Shanshan Tian

Development of a DNA-Templated Peptide Probe for Photoaffinity Labeling and Enrichment of the Histone Modification Reader Proteins

Histone post-translational modifications (HPTMs) provide signal platforms to recruit proteins or protein complexes to regulate gene expression. Therefore, the identification of these recruited partners (readers) is essential to understand the underlying regulatory mechanisms. However, it is still a major challenge to profile these partners because their interactions with HPTMs are rather weak and highly dynamic. Herein we report the development of a HPTM dual probe based on DNA-templated technology and a photo-crosslinking method for the identification of HPTM readers. By using the trimethylation of histone H3 lysine 4, we demonstrated that this HPTM dual probe can be successfully utilized for labeling and enrichment of HPTM readers, as well as for the discovery of potential HPTM partners. This study describes the development of a new chemical proteomics tool for profiling HPTM readers and can be adapted for broad biomedical applications.

Profiling post-translational modifications of histones in neural differentiation of embryonic stem cells using liquid chromatography-mass spectrometry.

The neural differentiation of embryonic stem cells (ESCs) is of great significance for understanding of the mechanism of diseases. Histone post-translational modifications (HPTMs) play a key role in the regulation of ESCs differentiation. Here, we combined the stable isotope chemical derivatization with nano-HPLC-mass spectrometry (MS) for comprehensive analysis and quantification of histone post-translational modifications (HPTMs) in mouse embryonic stem cells (mESCs) and neural progenitor cells (mNPCs) that was derived from ESCs. We identified 85 core HPTM sites in ESCs and 78HPTM sites in NPCs including some novel lysine modifications. Our quantitative analysis results further revealed the changes of HPTMs from ESCs to NPCs and suggested effect of combinational HPTMs in the differentiation. This study demonstrates that HPLC-MS-based quantitative proteomics has a considerable advantage on quantification of combinational PTMs and expands our understanding of HPTMs in the differentiation.

DNA-Templated Aptamer Probe for Identification of Target Proteins

Using aptamers as molecular probes for biomarker discovery has attracted a great deal of attention in recent years. However, it is still a big challenge to accurately identify those protein markers that are targeted by aptamers under physiological conditions due to weak and noncovalent aptamer-protein interactions. Herein, we developed an aptamer based dual-probe using DNA-templated chemistry and photo-cross-linking technique for the identification of target proteins that are recognized by aptamers. In this system, the aptamer was modified by a single strand DNA as binding probe (BP), and another complementary DNA with a photoactive group and reporter group was modified as capture probe (CP). BP was first added to recruit the binding protein via aptamer recognition, and subsequently CP was added to let the cross-linker close to the target via DNA self-assembly, and then a covalent bond between CP and its binding protein was achieved via photo-cross-linking reaction. The captured protein can be detected or affinity enrichment using the tag, finally identified by MS. By use of lysozyme as a model substrate, we demonstrated that this multiple functionalized probe can be utilized for a successful labeling and enrichment of target protein even under a complicated and real environment. Thus, a novel method to precisely identify the aptamer-targeted proteins has been developed and it has a potential application for discovery of aptamer-based biomarkers.

Probing the Binding Interfaces of Histone-Aptamer by Photo Cross-Linking Mass Spectrometry

Histone proteins, which could interact with DNA, play important roles in the regulation of chromatin structures, transcription, and other DNA-based biological processes. Here, we developed a novel aptamer-based probe for the analysis of histone H4-aptamer interfaces. This probe contains a DNA sequence for specific recognition of histone H4, a biotin tag for affinity enrichment, an aryl azide photoactive group for cross-linking and a cleavable disulfide group to dissociate aptamer from labeled histones. We successfully achieved specific enrichment of histone H4 and further developed a new analysis strategy for histone-aptamer interaction by photo cross-linking mass spectrometry. The binding area of histone H4 to aptamer was investigated and discussed for the first time. This strategy exhibits great potential and might further contribute to the understanding of histone-DNA interaction patterns.

USP52 acts as a deubiquitinase and promotes histone chaperone ASF1A stabilization

Histone chaperone ASF1A has been reported to be dysregulated in multiple tumors; however, the underlying molecular mechanism that how the abundance and function of ASF1A are regulated remains unclear. Here we report that ASF1A is physically associated with USP52, which is previously identified as a pseudo-deubiquitinase. Interestingly, we demonstrate that USP52 is a bona fide ubiquitin-specific protease, and USP52 promotes ASF1A deubiquitination and stabilization. USP52-promoted ASF1A stabilization facilitates chromatin assembly and favors cell cycle progression. Additionally, we find that USP52 is overexpressed in breast carcinomas, and its level of expression correlates with that of ASF1A. Moreover, we reveal that impairment of USP52-promoted ASF1A stabilization results in growth arrest of breast cancer cells and sensitizes these cells to DNA damage. Our experiments identify USP52 as a truly protein deubiquitinase, uncover a molecular mechanism of USP52 in chromatin assembly, and reveal a potential role of USP52 in breast carcinogenesis.Histone chaperone ASF1A is often dysregulated in cancers, however the regulation of its abundance is unclear. Here, the authors show that USP52 promotes ASF1A stability through deubiquitination while impairment of this stability reduces breast tumorigenesis and confers sensitivity to DNA damage.

