turgor was < 0.1 MPa, but it was increased by the addition of calcium ions. Electrolyte leakage from tissue was greatest at maximum turgor pressure but was decreased by the addition of calcium ions or osmoticum. Tissue growth was unaffected by a range of plant growth regulators (IAA, abscisic acid, benzyladenine and GA₃) but was inhibited, particularly at high turgor, by low concentrations of malic or citric acid. The low turgor pressure of pericarp tissue could be due to the presence of apoplastic solutes within the pericarp, and evidence for this is discussed. Thus, fruit tissue may be able to maintain optimal expansion rates only at moderate turgor and low calcium concentration.     

Control and manipulation of gene expression during tomato fruit ripening

Ripening is a complex developmental process involving changes in the biochemistry, physiology and gene expression of the fruit. It is an active process characterised by changes in all cellular compartments. cDNA cloning has been used as an approach to analyse changes in gene expression during fruit ripening. This has revealed that several genes are switched on specifically during fruit ripening, including one encoding polygalacturonase (PG), a major cell wall protein. These cDNA clones have been used to study the expression of the genes in normal and ripening mutant fruits, and under environmental stress conditions.The PG gene has been isolated and it has been demonstrated that 1450 bases 5 of the coding region are sufficient for the tissue- and development-specific expression of a bacterial marker gene in transgenic tomatoes. Antisense RNA techniques have been developed to generate novel mutant tomatoes in which the biochemical function of this enzyme and its involvement in fruit softening has been tested.     

Physiology and firmness determination of ripening tomato fruit

Tomato ( Lycopersicon esculentum Mill.) genotypes varying in intrinsic firmness were examined to determine the quantitative relationships between polygalacturonase (EC 3.2.1.15) activity, firmness and other ripening parameters including rate (days from mature-green to full red) and intensity (rate of ethylene production at climacteric peak) of ripening. Texture, respiration and ethylene production were monitored in the immature-green through the red (ripe) stages of development. Polygalacturonase activity was measured by direct assay of salt-extractable wall protein or by monitoring the release of pectins from isolated, enzymically active wall. In all fruit, polygalacturonase activity was highly correlated with pericarp softening, but only moderately correlated with softening of whole fruit (r = 0.920 and 0.757, respectively). Polygalacturonase activity was positively correlated with cell-wall autolytic activity in pink (r = 0.969) and red (r = 0.900) fruit. Firmer genotypes exhibited lower rates of respiration and ethylene production during ripening. Polygalacturonase activity in isolates prepared from fruit at the climacteric peak was positively correlated with ethylene production and respiration, and negatively correlated with days to ripening (r = 0.929, 0.805, and -0.791, respectively). The data demonstrate the importance of selecting the appropriate method of firmness determination and are consistent with the hypothesis that pectin fragments released by polygalacturonase contribute to the production of autocatalytic (system II) ethylene.     

Internal carbon dioxide and ethylene levels in ripening tomato fruit attached to or detached from the plant

The carbon dioxide and ethylene concentrations in tomato fruit ( Lycopersicon esculentum cv. Castelmart) and their stage of ripeness (characteristic external color changes) were periodically measured in fruit attached to and detached from the plant. An external collection apparatus was attached to the surface of individual tomato fruit to permit non-destructive sampling of internal gases. The concentration of carbon dioxide and ethylene in the collection apparatus reached 95% of the concentration in the fruit after 8 h. Gas samples were collected every 24 h. A characteristic climacteric surge in carbon dioxide (2-fold) and ethylene (10-fold) concentration occurred coincident with ripening of detached tomato fruit. Fruit attached to the plant exhibited a climacteric rise in ethylene (20-fold) concentration during ripening, but only a linear increase in carbon dioxide concentration. The carbon dioxide concentration increases in attached fruit during ripening, but the increase is a continuation of the linear increase seen in both attached and detached fruit before ripening and does not exhibit the characteristic pattern normally associated with ripening climacteric fruit. In tomato fruit, it appears that a respiratory climacteric per se, which has been considered intrinsic to the ripening of certain fruit, may not be necessary for the ripening of "climacteric" fruit at all, but instead may be an artifact of using harvested fruit.     

