Research Project: The Story of the American Chestnuts
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Transcript of Research Project: The Story of the American Chestnuts
Research Project:
The Story of the American
Chestnuts
Castanea dentata: “Redwoods of the East”
• Native to New England and the Appalachian Mts.
• 1 of every 4 trees in old-growth Appalachian forests was an American chestnut.
• 100+ feet tall, 10 ft. diameter trunks
• Gave food & shelter to black bears, wild turkeys, Carolina parakeets, moose, elk, deer, mountain lions…
• Rot- and water-resistant
wood that split easily• Abundant annual nuts
used in traditional American recipes
• Used for railroads, instruments, housing, telegraph/telephone poles, etc.
• Tannin extracts used for tanning leather
• Timber an important export to the early American economy
Blight Introduced from Asian Chestnut Varieties
1870: Imported Chinese and
Japanese chestnut trees,
better for orchards and
nut harvesting.
1904: Blight
detected in
American chestnuts
1910: American
chestnuts at the Bronx Zoo die
1940 – 1960: Nation-wide
efforts to stop blight spread, breed Asian-
American hybrid
1960: 4 billion American
chestnuts lost, U.S. Gov’t
ceases funding for restoration
efforts
• Cryphonectria paracitica enters through a wound, colonizes beneath bark
• Spreading hyphae produce oxalic acid and kill the cambium, an vital layer of bark
• Disease spreads up tree, but not to roots
• Roots attempt to regrow
• Result: “living stumps” that
never grow tall
How the Blight Works
~1980-2013 : The Backbreding Method
• Project led by The American Chestnut Foundation (TACF)
• Utilizes Mendelian
genetics • First use of “gene
knockout” on trees
• Goal: the “perfect” hybrid
Transgenic Trees & Synthetic Biology
• March 2013: OxO wheat gene and strong promoter, CaMV 35S inserted into American chestnuts
• April 2013: Powell’s transgenic trees planted in New York where the first trees died in 1910, hope for recovery
•Hybrid tree development time-consuming, still haven’t developed a flawless tree
•William Powell from SUNY-ESF begins developing GM trees as an alternative
•Realized Triticum aestivum, common wheat, has genes for proteins that break down oxalic acid
Design Project:N-Acyl Homoserine Lactone (N-AHL) Directed Bdellovibro bacteriovorus
Stewart’s Wilt (P. stewartii)
Stewart’s wilt is a corn disease caused by a rod-shaped, Gram-negative bacteria.
Corn flea beetles bring the bacteria into crops every Spring. P. stewartii overwinters in the beetle’s gut every year.
Current “Management”
clothianidin
thiamethoxamimidacloprid
Design Proposal
Engineer a “smart” bacteria with the ability to:
• Locate P. stewartii• Destroy the bacterial colony• Be non-pathogenic to humans, animals,
corn• Essentially function as an
environmentally friendly, pathogen-specific pesticide
Quorum-Sensing in Stewart’s Wilt
The Gram-negative quorum sensing systems are all very similar to the two-component system used by vibrio fischeri, the first discovered quorum-sensing system.
But, the QS proteins EsaI and EsaR in P. stewartii are slightly different:• EsaI creates the N-Acyl homoserine lactone OHHL• EsaR binds to OHHL, and detatches from the promoter it
is otherwise bound to
Thus, EsaR is unique in that it acts as a repressor, and AHL molecules cause derepression instead of the usual activation caused by Quorum sensing receptor proteins.
Bdellovibrio bacteriovorus
B. Bacteriovorus is a predatory Gram-negative bacteria that preys on other Gram-negative bacteria.
MotAB protein pairs are transmembrane protein complexes which affect flagellar rotation. B. bacteriovorus HD100 has three of these protein pairs that make up a hybrid motor.
Each protein pair contributes to rotational power, but MotAB3 has the most significant impact.
The chemotactic system utilizes methyl-accepting chemotactic proteins (MCPs), transmembrane proteins that detect and bind to external ligands, in order to set off a chain reaction of proteins in the chemotactic system.
These reactions then cause a “biased random walk” towards the chemical detected by the MCP. Traits of a biased random walk:
• Increased likelihood of “tumbling” when moving down a concentration
gradient
• Prolonged “smooth swimming” when moving up a concentration
gradient
Detection of OHHL by B.
bacteriovorus
Positive Chemotaxis
Transcription of MotAB3
Mean Swim Speed (μm/s)
+/- SD*
0 0 0 26.5 +/- 1.8
1 1 1 63.2 +/- 5.5
Design Proposal, revisited
• Add an esaR gene sequence to B. bacteriovorus such that an EsaR protein sits on the MotAB3 operon promoter.
• Artificially construct an MCP that accepts OHHL as its ligand. Replace all naturally occurring MCPs.
http://jb.asm.org/content/193/4/932.full*
Ideal Outcome
• These two alterations of B. bacteriovorus are regulated by
the same external chemical, OHHL.
• Ideally, this concurrent swim speed increase and directional
bias will “lock in” B. bacteriovorus to the desired prey, thus
causing a dramatic increase in the probability of prey being
P. stewartii.
• If predation levels are adequate, B. bacteriovorus will be
able to repress concentrations of the pathogen and prevent
severe cases of Stewart’s wilt in corn.
Considerations, Good and Bad
Positive
Could replace harmful pesticides that otherwise damage the ecosystem
Safe and easy to test (disregarding the development hurdle)
Potential model for targeting other Gram-negative bacteria
Negative
Increased probability of predation does not guarantee P. stewartii as the sole prey
P. stewartii is not detected until harmful levels are already present within the plant
More research is required to understand the structure and function of MCPs