Postharvest Biology and Technology 62 (2011) 5058
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Postharvest Biology and Technology
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Lina May Poa Department o 50250b Vegetable and ty, Co
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Article history:Received 14 MAccepted 16 A
ver, eted pon ofnternethyleel orabreaeningnts adegrebility
partially, to storage of the fruit for 5 days at 20 C. Nevertheless, ethylene degreening did not enhanceoff-avor perception or accumulation of off-avor volatiles, nor had any effect on levels of health pro-moting compounds such as vitamin C, total phenols and avonoids, or antioxidant-activity of citrus juice.We conclude that although ethylene affects peel color break, it is probably not involved in regulation ofinternal ripening processes in citrus fruit and, therefore, does not impair internal fruit quality.
2011 Elsevier B.V. All rights reserved.
In climaphysiologicing, includiacids, aromGiovanoni,their naturand ethylenexogenousrelated propigments anpeel tissueand Barmothese obserfruit to eth2030 C wand to rendNewhall, 19ing treatme
cteric fruit, ethylene plays a key role in governingal and biochemical changes that occur during ripen-ng color break, softening, and accumulation of sugars,a volatiles, vitamins, etc. (Lelievre et al., 1997; Barry and2007). In contrast, citrus fruit are non-climacteric, i.e.,al ripening is not accompanied by rises in respiratione production rates (Eaks, 1970). However, exposure toethylene has been shown to stimulate various ripening-cesses, such as destruction of the green chlorophylld accumulation of orange/yellow carotenoids, in citrus(Stewart and Wheaton, 1972; Barmore, 1975; Purvisre, 1981; Rodrigo and Zacarias, 2007). In the light ofvations, degreening practices involving exposure of theylene at concentrations of 25L L1 for about 72h atere developed, in order to accelerate peel color changeer the fruitmore acceptable formarketing (Grierson and60; Cohen, 1978). In particular, commercial degreen-nts are especially important for early varieties, in order
ding author. Tel.: +972 3 9683617; fax: +972 3 9683622.ress: firstname.lastname@example.org (R. Porat).
to extend their marketing seasons, and for fruit grown in warm,tropical climates, such as those in Florida or India, where natu-ral color development is relatively weak (Wardowsky et al., 2006;Porat, 2008).
Nevertheless, despite widespread knowledge of the effect ofethylene on peel color development, it is not yet known whetherexogenous ethylene regulates other biochemical changes associ-ated with internal ripening of citrus fruit, as it does in climactericfruit (Goldschmidt, 1998). The commondogma is that, in contrast toits effects on peel color change, ethylene has only relatively minoreffects on ripening processes in citrus esh, but this has neveryet been examined systematically. On the contrary, several linesof evidence suggest that ethylene may regulate various processesrelated to internal ripening. First, it is well known that exposureto ethylene accelerates respiration and ethylene-production ratesof citrus fruit, and these rates are indicators of activation of bio-chemical changes, such as breakdownof sugars and acids that serveas respiratory substrates (Aharoni, 1968; Vines et al., 1968; Eaks,1970). Second, previous studies have shown that ethylenedegreen-ing affects variousmetabolic pathways in citrus esh. For example,ethylene degreening decreased acidity levels in Mosambi oranges(LadaniyaandSingh, 2001), increasedproductionof aromavolatilesin green lemons (Norman and Craft, 1968), and slightly affectedaccumulation and composition of carotenoid pigments in the esh
see front matter 2011 Elsevier B.V. All rights reserved.postharvbio.2011.04.005thylene degreening affect internal quali
uonia, Zipora Tietela, Bhimanagouda S. Patil b, Ronf Postharvest Science of Fresh Produce, ARO, the Volcani Center, P.O. Box 6, Bet-DaganFruit Improvement Center, Department of Horticultural Sciences, Texas A&M Universi
e i n f o
arch 2011pril 2011
a b s t r a c t
Citrus fruit are non-climacteric. Howeing, stimulates various ripening-relachlorophyll pigments and accumulatiwhether exogenous ethylene affects iwe examined the possible effects ofof various citrus fruit, including Navsure to ethylene enhanced peel colorfruit tested. However, ethylene degreand had only minor effects on conteanalysis tests revealed that ethylenemarginally impaired sensory acceptaocate /postharvbio
of citrus fruit?
