Earthworms

1. Earthworms Possible Plant Detoxification and Bioremediation Tool Nick Durham Dr. A.M. Craig (Mentor) College of Veterinary Medicine

2. Willamette Valley Grass Seed • Grass seed is one of Oregon’s largest and most important agricultural products [$300 million] • Tall fescue is the most highly harvested grass • The seed is first harvested and then the remaining plant material is sold as straw[$65 million]

3. The Endophyte • 95% of tall fescue is infected with the endophyte Neotyphodium coenophialum • This endophyte beneficially provides the plant with • Drought resistance • Resistance to insects • Negatively, this endophyte produces ergot alkaloids which are toxins

4. Ergot Alkaloids • Toxic to livestock that feed on straw hay • Cause vasoconstriction • Livestock cannot regulate temperature • Responsible for $1 billion loss to livestock producers each year in the United States

5. Ergovaline and Ergotamine Two of the ergot alkaloids found in tall fescue Nitro-aromatic compounds that are difficult to degrade

6. How Would Bacteria Help? • External Solution: Degrade the toxins on straw before it is consumed • Internal Solution: Degrade the toxins inside the livestock before they have a chance to go systemic and cause deleterious effects

7. Background: Why Earthworms? • Earthworms can survive in toxic environments that contain ergot alkaloids • Earthworms have bacteria that produce nitrogen gas • Earthworms contain bacteria capable of reducing nitrogen compounds and degrading nitro aromatic compounds

8. Background: The Industry • A group of grass seed farmers in Halsey, OR have been composting grass seed with earthworms.

9. Earthworms are living on endophyte infected grass seed in a compost pile. • Earthworms have been thriving in an extremely toxic environment

10. Link • How can the earthworms survive such a toxic environment? • Can the bacteria in earthworms degrade toxic nitro-aromatic compounds? • Could these bacteria be used to protect cattle for toxicosis?

11. Objective • Characterize a method for monitoring the degradation of ergovaline by earthworms • Characterize the ability of earthworm bacteria to degrade ergovaline

12. Hypothesis • The bacteria from earthworms will be able to degrade Ergovaline into nontoxic intermediates • This degradation can be monitored by HPLC (High Performance Liquid Chromatography).

13. Making Compost • We made two compost bins • We added a great deal of tall fescue seed which contains the highest level of toxins • We spiked each bin with a different type of earthworm • Red Wiggler(Eisenia foetida) • Nightcrawler(Lumbricus rubellus)

14. Worms Thrived (Red Wigglers)

15. Methods Earthworm Bacteria Removal -Whole Worm and Gut -Aerobic and Anaerobic Sacrifice Worm and Sterilize Exterior Bacteria Cultured on Various Media Samples Are Taken at Time Points to Monitor Ergovaline Degradation Cultures Inoculated with Ergovaline Cultures Back-Transferred Twice Samples Are Purified Using a Solid Phase Extraction Syringe Final Product is analyzed by HPLC Ergovaline is extracted by Chloroform

16. HPLC of Ergot Alkaloids

17. Media and Environment • Rich anaerobic environment • Lots of nutrients, but no oxygen • Cometabolize toxin as they grow • 6 anaerobic consortiums were grown and tested for the ability to degrade ergovaline. • The level of ergovaline in the consortium was monitored at 24 hour intervals for 72 hours

18. Consortium 1 - HPLC Internal Standard Black – 0 hrs Blue – 24 hrs Red – 48 hrs Green – 72 hrs EV

19. Rich Anaerobic Trials • All 6 consortiums of bacteria failed to degrade any ergovaline • I did not find the right consortium • Maybe there was too much food, too many choices

20. Targeting Ergovaline Tripeptide: Proline, Valine, and Alanine Peptide Bond Potential Peptide Target

21. Media and Environment • Whole protein diet of milk casein • Lots of peptide bonds • No free amino acids • Grown with and without oxygen • 12 consortiums (6 aerobic/6 anaerobic) were grown and tested for the ability to degrade ergovaline. • The level of ergovaline in the consortium was monitored for 24 hours

22. Casein Trials • All 12 consortiums of bacteria failed to degrade any ergovaline • I did not find the right consortium • Maybe the bacteria still had casein left so it did not need to eat the ergovaline

23. Currently • Two new approaches • Minimal media: Force bacteria to learn to eat everything • Concentrate cells: Increase cell density while decreasing concentration of casein and add ergovaline

24. Summary of Objectives • I have successfully characterized a method for monitoring the degradation of ergovaline by earthworms • As of yet, none of my cultured bacteria have been capable of degrading ergovaline

25. Acknowledgements • Dr. A. Morrie Craig • Nevon Dernstein • Department of Microbiology • Howard Hughes Medical Institute • Dr. Kevin Ahern

26. Questions? E-mail: Durhamn@onid.orst.edu