Post-translational modifications (PTMs) of histone tails are major marks for transcription activation and silencing. Accordingly, detecting and capturing post-translationally modified histones represent a critical step in epigenetic research. A major technological bottleneck in this area of research is a paucity of high-quality affinity reagents. Polyclonal and monoclonal antibodies are the only widely available affinity reagents for histone tails, but they have fundamental limitations in reproducibility, scalability, storage and production throughput and expenses. The long-term goals of this project are to develop an innovative and powerful technology platform for facile production of high-quality affinity reagents for histone tails containing PTMs and to make a standard set of such affinity reagents broadly available to the epigenetics research community. This project is built on an innovative protein-engineering concept that our group has recently established. The concept, termed Affinity Clamping, harnesses the inherent specificity present in the so-called interaction domains and dramatically enhances their affinity and specificity by attaching an """"""""enhancer domain"""""""" and subsequently optimizing its interaction interface by directed evolution of combinatorial libraries. The resulting affinity reagents with clamshell architecture, collectively termed """"""""Affinity Clamps"""""""" thus """"""""clamp"""""""" the target, leading to orders-of-magnitude higher affinity and specificity. Protein libraries made in this manner are predisposed to binding to a specific class of peptide motifs (e.g. histone tails with a methylated lysine), and they virtually guarantee successful engineering of high-performance affinity reagents for a predefined peptide motif. Affinity Clamping represents a paradigm shift in affinity reagent generation. Because Affinity Clamps are fully recombinant reagents produced in E. coli, they can be easily produced in large quantities and distributed. Also they can be reformatted into a variety of fusion proteins suitable for in vitro and in vivo applications. Our proof-of-concept experiments have successfully demonstrated the general feasibility of the Affinity Clamping concept and suggest its enormous potential. Because there exist a number of interaction domains that weakly bind to post-translationally modified histone tails, we are confident that we can apply the Affinity Clamping strategy to produce high-quality affinity reagents to a variety of histone motifs. The proposed project will critically evaluate the feasibility and potential of applying the Affinity Clamping technology to epigenetic histone marks.
The specific aims of the initial project period are (i) to produce """"""""Histone Clamps"""""""" for well-characterized histone lysine methylation sites and benchmark them against commercially available monoclonal antibodies for their performance in commonly used assays; and (ii) to produce Histone Clamps for histone methylation sites for which no high-quality antibodies exist. Such Histone Clamps will be provided to the epigenetic community, which will have a major impact on the quality, scale and types of epigenetics research. ? ?

Public Health Relevance

Accurately measuring the type and amounts of chemically modified forms of histones and capturing them for downstream analysis are major technological challenges in epigenetic research. This project will establish a totally new approach to facile generation of high-performance reagents for these purposes. This innovative and powerful technology will fill a major void in the currently epigenetic research, and products from this project, termed """"""""Histone Clamps"""""""", will make it feasible to establish a standard set of epigenetic capture reagents that can be distributed broadly to the community and open new avenues of epigenetics research. ? ? ? ?

Agency
National Institute of Health (NIH)
Institute
National Institute on Drug Abuse (NIDA)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21DA025725-01
Application #
7570180
Study Section
Special Emphasis Panel (ZRG1-CB-B (50))
Program Officer
Satterlee, John S
Project Start
2008-09-20
Project End
2010-07-31
Budget Start
2008-09-20
Budget End
2009-07-31
Support Year
1
Fiscal Year
2008
Total Cost
$301,864
Indirect Cost
Name
University of Chicago
Department
Biochemistry
Type
Schools of Medicine
DUNS #
005421136
City
Chicago
State
IL
Country
United States
Zip Code
60637
Hattori, Takamitsu; Lai, Darson; Dementieva, Irina S et al. (2016) Antigen clasping by two antigen-binding sites of an exceptionally specific antibody for histone methylation. Proc Natl Acad Sci U S A 113:2092-7
Hattori, Takamitsu; Taft, Joseph M; Swist, Kalina M et al. (2013) Recombinant antibodies to histone post-translational modifications. Nat Methods 10:992-5
Nishikori, Shingo; Hattori, Takamitsu; Fuchs, Stephen M et al. (2012) Broad ranges of affinity and specificity of anti-histone antibodies revealed by a quantitative peptide immunoprecipitation assay. J Mol Biol 424:391-9
Huang, Jin; Koide, Shohei (2010) Rational conversion of affinity reagents into label-free sensors for Peptide motifs by designed allostery. ACS Chem Biol 5:273-7
Koide, Shohei (2009) Generation of new protein functions by nonhomologous combinations and rearrangements of domains and modules. Curr Opin Biotechnol 20:398-404
Koide, Shohei (2009) Engineering of recombinant crystallization chaperones. Curr Opin Struct Biol 19:449-57
Huang, Jin; Nagy, Stanislav S; Koide, Akiko et al. (2009) A peptide tag system for facile purification and single-molecule immobilization. Biochemistry 48:11834-6
Koide, Shohei; Sidhu, Sachdev S (2009) The importance of being tyrosine: lessons in molecular recognition from minimalist synthetic binding proteins. ACS Chem Biol 4:325-34
Huang, Jin; Makabe, Koki; Biancalana, Matthew et al. (2009) Structural basis for exquisite specificity of affinity clamps, synthetic binding proteins generated through directed domain-interface evolution. J Mol Biol 392:1221-31