Subscriber access provided by University of Newcastle, Australia
Article
Influence of Production Method on the Chemical Composition, Foaming Properties and Quality of Australian Carbonated and Sparkling White Wines Julie Culbert, Jacqui M. McRae, Bruna Condé, Leigh M. Schmidtke, Emily Nicholson, Paul A. Smith, Kate Howell, Paul Kenneth Boss, and Kerry L. Wilkinson J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.6b05678 • Publication Date (Web): 27 Jan 2017 Downloaded from http://pubs.acs.org on January 28, 2017
Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a free service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are accessible to all readers and citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.
Journal of Agricultural and Food Chemistry is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.
Page 1 of 35
Journal of Agricultural and Food Chemistry 1
Influence of Production Method on the Chemical Composition, Foaming Properties and Quality of Australian Carbonated and Sparkling White Wines
Julie A. Culbert,1,6 Jacqui M. McRae,2 Bruna C. Condé,3 Leigh M. Schmidtke,4 Emily L. Nicholson,5 Paul A. Smith,2 Kate S. Howell,3 Paul K. Boss5 and Kerry L. Wilkinson1,*
1
School of Agriculture, Food and Wine, The University of Adelaide, Waite Campus, PMB 1, Glen
Osmond, SA, 5064, Australia 2
Australian Wine Research Institute, P.O. Box 197, Glen Osmond SA 5064, Australia
3
Faculty of Veterinary and Agricultural Sciences, The University of Melbourne, Parkville, Victoria,
3010, Australia 4
National Wine and Grape Industry Centre, School of Agricultural and Wine Science, Charles Sturt
University, Wagga Wagga, New South Wales, 2678, Australia 5
Commonwealth Scientific and Industrial Research Organisation, Agriculture and Food, PMB2,
Glen Osmond SA 5064, Australia 6
Current address: Australian Wine Research Institute, P.O. Box 197, Glen Osmond SA 5064,
Australia
* Corresponding Author: Dr Kerry Wilkinson, telephone: + 61 8 8313 7360 facsimile: + 61 8 8313 7716, email:
[email protected] ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
Page 2 of 35 2
1
Abstract
2
The chemical composition (protein, polysaccharide, amino acid and fatty acid/ethyl ester content),
3
foaming properties and quality of fifty Australian sparkling white wines, representing the four key
4
production methods, i.e. Méthode Traditionelle (n=20), transfer (n=10), Charmat (n=10) and
5
carbonation (n=10), were studied. Méthode Traditionelle wines were typically rated highest in
6
quality and were higher in alcohol and protein content, but lower in residual sugar and total
7
phenolics, than other sparkling wines. They also exhibited higher foam volume and stability, which
8
might be attributable to higher protein concentrations. Bottle-fermented Méthode Traditionelle and
9
transfer wines contained greater proportions of yeast-derived mannoproteins, whereas Charmat and
10
carbonated wines were higher in grape-derived rhamnogalacturonans; however total polysaccharide
11
concentrations were not significantly different between sparkling wine styles. Free amino acids
12
were most abundant in carbonated wines, which likely reflects production via primary fermentation
13
only and/or the inclusion of non-traditional grape varieties. Fatty acids and their esters were not
14
correlated with foaming properties, but octanoic and decanoic acids and their ethyl esters were
15
present in Charmat and carbonated wines at significantly higher concentrations than bottle-
16
fermented wines, and were negatively correlated with quality ratings. Research findings provide
17
industry with a better understanding of the compositional factors driving the style and quality of
18
sparkling white wine.
19 20 21 22 23 24 25
Keywords: amino acids, fatty acids, foaming, polysaccharides, proteins, sparkling wine, wine
26
quality
ACS Paragon Plus Environment
Page 3 of 35
Journal of Agricultural and Food Chemistry 3
27
INTRODUCTION
28
The sensory properties of different styles of sparkling white wine are diverse, ranging from
29
predominantly simple, fruity characters to more complex toasty, yeasty and bready notes,1
30
depending on the method of production. In Australia, there are four key production methods,
31
involving either direct infusion of carbon dioxide into base wine (i.e. carbonation) or generation of
32
carbon dioxide via secondary fermentation of base wine, which can occur in pressurized tanks (i.e.
33
Charmat) or in the bottle (i.e. transfer and Méthode Traditionelle).1 Fruit driven styles of sparkling
34
wine are typically derived from carbonation or the Charmat method, whereas more complex
35
sparkling wines are achieved as a consequence of the bottle fermentation and/or lees aging
36
processes employed in the transfer method and Méthode Traditionelle; the latter being analogous
37
with the Méthode Champenoise used for Champagne.
