Saturday, September 30, 2017

Photosynthesis, Carbon Dioxide and Higher Alcohol Wines

Let me preface this piece by saying that I'm a fan of lower alcohol wines. I was first introduced to wine in 1980s Upstate New York, drinking 11.5% Rieslings and, yes, Cayuga Whites. Red wines from the area, like Marechal Foch and De Chaunac (for an overview of hybrid varieties like Cayuga White, Marechal Foch and De Chaunac, see here) were in the range of 12-12.5%. At the time, this wasn't considered low alcohol, it was considered the norm.

Perhaps because of this early exposure to lower alcohol wines, I've always preferred them, and I actively look for them when considering a purchase. New Zealand, despite being a cool climate winegrowing region, now regularly produces 13-13.5% whites and Pinot noirs are often seen with 14.5%. This goes against my, personal, ideas of what these wines should be.

I look forward to wines from the really challenging vintages where grapes struggle to get as ripe as the winemakers want them. The 2012 vintage in Hawkes Bay had a really cool and extended ripening period and grapes were brought in at much lower sugar levels (measured in degrees Brix in New Zealand and other places) than usual, but it resulted in some very good, and more elegant, in my opinion, wines as a result, with the alcohol being in balance with the other aspects of the palate. New Zealand's most recent vintage was also a challenge due to rainfall in the ripening period, resulting in grapes being brought in before target Brix were hit. I tasted my first of this vintage's wine in August, a Marlborough Sauvignon blanc, that had all the hallmarks of the region, but with only 12% alcohol: it was a much more harmonious assemblage than with the usual higher alcohol wines of the region.

Having got that out of the way, what about climbing alcohol percentages in wine?

Rising average alcohol levels in wines has been a topic of discussion for some time, and various reasons for this have been put forth over the years. A useful study to look at was published in 2011 by Alston et al. where data from California was examined to show that average harvest Brix levels between 1980 and 2010 increased. Sugars in red wine varieties increased by an average of 0.23% per year over that period, and notably, in their Figure 1, Brix for red varieties was pretty much flat from 1980 to the mid 1990s, rising from there to the 2010 average of around 23.8°. This was particularly noticeable for the North /Central Coast and Delta regions, where the rate of increase was 0.72, 0.75, and 0.96%, respectively, between 1990 and 2008, compared to 0.53% for California as a whole (Alston et al. 2011 Table 1).

So fruit sugars are going up (at least in California) and the wines made therefore have higher alcohol. But why are the sugars going up?

A different take on this has come about recently, where people are starting to look at rising carbon dioxide (CO2) concentrations in the atmosphere and linking this to increased plant productivity (e.g. here and here). This isn't a difficult link to make, as the process of photosynthesis takes CO2 and water and with the help of the enzyme Rubisco, releases oxygen and sugar (in the form of glucose). It stands to reason that if you increase the availability of a starting material, you can end up with more product. This is assuming that other starting materials (Rubisco, water, sufficiently warm temperatures and light energy in this case) aren't limiting, and that the products don't start piling up in the area where they're being produced - if glucose and oxygen keep building up in the cell, the rate of photosynthesis will slow through a process called feedback inhibition.

So increasing CO2 should mean more efficient photosynthesis and more sugars to go around? As we usually find, things aren't that simple.

There has been plenty of research into the effects of raising CO2 concentration and its positive effects on plant growth and productivity, however, much of this has been with relatively short duration experiments. When plants have a longer time and a chance to adapt to the changed conditions there is more talk of photosynthetic down-regulation, or acclimation, resulting in relatively little change.

A review by Makino and Mae notes that longer term plant adjustment is a complicated system. For example, if sugar is being produced more quickly, but the plant does not have the capability of moving the sugars out of the cell fast enough, photosynthesis will be slowed by feedback inhibition. This kind of makes sense, too, as the plant would change things so that a balance remains between production and utilisation of photosynthetic products.

There is also a suggestion that seedlings have a greater response to high CO2 compared to older plants, possibly because seedlings are generally carbohydrate supply limited, whereas older plants have a store of carbohydrates that are used when needed. Grapevines, being perennial plants, have decent carbohydrate stores even from a reasonably young age.

