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Your search keyword '"Burtner, Abigail E."' showing total 8 results
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8 results on '"Burtner, Abigail E."'

1. Gliding toward an understanding of the origin of flight in bats.

Author

Burtner, Abigail E., M. Grossnickle, David, Santana, Sharlene E., and Law, Chris J.

Subjects
FOSSILS, PHYLOGENETIC models, GLIDERS (Aeronautics), COMPARATIVE method, FORELIMB, BATS
Abstract

Bats are the only mammals capable of powered flight and have correspondingly specialized body plans, particularly in their limb morphology. The origin of bat flight is still not fully understood due to an uninformative fossil record but, from the perspective of a functional transition, it is widely hypothesized that bats evolved from gliding ancestors. Here, we test predictions of the gliding-to-flying hypothesis of the origin of bat flight by using phylogenetic comparative methods to model the evolution of forelimb and hindlimb traits on a dataset spanning four extinct bats and 231 extant mammals with diverse locomotor modes. Our results reveal that gliders exhibit adaptive trait optima (1) toward relatively elongate forelimbs that are intermediate between those of bats and non-gliding arborealists, and (2) toward relatively narrower but not longer hindlimbs that are intermediate between those of non-gliders and bats. We propose an adaptive landscape based on limb length and width optimal trends derived from our modeling analyses. Our results support a hypothetical evolutionary pathway wherein glider-like postcranial morphology precedes a bat-like morphology adapted to powered-flight, setting a foundation for future developmental, biomechanical, and evolutionary research to test this idea. [ABSTRACT FROM AUTHOR]

Published
2024
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8. De novo design of protein minibinder agonists of TLR3.

Author

Adams CS, Kim H, Burtner AE, Lee DS, Dobbins C, Criswell C, Coventry B, Kim HM, and King NP

Abstract

Toll-like Receptor 3 (TLR3) is a pattern recognition receptor that initiates antiviral immune responses upon binding double-stranded RNA (dsRNA). Several nucleic acid-based TLR3 agonists have been explored clinically as vaccine adjuvants in cancer and infectious disease, but present substantial manufacturing and formulation challenges. Here, we use computational protein design to create novel miniproteins that bind to human TLR3 with nanomolar affinities. Cryo-EM structures of two minibinders in complex with TLR3 reveal that they bind the target as designed, although one partially unfolds due to steric competition with a nearby N-linked glycan. Multimeric forms of both minibinders induce NF-κB signaling in TLR3-expressing cell lines, demonstrating that they may have therapeutically relevant biological activity. Our work provides a foundation for the development of specific, stable, and easy-to-formulate protein-based agonists of TLRs and other pattern recognition receptors., Competing Interests: Declaration of Interests A provisional patent application has been filed by the University of Washington on the TLR3 minibinders described here, listing C.S.A., B.C., and N.P.K. as co-inventors. The King lab has received unrelated sponsored research agreements from Pfizer and GSK. The other authors declare no competing interests.

Published
2024
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