通过表达ACC脱氨酶基因控制番茄果实的成熟

乙烯在跃变型果实的成熟过程中起着触发呼吸跃变和促进果实成熟的作用。细菌来源的1-氨基环丙烷-1-羧酸(ACC)脱氨酶能降解乙烯的直接前体ACC,从而抑制植物体内乙烯的合成。我们用PCR方法从假单孢杆菌中克隆到ACC脱氨酶基因并通过农杆菌介导的方法将其转入番茄(Lycopersicun esculentum)中。再生植株经Southern blot检测证明,ACC脱氨酶基因已整合到番茄基因组中并稳定表达。转基因番茄果实成熟期的推迟时间与体内乙烯的抑制程度有相关性。转基因番茄植株乙烯的合成降低80%左右,果实在离体条件下可保鲜75d左右。研究ACC脱氢酶基因在植物体内的作用可阐明高等植物体内乙烯的作用机理并为培育耐贮藏果蔬品种打下基础。     

Ripening Physiology of Fruit from Transgenic Tomato (Lycopersicon esculentum) Plants with Reduced Ethylene Synthesis

The physiological effects of reduced ethylene synthesis in a transgenic tomato (Lycopersicon esculentum) line expressing 1-aminocyclopropane-1-carboxylic acid (ACC) deaminase enzyme have been examined. Fruit from the transgenic line 5673 ripen significantly slower than control fruit when removed from the vine early in ripening. In contrast, fruit that remain attached to the plants ripen much more rapidly, exhibiting little delay relative to the control. Ethylene determinations on attached fruit revealed that there was significantly more internal ethylene in attached than detached fruit. The higher ethylene content can fully account for the observed faster on-the-vine ripening. All of the data are consistent with a catalytic role for ethylene in promoting many, although not all, aspects of fruit ripening. Biochemical analyses of transgenic fruit indicated no significant differences from controls in the levels of ACC oxidase or polygalacturonase. Because transgenic fruit are significantly firmer than controls, this last result indicates that other enzymes may have a significant role in fruit softening.     

Xyloglucan-derived oligosaccharides induce ethylene synthesis in persimmon (Diospyros khaki L.) fruit

In this work the effect of injection of xyloglucan-derived oligosaccharides (XGOs) into whole persimmon (Diospyros khaki L.) fruits on ethylene biosynthesis was investigated. Fruits collected during different ripening stages produced low levels of ethylene without a climacteric-like peak. Pretreatment of these fruits with 10 cm³ C2H4 m^-3 for 8 h stimulated little or no endogenous ethylene production. However, when persimmon fruits were injected with a mixture of XGOs a burst in ethylene production was observed compared with water-injected control fruits or fruits injected with different monosaccharide solutions. In order to study the influence of oligosaccharide structure and fruit ripening stage on the ability of XGOs to induce ethylene synthesis, fucosylated and non-fucosylated XGOs were injected into persimmon fruits harvested at two different ripening stages. Both oligosaccharide structures were able to induce ethylene production. Induction of ethylene by XGOs was much more evident in fruits harvested later in time, indicating that the process is developmentally regulated. The levels of 1-aminocyclopropane-1-carboxylic acid (ACC) in injected persimmon fruits were also examined. This study showed that the increase in the rate of ethylene biosynthesis induced by XGOs was accompanied by the accumulation of its metabolic precursor ACC.     

An Antisense Gene Stimulates Ethylene Hormone Production during Tomato Fruit Ripening

The ripening of many fruits is controlled by an increase in ethylene hormone concentration. E8 is a fruit ripening protein that is related to the enzyme that catalyzes the last step in the ethylene biosynthesis pathway, 1-aminocyclopropane-1-carboxylic (ACC) oxidase. To determine the function of E8, we have transformed tomato plants with an E8 antisense gene. We show here that the antisense gene inhibits the accumulation of E8 protein during ripening. Whereas others have shown that reduction of ACC oxidase results in reduced levels of ethylene biosynthesis, we find that reduction of the related E8 protein produces the opposite effect, an increase in ethylene evolution specifically during the ripening of detached fruit. Thus, E8 has a negative effect on ethylene production in fruit.     