It's not just photosynthesis that can change, either - under climate change scenarios, increasing temperatures will also increase the respiratory activity of Rubisco. Yes, this enzyme goes both ways: it can help convert CO2 into sugar, but the same enzyme also latches onto oxygen in the process of photorespiration. This opposes photosynthesis and makes the process less efficient. Photorespiration increases faster than photosynthesis as temperatures increase, so photosynthetic efficiency suffers.

And as Jamie Goode has pointed out (here in an article where he points out a whole bunch of interesting things on the subject) with higher CO2 plants don't need to open their stomatal pores as much, because a lesser amount of air holds the same amount of CO2. This can lead to less water use, as with less air movement in and out of the leaf, there is less water vapour lost, too. A side effect of this, however, would be a rise in leaf temperature due to less evaporative cooling (you can experience this by spraying your arm with water - it feels cooler right away because the water is evaporating, and to do that your body heat is used). Higher leaf temperatures could mean more photorespiration, and more time when the leaf gets too hot to keep the enzymatic machinery going. Higher temperatures, associated with climate change, will only make this problem worse.

The multiple changes to the environment will cause plants to respond, but exactly how they respond is really too complex for us to say at the moment, especially when you start to take into account that these changes will have an influence on all the other living creatures around and on the vine (disease organisms, insect pests, and don't forget the soil ecosystem!).

So the overall effect on grapes and wine gets hazy pretty quickly, with lots of factors, and responses, involved. Having said this, I agree with Jamie in that the rise in CO2 concentration is not really what's responsible for increasing wine alcohol - that has more to do with consumer preference and technological advances.

For those that are thinking about strategies for dealing with high Brix and high alcohol wines, we have a number of tools in the viticultural toolbox, but this is a topic for another article!

Tuesday, July 4, 2017

"Heavy" Drinking and Cancer Risk

I saw a recent headline about alcohol consumption that concerned me a bit, and because so many editors skew research report findings to get more clicks, I thought I'd take a closer look.

The article in question is titled "Heavy drinking Europeans most prone to digestive cancers." The information itself isn't too extraordinary - if you consume excessive amounts of alcohol, there are bound to be issues, much like if you consume too much of anything.

However, what worried me are two things: 1) what is considered heavy drinking and 2) at the end of the article was a quote from Richard Gardner, who is the CEO of the British Society of Gastroenterology. He said "Fundamentally, there’s no such thing as no-risk drinking."

As a scientist, I know that there is very rarely anything that is black and white, and I have some interest in the area of wine consumption and health issues (having followed in my father's footsteps with research into resveratrol production by grapevines). I have posted on this subject before (see here) and my views on moderate wine consumption and health have not changed in the intervening years...

So the undefined statement about heavy drinking and that about all alcohol consumption being bad immediately rang some alarm bells and got me more interested.

For starters, to be completely pedantic, there is no such thing as no risk anything. Every time we walk out the door, our odds of being injured increase, not to mention all the potential dangers in the home itself! So everything we do is a calculated risk - we have to make the decision, does the risk of a bad thing happening outweigh the benefits of the activity?

For alcohol consumption, there are many examples of research reports that indicate possible health issues generated by excessive drinking, but the key there is "excessive." The article above uses the phrase "heavy drinking." I do not think anyone would argue that consuming too much alcohol is bad for your health - the real question is, in terms of understanding the article, how much is too much and also, and a bit separately, is less than that beneficial or not?

Let's drill down and do some investigative reading of the article....

The headline I saw was on The Drinks Business, and most of the article is fair, noting that there is a range of consumption across the different countries. However, "heavy drinking" is defined as having "more than four alcoholic drinks at least once a week." This can be a bit confusing, as it could be interpreted as more than four drinks per week, but also as more than four drinks a day at least once a week. Without clarity around this, it's difficult to know how to interpret the information.

Because there can be losses or alterations to information as it gets transmitted around (see Chinese Whispers), it would be a good idea to go direct to the source, rather than relying on someone else's interpretation of the information (a very important component of reviewing scientific information, too).

The Drinks Business got their information from Bloomberg, who published "Europeans are drinking themselves to death."

In reading this article, we see a bit more detailed information, with a focus on the average number of drinks per day people consume in various countries.They also report that drinking "heavily" means "more than four alcoholic drinks - at least once a week," which still doesn't help us in interpreting what the data actually mean.

