Grapevine (Vitis vinifera L.) is an economically important fruit crop. Quality-determining grape components, such as sugars, acids, flavours, anthocyanins, tannins, etc., are accumulated during the different grape berry development stages. Thus, correlating the proteomic profiles with the biochemical and physiological changes occurring in grape is of paramount importance to advance the understanding of the berry development and ripening processes. Here, the developmental analysis of V. vinifera cv. Muscat Hamburg berries is reported at protein level, from fruit set to full ripening. A top-down proteomic approach based on differential in-gel electrophoresis (DIGE) followed by tandem mass spectrometry led to identification and quantification of 156 and 61 differentially expressed proteins in green and ripening phases, respectively. Two key points in development, with respect to changes in protein level, were detected: end of green development and beginning of ripening. The profiles of carbohydrate metabolism enzymes were consistent with a net conversion of sucrose to malate during green development. Pyrophosphate-dependent phosphofructokinase is likely to play a key role to allow an unrestricted carbon flow. The well-known change of imported sucrose fate at the beginning of ripening from accumulation of organic acid (malate) to hexoses (glucose and fructose) was well correlated with a switch in abundance between sucrose synthase and soluble acid invertase. The role of the identified proteins is discussed in relation to their biological function, grape berry development, and to quality traits. Another DIGE experiment comparing fully ripe berries from two vintages showed very few spots changing, thus indicating that protein changes detected throughout development are specific.
SummaryGrapevine stilbenes, particularly trans‐resveratrol, have a demonstrated pharmacological activity. Other natural stilbenes derived from resveratrol such as pterostilbene or piceatannol, display higher oral bioavailability and bioactivity than the parent compound, but are far less abundant in natural sources. Thus, to efficiently obtain these bioactive resveratrol derivatives, there is a need to develop new bioproduction systems. Grapevine cell cultures are able to produce large amounts of easily recoverable extracellular resveratrol when elicited with methylated cyclodextrins and methyl jasmonate. We devised this system as an interesting starting point of a metabolic engineering‐based strategy to produce resveratrol derivatives using resveratrol‐converting enzymes. Constitutive expression of either Vitis vinifera resveratrol O‐methyltransferase (Vv
ROMT) or human cytochrome P450 hydroxylase 1B1 (Hs
CYP1B1) led to pterostilbene or piceatannol, respectively, after the engineered cell cultures were treated with the aforementioned elicitors. Functionality of both gene products was first assessed in planta by Nicotiana benthamiana agroinfiltration assays, in which tobacco cells transiently expressed stilbene synthase and Vv
ROMT or Hs
CYP1B1. Grapevine cell cultures transformed with Vv
ROMT produced pterostilbene, which was detected in both intra‐ and extracellular compartments, at a level of micrograms per litre. Grapevine cell cultures transformed with Hs
CYP1B1 produced about 20 mg/L culture of piceatannol, displaying a sevenfold increase in relation to wild‐type cultures, and reaching an extracellular distribution of up to 45% of total production. The results obtained demonstrate the feasibility of this novel system for the bioproduction of natural and more bioactive resveratrol derivatives and suggest new ways for the improvement of production yields.
Quantitation of changes in protein abundance is key to discovering novel biomarkers. Currently, reverse phase liquid chromatography coupled to tandem mass spectrometry (HPLC-MS/MS) can be used to quantify changes in protein expression levels. Nevertheless, quantitative analysis of protein mixtures by HPLC-MS/MS is still hampered by the wide range of protein expression levels, the high dynamic range of protein concentrations and the lack of reliable quantitation algorithms. In this context, we describe two different samples (4-protmix and 8-protmix) suitable for relative protein quantitation using isobaric Tags for Relative and Absolute Quantitation (iTRAQ). Using the 4-protmix, relative protein changes of up to 24-fold were measured. The 8-protmix allowed the quantitation of the relative protein changes in a mixture of proteins within the range of two orders of magnitude in concentration and 10-fold differences in relative abundance.The two reference samples proposed here (4-protmix and 8-protmix) cover a wide range of protein fold changes and protein concentrations, respectively, which can be used to optimize the settings used during acquisition with different mass spectrometers and to test the performance of different quantitation algorithms used for iTRAQ experiments.Three technical replicates corresponding to 800 fmol of 4-protmix and 8-protmix were analyzed by HPLC-MS/MS using two platforms, a ChipLC coupled to a 6530 Q-ToF (Agilent Technologies) and a 1200 nano-HPLC (Agilent Technologies) coupled to -sult, the analysis of the 4-protmix and the 8-protmix all proteins in the samples (Tables 1 and 2 As shown here, we were able to detect up to 24-fold changes in protein ratios. The standard de--sponded to the highest protein fold change in our samples (24-fold).
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