Monday 15 December 2014

Brett Trois - A riddle, wrapped in a mystery, inside an enigma.

So recently a youtube viewer of mine (Dan Aba, whose youtube channel you need to check out if you haven't already) turned me onto a Facebook group dedicated to sour beers. Lo and behold, the first thread I see on the forum is one claiming that Brettanomyces trois is actually a Saccharomyces yeast! This info didn't just come from nowhere; Lance Shaner of Omega Yeast Labs sent of the strain to a friend for sequencing, and the sequence came back Saccharomyces. Unfortunately, the sequence quality was poor and the sample appears to be a mix of two strains - so I thought it was time to do my own investigation.

The process I followed was fairly straight forward:
  1. I grew up B. trois from my yeast bank, overnight in a 37oC shaking culture - 1.040 wort + penicillin and streptomycin (to ensure a bacteria-free culture, not because my stocks are dirty)
  2. I took some images to assess morphology of the yeast
  3. I isolated some DNA and sequenced the Internal Transcribed Spacer (ITS) and part of the small (18s) rRNA gene to identify the yeast, using an optimized version of what I was doing in my previous posts.
So what did these experiments show? . . . . . . . Answer (and details) below the fold.

And the species is...

So normally I would leave the big reveal to the end, but for those who want to avoid the nitty-gritty the answer is...

Brettanomyces trois - at least the version sold by White Labs (WLP644) - is a Saccharomyces. It is most likely Saccharomyces cerevisiae, but the genetic information doesn't nail that down completely.

So, how do I know?


Morphology

In my previous posts I have mentioned that morphology is not overly useful for identifying yeast - sometimes it can shorten the list of possibles, but on days like today it can also act to confuse things further. Keep in mind that this culture started off as a single colony; so its unlikely to be a blend of two or more yeasts. Even so, I see both sacc-like and brett-like morphologies. Saccharomyces cells tend to be slightly elliptical and symmetrical across the short and long axes. When they divide, Saccharomyces usually buds just to the side of one pole of the cell - i.e. they look exactly like the cells on the right side of the below montage. In contrast, Brettanomyces tends to show a range of cell morphologies - everything from Saccharomyces-like ovoids through to chains of elongated cells. Moreover, Brettanomyces is a little less rigorous about where it forms buds - just like the cells on the left side of the below montage...

Four WLP644 - in budding (top) and stationary (bottom) phase
Left: yeast with brett-like morphology
Right: yeast with sacc-like morphology
For those who want to get a better idea of the diversity of cell shapes and sizes, here is a field of view that does a good job highlighting the various morphologies that I observed in the culture of WLP644.

Click for Full-Size

Clearly microscopy isn't going to solve this riddle, so onto the DNA.

Ribosomal Sequencing

The next step was to sequence two parts of the yeast's ribosome in order to positively identify the genus and species of this yeast. I have blogged about these methods extensively (posts 1, 2, 3 and 4), so I'm not going to go into all of the details, but long story short I sequenced two parts (ITS and small ribosomal RNA) of the yeast genome useful for identifying different species of yeast; unfortunately, the small ribosomal sequence did not work, so all I have is the ITS
The ITS sequence is:

Internal Transcribed Space (ITS1)
>WLP644 ITS Sequence
CGATGAAGAACGCAGCGAAATGCGATACGTAATGTGAATTGCAGAATTCCGTGAAT
CATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATTCCAGGGGGCATGCCTGTT
TGAGCGTCATTTCCTTCTCAAACATTCTGTTTGGTAGTGAGTGATACTCTTTGGAG
TTAACTTGAAATTGCTGGCCTTTTCATTGGATGTTTTTTTTTCCAAAGAGAGGTTT
CTCTGCGTGCTTGAGGTATAATGCAAGTACGGTCGTTTTAGGTTTTACCAACTGCG
GCTAATCTTTTTTTATACTGAGCGTATTGGAACGTTATCGATAAGAAGAGAGCGTC
TAGGCGAACAATGTTCTTAAAGTTTGACCTCAAATCAGGTAGGAGTACCCGCTGAA
CTTAAGCATATCAATAAGC

The next step is obviously to identify to which species WLP644 is the most closely related to. I've done this in two ways - my old method of performing a BLAST search with settings that will hopefully pull quality matches, but as my older posts show, this method doesn't work well due to the high abundance of other yeast sequences - notably Picha strains - which tend to bias the results. None-the-less, based on the BLAST search, WLP644 is:
  • By ITS Sequence: 100% match to S. cerevisiae, S. bayanus, S. eubaranus, S. pastorianus, and S. uvarium
Clearly, we don't have a species-level ID, but we're down to a handful of species.