So the next step is to go back to the original source, United European Gastroenterology. Their press release is "Alcohol consumption putting vast majority of Europeans at risk of digestive cancers, report reveals." There, "people that consume 4 or more drinks per day" are considered to be heavy drinkers. This clarifies what they are really talking about, and makes sense - with that much alcohol per day, it's no wonder there is a health impact!

But the original report's version of "heavy" drinking differs considerably from what the editors at Bloomberg used - there is a definite alteration to how people might interpret what "heavy" drinking is with the Bloomberg version.

Lesson: If you can, don't trust the reporting - go back to the source!

Getting back to Richard Gardner's statement, "Fundamentally, there’s no such thing as no-risk drinking," let's take a closer look at that...

Currently, the American Cancer Society (see "Colorectal Cancer Risk Factors") recommends avoiding "heavy alcohol use" and recommends "no more than 2 drinks a day for men and 1 drink a day for women," adding that this "could have many health benefits, including a lower risk of colorectal cancer" (note that the Bloomberg article also points this out).

They're not the only ones saying that moderate consumption of alcohol can be beneficial. The National Institute on Alcohol Abuse and Alcoholism says this "may protect healthy adults from developing coronary heart disease."

The Centre for Disease Control and Prevention has a nice summary of what is considered excessive consumption (here) as does the NIAAA (here)

Not all agencies have quite the same take. The National Health Service (England) suggests that new research shows that "evidence on a protective effect from moderate drinking is less strong than previously thought"(source here). They state that fewer than 14 units of alcohol per week puts you in a "low risk"category as "there is no safe drinking level."

And that brings us back to the risks versus benefits. Saying that "there is no safe drinking level" is misleading because it implies that people should not consume alcohol at all. The fact remains that there is no completely "safe" level of anything. Equally valid, but useless statements could be "there is no safe amount of driving" or "there is no safe amount of sugary drink consumption."

 As the saying goes, "health is simply the slowest possible way to die..." 

We all make choices that have an effect on our health - some are worse, but some can be better.

So for me, I'm happy being in the "low risk" group the National Health Service identifies because based on my reading of the research, there is support for both positive aspects of the risk and for negative ones. 

I believe the positives outweigh the negatives by a large margin, and not just from a health standpoint, but just as importantly from a lifestyle standpoint. Wine gives me so much pleasure in life! Wine is part of a meal - it is part of a discussion - it is part of intellectual stimulation. 

For some, alcohol in whatever form may be a means to get drunk, but that is not at all how I view alcohol - alcohol to me is a component of a beverage that (in wine, at least) is complex, varied, nuanced and something to be thought about, discussed and most of all, enjoyed.

Sunday, March 29, 2015

The Peer-Review Process: Problems and Pitfalls, but it's Worth Saving!


The peer-review process for research articles is a well-established method of screening new results prior to being released to a larger audience. The results of peer-review are supposed to mean that if you read information in a peer-reviewed journal, you can be assured that what is being said makes sense and the information can be used as a sound basis for making decisions.

I should note at this point that I have reviewed articles for many international journals and am an Associate Editor for the American Journal of Enology and Viticulture. In that capacity I screen manuscripts for suitability (e.g. is it within the scope of the Journal, are there glaring errors in science etc.) before sending it out to two people with relevant experience for critical review. I take those reviewer comments, see if they are fair, and then pass them back to the authors for them to consider in revising the document. That is then submitted again and I would look to see if they have addressed all the relevant reviewer comments. If so, the paper is accepted for publication. If not, it may go back for further review, or rejected.

It's not a perfect system (it can take a long time to go through this process, you have potential biases from reviewers, it tends to be a conservative process etc.), but if you look after it well it does a good job.

All researchers that submit manuscripts for peer-review should be giving back to that process by accepting manuscripts to review for those journals -although there are a lot of questions about that process, too, as the people who do the reviewing work provide the engine that runs many for-profit publishers...

However, that aside, the model of peer-review is under fairly extreme pressure. The basis of the process is that people who have expertise in an area of research will do a critical review of papers submitted for publication. The key words there are "critical review."

In my experience, it takes some time to do this. Even screening an article before sending it out to reviewers can take more than an hour, and for me to do a proper review (which includes reading it carefully, researching problematic statements, and then typing up comments) takes about four hours or more.

