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The origins of the Guinness stout yeast
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  * Open access
  * Published: 12 January 2024

The origins of the Guinness stout yeast

  * Daniel W. M. Kerruish  ORCID: orcid.org/0009-0004-3580-7119^1,
  * Paul Cormican^2,
  * Elaine M. Kenny  ORCID: orcid.org/0000-0003-4676-3436^2,
  * Jessica Kearns^1,
  * Eibhlin Colgan^1,
  * Chris A. Boulton^3 &
  * ...
  * Sandra N. E. Stelma^1 

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Communications Biology volume 7, Article number: 68 (2024) Cite this
article

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  * Applied microbiology
  * Microbial ecology

Abstract

Beer is made via the fermentation of an aqueous extract predominantly
composed of malted barley flavoured with hops. The transforming
microorganism is typically a single strain of Saccharomyces
cerevisiae, and for the majority of major beer brands the yeast
strain is a unique component. The present yeast used to make Guinness
stout brewed in Dublin, Ireland, can be traced back to 1903, but its
origins are unknown. To that end, we used Illumina and Nanopore
sequencing to generate whole-genome sequencing data for a total of
22 S. cerevisiae yeast strains: 16 from the Guinness collection and 6
other historical Irish brewing. The origins of the Guinness yeast
were determined with a SNP-based analysis, demonstrating that the
Guinness strains occupy a distinct group separate from other
historical Irish brewing yeasts. Assessment of chromosome number,
copy number variation and phenotypic evaluation of key brewing
attributes established Guinness yeast-specific SNPs but no specific
chromosomal amplifications. Our analysis also demonstrated the
effects of yeast storage on phylogeny. Altogether, our results
suggest that the Guinness yeast used today is related to the first
deposited Guinness yeast; the 1903 Watling Laboratory Guinness yeast.

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Introduction

To mitigate against unpredictable climate and food shortages humans
moved from hunter gathering to an agrarian existence^1. In
consequence, animals, plants and unwittingly, some microorganisms
were domesticated^2 including the ethanol-forming and CO[2]
-generating yeast S. cerevisiae. The latter event occurred in
multiple geographical locations resulting in the almost universal
exploitation of the abilities of Saccharomyces yeasts to leaven bread
and produce a multitude of alcoholic beverages^3,4.

Largely based on its ease of cultivation and GRAS designation S.
cerevisiae has become the model for eukaryotic cell biology^5,6.
Principal component analysis of single nucleotide polymorphisms
(SNPs) have established a Chinese origin^3 of S. cerevisiae with the
Saccharomyces genus believed to be of Asian origin^7. Publications
using industrial strains have provided further understanding of the
phylogenetic origins of S. cerevisiae used in wine and beer
production^4,8. Recent publications have established the effects of
European and Asian wine admixture on today's industrial brewing yeast
^9 with those yeast more readily associated with commercial brewing
activities dominated by Asian admixture^10. Admixture within
domesticated S. cerevisiae is incongruous with other Saccharomyces
yeast, where admixture and heterozygosity levels are low^7. Many of
these industrial S. cerevisiae strains have genomes which feature
polyploidy, aneuploidy and loss of fitness, all characteristic of
domestication^3. These domesticated yeasts carry mutations conferring
properties that make them suitable for beer fermentations. These
include the formation of a spectrum of beer flavour yeast
metabolites, the ability to utilise sugars such as maltotriose and
maltose; ethanol tolerance and an ability to separate from beer at
the end of fermentation via the process of flocculation^8.

Historically, distinct beer styles were associated with specific
geographical regions based on the availability of raw materials and
the mineral composition of the water supply^11. In addition, specific
yeast strains were selected to enhance and meet the desired beer
style qualities. Initially this was unwitting since the role of yeast
was only proven in the early 19th century independently in France by
Cagniard-Latour and Germany by Schwann and Kutzing^11. Nevertheless,
brewers had actively been selecting yeast for their phenotypes in
Europe from at least the 1600s^4. This led to selection of specific
industrial brewing yeast strains from geographical locations
containing specific SNPs. Confirmation of geographical specific SNPs
have been observed in yeasts isolated from beers brewed in Germany,
Belgium, Britain, the USA and Norway^4,12.

Founded in 1759 by Arthur Guinness, the St James's Gate Dublin
brewery was by 1886 the world's largest by volume^13 (1.8 MHl per
annum) becoming synonymous with stout beer brewed in the Irish dry
stout style. The brewery archives provide comprehensive details of
the yeast studies performed by scientists employed by Guinness;
however, no information is held regarding the origins of the yeast
first used to brew beer at St James's Gate. The first mention of a
starting culture (yeast) is detailed in the 1809 Guinness Brewing
Book on the 10th and 11th of May. At the time of writing, the two
principal Guinness stouts; Guinness Irish Draught Stout (IDS) and
Guinness Foreign Extra Stout (FES) are brewed using yeast isolated
from the 1959 Guinness pitching yeast. The Guinness archives confirm
that the 1959 isolates were selected from the 1903 Watling Laboratory
Guinness yeast.

In this study, 13 Guinness yeast strains, the two current production
yeasts and six other historical Guinness strains were assessed to
establish the origins and nature of the Guinness yeast. Our analyses
have established that the Guinness yeast form a subgrouping within
the previously described Beer 1 clade^4. Furthermore, the Guinness
strains are mosaic sharing ancestral lineage that is different to
other historical Irish brewing yeast. Genomic assessment of the
Guinness yeasts confirmed that the Guinness yeast are genetically
similar with different phenotypes, demonstrating the importance of
phenotypic validation of yeast for brewing. The assessment of the
Guinness yeast chromosome and copy number variation (CNVs) supports
previous conclusions regarding the role of gene copy number and
phenotype. Consequently, the principal findings of this paper are
that the Guinness yeast strains are intimately related and are
derived from a common ancestor.

Results

Determining the origins of the Guinness yeast

The two current Guinness production and eleven historical Guinness
yeast were chosen to understand the origins and phylogeny of Guinness
yeast. Selection was based on a review of historical records held in
the Guinness archives (Table 1). The purity of the 13 Guinness yeast
strains was determined using the interdelta PCR method of the TY
retrotransposon elements^14. The method generated a 'fingerprint' for
each of the yeast strains (Supplementary Fig. 1). Dendrograms of the
PCR fragment lengths were assessed using hierarchical clustering
(Euclidean distance) with yeast confirmed as being identical given a
100% similarity score. For the two Guinness production yeast, FES and
IDS, the interdelta PCR method established that all three FES strains
were <100% similar, two of IDS strains were 100% similar and the
third 98%. Interdelta PCR assessment of the other eleven historical
Guinness yeast established the principal fingerprint of the strains;
subsequently representative samples of each of the eleven historical
Guinness yeast were determined. The fingerprinting evaluation of the
13 Guinness yeast, two production yeast encompassing the five
isolated individual yeast strains, and the eleven historical yeasts,
resulted in a selection of 16 Guinness yeast for whole-genome
sequencing.

Table 1 Name and description of yeast strains used in this study and
selected following a literature review of the Guinness archives.
Full size table

In addition to the 16 selected Guinness yeast a further 6 historical
Irish brewing yeast (Table 1) were sequenced using an Illumina MiSeq
machine reading with a minimum depth of 30x coverage using 2 x 250 bp
paired reads. The Sequences were assembled de novo using the S.
cerevisiae S288C reference genome (R64 1-1). Origins of the Guinness
strains were probed by comparing their genomes with those of the 6
other Irish Brewing yeasts and 154 previously published S. cerevisiae
strains^4. A total of 466,327 filtered variant sites were identified:
434,890 SNPs and 31,427 indels. For the Guinness yeast, 96,821
filtered variant sites were identified with: 88,271 SNPs and 8550
indels (Table 2). Some 5407 filtered variant sites were exclusive to
the Guinness yeasts, a total of 4907 SNPs and 500 indels.

Table 2 Sporulation percentage; mean sequencing coverage along S.
cerevisiae S288C genome, transition, transversion and singleton SNPs,
and total indels of the 16 sequenced Guinness yeast.
Full size table

A maximum-likelihood (ML) phylogenetic tree of the 176 yeast was
constructed using RAxML v8.2.12^15 based on the concatenated
alignment of orthologues protein coding genes and visualised using
ggtree (v 3.6.2)^16 (Fig. 1). Previous work has placed the 154 S.
cerevisiae strains into 8 separate lineages^4. Brewing strains were
located in either the Beer 1 or Beer 2 lineage. Our analysis
confirmed these observations with the Guinness and other historical
Irish brewing yeast placed within the Beer 1 clade (Fig. 1).