38 39
The sensory and foaming properties of sparkling wine, and therefore wine quality, are strongly
40
influenced by production method, which encompasses factors such as grape variety, the methods by
41
which fruit is harvested and processed, the yeast strains selected for primary and secondary
42
fermentation, the extent to which base wines are fined and filtered, and the duration of lees aging.2
43
During lees ageing, yeast autolysis occurs; i.e. intracellular enzymes slowly hydrolyze yeast to
44
release amino acids, peptides, proteins, polysaccharides (mannoproteins) and fatty acids,2,3 which
45
collectively influence the organoleptic properties of sparkling wine (i.e. aroma, flavor, taste and
46
mouthfeel). As a consequence, a number of studies have explored the compositional changes that
47
occur during sparkling wine production and the factors that influence mouthfeel and foaming
48
properties. Foaming is considered an especially important attribute, and an indicator of wine
49
quality,4,5 since bubbles are not only intrinsic to the sensory appeal of sparkling wine, but the first
50
characteristic observed by consumers.6
51
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
Page 4 of 35 4
52
In the case of amino acids, sparkling wine-related studies have typically focused on the influence of
53
yeast strain, yeast autolysis and aging during the traditional secondary fermentation process on their
54
concentrations.7–10 In contrast, wine proteins have received considerably more attention, given their
55
role in wine haze formation. Chitinases and thaumatin-like proteins are the two major haze forming
56
proteins present in wine; for which molecular weights range between 21 and 32 kDa.11 In sparkling
57
wine, previous studies have sought to understand the contribution of proteins to wine foaming
58
properties through protein fractionation and characterization,12,13 as well as changes to protein
59
composition during Champagne production14 or following the use of bentonite either for fining base
60
wines15 or as a riddling agent.16 Proteins are generally considered to positively impact wine foam
61
stability13,14,17,18 and to contribute sparkling wine body and quality.12
62 63
Wine polysaccharides also contribute to perceptions of body and mouthfeel,19 and given their
64
influence on viscosity, might also influence sparkling wine foaming properties. Polysaccharides can
65
either be grape or yeast derived, with their size and type largely determining their impact on wine
66
sensory and foaming properties.4,7,20 Grape-derived polysaccharides include type II arabinogalactan-
67
proteins (AGPs) and rhamnogalacturonans type I (RG-I) and type II (RG-II), while mannans and
68
mannoproteins (MPs) are examples of yeast-derived polysaccharides which can be released in wine
69
during fermentation or yeast autolysis.20 Polysaccharides, in particular mannoproteins, have been
70
shown to enhance foaming properties;18,20–22 but mannoproteins can also prevent protein haze23 and
71
potassium bitartrate crystallization,11 thereby improving wine quality.
72 73
Relatively few studies have investigated the occurrence and impact of lipids (fatty acids) on
74
sparkling wine foaming properties, with conflicting results published in the literature. An early
75
study reported a reduction in foam stability following the addition of octanoic and decanoic acids to
76
sparkling wine,24 whereas a subsequent study found the addition of a lipid mixture had no effect on
77
foaming, with alcohol being more influential.25 In a more recent study, octanoic (C8), decanoic
ACS Paragon Plus Environment
Page 5 of 35
Journal of Agricultural and Food Chemistry 5
78
(C10) and dodecanoic (C12) acids were found to be negatively correlated with foamability, while
79
ethyl hexanoate, ethyl octanoate and ethyl decanoate were positively correlated, but no effect on
80
foam stability was observed.26
81 82
To date, few studies have considered the compositional and/or organoleptic properties of Australian
83
sparkling wine. This study therefore aimed to profile the compositional variation amongst
84
Australian carbonated and sparkling white wines, and to determine to what extent production
85
method influences the compositional factors that drive sparkling wine style and quality.
86 87
MATERIALS AND METHODS
88
Chemicals. All reagents were analytical grade, unless otherwise stated. Fructose, glucose,
89
thaumatin, commercial dextrans (with molecular weights ranging from 5 to 270 kDa), amino acids,
90
hexanoic acid, octanoic acid, decanoic acid, ethyl hexanoate, ethyl octanoate and ethyl decanoate
91
were obtained from Sigma-Aldrich (Castle Hill, NSW, Australia). Deuterium-labelled internal
92
standards were sourced from CDN Isotopes (Pointe-Claire, CA), except for d5-ethyl nonanoate
93
which was synthesized as previously reported.27 Ethanol (absolute) was purchased from Merck
94
Millipore (Billerica, MA). The AccQ-Fluor Reagent Kit and AccQ-Tag Eluent A used for amino
95
acid derivitization and analysis were purchased from the Waters Corporation (Milford, MA).
