Proteomic analysis of banana fruit reveals proteins that are differentially accumulated during ripening

Proteomic analysis of banana fruit reveals proteins that are differentially accumulated during ripening

► Protein maps of banana pulp in preclimacteric and climacteric phases were compared. ► There were 50 differential proteins, and 26 of those proteins were identified. ► These proteins could be functional during ripening and related to fruit quality. Bananas (Musa spp.) are highly perishable fruit of...

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Bibliographic Details
Published in:Postharvest biology and technology Vol. 70; pp. 51 - 58
Main Authors: Toledo, Tatiana Torres, Nogueira, Silvia Beserra, Cordenunsi, Beatriz Rosana, Gozzo, Fábio César, Pilau, Eduardo Jorge, Lajolo, Franco Maria, do Nascimento, João Roberto Oliveira
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 01-08-2012
Elsevier
Subjects:
Banana
Biological and medical sciences
Differential proteome
Food industries
Fruit and vegetable industries
Fruit ripening
Fundamental and applied biological sciences. Psychology
Musa spp
MSDB
IPG
Differential proteome
DTT
HPAE-PAD
LC–MS/MS
HSPs
MDH
IFR
Pi
Cy3
Cy5
ACC
SDS
2D-DIGE
DAA
MS
ESI-QUAD-TOF
IAA
SAHH
LED
Fruit ripening
ACN
EDTA
CHAPS
Banana
AGPase
SDS-PAGE
Musa spp
FA
PL
SAM
Monocotyledones
Fruit
Proteome
Musaceae
Protein
Ripening
Musa
Angiospermae
Proteomics
Spermatophyta
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Summary:► Protein maps of banana pulp in preclimacteric and climacteric phases were compared. ► There were 50 differential proteins, and 26 of those proteins were identified. ► These proteins could be functional during ripening and related to fruit quality. Bananas (Musa spp.) are highly perishable fruit of notable economic and nutritional relevance. Because the identification of proteins involved in metabolic pathways could help to extend green-life and improve the quality of the fruit, this study aimed to compare the proteins of banana pulp at the pre-climacteric and climacteric stages. The use of two-dimensional fluorescence difference gel electrophoresis (2D-DIGE) revealed 50 differentially expressed proteins, and comparing those proteins to the Mass Spectrometry Protein Sequence Database (MSDB) identified 26 known proteins. Chitinases were the most abundant types of proteins in unripe bananas, and two isoforms in the ripe fruit have been implicated in the stress/defense response. In this regard, three heat shock proteins and isoflavone reductase were also abundant at the climacteric stage. Concerning fruit quality, pectate lyase, malate dehydrogenase, and starch phosphorylase accumulated during ripening. In addition to the ethylene formation enzyme amino cyclo carboxylic acid oxidase, the accumulation of S-adenosyl-l-homocysteine hydrolase was needed because of the increased ethylene synthesis and DNA methylation that occurred in ripening bananas. Differential analysis provided information on the ripening-associated changes that occurred in proteins involved in banana flavor, texture, defense, synthesis of ethylene, regulation of expression, and protein folding, and this analysis validated previous data on the transcripts during ripening. In this regard, the differential proteomics of fruit pulp enlarged our understanding of the process of banana ripening.
ISSN:0925-5214
1873-2356
DOI:10.1016/j.postharvbio.2012.04.005