Ongoing projects in our laboratory focus primarily on RNase A ribonucleases that promote host defense (the eosinophil ribonucleases, RNases 7 and 8, and leukocyte RNase A-2) with efforts directed toward understanding their biology, evolution and mechanism of antimicrobial action (Moser, Chan et al., in preparation). During this reporting period, we published the results of a study initiated by Dr. Wei Zhao during his sabbatical from Beijing Union College, Beijing, China, that was continued and completed as a result of the substantial efforts of a summer intern, Steven Siegel. In an effort to augment our current understanding of divergent mammalian RNase A ribonuclease sequences, we identified novel RNase 1 genes from four species of squirrel (order Rodentia, family Sciuridae). Squirrel RNase 1 genes encode typical RNase A ribonucleases, each with eight cysteines, a conserved CKXXNTF signature motif, and a canonical His(12)-Lys(41)-His(119) catalytic triad. Two alleles encode Callosciurus prevostii RNase 1, which include a Ser(18)<-->Pro, analogous to the sequence polymorphisms found among the RNase 1 duplications in the genome of Rattus exulans. Interestingly, although the squirrel RNase 1 genes are closely related to one another (77-95% amino acid sequence identity), the cluster as a whole is distinct and divergent from the clusters including RNase 1 genes from other rodent species. We examined the specific sites at which Sciuridae RNase 1s diverge from Muridae/Cricetidae RNase 1s and determined that the divergent sites are located on the external surface, with complete sparing of the catalytic crevice.

Project Start
Project End
Budget Start
Budget End
Support Year
7
Fiscal Year
2010
Total Cost
$190,661
Indirect Cost
City
State
Country
Zip Code
Rosenberg, Helene F; Druey, Kirk M (2018) Modeling asthma: Pitfalls, promises, and the road ahead. J Leukoc Biol 104:41-48
Ma, M; Redes, J L; Percopo, C M et al. (2018) Alternaria alternata challenge at the nasal mucosa results in eosinophilic inflammation and increased susceptibility to influenza virus infection. Clin Exp Allergy 48:691-702
Foster, Paul S; Maltby, Steven; Rosenberg, Helene F et al. (2017) Modeling TH 2 responses and airway inflammation to understand fundamental mechanisms regulating the pathogenesis of asthma. Immunol Rev 278:20-40
Percopo, Caroline M; Brenner, Todd A; Ma, Michelle et al. (2017) SiglecF+Gr1hi eosinophils are a distinct subpopulation within the lungs of allergen-challenged mice. J Leukoc Biol 101:321-328
Kraemer, Laura S; Brenner, Todd A; Krumholz, Julia O et al. (2017) A flow-cytometric method to evaluate eosinophil-mediated uptake of probiotic Lactobacillus reuteri. J Microbiol Methods 137:19-24
Rosenberg, Helene F; Druey, Kirk M (2016) Eosinophils, galectins, and a reason to breathe. Proc Natl Acad Sci U S A 113:9139-41
Rosenberg, Helene F (2015) Eosinophil-Derived Neurotoxin (EDN/RNase 2) and the Mouse Eosinophil-Associated RNases (mEars): Expanding Roles in Promoting Host Defense. Int J Mol Sci 16:15442-55
Yamada, Kelsey J; Barker, Tolga; Dyer, Kimberly D et al. (2015) Eosinophil-associated ribonuclease 11 is a macrophage chemoattractant. J Biol Chem 290:8863-75
Percopo, Caroline M; Dyer, Kimberly D; Ochkur, Sergei I et al. (2014) Activated mouse eosinophils protect against lethal respiratory virus infection. Blood 123:743-52
Yang, Ming; Eyers, Fiona; Xiang, Yang et al. (2014) Expression profiling of differentiating eosinophils in bone marrow cultures predicts functional links between microRNAs and their target mRNAs. PLoS One 9:e97537

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