Regulation of Ethylene Biosynthesis in Avocado Fruit during Ripening

Preclimacteric avocado (Persea americana Mill.) fruits produced very little ethylene and had only a trace amount of l-aminocyclopropane-1-carboxylic acid (ACC) and a very low activity of ACC synthase. In contrast, a significant amount of l-(malonylamino)cyclopropane-1-carboxylic acid (MACC) was detected during the preclimacteric stage. In harvested fruits, both ACC synthase activity and the level of ACC increased markedly during the climacteric rise reaching a peak shortly before the climacteric peak. The level of MACC also increased at the climacteric stage. Cycloheximide and cordycepin inhibited the synthesis of ACC synthase in discs excised from preclimacteric fruits. A low but measurable ethylene forming enzyme (EFE) activity was detected during the preclimacteric stage. During ripening, EFE activity increased only at the beginning of the climacteric rise. ACC synthase and EFE activities and the ACC level declined rapidly after the climacteric peak. Application of ACC to attached or detached fruits resulted in increased ethylene production and ripening of the fruits. Exogenous ethylene stimulated EFE activity in intact fruits prior to the increase in ethylene production. The data suggest that conversion of S-adenosylmethionine to ACC is the major factor limiting ethylene production during the preclimacteric stage. ACC synthase is first synthesized during ripening and this leads to the production of ethylene which in turn induces an additional increase in ACC synthase activity. Only when ethylene reaches a certain level does it induce increased EFE activity.     

The use of 1-methylcyclopropene (1-MCP) on fruits and vegetables

The recent availability of the inhibitor of ethylene perception, 1-methylcyclopropene (1-MCP), has resulted in an explosion of research on its effects on fruits and vegetables, both as a tool to further investigate the role of ethylene in ripening and senescence, and as a commercial technology to improve maintenance of product quality. The commercialization of 1-MCP was followed by rapid adoption by many apple industries around the world, and strengths and weaknesses of the new technology have been identified. However, use of 1-MCP remains limited for other products, and therefore it is still necessary to speculate on its commercial potential for most fruits and vegetables. In this review, the effects of 1-MCP on fruits and vegetables are considered from two aspects. First, a selected number of fruit (apple, avocado, banana, pear, peaches and nectarines, plums and tomato) are used to illustrate the range of responses to 1-MCP, and indicate possible benefits and limitations for commercialization of 1-MCP-based technology. Second, an outline of general physiological and biochemical responses of fruits and vegetables to the chemical is provided to illustrate the potential for use of 1-MCP to better understand the role of ethylene in ripening and senescence processes.     

Chilling-Induced Ethylene Production in the Peel and Pulp of Banana

Ethylene production rates and 1-aminocyclopropane-1-carboxylic acid (ACC) synthetase activities were 0. 78,0.91 nl· g-l ·h-land 0.02,0.05 nmol·g-1·h-1 respectively in the peel and pulp of newly harvested banana fruits(Musa acuminata Colla “warf cavendish”),their ethylene-forming enzyme(EFE)activities were yet as high as 10.5 and 5.1 nl·g-1·h-1. When the fruits were chilled at 1.5℃ ,the ethylene production and EFE activities of the peel and pulp kept decreasing with the time course of chilling treatment. However, after these chilled fruits were transferred to 20℃ for 24 h,their ACC synthetase activities increased markedly,and ethylene production had separate peaks(1.75 and 2.45 nl·g-1 ·h-1) in the peel and pulp. In this case,the endogenous low content of S-adenosylmethionine (SAM)in vivo was insufficient for its ACC synthesis, The inhibitory effect of cycloheximide on ACC synthesis showed that chilling-induced ethylene production was mainly the result of activity of the resynthesized ACC synthetase induced by chilling treatment. The production of chilling-induced ethylene could be good indicator of chilling injury, but it is unlikely an indicator of chilling damage during ripening process in banana. In the severly chilling-injured fruits, both the peel and pulp still had the capability of converting ACC to ethylene.     

