Method Article

A High Throughput Screen for Biomining Cellulase Activity from Metagenomic Libraries

DOI:

10.3791/2461

February 1st, 2011

In This Article

Summary

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This protocol describes a high throughput screen for cellulolytic activity from a metagenomic library expressed in Escherichia coli. The screen is solution based and highly automated, and uses one-pot chemistry in 384 well microplates with the final readout as an absorbance measurement.

Abstract

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Cellulose, the most abundant source of organic carbon on the planet, has wide-ranging industrial applications with increasing emphasis on biofuel production 1. Chemical methods to modify or degrade cellulose typically require strong acids and high temperatures. As such, enzymatic methods have become prominent in the bioconversion process. While the identification of active cellulases from bacterial and fungal isolates has been somewhat effective, the vast majority of microbes in nature resist laboratory cultivation. Environmental genomic, also known as metagenomic, screening approaches have great promise in bridging the cultivation gap in the search for novel bioconversion enzymes. Metagenomic screening approaches have successfully recovered novel cellulases from environments as varied as soils 2, buffalo rumen 3 and the termite hind-gut 4 using carboxymethylcellulose (CMC) agar plates stained with congo red dye (based on the method of Teather and Wood 5). However, the CMC method is limited in throughput, is not quantitative and manifests a low signal to noise ratio 6. Other methods have been reported 7,8 but each use an agar plate-based assay, which is undesirable for high-throughput screening of large insert genomic libraries. Here we present a solution-based screen for cellulase activity using a chromogenic dinitrophenol (DNP)-cellobioside substrate 9. Our library was cloned into the pCC1 copy control fosmid to increase assay sensitivity through copy number induction 10. The method uses one-pot chemistry in 384-well microplates with the final readout provided as an absorbance measurement. This readout is quantitative, sensitive and automated with a throughput of up to 100X 384-well plates per day using a liquid handler and plate reader with attached stacking system.

Protocol

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Before starting this protocol, you will need your metagenomic library stored in a 384 well plate format. In our study, we used the pCC1 copy control fosmid vector in combination with phage T1-resistant TransforMax EPI300-T1R E. coli cells as the library host and stored our plates at -80°C 11.

1. Replication of the Metagenomic Library Plates

  1. Defrost the plates containing your library at 37°C for approximately 20 minutes, or until all wells are thawed.
  2. Use the UV light sterilizing feature on the qPix2 to sterilize the robot for 15 minutes.
  3. Prepare LB broth with chloramphenic....

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Discussion

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A high throughput screen for the rapid detection of cellulolytic activity from a large insert genomic DNA metagenomic library expressed in E. coli is described in this protocol. This method is an improvement over the CMC/Congo Red assay commonly used in the literature. It is solution based, and allows for one-pot chemistry screening in 384-well plates, with the final output as absorbance readings from a plate reader allowing for quantitative analysis. The automation of each step of this process allows for the un.......

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Disclosures

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No conflicts of interest declared.

Acknowledgements

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The authors would like to thank Dr. Steve Withers and Hong-Ming Chen for providing DNP-Cellobioside substrate.

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Materials

List of materials used in this article
NameCompanyCatalog NumberComments
qPix2GenetixWith 384-pin gridding head
qFill3GenetixWith 384-well manifold
VarioskanThermo Fisher Scientific, Inc.
RapidStakThermo Fisher Scientific, Inc.Connected to Varioskan
Micro90 DetergentCole-Parmer18100-00Diluted to 2% in water
EthanolMajor Lab SupplierDiluted to 80% in water
ChloramphenicolSigma-AldrichC037812.5mg/mL in ethanol
LB broth, MillerFisher ScientificBP1426-225g/L, autoclaved
384-well flat bottom platesCorning3680
L-(+)-ArabinoseSigma-AldrichA3256100mg/mL in water
Potassium AcetateFisher ScientificP17150mM in water, autoclaved, adjusted to pH 5.5 with HCl
Triton X-100Fisher ScientificBP151
Trizma hydrochlorideSigma-AldrichT3253In TE buffer solution, 100mM
EDTA disodium saltSigma-AldrichE5134In TE buffer solution, 10mM
2,4-dinitrophenyl cellobiosideProvided by Dr. Steve Withers, UBC
Dimethyl SulfoxideSigma-AldrichD8418

References

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  1. Rubin, E. M. Genomics of cellulosic biofuels. Nature. 454, 841-845 (2008).
  2. Voget, S., Steele, H. L., Streit, W. R. Characterization of a metagenome derived halotolerant cellulase. J. Biotechnol. 126, 26-36 (2006).
  3. Duan, C. J.

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Tags

Metagenomic Library ScreeningCellulase Activity AssayDNP Cellobioside Substrate384 Well MicroplateHigh Throughput ScreeningSolution Based ScreenAbsorbance MeasurementPlate ReaderLiquid HandlerHumidity Box Incubation

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