Fig. 1: Phylogeny and population structure of the Guinness yeast and
other industrial S. cerevisiae strains.
figure 1

a Guinness and other Irish brewing yeast within the
maximum-likelihood phylogenetic tree of S. cerevisiae. Guinness and
other Irish brewing yeast were sequenced using an Illumina MiSeq
platform and combined with 154 previously sequenced S. cerevisiae^4.
Branch length reflects the number of substitutions per site, with
colour denoting the yeast lineage. A maximum-likelihood (ML)
phylogenetic tree was reconstructed in RAxML v8.2.4^15, performing
100 iterations to search for the best tree, using a discrete GTRGAMMA
model of rate heterogeneity. Bootstrap branch support was assessed by
performing 1000 pseudoreplicates. Trees were visualised using ggtree
(v 3.6.2)^16. Yeasts that are marked in highlighted orange are
described as being Mosaic^4. Yeast marked with three asterisk are
used to brew beers in the Hefeweizen style. b Principal component
analysis of 434,890 SNPs sites from the assessed 176 S. cerevisiae
strains. Population differences indicated by colour; NS not
specified. c Population structure of the 434,890 SNPs sites of the S.
cerevisiae strains used in this study. IDS1 was used as a
representative Guinness yeast sample for all Guinness yeast due to
the high degree of sequence similarity analysis consequently 161
genomes admixture were assessed. Resolved population fractions are
represented by the vertical axis; colours denote estimated ancestral
membership. Varying the number of ancestral populations (K) between 1
and 10 using the simple prior implemented in fastSTRUCTURE^17, K = 8
found to be optimal.

Full size image

The Beer 1 clade contains three separate subpopulations; a
consequence of allopatric activity. These three distinct geographical
groupings are Belgium/Germany, Britain and the USA. The non-Guinness
Irish brewing strains were located in the 'Britain' subpopulations,
whereas the Guinness yeast occupy their own subgroup outside the USA
and 'Britain' subpopulations. This was an unexpected observation as
the Guinness archives contain multiple records of the company
requesting and supplying yeast to other Irish brewers, examples of a
practice common until the mid-20th Century.

To understand the origins of the Guinness yeast populations,
structure and degree of admixture were determined for the 176 genomes
used in this study using FastSTRUCTURE (Version 1.0)^17. Owing to the
high degree of sequence similarity between the Guinness samples a
single representative, IDS1, was selected for analysis. Varying the
number of ancestral populations (K) between 1 and 10, K = 8 was found
to be optimal (Fig. 1); an observation in accordance with previous
ancestral population investigations^4. The non-Guinness Irish brewing
strains were all placed within the 'Britain' subpopulation, based on
>80% common ancestry. The brewing strains of companies Perry, Cherry
and Smithwicks aligned completely to the Britain subpopulation,
whereas the Great Northern, Macardles 1966, and Macardles 1993 yeast
aligned with the 'Britain' group (>88%) but also the US and Belgium/
Germany subpopulations.

Mosaicism within the phylogenetic tree is defined as a yeast
possessing an ancestry of <80% from a single population^4. Within the
Beer 1 subpopulation, 10 yeasts were designated as being mosaic;
these yeasts that are marked in highlighted orange in Fig. 1.
Analysis of the representative Guinness yeast, IDS1, established the
ancestry of IDS1 being <80% from one grouping. The Guinness yeast are
therefore Mosaic. Further analysis of the admixture (Supplementary
Fig. 2) using the Alpaca^18 software confirmed the observations of
the FastSTRUCTURE^17 analysis, with the genome hereditary of the
Guinness yeast belonging to multiple ancestry origins. The admixture
and Alpaca^18 analysis establish a non-linear monophyletic origin of
the Guinness strains. The non-overlapping segments across the 16
chromosomes display a high degree of similarity with segments from
yeasts derived from very distinct phylogenetic subclades and
geographical locations. Consequently, analysis present in
Supplementary Fig. 2 confirmed the highly non-linear genetic content
of the Guinness yeast relative to other members of the Beer 1 clade.
Furthermore, the phylogenetic tree presented in Fig. 1 placed the
yeast Beer042 as the closest relative to the Guinness yeast. The
Alpaca^18 analysis confirms this observation with all of the
chromosomes sharing SNPs observed in Beer042. Omission of the Beer042
from the analysis confirmed that SNPs from the 'not specified'
ancestry were the most significant (38.8%) (Supplementary Fig. 2).

Phylogeny assessment of the Guinness yeast using long read sequencing
technology

Short read sequencing de novo assembly against a reference genome
introduces potential scaffolding bias^19. It has been observed that
using S. cerevisiae S288C as the reference genome results in large
sequencing gaps in sub-telomeric regions and in consequence poor
yeast genome assembly^20. Long read sequencing provides a more
comprehensive genome assessment from which a reference genome can be
assembled and annotated^20. Using a Guinness yeast as the reference
genome is suitable since S. cerevisiae S288C is a distant relation
and this could result in potential phylogeny misrepresentation. The
Guinness yeast IDS1 was selected for long read sequencing using the
Minion system (Oxford Nanopore Technology, Oxford, UK). 421,040 reads
were generated and the genome assembled using Flye^21 (v 2.9)
programme. The other 15 Guinness yeast were then assembled against
IDS1. Following removal of intergenic variants, a total of 20,039
SNPs present in protein coding genes were identified in the 16
Guinness strains. Hierarchical clustering of the 16 Guinness strains
was established using standard dissimilarity matrix analysis. The
analysis of all SNPs identified in protein coding genes resulted in
assessment of 20,000 protein coding biallelic SNPs^3 (Fig. 2). With
the exception of the 1955 Brewing Pitching yeast the Guinness yeast
divide into two groupings, pre and post-1959. The observed
hierarchical clustering generated using IDS1 as the reference genome
was different from the observed clustering derived using S.
cerevisiae S288C. Analysis using the former indicated that there was
a deliberate selection of the Guinness yeast in 1959 confirming the
archival account of Robert Gilliland's 1959 Guinness yeast
reselection programme.

Fig. 2
figure 2

Hierarchical clustering of the 16 Guinness yeast using standard
dissimilarity matrix of 20,000 protein coding biallelic SNPs as
determined by de novo assembly of the Guinness yeast to the MinION
sequenced reference genome IDS1.

Full size image

Copy number variation and chromosomal arrangement of the Guinness
yeast

To determine the CNV for the different Guinness strains a full
normalised read depth analysis was performed in 250 bp windows across
each chromosome. The result was normalised against an estimated copy
number of 4 as this was the average chromosome copy number estimated
for the Guinness strains. The likely accuracy of Guinness ploidy
estimates was confirmed by reassessing the ploidy of previously
published yeast samples^4. The 250 bp window assessment of the
Guinness strains (Fig. 3) showed the presence of multiple copies of
chromosomes and CNVs within individual chromosomes. Whilst there are
chromosomal CNVs across all 16 chromosomes only chromosomes II, XIII
and XV have 5 chromosomal copies in 6 or more Guinness strains; even
yeast that are closely related, IDS1 and IDS2, exhibit difference in
CNV in chromosome II, VI, X and XVI. Consequently all 16 Guinness
yeast are aneuploid.

Fig. 3: Estimated CNV in 250 base pair non-overlapping windows across
the entire genome of the 16 Guinness yeast.
figure 3

A black dot on a plot represents a window where the estimate copy
number is 4. A blue dot represents a region with an estimated loss of
copy number (<4) and an orange dot represents a region of estimated
increased copy number (>4).

Full size image

Aneuploidy is common for ale brewing strains and has been previously
reported in multiple studies^4,11,22. Unlike natural isolates,
domesticated yeast have been influenced by human activity. This
selection pressures result in polyploidy for genes conferring
sought-after phenotypic qualities. In concert with this, decreased
global cellular fitness occurs^3. Consequently, wild type S.
cerevisiae are more likely to be diploid with a functioning sexual
phenotype^22. In contrast and presumably a consequence of the effects
of aneuploidy, all 16 of the Guinness strains exhibited poor
sporulation (Table 2); 7 strains did not sporulate at all and of the
other 9 the 1959 pitching yeast had the highest sporulation
percentage of just 2.8%. This observation is concurrent with Bilinski
and Casey^23 who also reported poor sporulation in aneuploid yeast.

