Difference between revisions of "Pediococcus"

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[[File:Pedio sugars.JPG|thumb|300|Pedio fermentables <ref>Wine Microbiology. Practical Applications and Procedures.  Kenneth C. Fugelsang, Charles G. Edwards.</ref>]]
 
[[File:Pedio sugars.JPG|thumb|300|Pedio fermentables <ref>Wine Microbiology. Practical Applications and Procedures.  Kenneth C. Fugelsang, Charles G. Edwards.</ref>]]
  
About 90% of sugar metabolized by ''Pediococcus'' produces lactic acid.  It does so by homolactic fermentation (same EMP pathway as [[Lactobacillus#Types_of_Metabolism|''Lactobacillus'' homolactic fermentation]]), although some species/strains can convert glycerol to lactic acid, acetic acid, acetoin, and CO2 under aerobic conditions (''P. damnosus'' is not in this category) <ref>[https://books.google.com/books?id=1b1CAgAAQBAJ&pg=RA2-PA1&lpg=RA2-PA1&dq=pediococcus+damnosus+homolactic&source=bl&ots=myI2alVB78&sig=cG-yWB4GuABQFEtqD2CAyKmU0TE&hl=en&sa=X&ved=0CEAQ6AEwBGoVChMI66C5593-xgIVCVKICh3Pcg7c#v=onepage&q=pediococcus%20damnosus%20homolactic&f=false Encyclopedia of Food Microbiology.  Pediococcus.  Carl A. Batt.  Academic Press, Sep 28, 1999 .]</ref>.  ''P. damnosus'' can ferment glucose, sucrose, and galactose.  Some strains can ferment maltose and sucrose <ref name="ucdavis"></ref>.
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About 90% of sugar metabolized by ''Pediococcus'' produces lactic acid.  It does so by homolactic fermentation (same EMP pathway as [[Lactobacillus#Types_of_Metabolism|''Lactobacillus'' homolactic fermentation]]), although some species/strains can convert glycerol to lactic acid, acetic acid, acetoin, and CO2 under aerobic conditions (''P. damnosus'' is not in this category) <ref>[https://books.google.com/books?id=1b1CAgAAQBAJ&pg=RA2-PA1&lpg=RA2-PA1&dq=pediococcus+damnosus+homolactic&source=bl&ots=myI2alVB78&sig=cG-yWB4GuABQFEtqD2CAyKmU0TE&hl=en&sa=X&ved=0CEAQ6AEwBGoVChMI66C5593-xgIVCVKICh3Pcg7c#v=onepage&q=pediococcus%20damnosus%20homolactic&f=false Encyclopedia of Food Microbiology.  Pediococcus.  Carl A. Batt.  Academic Press, Sep 28, 1999 .]</ref>.  ''P. damnosus'' can ferment glucose, sucrose, and galactose.  Some strains of P. damnosus can ferment maltose and sucrose <ref name="ucdavis"></ref>.
  
 
===Growth and Environment===
 
===Growth and Environment===

Revision as of 19:59, 28 July 2015

Pediococcus - picture taken by Per Karlsson

Pediococcus (often referred to as Pedio) are Gram-positive lactic acid bacteria (LAB) used in the production of Belgian style beers where additional acidity is desirable. They are native to plant material and fruits [1], and often found in spontaneously fermented beer as the primary source of lactic acid production (with P. damnosus being the only species identified in such beers) [2][3]. They are facultative anaerobes, meaning that they are capable of metabolism in both aerobic and anaerobic environments. Strains found in beer are hop tolerant [4]. Due to their continued metabolism of longer chain polysaccharides, acid production will increase with storage time. Pedio can form a pellicle.

Pediococcus may also cause “ropiness” (also called a "sick beer") due to the production of exopolysaccharides. "Ropy" or "sick" beer is more viscous and, in extreme circumstances, can form strands. Sickness effects mostly the mouthfeel and appearance of beer, and may have no influence on the flavor. Pediococcus species can also produce diacetyl with extended storage time. Brettanomyces can break down exopolysaccharides and diacetyl produced by Pediococcus and the two are often used together.