, Israelllege Station, TX 77845, USA
xposure to exogenous ethylene, e.g., during ethylene degreen-rocesses in the peel tissue, such as destruction of the greenorange/yellow carotenoids. Nonetheless, it is not yet knownal ripening processes in citrus esh. To address this question,ne on taste, aroma, perceived avor, and nutritional qualitynges, Star Ruby grapefruit and Satsuma mandarins. Expo-k, and respiration and ethylene production rates in all citrushad no effect on juice total soluble solids and acid contents,
nd composition of juice aroma volatiles. Moreover, sensoryening did not affect the avor of oranges and grapefruit, butof mandarins; the latter change could be attributed, at least
L. Mayuoni et al. / Postharvest Biology and Technology 62 (2011) 5058 51
of Satsuma mandarins (Matsumoto et al., 2009). Third, it has beenreported that presence of ethylene in storage rooms results inloss of desired avor, and enhanced accumulation of off-avorsin oranges, whereas removal of ethylene from storage roomsimproves oet al., 1992)of 661 transfactor of at48h,whichmetabolic a
In summvisual appeious adversit increasesand acceler1985; Carvaon whetheinuenced bestimated d
Over theglobal martional beneare attachinquality of forder to evregulation ocitrus fruit,degreeningvor, and nuRuby grapethat ethyleripening prfruit quality
2.1. Plant m
Navel ofruit (Citruscv. Miho)wSeptembersons. In allcolor breakthe packingvarietiesweMama.
Fruit weinto two lotlene for 24,them in 250amounts oftration of 4chromatogrushed dailnot exceedat 20 C, bu
2.3. Juice socontents
Total solwith aMod
aciditypercentagesweremeasuredby titration topH8.3with0.1MNaOH by means of a Model CH-9101 automatic titrator (Metrohm,Herisau, Switzerland). Each measurement comprised ve replica-tions, eachusing juice collected fromthreedifferent fruit, i.e., a total
ruit porbicby tmi eringcorbsed a
it senexponts weatmferenof10t assnstrry stanceof rere
f 15nsorre mrins
ma ving tendebit eglassilutels wma v, eacher timupleere ancubes wexlbenzco, Bls hin atlo Al5mogran1,temLm
or (Aat 7.7ctronc peaompologyof
nearverall fruit quality (McGlasson and Eaks, 1972; Testoni. Fourth, we recently found that the expression patternscripts in mandarin esh were signicantly altered by aleast 3, following exposure to ethylene at 4L L1 forsuggests that this exposuremight have affected variousnd adaptation processes (Mayuoni et al., 2011).ary, notwithstanding its advantages in improving fruitarance, the ethylene degreening process also has var-e effects on fruit quality and postharvest storability:susceptibility to stem-end rots, enhances weight loss,ates rind and calyx senescence (Barmore and Brown,lho et al., 2008; Porat, 2008). Therefore, the decision
r or not to degreen citrus fruit is not simple, and isy various circumstances, such as market demands andurations of storage and shelf life (Pool and Gray, 2002).last few years, because of increased competition in
kets and increasing public awareness of the nutri-ts of horticultural produce, growers and consumersg increasing importance to the avor and nutritional
ruit and vegetables (Kader, 2008; Patil et al., 2009). Inaluate the possible effects of ethylene degreening onf the internal ripening processes and on the quality ofwehave systematically examined theeffectsof ethyleneon taste, composition of aroma volatiles, perceived a-tritional quality of the citrus fruit Navel oranges, Starfruit, and Satsuma mandarins. Overall, we concludene is probably not involved in regulation of internalocesses in citrus and, therefore does not impair internal.
ls and methods
ranges (Citrus sinensis [L]. Osbeck), Star Ruby grape-paradisi Macf.), and Satsuma mandarins (Citrus unshiuere purchased fromcommercial packinghouses during
through November of the 2009 and 2010 growing sea-cases, fruit were harvested at the beginning of natural, and were collected directly from the harvest bins athouse. For taste score evaluations, additional mandarinre also tested, including Michal, Odem, Or, Mor, and
re selected for uniformity of size and color, and divideds, which were exposed, respectively, to air or to ethy-48, or 72h. They were exposed to ethylene by placing-L airtight sealed plastic tanks, into which appropriatepure ethylene were injected, to achieve a nal concen-L L1. Ethylene concentrations were veried by gasaphy according to Porat et al. (1999). The tanks werey to ensure that accumulated carbon dioxide levels did0.2%. Control fruit were held in the same storage roomt without ethylene.
luble solids, titratable acidity, and ascorbic acid
uble solids (TSS) content in the juice was determinedel PAL-1 digital refractometer (Atago, Tokyo, Japan), and
of 15 fAsc
minedto Hirocompa0.1% asexpres
FrudaysofsegmeEach trve difsistingpanelisto an uand veas distmeanselists wscale oThe sehere amanda
Aroaccordand blto inhi10mLMO), dThe via