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.     

Identification of mRNAs with enhanced expression in ripening strawberry fruit using polymerase chain reaction differential display

Fruit ripening is a complex developmental process that involves specific changes in gene expression and cellular metabolism. In climateric fruits these events are coordinated by the gaseous hormone ethylene, which is synthesized autocatalytically in the early stages of ripening. Nonclimacteric fruits do not synthesize or respond to ethylene in this manner, yet undergo many of the same physiological and biochemical changes associated with the production of a ripe fruit. To gain insight into the molecular determinants associated with nonclimacteric fruit ripening, we examined mRNA populations in ripening strawberry fruit using polymerase chain reaction (PCR) differential display. Five mRNAs with ripening-enhanced expression were identified using this approach. Three of the mRNAs appear to be fruit-specific, with little or no expression detected in vegetative tissues. Sequence analysis of cDNA clones revealed positive identities for three of the five mRNAs based on homology to known proteins. These results indicate that the differential display technique can be a useful tool to study fruit ripening and other developmental processes in plants at the RNA level.     

Tolerance of transgenic canola expressing 1-aminocyclopropane-1-carboxylic acid deaminase to growth inhibition by nickel.

Plant growth-promoting bacteria are useful to phytoremediation strategies in that they confer advantages to plants in contaminated soil. When plant growth-promoting bacteria contain the enzyme 1-aminocyclopropane-1-carboxylic acid (ACC) deaminase, the bacterial cell acts as a sink for ACC, the immediate biosynthetic precursor of the plant growth regulator ethylene thereby lowering plant ethylene levels and decreasing the negative effects of various environmental stresses. In an effort to gain the advantages provided by bacterial ACC deaminase in the phytoremediation of metals from the environment two transgenic canola lines with the gene for this enzyme were generated and tested. In these transgenic canola plants, expression of the ACC deaminase gene is driven by either tandem constitutive cauliflower mosaic virus (CaMV) 35S promoters or the root specific rolD promoter from Agrobacterium rhizogenes. Following the growth of transgenic and non-transformed canola in nickel contaminated soil, it was observed that the rolD plants demonstrate significantly increased tolerance to nickel compared to the non-transformed control plants.     

A quantitative analysis of root distortion from contrasting wheat cropping systems

Aims

Bacterial ACC deaminase is one of the key tools to ameliorate plant stress by lowering ethylene level in plants. The effects of ACC deaminase-producing bacteria on the volatile profiles in plants have not been examined to date. To address this, we performed metabolic profiling of volatiles in carrots following inoculation of the bacteria producing ACC deaminase.

Methods

We isolated ACC deaminase-producing bacteria from the inner part of the fruits and vegetables grown on organic farms by culturing on ACC-containing media, and screened them with PCR for the acdS gene, mungbean growth assay, and in vitro ACC deaminase activity. The isolated endophytes were evaluated for their ability to alter volatile profiles in carrots.

Results

Eleven bacterial strains possessing the activity to cleave ACC were selected among the 60 isolates grown on the medium containing ACC as a sole N source. Three of them that belonged to Pseudomonas could reduce the levels of (E)-2-hexenal and the other green leaf volatiles (GLVs) and terpenoids in the carrot leaves following inoculation of the seeds.

Conclusions

The isolated endophytes with ACC deaminase activity could alter the composition of volatiles in plants, probably through lowering ethylene level in the plant.