Phenotype analysis of the Guinness yeast

In order to determine whether the genetic similarity defined a
'Guinness yeast phenotype', the 16 strains were assessed for
phenotypic traits using mini-fermentations as described in the
methods section. Some differences in both patterns and extent of
attenuation, as well as ethanol production were observed (Fig. 4). A
one way ANOVA with Tukey's post-hoc test of the 16 Guinness yeast
determined that ethanol production was significantly different (P =
 3.09 x 10^-9). Assessment of all of the Guinness yeast using a
single representative IDS, FES and Park Royal yeast confirms that
ethanol production is significantly different (one way ANOVA P =
 0.00036), but separate one way ANOVA analysis of the ethanol
production of the two yeast identified within the IDS yeast were not
statistically significant (P = 0.64) likewise analysis of the Park
Royal yeast showed that there was no statistical difference between
the Park Royal yeast (P = 0.13). Only the FES yeast demonstrated
significant difference in ethanol production (One way ANOVA P =
 0.00011) but when FES 2 and FES 3 were assessed without the
inclusion of FES 1 ethanol production was determined not to be
statistically significant (P = 0.08). Likewise, time to attenuation
varied between strains with the Park Royal 1979 yeast achieving
attenuation in 22 h compared with 72 h for the 1959 Guinness pitching
yeast (Fig. 4).

Fig. 4: Phenotypic assessment of the Guinness yeast.
figure 4

a Percentage weight loss, b ethanol production, c sugar concentration
d assessment of esters, e higher alcohols and f 2, 3 butanedione
(diacetyl) production at the cessation of fermentation using the
different Guinness yeast. Fermentations were performed using 100 ml
of 12^oP all-malt wort, with an inoculation rate of 1 x 10^7 ml^-1
cells. Samples were incubated at 25 degC and stirred at 250 rpm.
Observations presented are n = 3 biologically independent
experiments. In a each time point represents the mean of 3
independent replicates and standard errors are shown as SD +- error
bars.

Full size image

The progress of brewing fermentations is typically assessed by
recording the decrease in wort density. Measuring loss of weight, in
the mini-fermentations described here is an indirect method which
also relies on a fall in density. This decrease is a consequence of
the utilisation of wort sugars by yeast and the formation of ethanol.
Brewing yeast strains can assimilate simple wort sugars which include
glucose, fructose, sucrose, maltose and maltotriose; dextrins are not
fermented^24.

Maltotriose utilisation correlates with the maltose multigene loci,
five of which (MAL1, 2, 3, 4 and 6) have been identified in S.
cerevisiae^25. Only the MAL1 and MAL3 multigene are present within
the reference yeast S. cerevisiae S288C. The MAL locus comprises
three genes, a maltose permease (gene 1), maltase (gene 2) and a
Trans acting MAL-activator (gene 3). Illumina sequencing of the 16
Guinness strains confirmed the presence of MAL1 and MAL3. A
homozygous premature stop codon was identified in the MAL1 maltose
permease gene (MAL11) for all 16 Guinness yeast (Supplementary data 1
). This stop codon mutation potentially prevents the loss of gene
function, although the occurrence of this stop codon is present
within 145 of the 176 yeast assessed in this study and maltotriose is
utilised by all of the Guinness yeast (Fig. 4). Within the
phylogenetic tree disruption to MAL11, whilst present in a small
number of Beer 1 yeast, is more readily associated with brewing yeast
present in the Beer 2 brewing yeast grouping^4.

Illumina analysis of MAL3 of S288C, established the presence of 16
heterozygous frameshift mutations in the maltose permease, MAL31.
Similar mutations were present in all the different Guinness yeast
strains (Supplementary Data 1). The frameshift mutations in MAL31 did
not result in loss of maltose and maltotriose utilisation as
assessment of maltose and maltotriose at the end of the fermentation
confirmed the consumption of these wort sugars (Fig. 4).

Further analysis of the Guinness strains using the longer nanopore
sequencing reads determined that the MAL6 locus was present. When
detected in other S. cerevisiae strains the MAL6 multigene locus is
located on Chromosome VIII and is arranged from the centromere as
MAL63, MAL61 and MAL62^26. In contrast, assessment of the Guinness
strains showed that MAL61 and MAL62 were arranged on Chromosome VIII,
as expected; however, MAL63 mapped to the sub-telomeric region of
chromosome XVI. In the reference strain S. cerevisiae S288C this Open
Reading Frame (ORF) on chromosome XVI is designated as gene YPR196W
and is described as a "Putative maltose-responsive transcription
factor". The unusual arrangement of the MAL6 locus appears to be
specific to the Guinness yeast and should be considered provisional
until confirmed through additional experimental data.

Production of flavour metabolites by Guinness yeast

Beer recovered from the completed mini-fermentations were analysed
for the flavour active esters: isoamyl acetate, ethyl butyrate, ethyl
hexanoate and ethyl acetate (Fig. 4). All were detected in the
Guinness yeast fermentations apart from ethyl butyrate. Ethyl
hexanoate was produced by 7 of the 16 Guinness strains, but at
concentrations lower than the flavour threshold of 0.2 ppm^27. The
concentrations of ethyl esters varied with strain. In the case of
ethyl hexanoate, isoamyl acetate and ethyl acetate the differences
were statistically significant; more so in the case of the latter two
esters, one way ANOVA p = 0.011, p = 9.32 x 10^-20 and p = 6.91 x 10^
-20, respectively. The 1947, 1950 and Park Royal 1960 yeasts produce
isoamyl acetate at concentrations above the flavour threshold
(1.1 ppm^27) whereas ethyl acetate is the most widely produced ethyl
ester. Eight of the 16 Guinness yeast strains produce ethyl acetate
above the flavour threshold of 10 ppm^27. A one way ANOVA of these 8
yeast confirms that ethyl acetate production in the Guinness yeast is
strain-specific (p = 8.06 x 10^-5); however, further analysis of
ethyl acetate production of the four Guinness yeast collected in 1959
and 1960 show no statistical significance (One way ANOVA p = 0.86),
likewise there is no statistical significance between the 1947 and
1950 pitching yeast (One way ANOVA p = 0.51).

Higher alcohols (fusel alcohols) are the most abundant yeast-derived
organoleptic compounds present in beer apart from ethanol^28.
Isobutanol and propanol impart solvent and alcohol/sweet aromas to
the beer. As in the case of ethanol production, the concentrations of
higher alcohols arising in the beers varied with strain (Fig. 4); one
way ANOVA isobutanol p = 4.79 x 10^-21 and propanol p = 4.42 x 10^
-32.

Higher alcohols are formed by transamination, decarboxylation and
reduction via the Ehrlich pathway^24. Transamination is
rate-determining and over-expression of BAT2 results in increased
higher alcohol production^29,30. CNV of the genes responsible for the
Ehrlich pathway (Supplementary data 2) established that CNV of BAT2
differed between the Guinness strains with a median value of 4. The
Park Royal 1960 produced the highest concentration of isobutanol and
was shown to have 6 copies of the BAT2 gene. The Guinness production
yeast IDS2 produce similar amounts of isobutanol compared to the Park
Royal 1960 strain (t-test P = 0.61) and has 4 copies of BAT2. Both
IDS1 and IDS2, have the same CNV of BAT2, but IDS1 produced
significantly less isobutanol (t-test P = 0.00048) indicating the
involvement of other factors. In fact, a frameshift mutation was
identified in the THI3 decarboxylase gene and the dehydrogenase AAD6
gene was not detected in the Guinness yeasts; deletions of THI3 and
AAD6 have been observed to negatively affect isobutanol production^30
.

The vicinal diketone, diacetyl (2,3 butanedione) arises in beer
during fermentation where it imparts a buttery or butterscotch like
flavour^31. Diacetyl is formed indirectly by brewing yeast during
fermentation from a-acetolactate. The latter is an intermediate in
the isoleucine valine (ILV) synthetic pathway and part of the pool is
exported from yeast cells where it undergoes spontaneous oxidative
decarboxylation in fermenting wort to form diacetyl. Diacetyl was
present at the end of fermentation for all of the Guinness yeast
(Fig. 4); however, only 7 of the 16 strains at a concentration
greater than the flavour threshold of 100-400 ppb^32. Differences in
diacetyl concentrations for individual strains were highly
statistically significant (one way ANOVA p = 7.09 x 10^-13).

The diacetyl precursor a-acetolactate is produced by the enzyme
acetolactate synthase^32. The responsible genes ILV2 and ILV6^33,34
were found in all Guinness yeasts, with a total of 11 SNPs present in
ILV2 compared to the reference yeast S. cerevisiae S288C. A total of
5 SNPs, and two non-synonymous mutations, for ILV6 were found in all
of the Guinness strains (Supplementary data 3). 4 of the 5 Guinness
yeasts which produced the highest residual diacetyl concentration had
5 copies of the ILV2 gene compared to a median value of 4 CNV. The
apparent correlation between copy number of ILV2 and residual
diacetyl concentration could be causative; for many traditional
beers' diacetyl removal occurs via lengthy periods of storage,
post-fermentation, at cool temperatures in the presence of yeast. For
the Guinness yeast it was observed that the strains with the most
rapid fermentations and corresponding longer post-fermentation time
had the lowest diacetyl concentration (Fig. 4). This is not
surprising since diacetyl is reduced principally in late fermentation
through passive uptake by yeast and subsequently enzymatic conversion
of diacetyl first to acetoin and thence to 2,3-butanediol^35,36.
Consequently for FES production, where the presence of diacetyl is
part of the beer's flavour profile, reducing yeast contact time post
attenuation ensures that the diacetyl flavour remains within the
beer.