Researchers have less and less time available to them for a variety of reasons - with constant reductions in budgets, we have more administrative duties. With non-replacement of staff, we're taking on more teaching. There is increased pressure to find external research dollars. There is increased pressure to publish, leading to taking on more research students. In short, we have less and less time to devote to something that produces no tangible benefit to our employers. Four hours spent doing a quality review of a manuscript is four hours spent not doing all the things that a employers wants.

So as an Associate Editor, I'm finding some reviews quite superficial. Increasingly, I also find it difficult to get someone to agree to doing a review in the first place.

As a reviewer, I still try to spend all the time that's necessary to do quality work, but this does come at a cost, personally and professionally.

This latest news item, "Major publisher retracts 43 scientific papers amid wider fake peer-review scandal," is not an isolated example. A visit to Retraction Watch will easily demonstrate this, though some papers are retracted for honest reasons.

But the article mentioned does highlight the problem with peer-review: It was developed in an era when researchers had more time - research money was not as highly contested, teaching loads were less, there was no pressure to publish - you published when you though the data were ready etc. There was plenty of time to pore over someone else's manuscript and give a thoughtful review of its content.

Some of the issues identified in the article linked above should have been caught by the associate editors of the journal -they are supposed to be choosing reviewers for the papers carefully before the paper is sent out: looking for connections between authors and reviewers, checking on the backgrounds of  reviewers and the like. The fact that they have not been doing this is another indication that people working with the papers are under pressure and feel they can't afford to take the time to look over the situation carefully.

So is peer-review doomed? I certainly hope not. The process has much merit to it, but it will struggle to survive until employers recognise the importance of peer-review to science progress. There needs to be a system in place where review of manuscripts is thought of as being of some importance - not as much as publishing a paper, but it needs to give some kudos to those who do it, and especially those who do it well.

Tuesday, January 8, 2013

Herbicide damage when converting to organics?


UPDATE: (June 2014)
More investigations by the vineyard manager all seem to point to the seaweed spray being associated with the symptoms. The explanation below (that the phosphate in the spray is causing the release of bound glyphosate) is still a possibility, but it is also possible that plant growth regulator-like substances in the seaweed spray are interacting with other environmental factors to cause the shoot tissues to respond, and glyphosate residue is not involved.

However, the exact cause is still a mystery!


Original post:
I recently visited a vineyard where vines were exhibiting classic glyphosate damage symptoms. Not so unusual, you say, except that this wasn't in patches - it was pretty even over the whole vineyard, spanning vines of different ages, rootstocks and varieties... Drift from another property was ruled out as surrounding vineyards were fine...


The vineyard had only recently converted to organics from years as a conventionally managed weed-free strip under the vines, created by the use of glyphosate (e.g. Roundup).

Symptoms appeared towards the end of November, after cultivation under the vines had been done. This is not the first time this sort of thing has happened (organics guru Bart Arnst has observed this sort of thing before). Could there be a link between the symptoms and the cultivation? Conventional thought is that glyphosate is rapidly inactivated when it comes into contact with the soil, so how could this be possible?

Well, that last statement is usually misinterpreted. Yes, it's inactivated, but that's not the same as being degraded and rendered harmless...

A bit of research shows that glyphosate is stable in sunlight, and tightly bound to soil particles (Rueppel et al., 1977), particularly clays and particularly in those that have high levels of aluminium and iron. Soil pH is also important, with higher adsorption rates at lower pH values (see Borggaard and Gimsing (2008) for a review on the topic). 

Soil organic matter has variable effects on glyphosate adsorption, but generally results in no change or tends to decrease it due to its blocking of binding sites in the soil (Gerritse et al., 1996), though studies exist to say the contrary (e.g. Sprankle et al., 1975).

Glyphosate can be degraded by soil micro-organisms, but generally not when it is bound to soil particles. The ability of a soil to mineralise the herbicide seems to correlate pretty well with general soil microbial activity, but few species have been identified that can directly act on the molecule itself (Borggaard and Gimsing, 2008; Forlani et al.,1999).  Because of all these variables, the half life of glyphosate in the soil varies from days to months.