I have, however, since developed a better analytical method for identifying yeast strains. I have built a database of ITS sequences from every species of Saccharomyces and Brettanomyces/Dekkera that exist in the NCBI nucleotide database. If more than two sequences are available for a given species, I tired to include a "type" species (e.g. the "default" or "model" strain for that species) as well as an additional strain from a different source. I limited the number of sequences for each species to 2, with the exceptions of Brettanomyces bruxellensis and Saccharomyces cerevisiae. I included additional sequences for these species as they are the most common brewing species and I wanted to ensure the best chance of a proper match.

Using a program called Mega6 I generated evolutionary trees comparing the ITS sequences of my database plus WLP644. This produces the following tree:



As you can see, WLP644 (blue highlights; Lance_2 & Bryan_2) is firmly rooted in the Saccharomyces genus. The sequence Lance_2 was provided by Lance from Omega Labs while I was running analysis - this was in addition to his earlier sequences that started this whole process. As you can see, Lance and I have near-identical sequences and these match up well with other Saccharmocyes, and the yeast is far removed from Brettanomyces (highlighted in yellow).

Of course, the downside to using this particular part of the genome for identifying yeast is that it does not tell apart several of the species which make up the Saccharmoces genus. This is why I switched to small ribosomal subunit sequencing for my own ID work, but unfortunately, that sequence didn't work this time around.

Can We Determine The Species - Other Peoples Work

Several others weer working their way through this identification at the same time as I. This included an RLFP analysis by Kristoffer Krogerus, which confirmed the Saccharomyces ID but didn't give a species-level ID. Richie Preiss tested growth on cycloheximide - the yeast didn't grow, indicative that it is not a Brettanomyces. Lance of Omega Yeast Labs had received his first set of sequences which he was kind enough to share with me. Importantly, sequenced a slightly different portion (ITS2 region) of the yeast's genome to ID the yeast, and got the following result:
Lance's Tree - B. trois is the top-most sequence
These results give us a bit more clarity - firstly WLP644 is closest to Saccharomyces cerevisiae than it is to other Saccharomyces yeasts, giving us a likely species identification. Secondly, it appears to be somewhat divergent from Saccharomyces cerevisiae as well - perhaps indicating that it is a a unique substrain, or perhaps even a unique species that has diverged from Saccharomyces cerevisiae.

So What Does it Mean?

Opinion here seems to be split - half of people falling on the "who cares, it still makes good beer" and half on the "this changes everything - how did we not know" sides of the spectrum.

Ultimately, I think it matters - but only a little.  Beer drinkers and brewers are getting ever more used to dealing with odd organisms in their beer, and it looks like WLP644 is simply a little less odd than previously thought. People entering beers brewed with this yeast may need to stop entering it as a brett-beer, but otherwise little changes on that end. In contrast, there are some commercial aspects to this of more import. Because this yeast is now known to be a Saccharomyces, breweries and yeast providers will likely have to change their labeling, or risk running afoul of labeling laws. The fact this yeast is Saccharomyces may also lead to breweries previously unwilling to bring Brett into their breweries to begin working with this yeast.

But it may mean one other thing - if you look at the last tree in my post it is apparent that while the "B." trois is most genetically similar to Saccharomyces cerevisiae, it is much more different from S. cerevisiae than other species of the Saccharomyces genus are from each other - for example, there appears to be ~40X more difference between "B." trois & S. cerevisiae as there is between S. baryanus, S. uvarium and S. pastorianus. What this may mean - although a lot of additional testing would be required to confirm - is that "B." trois is a new species within the Saccharomyces genus.

And that is pretty cool.

9 comments:

  1. Awesome work, Bryan... I'm not just saying that because you shouted me out. Thanks. :)

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  2. Well that would certainly explain why my IPA fermented with trois "acted just like any other yeast" or whatever I said in that post. Have you reached out to White Labs for comment? I've dealt with them in the past and they were incredibly good about responding to my questions. Interesting stuff!