     

Wound ethylene and 1-aminocyclopropane-1-carboxylate synthase in ripening tomato fruit

Ethylene production, 1-aminocyclopropane-1-carboxylic acid (ACC) levels and ACC-synthase activity were compared in intact and wounded tomato fruits (Lycopersicon esculentum Mill.) at different ripening stages. Freshly cut and wounded pericarp discs produced relatively little ethylene and had low levels of ACC and of ACC-synthase activity. The rate of ethylene synthesis, the level of ACC and the activity of ACC synthase all increased manyfold within 2 h after wounding. The rate of wound-ethylene formation and the activity of wound-induced ACC synthase were positively correlated with the rate of ethylene production in the intact fruit. When pericarp discs were incubated overnight, wound ethylene synthesis subsided, but the activity of ACC synthase remained high, and ACC accumulated, especially in discs from ripe fruits. In freshly harvested tomato fruits, the level of ACC and the activity of ACC synthase were higher in the inside parts of the fruit than in the pericarp. When wounded pericarp tissue of green tomato fruits was treated with cycloheximide, the activity of ACC synthase declined with an apparent half life of 30–40 in. The activity of ACC synthase in cycloheximide-treated, wounded pericarp of ripening tomatoes declined more slowly.Abbreviation ACC 1-aminocyclopropane-1-carboxylic acid     

Manipulation of ethylene biosynthesis

The plant hormone ethylene is involved in many plant processes ranging from seed germination to leaf and flower senescence and fruit ripening. Ethylene is synthesized from methionine, via S-adenosyl-L-methionine (SAM) and 1-amino-cyclopropane-1-carboxylic acid (ACC). The key ethylene biosynthetic enzymes are ACC synthase (ACS) and ACC oxidase (ACO). Manipulation of ethylene biosynthesis by chemicals and gene technology is discussed. Biotechnological modification of ethylene synthesis is a promising method to prevent spoilage of agricultural and horticultural products.     

Reduced symptoms of Verticillium wilt in transgenic tomato expressing a bacterial ACC deaminase

Ethylene evolved during compatible or susceptible disease interactions may hasten and/or worsen disease symptom development; if so, the prevention of disease-response ethylene should reduce disease symptoms. We have examined the effects of reduced ethylene synthesis on Verticillium wilt (causal organism, Verticillium dahliae) of tomato by transforming tomato with ACC deaminase, which cleaves ACC, the immediate biosynthetic precursor of ethylene in plants. Three promoters were used to express ACC deaminase in the plant: (i) CaMV 35S (constitutive expression); (ii) rolD (limits expression specifically to the site of Verticillium infection, i.e. the roots); and (iii) prb-1b (limits expression to certain environmental cues, e.g. disease infection). Significant reductions in the symptoms of Verticillium wilt were obtained for rolD- and prb-1b-, but not for 35S-transformants. The pathogen was detected in stem sections of plants with reduced symptoms, suggesting that reduced ethylene synthesis results in increased disease tolerance. The effective control of formerly recalcitrant diseases such as Verticillium wilt may thus be obtained by preventing disease-related ethylene production via the tissue-specific expression of ACC deaminase.     

Selected ion monitoring/isotope dilution mass spectrometric determination of 1-aminocyclopropane-1-carboxylic acid levels in ripening tomato fruit

A new method is described for the quantitation of 1-aminocyclopropane-1-carboxylic acid (ACC), the immediate precursor of ethylene in plants. [2,2,3,3,-2H4]ACC has been synthesized and used as an internal standard for selected ion monitoring/isotope dilution quantitation of this compound in ripening tomato fruit. These data are compared with those derived from the widely used indirect oxidative ACC assay (which underestimated the ACC levels by between two- and fourfold). The greater accuracy, sensitivity (100X), and specificity of the mass spectrometric method will be of considerable benefit to those interested in factors which control ACC and ultimately ethylene levels since it is believed that ACC synthesis and its oxidative metabolism to ethylene are the key points at which ethylene biosynthesis is regulated.     