Fermentations were repeated at a scale of 1hl as fermentations at
this increased scale are more representative of commercial-scale
brewing. Additionally, the increased volume allowed for the resultant
beers to be subjected to standard sensory profiling. Fermentations
were carried out in a pilot brewery using 12-degree Plato (^oP) wort.
Degree Plato is a measurement, related to density, and used by
brewers to determine the concentration of dissolved solids including
fermentable and non-fermentable sugars in brewers' wort. Guinness
stout wort was sourced from St James's Gate Brewery, Dublin. Two
Guinness strains, Park Royal 1979 and IDS2 were chosen for the trial
as the Park Royal 1979 time to attenuation was the shortest of the 16
Guinness strains and the IDS2 yeast was chosen as it was the atypical
IDS production yeast. The chosen yeasts were compared with a control,
a third-generation production Irish Draught yeast culture taken from
the St James's Gate brewery. Third generation refers to a culture
that had already been used for 3 previous cycles of serial
fermentations with intermediate cropping and storage. Yeast cultures
of this "age" is considered to produce standard fermentation
performance and generate typical beer. When the fermentations were
completed, the resultant beers were processed using the standard
Irish Guinness stout procedure. Beers were assessed chemically via
analysis and organoleptically via the Guinness external taste panel
using quantitative descriptive methodology.

The results were largely in accord with those obtained from the
mini-fermentation study (Fig. 5). The flavour panel detected isoamyl
acetate and phenolic off-flavour in the beer made with Park Royal
1979, and diacetyl in Guinness made using IDS2; these observations
were confirmed by GC-MS analysis (Supplementary Fig. 3). Times to
attenuation and final ethanol concentrations for both small and
larger scale fermentations were also similar.

Fig. 5: 1HL fermentation and flavour assessment of the Guinness Park
Royal 1979 and IDS2 yeast strains compared to present Guinness
production yeast.
figure 5

a Rate of fermentation and b flavour of Guinness Irish Draught Stout
brewed using a control Guinness yeast from Dublin St James's Gate and
the Guinness yeasts: Park Royal 1979 and IDS2. All fermentations were
conducted in 100 L fermentation vessels with Guinness wort collected
from St James's Gate Brewery. The tasting samples were assessed, in
duplicate using the Guinness Draught attribute list by an expert
panel using Quantitative Descriptive methodology. A minimum of n = 18
assessors were used to determine flavour attributes.

Full size image

Phenolic off-flavour (POF) phenotype of the Guinness yeast

The formation of 4-vinyl guaiacol, also known as Phenolic off-flavour
(POF), imbues beers with a medicinal, clove-like aroma and flavour.
It is produced from a precursor, ferulic acid, derived from cereal
grains, via expression of yeast genes^37. All the Guinness yeast
strains used in this study were POF^+ (Fig. 6). The degree of POF
character which developed varied with yeast strain (one way ANOVA P
value = 4.7 x 10^-21). The flavour threshold of 4-vinyl guaiacol in
beer is reportedly 200-400 ppb^38. Here, the Guinness yeasts: 1950,
1959BY, Ikeja and 1981 yeast all produced 4-vinyl guaiacol at
concentrations below the flavour threshold limit, whereas, the 1947,
1960 and Park Royal 1960 yeast all produced 4-vinyl guaiacol at a
mean concentrations >1000 ppb.

Fig. 6: Phenolic off-flavour and flocculation phenotype of the
Guinness yeast.
figure 6

a Phenolic Off Flavours (POF) production as determined by the
Analytica-EBC Method 2.3.9.5^97 and Gas chromatography mass
spectrometry, and b Illumina sequencing data of the single nucleotide
polymorphism mutations of the POF genes FDC1 and PAD1 of the
different Guinness yeast. The effects of the SNP mutations result in
amino acid substitutions that are non-synonymous (NS) or synonymous
(S). Each POF observations presented are n = 3 biologically
independent experiments. c Flocculence characteristics of the
different Guinness yeast as determined by the Analytica-EBC Gilliland
Method EBC 3.5.3.1^48. The method class yeast flocculence in terms of
non-flocculant (Class 1), slightly flocculant (Class 2), moderately
flocculant (Class 3) and highly flocculant (Class 4). Observations
presented are n = 10 biologically independent experiments.

Full size image

The POF phenotype performs an important environmental fitness
function for wild S. cerevisiae as it enables the yeast cell to
detoxify the phenylacrylic acids present in plant cell walls^39,40.
The genes PAD1 and FDC1, encoding a phenylacrylic acid decarboxylase
and a ferulic acid decarboxylase respectively decarboxylate the
phenylacrylic acid, ferulic acid, to 4-vinyl guaiacol^40. Illumina
sequence analysis of the Guinness yeasts identified two SNPs in FDC1
gene, and 9 SNPs in PAD1 (8 homozygous and 1 heterozygous). Of the 11
identified SNPs, 9 SNPs have been previously identified in other
strains of S. cerevisiae^40. The two SNPs identified only in the
Guinness yeast are the heterozygous SNP at position 425 in PAD1 gene
and the homozygous SNP at position 790 in FDC1. The identified
non-synonymous changes do not result in a loss of POF production
function.

The median average of the CNV of PAD1 and FDC1 within the Guinness
yeast was 4. Examination of the data showed that CNV and 4-vinyl
guaiacol occurrence in beers were not related for the production for
the Guinness yeast studied here (f-test P = 0.86; t-test P = 0.17)
POF; yeasts with identical SNPs and CNV within PAD1 and FDC1 genes
produced different concentrations of 4-vinyl guaiacol under identical
experimental conditions.

Flocculation phenotype of the Guinness yeast

Yeast flocculation is a reversible, non-sexual aggregation of cells
which is of benefit to brewers since it improves the efficiency of
sedimentation or separation from beer at the end of fermentation^41.
The timing of flocculation in S. cerevisiae is dependent upon
expression of the flocculation genes FLO1, FLO5, FLO8, FLO9, FLO10
and FLO11 and environmental factors such as calcium, pH, temperature,
fermentable sugars and other nutrients^42,43,44,45,46,47. For the
Guinness yeasts, the degree of flocculation observed was
strain-specific (Fig. 6).

Gilliland^48 developed a method for describing the flocculence
characteristics of brewing yeast. Four classification types were
defined: Class I non-flocculant, Class II slight flocculant, Class
III moderately flocculant and Class IV highly flocculant. The
production yeast IDS and FES were shown to be Class II and Class I
respectively, confirming that the flocculation phenotype of the
current Guinness production yeast is the same as those selected in
1959 and 1960 (Fig. 6c).

Nanopore assessment of the IDS1 Guinness production yeast established
that three complete FLO genes, FLO9, FLO11 and FLO8 were present.
Scaffolding of the other Guinness yeast using IDS1 as the reference
genome confirmed the presence of the three FLO genes indicating that
FLO9, FLO11 and FLO8 are common to the Guinness yeasts. Of the
incomplete FLO genes, FLO1, FLO5 and FLO10, a truncated version of
FLO1 was identified. A partial read of FLO5 was identified in the
sub-telomeric region of chromosome VIII. The presence of FLO10 could
not be confirmed as the sub-telomeric region of chromosome XI was
absent in the nanopore sequencing data resulting in the loss of FLO10
and the adjacent genes VBA5, NFT1 and GEX2.

The FLO genes identified in the Guinness yeast encode flocculins,
FLO9 and FLO11, and the flocculation transcription factor FLO8.
Flocculation phenotype is affected by the length of the flocculin
molecules which projects from the cell wall surface. The longer the
flocculin the stronger flocculation competence^49. The size of the
FLO encoded flocculins is a consequence of the number of tandem
repeats within the ORF^49,50 (Supplementary data 4). The FLO11 ORF in
the Guinness yeasts transcribes a 744 amino acid protein, in
comparison that of the reference S. cerevisiae S288C genome comprises
1367 amino acid residues^51. Furthermore, FLO9 contains two ORF
encoding two fragments of the flocculin gene. For the Guinness yeasts
FES 3, Ikeja, 1960 pitching yeast, and the 1979 and 1986 Park Royal
yeasts a heterozygous SNP mutation at position 12,114 induces a
premature stop codon, all the other Guinness yeast retain the
consensus SNP resulting in a functioning ORF. The five Guinness yeast
that carry the heterozygous SNP in FLO9 have a flocculation phenotype
of <1.5 with three of the yeast observed to be Class I and therefore
described as being non-flocculant. The FLO8 transcription factor is
functional in all of the Guinness yeasts examined here.