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    Replies
    1. A few people already have reached out to white labs, and they're on the case:
      http://www.whitelabs.com/blog/wlp644-background

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  3. Hello Bryan:
    Very nice work.I am still playing with PCR/RFLP to ID SAC. and BRETT and now doing Acetobacter detection with PCR/RFLP (mostly because my 8 gall bourbon barreled flanders red seems quite acetic. These work nicely in the lab with undergrads BUT really gotta use the sequencing approach.
    Have a great holiday season.

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  4. Does this imply that the BSI Brett Trois is also sacch? Has anyone sequenced that yeast? Most of the commercially available 100% brett IPA type beers that I have had use that strain over the White Labs version.

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  5. Luke,

    BSI doesn't have Brett Trios... =) BSI has Brett Drie which is a B. bruxellensis strain. You can read about it at the Brettanomyces Project post- http://www.brettanomycesproject.com/2009/10/species-identification/

    If you ask me, which no one did.. So I offer this up.. This is not surprising, this is the same thing I found over 5 years ago and posted about 4 years ago on the Burgundian Babble Belt: http://babblebelt.com/newboard/thread.html?tid=1108752780&th=1281111541
    I found this same thing with the Claussenii strain back in the day. Although that actually did have Calussennii in it as well os some of their other yeast and bacteria. The same went for the B. lambicus strain I plated out. The reality of it is, keeping yeast clean is no small task. White Labs offers amazing strains and does a killer job. But at the end of the day it's going to happen sometimes. Breweries struggle with keeping their cultures clean. Any brewery that says they don't have occasional cross contamination is not doing enough QA/QC to pick it up. It's just the nature of how it works. It's unrealistic to thick cross contamination doesn't happen from time to time. Now imagine a yeast company that only works with yeast. It is not a fair example of White Labs quality because Chris White and the crew at White Labs does a great job. This type thing is bound to happen, and when it does, the yeast company goes back to the original culture and starts up a new prop and then you are back to the pure culture, original yeast again. I'm sure White Labs has already done this and the Brett Trois that will be available will be Brett brux again as it usually is.

    By the way, who else is making a 100% Brett IPA? =)

    Cheers,
    Chad

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    Replies
    1. Wow, the big man himself!

      That said, I'm not sure this is a contamination issue, for a number of reasons:

      1) I've tried (and am still trying) to enrich for brett. This is being done through culturing the WLP644 in media with cycloheximide. I have two different WLP644 isolates, but even after 1.5 weeks @ 28C I still have no growth from either sample.

      2) The ITS PCR is quite sensitive to contamination - I've performed it on mixed brett/sacc cultures in the past and observed the expected ~800bp (sacc) and 500bp (brett) bands. From a purely theoretical standpoint, a visible band should be produced even if brett is present at 10^-7th the amount as the sacc.

      3) No minor traces were present in the sequencing result; again, if this were a mixed culture that should have been observed.

      4) Several others, using different WLP644 isolates, have found the same thing. That, despite the fact that we all used different batches of WLP644 - ranging from one of mine that I know to be one of white labs original releases (summer 2012), through to a new out-of-the-tube batch used by Lance, and we see the same result across those different isolates.

      5) My isolates at least - and I assume those at Omega yeast labs and in the home breweries of those who also ran tests - produce beers with the expected flavour profile, and at least in my case, do so without requiring the extensive ageing one would expect if the flavour was being developed by a minute portion of the population.

      I agree with you completely - White labs does great work, and if this is a contamination issue they will resolve it. But given this yeasts history, it may be very well possible that it was simply misidentified originally and that error has since been unwittingly propagated by the various yeast companies out there who've released the yeast.

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  6. Bryan, I'm interested in trying a brett fermented recipe, and am wondering if when using Brett Trois I can forego any contamination containment procedures. Can I treat it just like my regular ferments, or do I need separate equipment?

    Cheers

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    Replies
    1. As a rule, you do not need separate equipment for brett as it is no more difficult to get rid of than sacc (clean + starsan). That said, Trois is confirmed by white labs to be sacc, so working with it is no different than working with any other brewing yeast strain...other than its flocculation is horrendously bad.

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