See Lactobacillus, Brettanomyces, Saccharomyces, and Mixed Cultures charts for other commercially available cultures.

Commercial Pediococcus Cultures

Name Mfg# Taxonomy Note
White Labs WLP661 damnosus High diacetyl producer and slow growing. Fermentation temp: 70-85°F (21-29.4° C). Attenuation: 65%
Wyeast 5733 damnosus May cause “ropiness” and produce low levels of diacetyl with extended storage time. Temp range: 60-95° F (15-35° C).
RVA Yeast Labs RVA 601 damnosus Lactic acid bacteria used in souring Belgian-style beers such as gueze and Lambic. Acid production increases with storage. Temperature range is 60-95º F.

Manufacturer Tips

Wyeast on 5733

"If using 1 pack of 5733 per 5 gallon batch; and either adding to secondary after alcoholic fermentation is complete, or co-inoculating with a Sacch' strain, then a starter would not be necessary. If you did want or need to propagate, I'd recommend 2 liters of 1.030-1.040 wort per pack, incubated at 80-90*F, without agitation." - Michael Dawson, Wyeast.

"For propagation, we recommend using 1.040 OG wort and incubating at 30-35*C without aeration for 48-96 hours; pH drop will indicate when it's ready to pitch. For co-inoculation or post-primary addition, we recommend 0.5 million cells per mL, which is the equivalent of 1 pack in 5 gallons/20 liters. For larger volumes, you can propagate and inoculate with the starter culture at a rate 2.5-5% of the total volume of the main batch." - Michael Dawson, Wyeast.

White Labs on WLP661

"That one does well in 70-85 deg F. You can do a starter, but you shouldn't have to if you are doing a 5 gallon batch. It does take a while to sour, so just be patient and let it do it's thing." Sarah Neel, Sales and Customer Service, White Labs

Tips From MTF

The Rare Barrel

"We just performed an interesting experiment at The Rare Barrel with pedio. Jay, our head brewer and blender, wanted a more acidic beer that we could use as a blending component while also growing up our diminishing pedio culture. So we racked 2 oak barrels of gold fermented with Brettanomyces claussenii and White Labs Pediococcus damnosus (WLP661) into one of our 30 bbl batches of 12*p gold wort that had been acidified to about 4.5 pH in the kettle using lactic acid (our first hot side experiment!). No oxygen, really wanted to encourage the bacteria. Within 10 days the pH was 3.6 and the gravity 10.7. We were all surprised how quickly the pedio was working. We eventually racked a "splash" of fermenting gold with BSI Brett D and BSI Lacto D to drop the gravity. The beer had a bright acidity quickly and I was surprised at how well rounded the flavors were when we racked into barrels after a month in the fermenting vessel.

This might be a little harder to do at home, but I think there's potential for interesting results. Pediococcus shines long term traditionally so I agree with the posts above, if you're going for quick acidity I'd go lacto, but I plan on playing around with early Pediococcus fermentations at home." - Mike Makris from The Rare Barrel [5].

Metabolism

Lactic Acid Production

Pedio fermentables [6]

About 90% of sugar metabolized by Pediococcus produces lactic acid. It does so by homolactic fermentation (same EMP pathway as Lactobacillus homolactic fermentation), although some species/strains can convert glycerol to lactic acid, acetic acid, acetoin, and CO2 under aerobic conditions (P. damnosus is not in this category) [7]. P. damnosus can ferment glucose, sucrose, and galactose. Some strains of P. damnosus can ferment maltose and sucrose [1].

Growth and Environment

P. damnosus is sensitive to temperature and pH. It is unable to grow at a pH of 8 or higher or at 35°C. The optimal growth occurs at 22°C and 5.5 pH. P. damnosus is sensitive to environments that contain NaCl, and will not grow with concentrations of 4% NaCl [1].