Discussion

Our analysis established that the Guinness yeast form their own
subgroup within the previously described Beer 1 brewing clade and
that the grouping of the Guinness yeast is separate from other
historical Irish Brewing yeast strains. The Beer 1 clade SNPs are of
European and Asian origin^9,10 and unlike the other historical Irish
Brewing yeast that group within the 'Britain' subpopulations, the
data presented in this study indicates the contribution of several
lineages to the genetic make-up of the Guinness strains. These
different lineages presented in this study establishes that the
Guinness yeast are mosaic with an ancestry <80% from a single
geographical population.

The analysis presented in Fig. 1 and Supplementary Fig. 2 establishes
that the yeast Beer042 shares a recent common ancestor with the
Guinness yeast. The Beer042 was deposited in 1979 and at that time
was used to brew a lager-style beer in Belgium (personal
communication with the owners of Beer042). Beer042 was deposited
using the then accepted nomenclature for lager strains Saccharomyces
carlsbergensis Hansen. Subsequent whole-genome sequencing has
confirmed that it was mislabelled and that it is a S. cerevisiae
yeast. Within the Guinness archive, the last mention of yeast being
brought into the brewery is on the 2nd of January 1854. The
performance of this yeast was described as poor, consequently it was
disposed of, and brewing continued using the then house yeast. There
are no subsequent entries of additional yeast in the Guinness
archives, other than the Guinness yeast, being used to brew Guinness.
As Beer042 was labelled as Saccharomyces carlsbergensis Hansen it is
likely that it originated from Emil Hansen's Carlsberg group yeast
collection. At the end of the 19th century Emil Hansen pioneered the
selection and propagation of pure yeast strains for use in brewing^11
. At that time this was a novel concept, and it prompted much
interaction between various European brewers^52. In the case of
Guinness, company scientists visited numerous breweries in the UK on
multiple occasions^53. Consequently, a plausible reason for the
relationship demonstrated here with Beer042 and the Guinness yeast is
that a common ancestor was shared from Dublin to other European
brewers. Originally, this common ancestor would have been deposited
in Emil Hansen's collection. The resulting observed differences in
SNPs between Beer042 and the Guinness yeast are likely due to the
consequences of yeast evolution driven by differences in handling
practices.

The phylogeny assessment of the Guinness yeast confirmed the expected
genealogical relationship between the historical and current
production strains, with a division being observed at a pre- and
post- '1959' timeline. The 1960 pitching yeast and Park Royal 1960,
were collected in 1960 but are yeasts derived from pre-1959 stock.
The selection that was undertaken in 1959 used single-cell isolates
obtained from the then Guinness Pitching yeast (Guinness Archives).
These isolates were tested in the Guinness Research Laboratory with
the flocculation phenotype used as the principal differentiating
selection criterion. Subsequently the Class II IDS yeast was chosen
to brew Guinness Irish Stout, with a second selection from the
single-cell isolates undertaken in 1960. This produced a Class I
flocculant yeast which was chosen to produce FES on the basis that it
was advantageous for yeast to remain suspended in bottle conditioned
stout intended for the export market.

The flocculation assessment of the Guinness yeast reported in this
study confirmed that the phenotype of the production yeasts FES and
IDS have been preserved when compared with their 1959 and 1960
phenotypes. Whilst the flocculation phenotype of the production yeast
has been maintained the present production yeast have diverged from
the 1959 Guinness pitching yeast with regard to other
characteristics. The reason for this may be related to changes in the
methods used for preserving cultures. Prior to 1986 all yeast
cultures were maintained on wort agar slopes stored at 4 degC and
sub-cultured every 6 months. This method was standard industry
practice up until the 1970s and 1980s. Following the work by Labatt's
Brewing Company^54 yeast culture storage in liquid nitrogen was
introduced and widely adopted.

The production yeast IDS and FES were subjected to an additional
reselection procedure which started with individual non-petite yeast
colonies from which phenotypes were chosen that were 'prone to
spontaneous changes'^55. The phenotypic characters of interest were
flocculation, maltotriose utilisation and head formation (cropping
behaviour at the end of fermentation). Some 50 colonies were
selected, pooled, and cultured on fresh agar slopes. The rationale
was that this should minimise the risk of selection of a potential
defect or mutation from a single source which would adversely affect
the Guinness yeast. This strategy was adopted since it was concluded
that it would mitigate the potential adverse effects of long-term
maintenance of yeast cultures on slopes^56. This process of selecting
positive phenotypic traits could over time increase dissimilarities
resulting in potential divergence from the original 1959 Guinness
yeast. This process is similar to adaptive evolution, the process of
positive selection of an advantageous phenotype. Adaptive evolution
has been used successfully by others to enhance yeast phenotypes^31,
57,58. The 'adaptive evolution' hypothesis is further supported by
the observable differences in the 1981 IDS Guinness yeast compared to
the IDS1 and IDS2 production yeast. The last reselection of the
Guinness production yeast took place in 1989, 8 years after the 1981
Guinness pitching yeast was deposited in the yeast library. The 1981
IDS yeast is chronologically the closest yeast to the current IDS
production yeast, unlike the IDS yeast, the 1981 IDS yeast was not
reselected therefore the 1981 yeast is a record of IDS yeast at that
time. The observable hierarchal clustering of the Nanopore phylogeny
assessment places the 1981 IDS yeast closest to the IDS yeasts,
accordingly the observable differences between the IDS yeasts and the
1981 IDS yeast are likely to be a consequence of the Guinness yeast
'adaptive evolution' reselection process.

The loss of meiotic cell division and observed aneuploidy of the
Guinness yeast are congruent with yeast domestication^59. Aneuploidy
can confer phenotypic advantages such as enhanced tolerance to
ethanol, temperature and oxidative stresses^60,62,63,63. Although
assessment of stress resistance was not in the scope of this study
the observed variable ploidy together with the phenotypic assessments
made via studies of fermentation performance suggest that the
Guinness strains have evolved to manage environmental stresses
associated with commercial brewing. For example, acquisition of
additional copies of chromosome III which correlated with improved
ethanol tolerance has been reported^22. Others, studying industrial
processes employing S. cerevisiae, including baking and sake brewing,
have suggested there is no evidence of amplification of specific
chromosomes carrying traits which can be directly attributable to
industrial practices^63. The studies reported here support the latter
contention. For the strains examined, no specific chromosome was
identified as being responsible for the Guinness yeast phenotype.

In addition to ploidy, gene copy number correlates with gene
expression. Aneuploid yeast with multiple gene copy numbers will have
increased expression levels compared to a haploid yeast with a single
copy gene^22,61. Increased gene copy numbers does not always result
in an increase in the concentrations of the resultant proteins, even
though the genes are translated since turnover via proteolysis also
occurs^64. Data presented in this study established that there are
gene CNVs between the different Guinness yeast strains but with
reference to the concentrations of important beer flavour
yeast-derived metabolites: higher alcohols, diacetyl and phenolic
off-flavour (POF), the CNV did not significantly influence the
phenotypic outcome.

The observed difference in phenotype between the Guinness yeasts are
of interest to brewers as the data presented in this study
establishes that yeast that are genotypically similar can be
phenotypically diverse. The phenotypic data presented in this study
does not correlate with the group of yeast. For example, there are
differences between the Park Royal Guinness yeast, present production
yeast, pre-1959 and post-1959 Guinness yeast. The difference in POF,
esters, higher alcohols and ethanol production is yeast
strain-specific. Predicting phenotype based upon genotype is
challenging^65,66,67,68, even with the use of machine learning
predicting phenotype based upon genotype^69 has a poor correlation
for S. cerevisiae (<22%). The data presented in this study provides
further valuable awareness of the relationship of genotype and
phenotype and confirms previous studies' conclusions on the
difficulty of predicting phenotype from genotype.

Good brewing practice is to replace pitching yeast; the yeast added
to wort, after 8-15 re-pitching procedures^70,71. A major reason for
this practice is to avoid genetic drift so that the fermentation
outputs remain consistent^72. The data presented in this study offers
another potential explanation; especially for pitching yeast that are
not pooled from a pure culture. The differences in fermentation
behaviour maybe a consequence of the difference in phenotype. The
Guinness production yeast, IDS and FES contain yeast that are
phenotypically diverse although they are genotypically similar,
consequently, as the yeast is re-pitched there is potential for the
concentration of the different yeast to change resulting in a
different fermentation/phenotype response. The observations of
phenotype and genotype in this study raises important questions for
brewers and other groups that use S. cerevisiae yeast for industrial
processes and highlights the importance of brewers maintaining their
production yeast. Further consideration should be given to
understanding the role of genotype on phenotype as this will improve
S. cerevisiae industrial comprehension.