The upshot of all this is that the glyphosate sprayed on the soil doesn't disappear - it is bound to soil particles and can be degraded only under the right conditions. Those conditions include levels of microbial activity, but surprise surprise, there isn't a lot of that near the surface of a herbicide-treated soil (Reinecke et al., 2008; Whitelaw-Weckert et al., 2009). Microbes need moisture, nutrients and organic matter to do well, and none of those are very common near the surface of a herbicide strip.

So this is evidence that glyphosate applied season after season is still present in the vineyard, but why does it become a problem when cultivation starts?

A little more digging (pardon the pun...) reveals that glyphosate and phosphate compete for binding sites in the soil, so adding phosphate to soil could release glyphosate (Gimsing and Borggaard,2001). This is why high phosphate soils can bind less glyphosate in the first place (Sprankle et al., 1975).

So here is a possible explanation! The vines in this case had a soil drench of seaweed extract and fish oil, which could have relatively high levels of phosphates. These could have encouraged glyphosate to de-sorb from the clay particles and be taken up by the roots.

Even then, I suspect there is an interaction with rainfall events as the symptoms appeared to stop developing, but later came back after a significant rain event. It's possible that there is renewed root growth into the herbicide-containing soil, leading to more uptake.

Curiously, reports are that the shoots arising from the base of the vine trunks show no symptoms.

As with every other season, there is at least one situation that makes you scratch your head and go, "Huh???"

If anyone has similar experiences, please leave a comment!!
 



Thursday, June 7, 2012

Climate change and its interaction with winegrowing

A Radio NZ article about University of Waikato student Electra Kalaugher and her work on climate change and dairy farms, and the accompanying video was particularly timely, because at about the same time I was answering a questionnaire sent to me by a student studying an MBA in Bordeaux. Her thesis is on climate change on winemaking and how it concerns the French legislation relating to the wine industry.

Below are her questions and my answers to them. My thanks to her for permission to post the information here...

1-Climate change has been affecting the wine industry, like all fields in agriculture. What is your experience in the vineyards of New Zealand so far?


Of those events that are supposed to be altered with climate change, in recent years I think we have seen wider swings in weather events, such as rainfall, snow, frosts and the like. We have had some periods of significant drought, as well as highly unusual heavy rainfall. We have seen some late season frosts, and unusually large amounts of snow in some areas. However, it remains to be seen whether these events are considered to be abnormal in the longer term.

2-Do you think New Zealand will benefit from the climate change since the warmer areas expand?


It is possible that new geographic areas will open up to winegrowing as a result of the overall warmer temperatures. However, this will have implications for the existing areas, where the warmer climate may mean that making wine styles associated with a particular region could be made more difficult. For example, the Marlborough style of Sauvignon blanc is associated with the cooler ripening period that the region has experience. If temperatures rise, the flavours in the wines will also change, and so the wine style.

This is one challenge, and another significant one is the chance of more extreme weather events. Of the possibilities, early season or late season frosts are a particular concern for the wine industry, as many areas are already prone to damaging frost events, so having them occur later into the growing season, and earlier as the season ends and harvest approaches, will have a direct impact on profitability.

Some forecasts for seasonal changes in precipitation point to less overall rainfall as a result of climate change in the eastern parts of New Zealand. Therefore, water will become an even more valuable resource, potentially limiting grape production.

Overall, I do not think that climate change will be a beneficial thing for the New Zealand wine industry, but the reality is that we will have to deal with it.

3-What are the challenges that the wine producers have been facing due to climate change effects?


I've mentioned some of these already - the possibility of frosts happening later in the beginning of the season and also happening before fruit is harvested. Water availability has been an issue with the establishment of newer vineyards, with water schemes needing to be developed to ensure a reasonably reliable water supply. Increased heat means that some grapevines will need to be grown slightly differently in order to retain the flavour profiles that are wanted in the wine. Severe flooding has had minor impacts on vines so far, but this will probably be more of an issue in the future.

4-What kind of changes should be made in the vineyards in order to adapt the shift in climate?


Viticulturally, it will be necessary to change the management of the vines to retain flavour profiles - for example, doing less leaf removal, or changing its timing. Trellising systems may need to be changed to help with this, as Vertical Shoot Positioning, which is the most widely used system in New Zealand, may give the fruit too much exposure.

Irrigation management (and linked with that, cover crop management) will have to be tweaked to ensure vines don't get water stressed at inappropriate times. More efficient ways of delivering water to the vines, and measuring soil and grapevine water status, need to be developed.

