Ming Ning1, Fengxian Tang1, Jiluan Chen1, Wen Song1, Wenchao Cai1, Qin Zhang1, Xinxin Zhao1, Xinquan Yang1, Chunhui Shan2, Guangfei Hao3. 1. Food College, Shihezi University, Xinjiang, 832003, People's Republic of China. 2. Food College, Shihezi University, Xinjiang, 832003, People's Republic of China. 972338194@qq.com. 3. School of Life Science and Food Engineering, Hebei University of Engineering, Handan, 056038, People's Republic of China. wuyucool@126.com.
Abstract
MAIN CONCLUSION: The proteome and its time-dependent effects reveal the importance of stress response (including expression regulation of heat-shock proteins) and fatty acid metabolism in cold adaptation and preservation of Hami melon. To better understand the molecular mechanism of how Hami melons respond to low-temperature stress, this study investigated the relevant physiological characteristics, catalytic antibody activity, and quantitative proteomics of Hami melon (Jiashi muskmelon) during low-temperature storage. Jiashi muskmelon was stored inside two refrigerators set at 21 °C (control group) and 3 °C, respectively, for 24 days. Low-temperature storage led to a significantly reduced decay rate, weight loss rate, and loss of relative conductivity. It also maintained fruit firmness, inhibited the production rate of malondialdehyde and H2O2, and induced over-expression of antioxidant enzyme and ATPase. A total of 1064 differentially expressed proteins (DEPs) were identified during low-temperature storage. Stimulation response was the main process in response to low-temperature. To further verify the proteome data, we selected four heat-shock proteins (HSP) displaying relatively high expression levels. Real-time fluorescence PCR results confirmed that HmHSP90 I, HmHSP90 II, HmHSP70, and HmsHSP were significantly up-regulated upon low-temperature induction. These proteins may protect the Hami melon from physiological and cellular damage due to the low-temperature stress by acting alone or synergistically. Additionally, the main enrichment term of the fatty acid metabolism-related DEPs was fatty acid beta oxidation at 21 °C in contrast to fatty acid biosynthesis processes at 3 °C. It is speculated that Hami melon enhances low-temperature adaptability by slowing down the oxidative degradation of fatty acids and synthesizing new fatty acids at low temperatures. This study provides new insights into the mechanism of low-temperature adaptation and preservation in post-harvest Hami melon during cold storage.
MAIN CONCLUSION: The proteome and its time-dependent effects reveal the importance of stress response (including expression regulation of heat-shock proteins) and fatty acid metabolism in cold adaptation and preservation of Hami melon. To better understand the molecular mechanism of how Hami melons respond to low-temperature stress, this study investigated the relevant physiological characteristics, catalytic antibody activity, and quantitative proteomics of Hami melon (Jiashi muskmelon) during low-temperature storage. Jiashi muskmelon was stored inside two refrigerators set at 21 °C (control group) and 3 °C, respectively, for 24 days. Low-temperature storage led to a significantly reduced decay rate, weight loss rate, and loss of relative conductivity. It also maintained fruit firmness, inhibited the production rate of malondialdehyde and H2O2, and induced over-expression of antioxidant enzyme and ATPase. A total of 1064 differentially expressed proteins (DEPs) were identified during low-temperature storage. Stimulation response was the main process in response to low-temperature. To further verify the proteome data, we selected four heat-shock proteins (HSP) displaying relatively high expression levels. Real-time fluorescence PCR results confirmed that HmHSP90 I, HmHSP90 II, HmHSP70, and HmsHSP were significantly up-regulated upon low-temperature induction. These proteins may protect the Hami melon from physiological and cellular damage due to the low-temperature stress by acting alone or synergistically. Additionally, the main enrichment term of the fatty acid metabolism-related DEPs was fatty acid beta oxidation at 21 °C in contrast to fatty acid biosynthesis processes at 3 °C. It is speculated that Hami melon enhances low-temperature adaptability by slowing down the oxidative degradation of fatty acids and synthesizing new fatty acids at low temperatures. This study provides new insights into the mechanism of low-temperature adaptation and preservation in post-harvest Hami melon during cold storage.
Authors: M Luisa Hernández; María N Padilla; M Dolores Sicardo; Manuel Mancha; José M Martínez-Rivas Journal: Phytochemistry Date: 2010-12-29 Impact factor: 4.072
Authors: Annick Moing; Asaph Aharoni; Benoit Biais; Ilana Rogachev; Sagit Meir; Leonid Brodsky; J William Allwood; Alexander Erban; Warwick B Dunn; Lorraine Kay; Sjaak de Koning; Ric C H de Vos; Harry Jonker; Roland Mumm; Catherine Deborde; Michael Maucourt; Stéphane Bernillon; Yves Gibon; Thomas H Hansen; Søren Husted; Royston Goodacre; Joachim Kopka; Jan K Schjoerring; Dominique Rolin; Robert D Hall Journal: New Phytol Date: 2011-01-28 Impact factor: 10.151