One study showed that by starting growth in a medium (MRS media that began with a pH of 6.7, and allowing the pH to drop to 4.14 naturally from fermentation, that better growth was observed. The addition of bacteriological peptone, MnSO4, and Tween 80 also increased activity [8].

"Ropy" or "Sick" Beer

Exopolysaccharide pathway [9]

Some strains of P. damnosus can cause a beer (or wine) to go "ropy". This "ropiness" is actually caused by β-glucan production, a type of exopolysaccharide (EPS). The gene known as Dps has been identified with the production of β-glucan/EPS. Pediococci that are ropy have been found to be more acid, alcohol, and SO2 tolerant than other Pediococci. The thickness of the ropiness is increased with the presence of malic acid. One study showed that the production of β-glucan coincided with the end of the growth phase of Pediococcus. After 2 days of growth, β-glucan production increased as growth slowed. β-glucan production stopped when growth stopped. This would explain why beer containing Pedio often goes ropy in shortly after naturally carbonating in the bottle. This study found that other factors, such as alcohol levels. The study also found that the lack of agitation increased the β-glucan production. Higher initial pH encourages higher growth, so that also increased β-glucan production. Glocuse is needed for β-glucan production, while fructose is insufficient [9].

Other Metabolites

P. damnosus can produce high amounts of diacetyl during lactic acid production [10][11]. P. damnosus also produces an antimicrobial compound called pediocin PD-1, which can inhibit several bacterias including O. oeni [12][13].

See Also

Additional Articles on MTF Wiki

External Resources

References

  1. 1.0 1.1 1.2 Viticulture & Enology. UC Davis website. Pedioccous damnosus. Retreived 07/28/2015.
  2. The Microbial Diversity of Traditional Spontaneously Fermented Lambic Beer. Freek Spitaels, Anneleen D. Wieme, Maarten Janssens, Maarten Aerts, Heide-Marie Daniel, Anita Van Landschoot, Luc De Vuyst, Peter Vandamme. April 18, 2014.
  3. Scientific_Publications#Lambic_and_Spontaneous_Fermentation Multiple Scientific publications linked on MTF.
  4. Comparative genome analysis of Pediococcus damnosus LMG 28219, a strain well-adapted to the beer environment. Isabel Snauwaert, Pieter Stragier, Luc De Vuyst and Peter Vandamme. April 2015.
  5. Conversation with Mike Makris on Milk The Funk.
  6. Wine Microbiology. Practical Applications and Procedures. Kenneth C. Fugelsang, Charles G. Edwards.
  7. Encyclopedia of Food Microbiology. Pediococcus. Carl A. Batt. Academic Press, Sep 28, 1999 .
  8. Nel HA, Bauer R, Vandamme EJ, Dicks LM. Growth optimization of Pediococcus damnosus NCFB 1832 and the influence of pH and nutrients on the production of pediocin PD-1. Department of Microbiology, University of Stellenbosch, Stellenbosch, South Africa. Dec 2001.
  9. 9.0 9.1 Glucose fermentation kinetics and exopolysaccharide production by ropy Pediococcus damnosus IOEB8801. Emilie Walling, Marguerite Dols-Lafargue, Aline Lonvaud-Funel. Food Microbiology Volume 22, Issue 1, January 2005, Pages 71–78.
  10. Identification of pediococci by ribotyping. R. Satokari, T. Mattila-Sandholm and M.L. Suihko. Journal of Applied Microbiology 2000, 88, 260–265.
  11. The Microbiology of Malting and Brewing. Nicholas A. Bokulicha, and Charles W. Bamforth. June 2013.
  12. Growth optimization of Pediococcus damnosus NCFB 1832 and the influence of pH and nutrients on the production of pediocin PD-1. H.A. Nel1, R. Bauer, E.J. Vandamme and L.M.T. Dicks. Jan 2002.
  13. Purification, partial amino acid sequence and mode of action of pediocin PD-1, a bacteriocin produced by Pediococcus damnosus NCFB 1832. Bauer R, Chikindas ML, Dicks LM. May 2005.