96
Ultrapure water was obtained from a Milli-Q purification system (Millipore, North Ryde, NSW,
97
Australia).
98 99
Sparkling Wine Samples. Fifty Australian sparkling white wines were selected with input from an
100
industry reference group comprising of four prominent sparkling winemakers and sourced from
101
producers or retail outlets. The selected wines represented the four key production methods
102
employed in Australia: Méthode Traditionelle (n=20, hereafter designated as MT01–MT20),
103
transfer (n=10, hereafter designated as Tr01–Tr10), Charmat (n=10, hereafter designated as Ch01–
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
Page 6 of 35 6
104
Ch10) and carbonation (n=10, hereafter designated as Ca01–Ca10), as well as a range of wine
105
regions, price points (being AUD $5 to $90, for 750 mL bottles) and established brands. Méthode
106
Traditionelle sparkling wines comprised 15 vintage (3 x 2004; 1 x 2005; 3 x 2008; 3 x 2009; 4 x
107
2010; 1 x 2011) and 5 non-vintage wines; while 4 transfer wines were vintage (1 x 2008; 3 x 2011)
108
and 6 were non-vintage. Charmat and carbonated wines were non-vintage, with the exception of one
109
carbonated wine (Ca04, vintage 2012). Sparkling wines were predominantly made from
110
Chardonnay, Pinot Noir and Pinot Meunier (i.e. the classic varieties), or blends thereof; except for
111
Ca01, Ca02, Ca05, Ca06 and Ca07, which comprised Chardonnay blended with one or more non-
112
classic varieties (Chenin Blanc, Colombard, Sauvignon Blanc and Semillon). The vintage, varietal
113
composition, geographical origin, price and bottle weight of each sparkling wine is provided as
114
Supporting Information, Table S1. Bottle weights were measured (in duplicate, two separate
115
bottles) with an analytical balance (AUW220D, Shimadzu, Rydalmere, NSW, Australia).
116 117
Basic Wine Composition. Sparkling wine samples were degassed prior to basic compositional
118
analyses (in triplicate, from three separate bottles). Wine (~10 mL) was placed in a loosely capped
119
50 mL Schott bottle and sonicated in an ultrasonic bath (Sonorex Digitec DT 1028F, Bandelin
120
Electronic GmbH & Co. KG, Berlin Germany) for 10 minutes. pH and titratable acidity (TA,
121
expressed as g/L of tartaric acid) were determined using an autotitrator (Compact Titrator, Crison
122
Instruments SA, Allela, Spain), ethanol content (% alcohol by volume, abv) was determined with an
123
alcolyzer (Anton Paar, Graz, Austria), and glucose and fructose (i.e. residual sugar) were
124
determined enzymatically (Boehringer-Mannheim, R-BioPharm, Darmstadt, Germany) with a
125
liquid handling robot (CAS-3800, Corbett Robotics, Eight Mile Plain, Qld, Australia) and
126
spectrophotometric plate reader (Infinite M200 Pro, Tecan, Grödig, Austria). The absorbance of
127
degassed wines (at 280 nm) was measured using a spectrophotometer (GBC Scientific Equipment,
128
Melbourne, Australia) to determine total phenolics.
129
ACS Paragon Plus Environment
Page 7 of 35
Journal of Agricultural and Food Chemistry 7
130
Protein Analysis. The concentration of haze-forming proteins, including chitinases and thaumatin-
131
like proteins, were measured in each sparkling wine (in duplicate, from two separate bottles) using
132
ultra-high performance liquid chromatography (UHPLC), as described previously,28 with
133
modifications. Degassed wine samples (1.5 mL) were filter-sterilized (0.45 µm PVDF syringe filter,
134
Merck Millipore, Billerica, MA) prior to injection on an Agilent (Palo Alto, CA) 1260 UHPLC
135
equipped with a Prozap C18 column (10 mm x 2.1 mm, Agilent). Separation was achieved with a
136
solvent system of 0.1% TFA/H2O (Solvent A) and 0.1%TFA/ACN (solvent B) and a flow rate of
137
0.75 mL/min. The mobile phase gradient was: 0–1 min 10–20% B; 1–4 min 20–40% B; 4–6 min
138
40–80% B; 6–7 min 80% B; and 7–10 min 10% B. Proteins were detected at 210 nm, using an
139
Agilent UV/Vis detector. Identification was achieved by comparing retention times with isolated
140
standards28 and quantitation performed against an external standard curve for thaumatin; results are
141
expressed as mg/L thaumatin equivalents.