A tomato HD-Zip homeobox protein, LeHB-1, plays an important role in floral organogenesis and ripening

Ethylene is required for climacteric fruit ripening. Inhibition of ethylene biosynthesis genes, 1-aminocyclopropane-1-carboxylate (ACC) synthase and ACC oxidase, prevents or delays ripening, but it is not known how these genes are modulated during normal development. LeHB-1, a previously uncharacterized tomato homeobox protein, was shown by gel retardation assay to interact with the promoter of LeACO1 , an ACC oxidase gene expressed during ripening. Inhibition of LeHB-1 mRNA accumulation in tomato fruit, using virus-induced gene silencing, greatly reduced LeACO1 mRNA levels, and inhibited ripening. Conversely, ectopic overexpression of LeHB-1 by viral delivery to developing flowers elsewhere on injected plants triggered altered floral organ morphology, including production of multiple flowers within one sepal whorl, fusion of sepals and petals, and conversion of sepals into carpel-like structures that grew into fruits and ripened. Our findings suggest that LeHB-1 is not only involved in the control of ripening but also plays a critical role in floral organogenesis.     

Plant encoded 1-aminocyclopropane-1-carboxylic acid deaminase activity implicated in different aspects of plant development

Proper plant development is dependent on the coordination and tight control of a wide variety of different signals. In the study of the plant hormone ethylene, control of the immediate biosynthetic precursor 1-aminocyclopropane-1-carboxylic acid (ACC) is of interest as the level of ethylene can either help or hinder plant growth during times of stress. It is known that ACC can be reversibly removed from the biosynthesis pathway through conjugation into other compounds. We recently reported that plants can also irreversibly remove ACC from ethylene production through the activity of a plant encoded ACC deaminase. Heretofore only found in bacteria, we showed that there was ACC deaminase activity in both Arabidopsis and in developing wood of poplar. Here we extend this original work and show that there is also ACC deaminase activity in tomato plants, and that this activity is regulated during tomato fruit development. Further, using an antisense construct of AtACD1 in Arabidopsis, we investigate the role of ACC deamination during salt stress. Together these studies shed light on a new level of control during ethylene production in a wide variety of plant species and during different plant developmental stages.Key words: tomato fruit ripening, wood development, stress response, hormone, antisense, synthesisHormones are a class of signaling molecules produced and sensed at very low levels; therefore control of their biosynthesis is crucial for proper plant development. The plant hormone ethylene has been studied for over a century and can positively impact plant development, such as in the initiation of fruit ripening, but ethylene accumulation can also induce widespread damage during stress responses.¹ Ethylene is produced in two steps from the S-adenosylmethionine (SAM) that is derived from the Yang cycle.² In the first committed step, SAM is converted into 1-aminocyclopropane-1-carboxcylic acid (ACC) via the action of ACC SYNTHASEs (ACSs).³ ACC is then converted into ethylene by ACC OXIDASEs (ACOs), a particular adaptation of flowering plants.⁴ Once ACC is produced, there are few proven pathways that can divert it from conversion into ethylene. ACC can be conjugated into malonyl-1-aminocyclopropane- 1-carboxylic acid (MACC) through the activity of ACC malonyl transferase⁵ or to 1-(γ-L-glutamyl-amino) cyclopropane-1-carboxylic acid (GACC) via γ-glutamyltranspeptidase.⁶ In bacteria, another pathway exists that can break down ACC obtained from plants through an irreversible deamination process.⁷ Through heterologous expression of bacterial ACC DEAMINASEs (ACDs) in plants it has been possible to engineer plants that have reduced production of ethylene by affecting the native pools of ACC.⁸ Until recently no ACC deaminase pathway has ever been proven in plants, although a number of different plant genomes encode genes which bear sequence homology to bacterial ACDs. Should these genes code for active ACDs, this would provide an additional level of control for ethylene production beyond the activity of ACSs and ACOs. Recently we reported that Arabidopsis and Populus have inherent ACC deaminase activity, and we showed that this activity in Arabidopsis is due, in part, to the product of ACC DEAMINASE1 (AtACD1) (At1g48420).⁹ This discovery raises many questions concerning the role of ACC deaminases during ethylene mediated processes in a number of different plant models. We report here some of our preliminary findings in the areas of tomato fruit ripening and salt stress in Arabidopsis.As precise control of ethylene levels is essential during climacteric fruit development, in parallel with our reported studies we also studied ACC deaminase activity in developing tomato fruit. Ethylene production during ripening in tomato is controlled by ethylene receptor turnover¹⁰ and conjugation of ACC by MACC and GACC.^6,11,12 We found that tomatoes also have inherent ACD activity, and that this activity varies over ripening of the fruit (Fig. 1; solid line). During the immature green stage in tomato development ACC deaminase activity was low. This activity increased significantly during the ‘late breaker’ stage, just prior to the orange/red stage of development, and then decreased during later stages of tomato ripening. Also shown in this figure are the predicted levels of ethylene during fruit development. It is interesting to note that the highest amount of ACC deaminase activity coincides with the drop in ethylene levels soon after the breaker stage (Fig. 1; dashed line; based on Brady¹³). Our data would suggest that, in addition to ethylene receptor turnover and GACC and MACC activity, ACC deaminase activity may also help control ethylene levels. It has already been shown that constitutive expression of a bacterial ACC deaminase in tomato can delay the rate of tomato fruit ripening by reduction of ethylene production.