With frost events potentially happening when vines have more canopy on them, more efficient ways of dealing with frosts will be needed. If enough water can be found (which is unlikely for large vineyards), sprinkler systems will work, but most are using fans or helicopters at the moment, which rely on the presence of an inversion layer, which holds warm air. As well, it isn't certain how climate change will alter the occurrence and strength of inversion layers...

New vineyards should be planted with future shifts in climate in mind. This encompasses most aspects of vineyards, but also variety choice and potential wine styles to be produced.

5-As a viticulturist, what are your conclusions for the future concerning the climate change effects, for New Zealand and also globally?


In my mind at least, climate change is a reality that we should be ready for. Planning for its occurrence, using the latest forecasts (e.g. NIWA's Climate Change Scenarios for New Zealand), is the best we can do. 

The wine industry will be able to cope with climate change, but it will likely have an impact on the financial planning, with increased risk of crop loss and increased management costs. The possible changes to wine style also need to be considered carefully, as the consumer may want to stick with the current style, but it may not be able to be grown in the same area or it wouldn't be cost effective to do so given the extra labour inputs.

Tuesday, March 13, 2012

What's the weather doing this season?

The Growing Degree Days (GDD) figures for Lincoln through March 13th don't make for pretty reading!!

Currently we sit at 686 GDD (base 10, calculated on a daily basis) while the long term average (LTA, 1931 through 2010) to this point in the season is 812.

 Figure showing the growing degree days for Lincoln, Canterbury based on daily calculations at base 10C

December was the only decent month, having a heat accumulation close to that of LTA, but November, January and February were all cooler than LTA to the tune of about 85% of the value.

Rainfall is about aligned with LTA, the current season to March 13 being about 18mm greater than the LTA of 441mm.

Often, we get a nice March and early April after seasons where the early months' temperatures have been lower than average, but so far this doesn't look like it's happening, with the weather patterns seemingly stuck on cool and unsettled.

The Seasonal Forecast for New Zealand (http://www.niwa.co.nz/seasonal-climate-outlook-march-may-2012) indicates they are expecting more winds from the north-east, which for many of the growing regions in New Zealand, which are along the East coast of the country, means cooler temperatures.

When I look back at the pattern of heat accumulation for Lincoln Uni since the 1998-1999 season when I first arrived in Canterbury, this is the coolest season of them all, bar the 2000-2001 vintage. It's also been a remarkably consistently cool season, whereas in other years it tends to be warmer than LTA at first, then cooler nearer to harvest or vice versa.

So what does this mean for vintage? As long as the fruit stays free of disease (which we've been encouraging through an open canopy), we should be all right. Any opportunity to drop off crop that is tailing behind the average in terms of ripening is a good idea, as well as keeping the canopy open so the fruit dries out more quickly and also gets warming by the sun. We also have to hope that the night-time temperatures don't get too low, as this can be a signal for the vines to get ready for winter and start dropping their leaves! We've already had a couple of nights near 3C!

Our own vineyard, in which we're growing Pinot noir (and a bit of Pinot meunier) for sparkling wine is about 10km from the Lincoln Uni vineyard, but we're harvesting very shortly as the fruit is up to 19 Brix. In a season like this, this show the value of site selection (our vineyard is on the Port Hills and protected from the easterly (and cool) winds), good canopy management and end use of the grapes (sparkling wine, so they are harvested earlier). Of course, that isn't saying anything about how easy it is to sell the wine!

I suppose the good news out of all of this bad weather information is that the December temperatures were reasonably warm, which should mean we still have a decent initiation of flower clusters for the 2012-2013 vintage. 

At least we will have a promising potential to work with!!




Thursday, March 1, 2012

Selecting the Right Clusters for Your Wine

This article will appear in the Wines of Canterbury Newsletter

"Quality is never an accident" - usually attributed to William Foster or John Ruskin

Colour change and ripening has begun in our grapes, and a lot of people start thinking about cluster thinning at this time. But have you stopped to think about why you're doing this? Here are some possible answers and few thoughts on each:

  • To reduce the crop load
Yes, true. But it takes time and money to do this, and at the same time, you're reducing the amount of fruit harvested and paid for. There has to be more to it than this!