All Guinness yeast strains examined had a POF^+ phenotype. This
phenotype is widely found within the wild S. cerevisiae population
but much less common in industrial strains^4. The same authors and
others have reported that none of the examples of the Britain,
Ireland and USA brewing yeasts assessed were POF^+ ^4,8. This
suggested that the loss of POF production is a consequence of
deliberate selection by the brewer. In contrast, where the POF
flavour is an important characteristic; as with German Hefeweizen
beers (wheat beers), the POF phenotype has been retained^4,8. In the
case of the Guinness yeast retention of the POF genotype is unusual
for domesticated brewing yeast^4,8.

Retention of the POF phenotype in the Guinness yeasts was unlikely to
have been a deliberate act; rather at the concentrations found in the
beers the effect was benign as it did not create flavour issues. The
precursor of 4-vinyl guaiacol, the causative agent of POF, is ferulic
acid a component of cell wall polysaccharides of barley, wheat, rice
and maize^38. Free ferulic acid is released during the mashing stage,
a process used by brewers to convert grain starches into fermentable
sugars during wort production. The free ferulic acid is then
converted to 4-vinyl guaiacol by POF^+ yeast during fermentation. The
extent of ferulic acid release is influenced by the conditions
employed during mashing^73. A mash temperature stand of 45-50 degC is
optimal for releasing ferulic acid^24. This is a typical starting
temperature for Continental European brewers and consequently this
suits those beers that have a pronounced POF character, otherwise POF
^- yeast strains must be used^74. Irish and British brewers prefer
isothermal or infusion mashing using a temperature of 67 degC^74. This
regime does not favour extensive release of ferulic acid^74 and
therefore the potential for development of POF in Guinness stouts
would not be great. The importance of the presence of POF in Guinness
beers is further reduced since an internal expert sensory panel has
determined that the flavour threshold concentration for 4-vinyl
guaiacol in Guinness stouts is higher than in other beer styles.
These factors in concert would reduce pressures to eliminate POF
genes in Guinness production yeast.

All Guinness yeasts are POF^+ but the concentration of 4-vinyl
guaiacol formed varies with individual yeast strains. The Guinness
yeast all share the same SNP mutations and the CNV number does not
affect POF production. The presence of stop codon in FDC1 and PAD1
result in the loss of POF in negative yeast strains^4,8. However,
Goncalves et al.^8 observed that in the yeast TUM 507 stop codons
present in PAD1 and FDC1 did not result in loss of POF phenotype,
moreover, in the TUM 380 yeast where there were functioning PAD1 and
FDC1 genes present, there was a loss of POF production phenotype^8.
Goncalves^8 concluded that as yet unidentified compounds or enzymes
were affecting POF production in TUM 380 and 507 yeasts. Observations
made in this study may corroborate Goncalves's^8 conclusions since
individual Guinness strains produce significantly different
concentrations of 4-vinyl guaiacol even though all yeast share the
same gene content. These observations warrant further investigation.

This study provides evidence of beer style influencing yeast
selection. With the exception of Hefeweizen specific yeast, previous
studies have demonstrated that yeast subdivide along geographical
locations and not beer style^4; our findings run contradictory to
this observation. The data presented in this study establishes that
yeast from a similar geographical location, Ireland, are
genealogically dissimilar despite documented evidence of the wide
sharing of yeast between brewers. All of the non-Guinness Irish
brewing yeast were used to brew ales, whilst the Guinness yeast were
used to make stout. The phylogeny assessment of the Irish yeast
divide on the stout/ale brewing axis. Perhaps the reason for the
difference is that yeast used to brew ales are generalist, brewing
different types of beers, consequently yeast with universally
preferable characteristics such as good flocculation and POF^- would
be selected for by the brewer. For yeast that brew a specific beer
style these universal characteristics are not essential subsequently
brewers can select a yeast that enhances the features of a particular
beer style even if these characteristics are unsuitable for
generalist yeast. This hypothesis is supported by the findings of
both Gallone et al.^4 and Goncalves et al.^8 who observed that yeast
used to brew beers in the Hefeweizen style are distinct, forming
their own subgrouping; interestingly like the Guinness yeast
Hefeweizen yeast are also mosaic^4,8. The effects of raw material,
especially the mineral content of water are well known^24. This has
led to the association of geographical locations with certain beer
types such as Burton on Trent in the United Kingdom with ales, and
delicate lagers associated with Pilsen in the Czech Republic^24.
Unlike brewers vintners use the microflora of the raw material grapes
to ferment. Studies have demonstrated that the microflora of
geographical regions are associated with certain types of wine^75
this has resulted in the concept of terroir. For wine terroir is
well-established but the concept of terroir in beer is still in its
infancy despite the recent studies on the terroir of hops^76,77. Our
findings provide another possible avenue for brewers to further
explore the concept of beer associated terroir.

In conclusion the analysis presented in this study establishes that
the Guinness yeast are not only significantly different from other
historical Irish Brewing yeast but they form a sub- group within the
brewing yeast clade. The genealogy of the different Guinness yeast is
confirmed by our analysis and supports the Guinness archive
historical records that the Guinness yeast used today is related to
the first deposited Guinness yeast; the 1903 Watling Laboratory
Guinness yeast.

Methods

Yeast strain selection and maintenance

A total of 19 Irish brewing yeast strains including 13 from the
Guinness collection were selected for assessment (Table 1). The
Guinness strains included two current production strains and 11 other
historical strains selected as they were the principal brewing
strains used to produce Guinness at that time. Cultures were stored
in cryo vials (Fisher) in liquid nitrogen at -196 degC using 50%
glycerol (Sigma-Aldrich) as a cryo-preservative. Cultures were
recovered and inoculated into 25 ml tubes containing 10 ml of YPD
(10 g l^-1 yeast extract, 20 g l^-1 peptone, 20 g l^-1 glucose)
(Oxoid) and incubated at 25 degC in an orbital shaker (Stuart
Scientific) at 120 rpm for 24 h. Serial dilutions of 100 ul of
cultures were spread plated onto Wallerstein Nutrient Agar (Oxoid)
and incubated at 25 degC for 12 days in accordance with the EBC Yeast
Giant Colony method 3.2.1.1^78. At the end of the incubation, single
yeast colonies were selected.

DNA extraction and interdelta yeast typing

Three giant colonies of each culture were selected and transferred to
microfuge tubes containing 700 ul of molecular grade water (Fisher).
Yeast cells were recovered by centrifugation and DNA was extracted in
accordance with the manufacture's guidelines using a PureLink
Microbiome DNA Purification Kit (Invitrogen). Individual strains were
identified using the interdelta (ITS) Polymerase chain reaction PCR
method^14,79; primers d2 (5'-GTGGATTTTTATTCCAAC-3') and d12
(5'-TCAACAATGGAATCCCAAC-3'), using a BioRad T100 Thermocycler and
Invitrogen's Platinum Hot start PCR Master Mix. PCR products were
analysed on an Agilent 2100 Bioanalyzer using the Agilent DNA 7500
chip. The resulting bands were analysed using Minitab 19 Statistical
software (2019) hierarchical clustering function with dendrograms
produced using Euclidean distance function.

Illumina whole-genome sequencing and de novo assembly

The ITS results were used to select strains for whole-genome
sequencing with typical ITS banding used as the selection criterion
for the historical Guinness and Irish brewing yeast. In the case of
the FES and IDS production yeast all yeasts that were determined to
be unique were selected. In total, 16 Guinness strains and 6 other
historical Irish brewing yeast were subjected to whole-genome
sequencing performed by Elda Biotech (Kildare, Ireland). Yeast
samples were sub-cultured onto Wallerstein Nutrient Agar (Oxoid) and
single colonies were picked for DNA extraction using the Thermo
Scientific Yeast DNA extraction kit (Thermo Scientific). Extracted
DNA was analysed using a Qubit (Thermo Fisher Scientific) to
determine dsDNA content. Aliquots of 1 ng of DNA was used as input
for library preparation using the Illumina Nextera XT DNA library
prep protocol with no deviations. Stock libraries of 1-4 nM were
generated and samples were pooled for sequencing and denatured
according to the manufacturer's instructions for loading on the
Illumina MiSeq(12 pM) sequencer. Samples were sequenced using the
Illumina MiSeq machine reading with a minimum depth of 30x coverage
using 2 x 250 bp paired reads. All samples were quality checked for
low-quality sequence bases and the presence of adaptor contamination
using Trimgalore (Version 0.6.1). All identified adaptors were
cleaved from both the forward and reverse sequencing reads and those
with runs of low-quality bases were trimmed using a Phred scale
cutoff of 10. All samples were aligned to the reference genome S.
cerevisiae S288C (http://downloads.yeastgenome.org/sequence/
S288C_reference/genome_releases/
S288C_reference_genome_R64-1-1_20110203.tgz) using BWA (Version
0.7.17)^80. Alignments were sorted and duplicate reads were
identified and marked for exclusion from downstream analysis using
Samtools (Version 1.10)^81. Alignment metrics for each sample were
collated using Qualimap (Version 2.2.1)^82. All samples were de novo
assembled using Spades (Version 3.14). For each sample all contigs
shorter than 500 base pairs in length were discarded. A reference
guided scaffold of each assembled sample genome against the
Saccharomyces cerevisiae S288C genome sequence was generated using
Ragtag (v. 1.0.2)^83 Artificial padding of "N" characters was placed
between the reference scaffolded contigs. All bioinformatic software
used in this study is specified in Supplementary Table 1.