The use of transgenic and naturally occurring mutants to understand and manipulate tomato fruit ripening

In the years since we last reviewed the use of mutants to study tomato fruit ripening ( Grierson et al. 1987 ), considerable information has been gained by the cloning, sequencing and identification of many mRNAs implicated in this developmental process. Genes involved in cell wall degradation, colour change and ethylene synthesis have been cloned, and antisense techniques have been developed and used to produce genetically engineered mutant fruit deficient in these aspects of ripening (see Gray et al. 1992 ). Recently, a previously cloned ripening gene has been used to complement a naturally occurring fruit colour mutant, yellow flesh ( Fray & Grierson 1993a ), and a ripening impaired mutant, ripening inhibitor, has been used to identify several new ripening-related mRNAs ( Picton et al. 1993b ). The chromosomal region bearing the ripening inhibitor mutation has been subjected to high-resolution mapping ( Churchill, Giovannoni & Tanksley 1993 ) and chromosome walking experiments are in progress to identify this gene.     

果实成熟乙烯相关基因工程研究进展(综述)

果实成熟是一个复杂的生理生化过程,而乙烯是引发果实成熟的主要因素.本文简述乙烯合成过程中S-腺苷甲硫氨酸水解酶、ACC合成酶与ACC氧化酶、ACC脱氨酶基因和乙烯受体突变体的特性及克隆;同时,评述利用基因工程技术控制果实成熟的应用前景.     

Dual effect of 2, 4-D on ethylene production and ripening of tomato fruit tissue

Tomato fruits (Lycopersicon esculentum Mill. cv. Indian River) were treated with aqueous solutions of 2, 4-dichlorophenoxyacetic acid (2, 4-D) and the effects on respiration, ethylene production, and ripening were examined. 10-³ and 10-⁵ M 2, 4-D solutions were used. Dipping treatment of whole fruit picked at the 74% stage of development, gave an increase in respiration and ethylene production, the effect being directly related to 2, 4-D concentration. Ripening was advanced relative to control fruit.
Tomato disks cut from the pericarp tissue of fruit picked at the 81% stage of development were vacuum-infiltrated with the same 2, 4-D solutions. In these disks the increase in respiration continued longer compared to control disks. Ethylene production was considerably increased, and after an initial recovery the 2, 4-D-treated disks showed another increase at a much faster rate than controls. However, contrary to what could be expected from this increase in ethylene, ripening was delayed. Nevertheless, all disk samples showed advance ripening compared to whole fruit of the same age, indicating that they could not recover completely from the effect of cutting and treatment.
The results showed that 2, 4-D causes a dual effect in tomato fruit tissue: an increase in ethylene production which promotes ripening, and a delay in ripening. This last effect, depending on the uniformity of the auxin distribution and its concentration, prevails.     

Peroxidase isozyme patterns in the skin of maturing tomato fruit

The cessation of tomato fruit growth is thought to be induced by an increase in the activity of enzymes which rigidify cell walls in the fruit skin. Peroxidase could catalyse such wall‐stiffening reactions, and marked rises in peroxidase activity were recently reported in skin cell walls towards fruit maturity. Peroxidase isoforms in the fruit are here analysed using native gel electrophoresis. New isoforms of apparent M_r 44, 48 and 53 kDa are shown to appear in cell walls of the fruit skin at around the time of cessation of growth. It is inferred that these isozymes are present in the cell wall in vivo. Fruit from a range of non‐ripening mutants were also examined. Some of these do not soften or ripen for many weeks after achieving their final size. The new isozymes were found in skin cell walls of mature fruit in each of these mutants, as in the wild‐type and commercial varieties. It is concluded that the late‐appearing isozymes are not associated with fruit ripening or softening, and are probably not ethylene‐induced. They may act to control fruit growth by cross‐linking wall polymers within the fruit skin, thus mechanically stiffening the walls and terminating growth.     

Genetic engineering of parthenocarpic fruit development in tomato

Parthenocarpy was engineered in two genotypes of Lycopersicon esculentum Mill. by using the DefH9-iaaM chimeric gene. The parthenocarpic trait consists of fruit set and growth in the absence of fertilization. Seedless parthenocarpic fruits were obtained from emasculated flowers, and fruits with seeds from pollinated flowers. All parthenocarpic tomato plants analysed expressed the DefH9-iaaM gene during flower development. The fruit set percentage of emasculated transgenic flowers was similar to that of control plants. In 7 out of 8 independent transgenic plants, the fresh weight of fruits derived from pollinated or emasculated flowers did not significantly differ from that of fruits obtained by pollination of the control plants. The pH of the parthenocarpic fruit was generally unaffected and the soluble solid concentration was either unchanged or increased. Thus, the DefH9-iaaM gene is a genetic tool that might be used to improve tomato productivity.