Difference between revisions of "Team:DTU-Denmark/substrate"

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                   <img id="EmY" class="enlarge img-responsive figure-img" src="https://2016.igem.org/File:T--DTU-Denmark--Glycerol_(Emmelev)_y.lip.png" alt="DESCRIPTION">
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                   <figcaption class="figure-caption"><i>Y. Lipolytica</i> growth on glycerol from first generation biodisel</figcaption>
 
                   <figcaption class="figure-caption"><i>Y. Lipolytica</i> growth on glycerol from first generation biodisel</figcaption>
 
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Introduction

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Someone famous in Source Title

The dimorphic, non-conventional yeast Yarrowia lipolytica, belonging to the Ascomyceta phylum, was first isolated in 1960s from lipid-rich materials, hence the name “lipolytica”. The organism was classified and reclassified a number of times, first as Candida lipolytica, then Endomycopsis lipolytica, Saccharomycopsis lipolytica and finally Yarrowia lipolytica1. The figure shows Y. lipolytica cells under a microscope. The magnification factor is 100x.

DESCRIPTION
This figure shows Y.lipolytica in plactonic growth with 100x magnification

In recent years Y. Lipolytica has received increased attention from researchers, as studies have found it to possess great potential for producing industrial enzymes and pharmaceutical proteins Biotechnological applications of Yarrowia lipolytica: Past, present and future. This potential is a result of several advantages Y. Lipolytica has over the conventional yeast S. cerevisiae. Y. Lipolytica prefer secreting proteins through the co-transcription pathway and does so very efficiently2, it does not exhibit hyperglycosylation as S. cerevisiae3. Y. Lipolytica has also been shown to exhibit excellent characteristics for the production of value-added chemicals such as a long range of organic acids and polyols Biotechnological applications of Yarrowia lipolytica: Past, present and future, and the recent introduction of several genome-scale models for Y. Lipolytica will most likely lead to more processes utilizing the chassis for production. Perhaps the most important advantage for using Y. Lipolytica over S. cerevisiae, to our project at least, is the broad substrate utilization range of Y. Lipolytica. Y. Lipolytica is known to naturally utilize alcohols (especially glycerol), acetate and hydrophobic substrates (eg. alkanes, fatty acids and oils) as carbon sources4. This has naturally lead to Y. Lipolytica becoming a model organism for several metabolic pathways, especially fatty acid transport and metabolism, and single cell oil (SCO) accumulation. Y. Lipolytica has even been shown to exhibit enhanced growth on mixed substrates Yarrowia lipolytica as an oleaginous cell factory platform for production of fatty acid-based biofuel and bioproducts, which renders it ideal for utilization of industrial waste streams due to the highly diverse content of these. These findings had us believe that we had found an excellent candidate chassis for our project. The table shows a comparison of the substrate range of Y. Lipolytica W29 and S. cerevisiae CEN.PK113-7D.

Y. Lipolytica S. cerevisiae
Sediment from canola oil production µ = 0.31 None
Glycerol from Perstop µ = 0.27 None
Glycerol from Emmelev µ = 0.45 None
Glycerol from Daka µ = 0.31 None
Molasses from Dansukker µ = 0.42* µ = 0.47

* it should be noted that the molasses was autoclaved thus degrading some of the sucrose content. This growth might not be possible to replicate with untreated molasses.

As seen in the table Y. Lipolytica is able to grow on all the waste sources we tested, while S. cerevisiae is only able to grow on molasses.

Methods

Each growth experiment (for Y. Lipolytica and S. cerevisiae) is conducted according to the following:

Minimal medium is produced as stated by Mhairi Workman5 using a C-source concentration of 20 g/L was used all for growth experiments.

The cells were grown overnight in YPD medium, and prepared by spinning down and washed twice. The preculture was then used as inoculum for minimal medium (substituents) to a final concentration of 0,001 (OD600). The cultivations were carried out in a cytometer (brand) shaking 900 rpm at 30 degrees celsius. Cultures were grown, shaked and measured in 48 well microtitre plates (Cellstar). Measurements was carried out by a Hamilton Robot, (cpe201, Hamilton industries) connected to a BioTek spectrophotometer (See protocols here). OD600 Measurements were taken every 2 hours until the cultures reached stationary phase, and data was analysed using R-studio.

Strains Genotype Comment/source
Y. Lipolytica Wildtype Parent strain to our laboratory bug, PO1f
S. cerevisiae CEN.PK113-7D Derived from parental strains ENY.WA-1A and MC996A,
and is popular for use in systems biology studies

Outline of proces

We performed growth experiments on an array of pure C-sources to get a baseline of Y. Lipolytica growth patterns starting to determine the substrate range. In these experiments we observed the following growth rates or lack of growth.