Nanopore MINION sequencing

Two nanopore Minion runs of Irish Draught Stout yeast number 1 (IDS1)
were carried out by ELDA Biotech (Kildare, Ireland). DNA from an IDS1
colony grown on Wallerstein Nutrient Agar (Oxoid) was extract using
the Thermo Scientific Yeast DNA extraction kit (Thermo Scientific).
Extracted DNA was processed using the 1D Genomic DNA by ligation
(SQK-LSK108) protocol from Oxford Nanopore Technologies. DNA was
fragmented using a Covaris g-TUBE (Covaris) with DNA repair performed
using End Prep (New England Biolabs). Library clean up and adaptor
ligation were performed with AMPure XP beads (Beckman Coulter), and
extracted DNA measured using a Qubit (Thermo Fisher Scientific).
3.6fmol of DNA library was loaded onto the flongle for sequencing
(Oxford Nanopore Technologies). Sequencing was conducted according to
the Nanopore Minion manufacturer's instructions (Oxford Nanopore
Technologies). All Minion run Fast5 files were converted to FASTQ
format using Guppy (3.6). NanoFilt was used to remove low-quality
reads (Q10) and reads shorter than 1000 bases, with Porechop v6^84
used to find and remove adaptors located at the start, end or
internal reads. Contaminant (non-fungal) reads were identified using
both Kraken2 and BLAST searches against the NCBI non-redundant
database. Identified contaminant reads were removed using Seqtk
(v1.3). The first Nanopore Minion run resulted in 421,040 usable
reads and 64,105 in the second. Reads from both runs were combined
for a unified assembly using Flye (v. 2.8)^21. A corrected consensus
sequence for the Flye assembly was generated using Medaka (v 1.0.3).
Racon was used as a polishing tool for the Medaka consensus sequence
using the previously generated IDS1 Illumina data and an assembly
evaluation using Quast 5.10.0 was carried out using this nanopore
assembled genome and the previously assembled Illumina only IDS1
genome. Gene content completeness of the assembled genome was
estimated using Busco (v3)^85 with the assembled nanopore genome
scaffolded against the S. cerevisiae S288C reference genome using
Ragtag (v. 1.0.2)^83. Finally, the scaffolded assembly was annotated
using Funannotate (v 1.74)^86.

Determination of the Guinness yeast phylogeny

Sequencing data for 154 S. cerevisiae samples^4 were retrieved from
NCBI (BioProject PRJNA323691) and combined with the 22 S. cerevisiae
sequenced for this investigation. All retrieved samples were quality
checked for low-quality sequence bases and the presence of adaptor
contamination using Trimgalore (Version 0.6.1). All identified
adaptors were cleaved from both the forward and reverse sequencing
reads and reads with runs of low-quality bases trimmed using a Phred
scale cutoff of 10. All samples were aligned to S. cerevisiae S288C
reference genome using BWA mem (version 0.7.17)^80. Alignments were
sorted and duplicate reads were identified and marked for exclusion
from downstream analysis using Picard (Version 2.18.23). Alignment
metrics for each sample were collated using Qualimap (Version 2.2.1)^
82. Misalignment of reads in original BWA alignments were corrected
using GATK (Version 4.1.4-1)^87 with the base score recalibration
carried out on the corrected alignments. SNP and Indel discovery and
genotyping was performed across all 176 samples simultaneously with
GATK used to filter sites based on the following metrics: quality
score >30, mapping scores >40, read position rank sum <8. All
individual genotypes with less than 10x coverage were set to
uncalled. Annotation and effect prediction for each variant was
estimated using SnpEff (Version 4.3)^88.

Orthologous genes across all assembled genomes were inferred using
Orthofinder (Version 2.3.3)^89. Sequences from orthologous genes were
concatenated and aligned using MUSCLE (Version 3.8.31). A
phylogenetic analysis of the concatenated alignment of data from all
orthologous genes was carried out using the maximum-likelihood
approach implemented in RAxML (Version 8.2.4)^15 based on the
GTRGAMMA model of sequence evolution and a rapid bootstrap analysis
for 1000 bootstrap replicates. The tree which was rooted using the
outgroup species S. paradoxus was visualised and annotated using the
ggtree^16 package in R.

FastSTRUCTURE (Version 1.0)^17 was used to quantify the number of
populations and the degree of admixture in the genomes examined in
this study. Owing to the high degree of sequence similarity between
the Guinness samples a single representative sample (IDS1) was used
in this analysis consequently 161 genomes admixture were assessed.
The full set of biallelic segregating sites identified across all
samples was filtered based on a minor allele frequency (MAF) < 0.05
and SNPs in linkage-disequilibrium, using PLINK (v1.09)^90.
FastSTRUCTURE^17 was run on a filtered set of SNPs, varying the
number of ancestral populations (K) between 1 and 10 using the simple
prior implemented in fastSTRUCTURE^17 with K = 8 found to be optimal.
The admixture of IDS1 was determined from the sequence data of the
154 S. cerevisiae samples^4 using Alpaca (v1)^18 and a kmer length of
21 over 5000 base pair sliding windows.

Copy number variation

Analysis of the heterozygous biallelic SNPs for each Guinness yeast
established variable copy number across the chromosomes and
subsequently CNVs was normalised against an appropriate background
copy number for each strain. In addition, CNVs was estimated in 250
base pair non-overlapping windows across the entire ~12 million bases
of the S. cerevisiae genome using Control-FREEC (Version 5.7)^91.
Plots depicting CNVs for the Guinness yeasts were generated in R
using publicly available code^92.

Sporulation

The sporulation potential of the different Guinness yeast strains was
assessed using the ASBC Yeast 7 sporulation method^93. A total of
1000 cells per sample were examined using a Nikon Eclipse Ci
microscope 100x magnification. Ascospores stained green to blue green
while vegetative yeast cells-stained pink to red. independent
triplicate analyses were performed for each strain. The incidence of
sporulation was expressed as a percentage.

Assessment of fermentation properties

Fermentation ability was assessed using 180 ml mini fermenters
(Fisher) containing 120 ml of 12^oP wort. Cultures were recovered
from liquid nitrogen and sufficient yeast for the experiments
generated by successive serial aerobic incubations in 10 ml YPD,
90 ml 12^oP wort and 900 ml 12^oP wort. A single batch of all-malt
hopped wort was used for all experiments to eliminate batch to batch
variation. Wort was produced in the Guinness Pilot plant and stored
at -20 degC in 5 l aliquots. Prior to use it was thawed and sterilised
by autoclaving.

Yeast cells were recovered by centrifugation and washed three times
by successive suspension in distilled water and re-centrifugation.
Viability and yeast cell concentration of each culture was determined
using the EBC methods, EBC 3.1.1.1 Haemocytometer^94 and EBC 3.2.1.1
Methylene Blue^95. Triplicate fermentations were inoculated with
1 x 10^7 viable yeast cells per ml into 180 ml mini fermenters
containing 120 ml of air-saturated 12^oP wort. Fermentations were
incubated at 25 degC and stirred continuously using a stirrer plate
(mix 15 eco plate Camlab) set at 250 rpm. Mini fermenters were sealed
with a butyl rubber plug secured with an aluminium cap (Fisher) and
fitted with a Bunsen valve to allow CO[2] to be released.
Fermentation progression was measured by periodically monitoring
weight loss. The endpoint was established when three successive
identical readings were recorded.

Analysis of fermentation metabolites

Concentrations of selected yeast-derived flavour compounds were
measured using a gas chromatographic procedure using a modified
version of the EBC Vicinal Diketone method Analytica-EBC Method
9.24.2^96. End-fermentation samples (30 ml) previously clarified by
centrifugation were transferred to McCartney bottles which after
sealing were heated at 65 degC for 30 min to convert precursor
a-acetolactate into free diacetyl. Diacetyl (2,3 butanedione)
concentration was determined using an ECD detector; with esters and
higher alcohol concentrations determined using an FID detector. Peak
areas for the metabolites were normalised using appropriate internal
standards.