  • To make the winemaker happy
At the recent International Cool Climate Symposium for Viticulture and Oenology in Tasmania, Richard Smart said the best time to start thinning your crop was just before the winemaker visited the vineyard, and the best time to stop was as soon as he left!

The best way to make the winemaker happy is to deliver high quality fruit in relation to what they are paying. Do all winemakers know enough about viticulture and the production of high quality grapes to be able to tell you what is and isn't right for the vines? Some do, but many don't. Their heads should be filled with all things winemaking, and viticulturists' should be filled with all things viticultural.

The best thing to do is get the winemaker to tell you what s/he wants from the vineyard's fruit, and for you to do what's necessary to have fruit that most closely meets those needs. Sometimes, removing lots of fruit is not the answer!

  • To increase sugar accumulation in the fruit
If you go through a vineyard at veraison and remove fruit randomly, I doubt there would be much, if any difference in the harvested fruit composition - that is, the rate of sugar accumulation in the remaining fruit is no faster because you've removed some crop. I haven't seen any consistent and convincing evidence to suggest that removing crop randomly this late in the season brings harvest forward.


However, if we do commercial practice and remove that fruit which is not as ripe as the rest (in the left side of the figure below), then we're decreasing the variability of that fruit by removing the less ripe stuff, and thereby increasing the average ripeness of what remains. So what's happening there is removal the tail end of ripening fruit.




By doing this, you can increase the quality of the resulting wine, which is the overall goal of the viticulture-wine making pathway that we all travel along, and therefore the goal of crop thinning.

Because fruit are being removed selectively, and there will always be some fruit that lags behind in development, this form of thinning can be effective in improving wine quality in any season - particularly in cooler climates, where getting fruit to its optimum ripeness is a challenge.

But it doesn't stop there. If we want to maximise the quality of the wine made from the grapes, we need to ensure that only the best quality fruit ends up in the receival bin at the winery. This process continues on from crop thinning to monitoring the fruit and fixing problems before they arrive, so you have the greatest amount of harvestable crop possible. Things to think about here are:
  • Removing leaves resting directly on clusters. Airflow around and if possible, through, clusters is a very important part of keeping Botrytis at bay! Leaves on top of, or resting next to, clusters keeps the environment more humid and for longer, which is what Botrytis needs to germinate and infect.
  • Similarly, arranging clusters so they are not draped on top of one another. Multiple clusters trying to occupy the same space mean restricted airflow and poor exposure to the sun, leading to greater disease risk and less ripe flavours. The best time to combat this is even a few weeks after fruit set, when it's easier to separate clusters and try to arrange them so they don't touch. If you can't keep them from sitting on top of one another, take the short term loss by clipping off of one of the clusters rather than doing nothing and having the real risk of losing all the fruit to rot.
  • Cutting out clusters or parts of clusters damaged or diseased. Physically damaged fruit can, and usually does, harbour Botrytis - something most evident when a couple of weeks ago I took a few split berries i found in the vineyard (like those pictured below)  and incubated them in high humidity conditions for a day or two. Lots of fungal growth appeared from the damaged areas, but none from the intact parts of the berry. As well, fruit that has a bit of Powdery Mildew on it can split when the berry starts to ripen, inviting Botrytis and other rot organisms. Once it's in and established, it's much more likely to spread around.


  • If you're machine harvesting, have a crew go through beforehand to remove any second set crop that might also be harvested, because even a small amount in a load can have a significant effect on wine flavour. As well, have them take out any diseased or sunburnt fruit, as these can lower the quality of the wine. Monitor their work for slips and keep them on the right track.
  • If you're hand harvesting, the best time to sort grapes is in the vineyard, not on a winery sorting table. Why pick and transport poor quality and diseased fruit, only to discard it at the winery? You make more work for yourself, and increase the risk of spreading the disease around. Make sure your picking crew is well trained to leave the undesirable fruit, and check on them periodically to make sure they continue to do it right.

While this is all sound advice, I'm not trying to say that it's right for everyone. For some wine products, this level of attention to detail is not warranted - there just isn't the payback to justify it. However, if you're thinking about quality first, then every little bit counts. There isn't one, single, management decision that will deliver quality to the winery - it's a series of actions that contribute to the health and suitability of the harvested crop that makes the difference...