Y. Lipolytica S. cerevisiae
Glucose µ = 0.24 µ = 0.19
Fructose µ = 0.23 µ = 0.426
Glycerol µ = 0.27 None
Canola oil µ = 0.08 None
Sucrose None µ = 0.396
Maltose None Growth7
Xylose None None8
Arabinose None None8
Starch None None

Even though the pure carbon sources suggests that Y. Lipolytica exhibits excellent substrate utilization, we did not know if this translated into utilization of industrial waste streams. To investigate this, we had to get our hands on a few waste streams we could test. We contacted local industry that we knew had waste streams containing either sugars, glycerol og oily constituents. After many phone calls and long meetings, we received the following byproducts of organically based productions:

  • Canola oil sediment
  • Glycerol Perstorp Tech
  • Glycerol Emmelev
  • Glycerol Daka
  • Molasses Dansukker

Canola oil sediment - Grønningaard

Grønningaard is a canola oil production facility situated on Zealand, Denmark. They produce 100 - 120 tons canola oil annually, and sell the remaining protein rich press cake for animal feed. The oil is derived by cold pressing organic rapeseeds. As cold pressing does not allow for filtering of the oil, small fibres remain in the oil. These fibres are removed by allowing the oil to sediment for 1 month and extracting the sediment. Besides the fibres from the plants and residual oil, the sediment contain, polyaromatic hydrocarbons in too high concentrations making the sediment unsuitable to be recycled in the process or used for animal feed, rendering it a “true waste” in the sense that it is only useful for generating heat through burning. The figure shows an overview of the process. The sediment constitutes 1-1.6% of the biomass of the product, amounting to 1 - 1.92 tons annually. These figures are based on the 4th. biggest producer in denmark Grønninggård. The largest with an estimated 80% market share is not willing to provide production numbers. (Personal communication)

DESCRIPTION
Flow chart for the production of cold pressed canola oil

During the experiments with this substrate we experienced a lot of problems with the od measurements because of the high content of plant fibers. By pressure filtering the sediment we extracted a sample that was transparent. From this sample we showed that Y. Lipolytica grows weary well on this waste stream. S. cerevisiae on the other hand is not able to utilize this carbon source as seen in the figures.

DESCRIPTION
Y. Lipolytica growth on sediment from canola oil production
DESCRIPTION
S. cerevisiae does not grow on sediment from canola oil production.

Glycerol byproduct

In trying to find alternatives to fossil fuels the production of biodiesel have increased tremendously in the last two decades. Biodiesel is produced by ar base-catalyzed transesterification by a short chained alcohol and triacylglycerols derived from natural sources as seen below. This reaction produces 0.102 kg glycerol pr. liter biodiesel9. In 2011 the production of biodiesel reached over 21 billion liters resulting in an increased production of glycerol10. The increased production have resulted in a plummeting of glycerol prices making it a promising substrate for industrial fermentation11.

DESCRIPTION
Flow chart for production of biodisel and glycerol waste.

Second generation biodiesel facility (DAKA)

The Danish branch of DAKA refines waste streams from the feedstock industry (such as meat and agricultural industry), turning it into products such as fertilizers, animal feed and biodiesel. The biodiesel production is based on animal tallow and fats from the danish meat industry. The glycerol derived from from this production, has a high salt content and a particularly low pH, and therefore requires several purification steps before it can be used in the chemical industry. By adding NaOH raising the pH to 6 we able to make Y. Lipolytica grow fairly well despite of the relatively high salt levels. (Personal communication)

DESCRIPTION
Y. Lipolytica growth on glycerol from second generation biodisel
DESCRIPTION
S. cerevisiae does not grow on glycerol.

First generation glycerol/glycerin (Perstorp/ Emmelev)

Perstop has two biodiesel production facilities. One located in Sweden and one in Norway. They produce high quality glycerin and glycerol, that is sold as a component for chemical production. This has a purity of og 98% and the rest is mostly water (Personal communication). This byproduct is also a great substrate for Y. Lipolytica as seen in the figure.

DESCRIPTION
Y. Lipolytica growth on glycerol from first generation biodisel
DESCRIPTION
S. cerevisiae does not grow on glycerol.

Glycerin from first generation biodiesel facility Emmelev A/S. Emmelev A/S is a local oil mill, first gen. biodiesel plant and glycerin destillor located on the second biggest island in Denmark, Fyn. The glycerin is distilled to 80% purity and sold to the chemical industry (Personal communication) . This is fairly high quality and there are no content inhibiting the growth of Y. Lipolytica as seen in the figure.

DESCRIPTION
Y. Lipolytica growth on glycerol from first generation biodisel
DESCRIPTION
S. cerevisiae does not grow on glycerol.

Molasses

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References

  1. Barth and Gaillardin, 1996
  2. (Domínguez et al., 1998)
  3. (Shusta et al. 1998)
  4. Barth 2013
  5. (Mhairi Workman, Philippe Holt, 2013)
  6. H. Shafaghat, G.D. Najafpour. Growth Kinetics and Ethanol Productivity of Saccharomyces cerevisiae PTCC 24860 on Varius Carbon Sources. ISSN 1818-4952
  7. Jansen, M. L. A., Daran-Lapujade, P., de Winde, J. H., Piper, M. D. W., & Pronk, J. T. (2004). Prolonged Maltose-Limited Cultivation of Saccharomyces cerevisiae Selects for Cells with Improved Maltose Affinity and Hypersensitivity. Applied and Environmental Microbiology, 70(4), 1956–1963. http://doi.org/10.1128/AEM.70.4.1956-1963.2004
  8. Wisselink, H. W., Toirkens, M. J., del Rosario Franco Berriel, M., Winkler, A. A., van Dijken, J. P., Pronk, J. T., & van Maris, A. J. A. (2007). Engineering of Saccharomyces cerevisiae for Efficient Anaerobic Alcoholic Fermentation of l-Arabinose . Applied and Environmental Microbiology, 73(15), 4881–4891. http://doi.org/10.1128/AEM.00177-07
  9. (Yazdani and Gonzalez, 2007)
  10. (Avinash, 2014)
  11. (Ashby et al., 2008)

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