Analysis for phenolic off-flavour (4-vinyl guaiacol, 4-VG)

The ability of yeast to produce 4-vinyl guaiacol was determined
according to Analytica-EBC Method 2.3.9.5^97 phenolic off-flavour
method using gas chromatography mass spectrometry. Washed yeast
samples were inoculated at a concentration of 1 x 10^6 viable cells
ml^-1 into 25 ml tubes containing 10 mls of YPD medium supplemented
with 0.1 ml of ferulic acid (hydroxycinnamic acid) solution.
Triplicate incubations were performed for each yeast strain. After
incubation at 25 degC for 48 h. 5 ml was transferred to an autosampler
vial (Fisher) containing 2 ul of the internal standard containing:
4-vinyl guaiacol (Sigma-Aldrich). Analyses were carried out using an
Agilent 6890/7890 GC systems fitted with a Zebron ZB-Wax
60.0 m x 250.00 mm x 0.25mm column. The initial oven temperature was
60 degC. After 10 min this was increased to 220 degC at a rate of 10 degC
min^-1 then held for 2 min. 4-vinyl guaiacol concentration was
determined using an ECB detector; temperature 150 degC, make-up flow
rate of 60 ml min^-1 (Helium gas). Peak area for 4-vinyl guaiacol
were normalised against the internal 4-vinyl guaiacol standard.

Alcohol concentration

Ethanol concentration was determined using near infrared spectroscopy
using an Anton Paar Alcolyser in accordance with the manufacture's
guidelines.

Sugar concentration

Samples were analysed tested using an Agilent 1260 Infinity II system
with a refractive index detector (Infinity II 1260 WR RID) and a
Zorbax Carbohydrate column (4.6 x 250 mm, 5 um, P/N: 840300-908). The
other acquisition conditions were as follows: mobile phase was a 70/
30 mix of acetonitrile and water; sample injection volume was 50 uL;
flow rate was isocratic and set at 1.5 ml min^-1. The column oven was
kept at a constant 35 degC. No internal standard was used. However,
samples were bracketed either side with freshly made known standard.

Flocculation

Flocculation was assessed using EBC Gilliland method EBC 3.5.31^48.
The EBC method uses visual inspection of flocculation behaviour
categorising the yeast using prescribed classifications: Class 1
non-flocculant, Class 2 slightly flocculant, Class 3 moderately
flocculant and Class 4 highly flocculant. An addendum to the EBC
method was the addition of four control yeasts representing the
different classifications.

1HL fermentations

In order to prepare sufficient beer for taste testing 1 hL
fermentations using selected yeast strains were carried out using the
Guinness pilot scale plant. Standard Guinness wort was taken from the
St James' Gate Brewery and diluted to 12^oP with deaerated water and
autoclaved prior to use. Yeast strains were retrieved from long-term
liquid nitrogen and propagated by successive serial aerobic
incubations in 10 ml YPD, 90 ml 12^oP wort and 900 ml 12^oP wort. To
ensure that sufficient yeast was available the terminal cultures were
prepared in a Carlsberg flask (GEA) containing 15 litres of sterile
12^oP Guinness wort and incubated at 25 degC for 48 h with continuous
oxygenation. This generated sufficient yeast to inoculate 80 L of
wort at an initial count of 1 x 10^7 viable yeast cells ml^-1.
Fermentations were attemperated at 22 degC. After the desired final
gravity was achieved the beer was held at 25 degC for 24 h to allow
removal of diacetyl. A 20 L sample of beer was then removed and
transferred to a sterile keg. After storage at 4 degC for 48 h the beer
was clarified by passage through a sheet filter then bottled and
pasteurised (25 PU). Triplicate samples of the beers were analysed
for alcohol, fermentation metabolites, and POF production using an
Anton Paar Alcolyser, gas chromatographic procedure using a modified
version of the EBC Vicinal Diketone method Analytica-EBC Method
9.24.2^96 and Analytica-EBC Method 2.3.9.5^97, phenolic off-flavour
method using gas chromatography mass spectrometry. Organoleptic
properties were assessed by a trained beer sensory panel consisting
of 18 members. Using Quantitative Descriptive methodology^98 and a
list of predefined Guinness Stout sensory attributes all three
samples were tested in duplicate by the panel in a single tasting
session. Individual sensory attributes were rated on a linear scale
(0-10)^99, with a subset of these attributes identified to explain
differences and similarities across samples. The samples were
randomised and presented to the taste panel labelled with a
three-digit code. Sensory scores were analysed using a 2-way ANOVA
including sensory assessor's as a random factor^99.

Statistics and reproducibility

Statistical analyses were preformed using Minitab 19 Statistical
software (2019) and Xlstat 20 Excel statistical package (2020).
Mini-fermentations were performed using three independent biological
replicates and statistical significance of ethanol production,
fermentation metabolites and POF determined using one way ANOVAs. The
organoleptic properties of the 1Hl fermentation Guinness brews were
determined by Quantitative Descriptive methodology^98 using a trained
taste panel of 18 independent members, and the resulting data
analysed using 2-way ANOVA. T-test were performed on isobutanol
production of IDS1 and IDS2. The effects of CNV on POF production was
established using f and t-tests.

Reporting summary

Further information on research design is available in the Nature
Portfolio Reporting Summary linked to this article.

Data availability

Illumina and Nanopore (basecalled, demultiplexed) reads for all
sequenced samples in this manuscript are deposited in the European
Nucleotide Archive (ENA) under the project accession PRJEB62101. All
experimental data underlying figures are presented in Supplementary
Data 5.

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Acknowledgements

The authors would like to thank the Guinness Brand Team for
sponsoring the work. The historic records presented in this study
were curated with the help of former Guinness Group Microbiologists
Dr Edward Bourke. The authors would like to thank Dr Kieran Joyce and
his team for their analytical support and Marcus Bengelstorff and
Patrick Kerr for their brewing expertise. D.K. and P.C. would like to
thank Dr Brigida Gallone, Dr Jan Steensels, Prof Kevin Verstrepen et
al. for their 2016 investigation. The St James's Gate Yeast Library
has been maintained since 1903 by numerous Guinness' Microbiologists
however the authors would like to give special thanks to June Hurley,
Dr Barbara Cantwell, Dr Daniel Donnelly, Angela Larkin, Dr Vidya
Dixit and Noel Early.

Author information

Authors and Affiliations

 1. Diageo Ireland, St James's Gate, The Liberties, Dublin, Ireland

    Daniel W. M. Kerruish, Jessica Kearns, Eibhlin Colgan & Sandra N.
    E. Stelma

 2. ELDA biotech, Kildare, Ireland

    Paul Cormican & Elaine M. Kenny

 3. Brewing Consultant, Burton on Trent, UK

    Chris A. Boulton

Authors

 1. Daniel W. M. Kerruish
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 2. Paul Cormican
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 3. Elaine M. Kenny
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 4. Jessica Kearns
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 5. Eibhlin Colgan
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 6. Chris A. Boulton
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 7. Sandra N. E. Stelma
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Contributions

Illumina and Nanopore sequencing were performed by E.K. with
bioinformatic analysis done by P.C. Phenotypic analysis was conducted
by D.K. and J.K. Historical archive analysis was provided by E.C. D.K
designed the study with bioinformatic experimental design made with
P.C. and E.K. D.K. wrote the manuscript with editorial input from
E.K., P.C., C.B. and S.S.

Corresponding author

Correspondence to Daniel W. M. Kerruish.

Ethics declarations

Competing interests

Daniel Kerrruish, Jessica Kearns, Eibhlin Colgan, and Sandra Stelma
are employees of Diageo Ireland, the owners of Guinness. Chris
Boulton is employed as a consultant by Diageo Ireland. All other
authors declare no competing interests.

Peer review

Peer review information

Communications Biology thanks Isheng Tsai and the other, anonymous,
reviewer(s) for their contribution to the peer review of this work.
Primary Handling Editor: George Inglis. A peer review file is
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Supplementary Information

Description of Additional Supplementary Files

Supplementary Data 1

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Reporting Summary

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Cite this article

Kerruish, D.W.M., Cormican, P., Kenny, E.M. et al. The origins of the
Guinness stout yeast. Commun Biol 7, 68 (2024). https://doi.org/
10.1038/s42003-023-05587-3

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  * Received: 12 July 2022

  * Accepted: 14 November 2023

  * Published: 12 January 2024

  * DOI: https://doi.org/10.1038/s42003-023-05587-3

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