⁸ Although ACD activity is evident during ripening in tomato, the gene responsible has not been identified. Recently a tomato gene with sequence similarity to bacterial ACC deaminases was tested for ACD activity. It was found that, despite the close sequence similarity, this gene (accession number {"type":"entrez-nucleotide","attrs":{"text":"EU639448","term_id":"186920268","term_text":"EU639448"}}EU639448) did not have ACD activity.¹⁴ Therefore, additional work must be done to isolate the gene responsible for the ACD activity we demonstrate in tomato fruit.Open in a separate windowFigure 1Tomato fruits exhibit AC deaminase activity during ripening. A plot of ACC Deaminase activity (Solid Line) with known levels of ethylene production during ripening (Dashed Line; Brady¹³) superimposed over pictures of the corresponding stage of tomato development. *Indicates significant increase in activity (†nmol mg⁻¹ hr⁻¹). AC deaminase activity analysis was performed on total tomato fruit protein as per Penrose and Glick (2003).²¹Our discovery of a plant encoded ACC deaminase in Arabidopsis allows us, for the first time, to downregulate ACC deaminase activity and investigate how this affects plant development. Previously, we showed that downregulation of AtACD1 using antisense resulted in up to a 30% reduction in ACD activity and up to a 2.5-fold increase in the evolution of ethylene.⁹ We showed that this difference in ACD activity was sufficient to alter hypocotyl elongation during Arabidopsis germination on different concentrations of ACC. It was unknown, however, if this difference was sufficient to affect other areas of development, such as stress response, in Arabidopsis. The expression of bacterial ACC deaminases in plants are known to increase plant resistance to a number of stressors due to decreased ethylene evolution.^15–18 Based on microarray data, it is known that AtACD1 expression is upregulated 150% during salt stress¹⁹ and functionally it has been demonstrated that ACC production is increased in salt stressed roots²⁰ and overexpression of bacterial ACDs in canola increases salt tolerance.¹⁸ It was unknown, however, if a reduction in native ACD activity would result in reduced vigour of plants grown on increasing concentrations of sodium chloride. We observed that there was no significant difference in rosette size, leaf production or percent dry weight between wildtype and three independent Arabidopsis lines expressing the AtACD1 antisense construct when grown on MS media without salt (Fig. 2A–C). As the concentration of salt increased in the growth media it was found that the antisense lines also did not differ from wildtype in their growth. The lack of a definitive phenotype under salt stress may mean that the level of reduced ACD activity achieved in the AtACD1 antisense lines was not sufficient to quantifiably affect the development of Arabidopsis. Additionally, as ethylene is not the only factor that affects a plant’s survival during times of salt stress, it is also possible that the plants were able to compensate for increased ethylene production in the AtACD1 antisense lines to promote normal plant development. This finding highlights the complex nature of the different signals involved in a plant’s response to salt stress and the need for a better understanding of the role of plant ACDs and how the plant may compensate for altered ACD activity.Open in a separate windowFigure 2Growth and development of Arabidopsis wildtype and three Antisense AtACD1 lines on increasing concentrations of salt. Stratified wildtype Arabidopsis (Col-0) and three independent transgenic lines expressing an antisense construct of AtACD1 (A1, A2, A3) were sown on 0 mM NaCl (Dark Grey Bars), 100 mM NaCl (White Bars), 125 mM NaCl (Black Bars) and 150 mM NaCl (Light Grey Bars) and allowed to germinate and grow for 2 weeks under long-day conditions (16 h light/8 h dark) at a light intensity of 130 to 190 µE m-2s⁻¹ at the rosette level at 21°C in Econair AC -60 growth chambers. Plants were analyzed for rosette diameter (A), leaf production (B) and percent dry weight (C). Error bars are ± SE.In the known framework of ethylene synthesis our work has shown that plants do have the ability to reduce ethylene synthesis by irreversibly deaminating ACC through the action of a native ACC deaminase. Further to our first study, we show here that there is inherent ACC deaminase activity in tomatoes and that this activity varies during tomato ripening in a manner consistent with a factor that is involved in the regulation of ethylene levels. We also show here that transgenic Arabidopsis lines with a mild reduction in ACD1 activity do not have an obvious affect on mediation of salt stress. This finding, however, does not preclude a role for ACD1 in mediating other aspects of plant development or in affecting plant development during other types of plant stress (i.e., drought). Therefore, there still remain many questions to answer concerning the role of plant encoded ACC deaminases and many exciting avenues of ethylene regulation to pursue. The identification and exploitation of tomato, poplar and other plant ACC deaminases could be used to alter fruit ripening, wood production and stress tolerance—all aspects of plant development that are economically and scientifically important.     

