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Seth DeBolt, Renata Ristic, Patrick G. Iland, and Christopher M. Ford

between light exposure and organic acid biosynthesis by both immature and mature berries has been reported ( DeBolt et al., 2006 , 2007 ; Kliewer and Schultz, 1964 ) and showed that full sun exposure resulted in maximum levels of tartaric acid formation

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A.M. Salama, J.R. Hicks, and J.F. Nock

Maleic hydrazide (MH)-treated and untreated (control) onion (Allium cepa L.) bulbs were stored for up to 20 weeks at 0, 15, or 30C with relative humidities (RH) of 40% or 60%. MH and RH had minimal effect on sugars and organic acids in inner or outer scale leaves that were analyzed at S-week intervals. Concentrations of fructose, glucose, and total sugars were higher in inner than outer leaves of the bulb, while the reverse was true for sucrose. Total sugars, glucose, and fructose decreased and sucrose increased with higher storage temperature. Total sugars and glucose decreased with increased storage duration. Malic acid concentration was greater in the outer leaves while citric acid levels were higher in inner leaves. Malic acid increased in onion bulbs during storage while citric acid levels were not influenced by storage duration. Total acids showed little difference across temperatures, due to the concurrent increase in citric acid and decrease in malic acid at 30C.

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T. Casey Barickman, Dean A. Kopsell, and Carl E. Sams

antioxidants linked to inhibiting cancers such as prostate ( Giovannucci et al., 1995 ), skin ( Gonzalez et al., 2003 ), and colon ( Slattery et al., 1999 ). Organic acids, such as malic and citric, and soluble sugars, such as fructose and glucose, contribute

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Yifei Wang, Stephanie K. Fong, Ajay P. Singh, Nicholi Vorsa, and Jennifer Johnson-Cicalese

, 2014 ; Horvat and Senter, 1985 ), blueberries also contain different organic acids, including citric, quinic, malic, and succinic acids that contribute to their unique flavor ( Ehlenfeldt et al., 1994 ). Moreover, they are also known for the rich

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Yongfeng Yang, Zhixiao Yang, Shizhou Yu, and Hongli Chen

et al., 2011 ). Cluster roots are characterized to release organic acid anions at a high level, and citrate is demonstrated to be the predominant acid released by cluster roots of tobacco under a K-deficient condition ( Wu et al., 2013 ). Collectively

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Yu Wang, Haobo Yang, Shuai Zhong, Xin Liu, Tong Li, and Chengwen Zong

China is 7 million kilograms, which is primarily used for producing wine, juice, jam, and preserved products ( Zong et al., 2011 ). Anthocyanins, flavonoids, phenols, and organic acids in V. uliginosum fruit show various biological properties

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Tripti Vashisth, Mercy A. Olmstead, James Olmstead, and Thomas A. Colquhoun

to yield high quality, nutritious fruit, in addition to optimum production. Therefore, in the present study, we focused on the impact of different rates of N fertilization on fruit quality including organic acid, TSS, TA, total phenolic content

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Mark K. Ehlenfeldt, Filmore I. Meredith, and James R. Ballington

The fruit of six highbush (Vaccinium corymbosum L.) cultivars and eight rabbiteye (V. ashei Reade) cultivars and selections were evaluated by high-performance liquid chromatography for levels of the commonly found organic acids, citric, malic, succinic, and quinic. The two cultivar groups possessed distinctive patterns of relative organic acid proportions that could unambiguously separate pure rabbiteye and highbush clones in a principal component analysis. Highbush clones were characterized by high citric acid content, with percentages averaging 75% (range 38% to 90%). Succinic acid was the second most plentiful acid, averaging 17%. In contrast, rabbiteye cultivars and selections contained 10% citric acid, and no clone had >22%. Succinic acid and malic acid were found in greater quantities than in highbush, averaging 50% and 34%, respectively. Analysis of the fruit of seven albino-fruited highbush selections exhibited a profile similar to standard highbush cultivars, but with a citric acid average of <50%, and proportionally greater amounts of succinic and quinic acids. Given the differences in sensory quality of these four acids, it is likely that acid partitioning patterns can largely account for some of the perceived flavor differences between rabbiteye and highbush blueberries. Because several current breeding efforts involve hybridization between highbush and rabbiteye blueberries, a consideration of acid composition of breeding parents maybe worthwhile.

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Franco Famiani and Robert P. Walker

ripening is mostly a result of the accumulation of fructose and glucose ( Kafkas et al., 2006 ; Perkins-Veazie et al., 2000 ; Wrolstad et al., 1980 ). Isocitric, lactoisocitric, and malic acids make up the bulk of organic acids in blackberry; however, the

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Ki-Cheol Son, Ray F. Severson, Maurice E. Snook, and Stanley J. Kays

Methanol extracts of external (outer 3 mm) and interior root tissue of four sweetpotato [Ipomoea batatas (L.) Lam.] cultivars (`Centennial', `Jewel', `Regal', and `Resisto') having different levels of susceptibility to the sweetpotato weevil [Cylas formicarius elegantulus Summer] were analyzed for simple carbohydrates (fructose, glucose, sucrose, inositol) and organic acids (malic, citric, quinic) by gas chromatography and for phenolics (caffeic acid, caffeoylquinic acids, rutin) by high-performance liquid chromatography. There were significant differences among cultivars in the concentrations of total sugars and phenolics in the external tissue (P < 0.05). In addition, the distribution of carbohydrates, organic acids, and chlorogenic acid [3-O-caffeoylquinic acid] differed between external and interior tissues. Sucrose was the major water-soluble carbohydrate in all cultivars. With the exception of malic acid, the concentration of carbohydrates, organic acids, and phenolics did not correlate with cultivar susceptibility to the sweetpotato weevil.