142 143
Polysaccharide Analysis. Polysaccharides were isolated and analyzed for each sparkling wine (in
144
duplicate, from two separate bottles) using HPLC and a refractive index detector (RID), as
145
previously described.29 In brief, polysaccharides were precipitated from degassed wine (1 mL)
146
following the addition of ethanol (absolute; 5 mL) and overnight chilling (at 4°C). The crude
147
polysaccharide precipitate was isolated as a pellet after centrifugation, then further purified by
148
dialysis (Pur-A-Lyzer Midi 3500, 50–800 µL, Sigma-Aldrich) over 48 hours. Following dialysis,
149
samples were freeze dried and the resulting purified polysaccharide re-suspended in buffer solution
150
(0.1 M sodium nitrate, 150 µL) for HPLC analysis. Separation was achieved with a BioSep Sec
151
2000 column (300 mm x 7.8 mm, Phenomenex, Lane Cove, NSW, Australia). Polysaccharide
152
classes were quantified as: high molecular weight (approximately 200 kDa), medium molecular
153
weight (approximately 100 kDa) and low molecular weight (with molecular distributions of 50, 20
154
and 10 kDa). Polysaccharide concentrations were estimated by comparing peak areas against a
155
standard curve for dextran; results are expressed as mg/L of 50 kDa dextran equivalents.
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
Page 8 of 35 8
156 157
Amino Acid Analysis. Prior to analysis, amino acids were converted to their highly fluorescent 6-
158
aminoquinolyl-N-hydroxysuccinimidyl carbamate (AQC) derivatives using the AccQ-Fluor reagent
159
kit (Waters Corporation, Milford, MA); with each sparkling wine analyzed in duplicate (from two
160
separate bottles). Wine samples (50 µL) were mixed with α-aminobutyric acid (0.5 mM in Milli-Q
161
water, 50 µL) and sodium borate buffer (0.2 M, pH 8.8, 900 µL) and a portion of the mixture (20
162
µL) was subsequently transferred to a 2 mL high recovery vial (Agilent Technologies) containing
163
AccQ-Fluor Borate Buffer (60 µL) and reconstituted AccQ-Fluor reagent (20 µL, prepared by
164
adding AccQ-Fluor reagent diluent (1 mL) to the AccQ-Fluor reagent powder, with vortexing for 10
165
sec and heating at 55°C for 10 min). The resulting mixture was incubated for 1 min at ambient
166
temperature before heating at 55°C for 10 min, and then quantitation. HPLC Method: The
167
derivatized amino acids were analyzed on an Agilent 1200 series HPLC equipped with a
168
fluorescence detector. Separation was achieved using a Phenomenex (Torrance, CA) Luna 3 µm
169
C18 column (150 x 4.6 mm) fitted with a guard cartridge. Mobile phase A consisted of AccQ-Tag
170
Eluent A (100 mL concentrate added to 1L Milli-Q water); mobile phase B consisted of 60%
171
acetonitrile in Milli-Q water. The injection volume was 10 µL (with a needle wash with water
172
between samples) and the pump flow rate was constant at 1 mL/min. The solvent gradient was as
173
follows: 0% B to 2% B (0.5 min); 2% B to 7% B (14.5 min); 7% B to 13% B (7 min); 13% B to
174
32% B (19 min); 32% B to 40% B (5 min); 40% B to 85% B (9 min); 85% B to 100% B (1 min);
175
100% B isocratic for 5 min; 100% B to 0% B (2 min); 0% B isocratic for 10 min; giving a total
176
runtime of 73 min. Fluorescence detector parameters comprised excitation at 250 nm and emission
177
at 395 nm. Amino acids were quantified against calibration solutions of known concentrations.