Expression of MdCAS1 and MdCAS2, encoding apple beta-cyanoalanine synthase homologs, is concomitantly induced during ripening and implicates MdCASs in the possible role of the cyanide detoxification in Fuji apple (Malus domestica Borkh.) fruits

Fruit ripening involves complex biochemical and physiological changes. Ethylene is an essential hormone for the ripening of climacteric fruits. In the process of ethylene biosynthesis, cyanide (HCN), an extremely toxic compound, is produced as a co-product. Thus, most cyanide produced during fruit ripening should be detoxified rapidly by fruit cells. In higher plants, the key enzyme involved in the detoxification of HCN is β-cyanoalanine synthase (β-CAS). As little is known about the molecular function of β-CAS genes in climacteric fruits, we identified two homologous genes, MdCAS1 and MdCAS2, encoding Fuji apple β-CAS homologs. The structural features of the predicted polypeptides as well as an in vitro enzyme activity assay with bacterially expressed recombinant proteins indicated that MdCAS1 and MdCAS2 may indeed function as β-CAS isozymes in apple fruits. RNA gel-blot studies revealed that both MdCAS1 and MdCAS2 mRNAs were coordinately induced during the ripening process of apple fruits in an expression pattern comparable with that of ACC oxidase and ethylene production. The MdCAS genes were also activated effectively by exogenous ethylene treatment and mechanical wounding. Thus, it seems like that, in ripening apple fruits, expression of MdCAS1 and MdCAS2 genes is intimately correlated with a climacteric ethylene production and ACC oxidase activity. In addition, β-CAS enzyme activity was also enhanced as the fruit ripened, although this increase was not as dramatic as the mRNA induction pattern. Overall, these results suggest that MdCAS may play a role in cyanide detoxification in ripening apple fruits.