Ubiquitin-specific protease 7 sustains DNA damage response and promotes cervical carcinogenesis

Central to the recognition, signaling, and repair of DNA double-strand breaks (DSBs) are the MRE11-RAD50-NBS1 (MRN) complex and mediator of DNA damage checkpoint protein 1 (MDC1), the interplay of which is essential for initiation and amplification of the DNA damage response (DDR). The intrinsic rule governing the regulation of the function of this molecular machinery remains to be investigated. We report here that the ubiquitin-specific protease USP7 was physically associated with the MRN-MDC1 complex and that the MRN-MDC1 complex acted as a platform for USP7 to efficiently deubiquitinate and stabilize MDC1, thereby sustaining the DDR. Accordingly, depletion of USP7 impaired the engagement of the MRN-MDC1 complex and the consequent recruitment of the downstream factors p53-binding protein 1 (53BP1) and breast cancer protein 1 (BRCA1) at DNA lesions. Significantly, USP7 was overexpressed in cervical cancer, and the level of its expression positively correlated with that of MDC1 and worse survival rates for patients with cervical cancer. We demonstrate that USP7-mediated MDC1 stabilization promoted cervical cancer cell survival and conferred cellular resistance to genotoxic insults. Together, our study reveals a role for USP7 in regulating the function of the MRN-MDC1 complex and activity of the DDR, supporting the pursuit of USP7 as a potential therapeutic target for MDC1-proficient cancers.

An integrated approach based on DNA self-assemble technique for characterization of crosstalk among combinatorial histone modifications

Combinatorial histone post-translational modifications (HPTMs) form a complex epigenetic code that can be decoded by specific binding proteins, termed as readers. Their specific interplays have been thought to determine gene expression and downstream biological functions. However, it is still a big challenge to analyze such interactions due to various limitations including rather weak, transient, and complicated interactions between HPTMs and readers, the high dynamic property of HPTMs, and the low abundance of reader proteins. Here we sought to take advantage of DNA-templated and photo-cross-linking techniques to design a group of combinatorial histone PTM peptide probes for the identification of multivalent interactions among histone PTMs and readers. By use of trimethylation on histone H3K4 (H3K4me3) and phosphorylation on H3T3, we demonstrated that this approach can be successfully utilized for identification of the PTM crosstalk on the same histone. By use of H3K4me3 and acetylation on H4K16, we showed the potential application of the probe in the multivalent interactions among PTMs on different histones. Thus, this new chemical proteomics tool combined with mass spectrometry holds a promising potential in profiling of the readers of combinatorial HPTMs and characterization of crosstalk among multiple PTMs on histones and can be adapted for broad biomedical applications.

Maltose-Functionalized Hydrophilic Magnetic Nanoparticles with Polymer Brushes for Highly Selective Enrichment of N-Linked Glycopeptides

Efficient enrichment glycoproteins/glycopeptides from complex biological solutions are very important in the biomedical sciences, in particular biomarker research. In this work, the high hydrophilic polyethylenimine conjugated polymaltose polymer brushes functionalized magnetic Fe3O4 nanoparticles (NPs) denoted as Fe3O4–PEI–pMaltose were designed and synthesized via a simple two-step modification. The obtained superhydrophilic Fe3O4–PEI–pMaltose NPs displayed outstanding advantages in the enrichment of N-linked glycopeptides, including high selectivity (1:100, mass ratios of HRP and bovine serum albumin (BSA) digest), low detection limit (10 fmol), large binding capacity (200 mg/g), and high enrichment recovery (above 85%). The above-mentioned excellent performance of novel Fe3O4–PEI–pMaltose NPs was attributed to graft of maltose polymer brushes and efficient assembly strategy. Moreover, Fe3O4–PEI–pMaltose NPs were further utilized to selectively enrich glycopeptides from human renal mesangial cell (HRMC, 200 μg) tryptic digest, and 449 N-linked glycopeptides, representing 323 different glycoproteins and 476 glycosylation sites, were identified. It was expected that the as-synthesized Fe3O4–PEI–pMaltose NPs, possessing excellent performance (high binding capacity, good selectivity, low detection limit, high enrichment recovery, and easy magnetic separation) coupled to a facile preparation procedure, have a huge potential in N-glycosylation proteome analysis of complex biological samples.

Identification of hydroxylation at aromatic amino acid residues in yeast kinase using mass spectrometry with affinity enrichment.

RATIONALE Protein kinases represent the key elements in phosphorylation-based signal transmission. Recent studies suggest that hydroxylation may mediate activities of protein kinases. This paper aims to examine the hydroxylation in protein kinases for improving our understanding of the protein modification. METHODS We combined affinity-based protein purification with MS analysis for identification of novel hydroxylation at aromatic amino acid residues in yeast kinases. RESULTS We identified 17 hydroxylation at aromatic amino acid residues (10 at Phe, 1 at Tyr and 6 at Trp) using MS analysis. We further characterized the localization and studied the potential significance of these modifications. CONCLUSIONS This is a new report on the identification of hydroxylation at aromatic amino acid residues in yeast kinases. This study expands the catalog of hydroxylation in kinases and suggests the potential function of hydroxylation. Copyright

Quantitative characterization of histone post-translational modifications using a stable isotope dimethyl-labeling strategy

Histone post-translational modifications (PTMs) have been considered to be a major group of important epigenetic marks and play critical roles in the regulation of chromatin-templated biological processes. To date, novel strategies for the quantification of histone PTMs are still highly desirable. Herein, we present an efficient approach to quantitatively characterize histone PTMs using stable isotope dimethyl labeling coupled with mass spectrometry. At first, all of the e-amino groups of free lysines are derivatized by heavy formaldehyde to enable an easy distinction of free lysines from those of naturally occurring lysine-dimethylation upon MS analysis. After tryptic digestion, a second derivatization was applied with heavy- and light-stable isotope dimethyl labeling to label the N-termini of tryptic peptides from different sample sources. The mixture was further identified and quantified by HPLC-MS/MS. This method enables the comparison of histone PTMs from multiple sample sources and the quantification of different PTMs at certain amino-acid residues of histones in one single experiment. Thus, it is highly attractive for the identification of epigenetic histone marks.