178 179
Fatty Acid (C6, C8 and C10) and Ethyl Ester Analysis. Fatty acids and their ethyl esters were
180
determined in each sparkling wine in triplicate (from three separate bottles). Wine samples (0.5 mL)
181
were placed in 20 mL autosampler vials containing sodium chloride (2.0 g) and Milli-Q water (4.5
ACS Paragon Plus Environment
Page 9 of 35
Journal of Agricultural and Food Chemistry 9
182
mL). To this was added an internal standard solution containing d4-methyl-1-butanol, d3-hexyl
183
acetate, d13-1-hexanol, d5-ethyl nonanoate, d5- phenethyl alcohol and d19-decanoic acid (10 µL), to
184
give final concentrations of 48.0, 0.5, 1.0, 0.084, 10.0 and 1.0 mg/L, respectively. Vials were sealed
185
and mixed thoroughly prior to GC-MS analysis. GC-MS Method: Samples were analyzed using a
186
7890A gas chromatogram coupled to a 5975C inert XL mass selective detector (Agilent
187
Technologies, Santa Clara, USA) and equipped with a Gerstel MPS2 Multipurpose sampler
188
(Gerstel, Mülheim an der Ruhr, Germany). The GC-MS instrument was controlled using
189
ChemStation software in combination with Gerstel Maestro software. Samples were incubated with
190
agitation for 10 min at 50°C prior to headspace-solid phase microextraction (HS-SPME) for 30 min
191
at 50°C (with agitation) using a Supelco 50/30um DVB/CAR/PDMS 1 cm SPME fiber. The SPME
192
fiber was desorbed in the GC inlet containing an ultra-inert glass SPME liner (straight taper with
193
0.75 mm i.d.) operated in splitless mode at a temperature of 240°C. The SPME fiber remained in
194
the inlet for 10 min but with a purge flow to the split vent of 20 mL/min after 3 min. Separation of
195
volatiles was achieved using a J&W DB-WAXetr capillary column (60 m x 0.25 mm i.d. x 0.25 µm,
196
Agilent Technologies) with a constant carrier gas (ultrahigh purity helium) at a flow rate of 1.5
197
mL/min. The oven program comprised: 40°C (held for 5 min); 2°C/min until 210°C (held for 5
198
min); and then 5°C/min until 240°C (held for 10 min); giving a total runtime of 111 min. The MS
199
was operated using positive ion electron impact at 70 eV in full scan mode (m/z 35–350), with MS
200
source and quadrupole temperatures of 230°C and 150°C, respectively. The MS transfer line was
201
held at 240°C. GC-MS data (3D) was exported to Excel and subjected to multivariate curve
202
resolution and alternating least squares (MCR-ALS) analysis, using methods described
203
previously.30 Briefly all chromatogram TICs were overlaid and inspected for elution time segments
204
suitable for batch processing based upon stable baseline and peak heights. Segments were processed
205
by smoothing each m/z channel; aligning the resulting TIC and applying the alignment to the three
206
dimensional data cube before feature extraction. The number of features in each segments was
207
determined from visual inspection of the data. The MCR-ALS deconvolution commenced using an
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
Page 10 of 35 10
208
initial estimate of the spectra for each feature obtained using SIMPLISMA.31 Peak areas of
209
identified features and spectral libraries derived from MCR-ALS were exported from MATLAB
210
(version 7.4.0.287 R2007a) in a format compatible with the National Institute of Standards and
211
Technology (NIST) mass spectral search program (version 2.0). Compound identification was
212
achieved using the NIST 05 Mass Spectral library database, as well as by comparing retention times
213
and mass spectra to those of known standards. Areas for: octanoic acid and decanoic were corrected
214
using d19-decanoic acid; hexanoic acid using d13-hexanol; and ethyl hexanoate, ethyl octanoate and
215
ethyl decanoate using d3-hexyl acetate.
216 217
Foaming Analysis. Two parameters representative of foam stability and foamability were
218
calculated, being the maximum volume of foam (Vf) and the average lifetime of foam (Lf), using a
219
robotic pourer and image analysis according to previously described methodology.32 Measurements
220
were performed (in duplicate, from two separate bottles) on chilled wines (5°C), with the exception
221
of one Méthode Traditionelle wine which could not be measured because the bottle did not fit the
222
pourer. Data for this production method therefore represents 19 wines only.
223 224
Quality Ratings. Quality ratings were measured as described previously.33 Briefly, an expert panel
225
comprising sparkling winemakers and wine show judges (n=19) rated the quality of each sparkling
226
wine (with 5 wines presented in duplicate to validate reproducibility) using the 20 point scoring
227
system employed in Australian wine shows;34 with wines presented to panelists as brackets of 5
228
freshly poured, chilled (5 ºC) wines, in random order, in three digit coded XL5 (ISO standard) wine
229
glasses.
230 231
Statistical Analysis. Data were analyzed using a combination of descriptive and multivariate
232
techniques, including Analysis of Variance (ANOVA) with post-hoc Tukey's test at P
