研究领域
Biochemistry
1) Multiplexed chemical labeling of proteins in living cells: Molecules that bind specifically and with high affinity to proteins can be developed into powerful tools for chemical biology. The interaction between substituted 5-benzyl pyrimidines and different forms of dihydrofolate reductase (DHFR) can be exploited for chemically labeling fusion proteins in mammalian cells. For example, the specific, high affinity (KD ~ 1 nM) interaction between trimethoprim and E. coli DHFR has been exploited to develop the LigandLink(tm) Universal Labeling technology (Active Motif, Inc., Carlsbad, CA, www.activemotif.com) that makes it possible to tag eDHFR fusion proteins in wild-type mammalian cells with cell-permeable trimethoprim-fluorophore conjugates (Figure 1). We are currently developing additional antifolate/DHFR pairs for in vivo protein labeling, with the ultimate goal being the simultaneously labeling of multiple proteins in a single cell.
2) Time-resolved microscopy of lanthanide probes. Lanthanide luminescence offers several advantages for fluorescence-based biological assays: 1) large Stoke’s shifts (>150 nm) and multiple, narrow emission bands (<10 nm at half-maximum) allow efficient spectral separation of emission signals; 2) long luminescence lifetimes (micro- to millisecond) enable time-resolved detection methods to remove scattering and autofluorescence background; and 3) relative insensitivity to photobleaching allows for prolonged detection. We are exploring time-resolve microscopy (Figure 2) as a means of imaging lanthanide probe-labeled proteins at the single-molecule limit of detection.
3) Dynamic visualization of protein-protein interactions: Transient protein-protein interactions control cell growth and function. We are developing lanthanide-based, protein labels with long (msec) luminescent lifetimes (Figure 2). These probes will facilitate in vivo, time-resolved imaging of resonance energy transfer between interacting proteins. By analyzing the luminescent decay curves of long-lifetime donors, it will be possible to determine the stoichiometry of the interaction, as well as the dynamic localization within the cell. Furthermore, it will be possible to time-gate out any background fluorescence from endogenous biomolecules, allowing luminescent live cell imaging with unprecedented signal-to-noise ratio.
近期论文
查看导师新发文章
(温馨提示:请注意重名现象,建议点开原文通过作者单位确认)
H.E. Rajapakse, D.R. Reddy, S. Mohandessi, N.G. Butlin, and L.W. Miller “Luminescent Terbium Protein Labels for Time-Resolved Microscopy and Screening.” (2009) Angew. Chem. Int. Ed. 48:4990-4992.
L.E. Pedró Rosa, D.R. Reddy, S.F. Queener, and L.W. Miller “Selective Antifolates for Chemically Labeling Proteins in Mammalian Cells.” (2009) Chembiochem 10:1462-1464.
L.W. Miller (Ed.) “Probes and Tags to Study Biomolecular Function.” (2008) Miller, L. W. Wiley-VCH, Weinheim.
N.T. Calloway, M. Choob, A. Sanz, M.P. Sheetz, L.W. Miller, and V.W. Cornish “Optimized Fluorescent Trimethoprim Derivatives for in Vivo Protein Labeling.” (2007) Chembiochem 8:767-774.
L.W. Miller, Y. Cai, M.P. Sheetz, and V.W. Cornish “In Vivo Protein Labeling With Trimethoprim Conjugates: A Flexible Chemical Tag.” (2005) Nat. Methods 2:255-257.
L.W. Miller and V.W. Cornish “Selective Chemical Labeling of Proteins in Living Cells.” (2005) Curr. Opin. Chem. Biol. 9:56-61.