Aaron A. Hoskins
Credentials: Wasson Professor in Biochemistry, Department of Biochemistry
Email: ahoskins@wisc.edu
Website: Lab Website
Address:
2214A HF DeLuca Biochemical Sciences Building
440 Henry Mall, Madison, WI 53706-1535
- Education
- B.S., Purdue University; Ph.D., Massachusetts Institute of Technology; Postdoctoral, Brandeis University and University of Massachusetts Medical School
- Areas of Expertise
- Biomolecular Folding & Interactions; Chemical Biology & Enzymology; Gene Expression & RNA Biology; Quantitative Biology
Mechanistic studies of eukaryotic RNA processing using chemical, genetic, and biophysical approaches
In the cell, RNA is built, processed, and degraded by a number of macromolecular machines. Many of these machines are composed of dozens, or even hundreds, of protein components. Studying the underlying biochemistry of these enzymes is particularly challenging given these huge numbers of parts. Work in my laboratory utilizes a number of assays, including multi-wavelength single molecule fluorescence microscopy, to elucidate these processes.
We are particularly focused on studies of pre-mRNA splicing–the process of removing introns from nascent transcripts. This reaction is carried out by the spliceosome. For every intron that is removed, the spliceosome is built, activated for catalysis, and disassembled on the pre-mRNA transcript. This is a remarkable feat of cellular engineering involving the coordinated actions of ~100 proteins and 5 snRNAs
In order to study this process, we simplify our system by studying one spliceosome at a time using CoSMoS: Co-localization Single Molecule Spectroscopy. In this technique, biomolecules (such as pre-mRNAs) are fluorescently labeled and tethered to a glass or silica surface. We then study association of other fluorescent bio-molecules (such as spliceosomes) with the tethered biomolecules. By analyzing the comings and goings of many molecules, we are able to provide mechanistic insight into complex systems even in a whole cell extract!
Recognition of Splice Sites during Spliceosome Assembly and Activation
Arguably, the most important function of the spliceosome is not the chemistry per se but determining the correct location of the chemistry. The spliceosome is not just a machine–it is an intelligent machine! This project focuses on using kinetic measurements to determine how the spliceosome chooses the 5′ splice site and branchsite in a pre-mRNA sequence. Work on this project makes use of single molecule fluorescence and ensemble experiments to study these events. In addition to carrying out these reactions in cell extracts, efforts in this area will also include work on purified systems, the use of yeast genetic engineering, and many types of biochemical assays.
Coupling between Eukaryotic RNA Processing Events
The spliceosome does not function in isolation within the cell’s nucleus. Many experiments have suggested a tight coupling of nuclear RNA processing events including chromatin remodeling, transcription, splicing, capping, poly-A tail formation, RNA decay, and transport into the cytosol. The work in this area focuses on understanding the biochemical mechanisms behind coupling of splicing with two processes: transcription and RNA capping. These projects will make use of both single molecule and many molecule experiments to uncover the biochemistry behind these phenomena.
Chemical Tools for Modifying RNPs in vitro and in vivo
While currently there exist many methods for studying proteins in cells by fluorescence, analysis of in vivo RNAs is limited and often confined to analysis of mRNAs rather than structured ribonucleoproteins (RNPs). The goal of this research is to develop new chemical tools for studying RNPs in vitro and in vivo in both wild type and disease-related backgrounds. This project will combine organic synthesis, biochemical assays, and cell biology to create “RNA Tags” for cellular imaging.
Publication Highlights
Kaur H, van der Feltz C, Sun Y, Hoskins AA. (2022) Network theory reveals principles of spliceosome structure and dynamics Structure 30(1):190-200 (PMC8741635) Pubmed Record
Hansen SR, White DS, Scalf M, Correa Jr IR, Smith LM, Hoskins, AA. (2022) Multi-step recognition of potential 5′ splice sites by the Saccharomyces cerevisiae U1 snRNP Elife 11:e70534 Pubmed Record
Fu, X, Kaur, H, Rodgers, M L, Montemayor, E J, Butcher, S E, Hoskins, A A. (2022) Identification of transient intermediates during spliceosome activation by single molecule fluorescence microscopy Proc Natl Acad Sci USA 119(48):e2206815119 Pubmed Record
Lipinski, KA, Chi, J, Chen, X, Hoskins, AA, and Brow DA. (2022) Yeast U6 snRNA made by RNA polymerase II is less stable but functional RNA 28(12):1606-1620 PMC9670810 Pubmed Record