Jun Seop Jeong

Profiling the Human Protein-DNA Interactome Reveals ERK2 as a Transcriptional Repressor of Interferon Signaling

Protein-DNA interactions (PDIs) mediate a broad range of functions essential for cellular differentiation, function, and survival. However, it is still a daunting task to comprehensively identify and profile sequence-specific PDIs in complex genomes. Here, we have used a combined bioinformatics and protein microarray-based strategy to systematically characterize the human protein-DNA interactome. We identified 17,718 PDIs between 460 DNA motifs predicted to regulate transcription and 4,191 human proteins of various functional classes. Among them, we recovered many known PDIs for transcription factors (TFs). We identified a large number of unanticipated PDIs for known TFs, as well as for previously uncharacterized TFs. We also found that over three hundred unconventional DNA-binding proteins (uDBPs)--which include RNA-binding proteins, mitochondrial proteins, and protein kinases--showed sequence-specific PDIs. One such uDBP, ERK2, acts as a transcriptional repressor for interferon gamma-induced genes, suggesting important biological roles for such proteins.

Construction of human activity-based phosphorylation networks.

The landscape of human phosphorylation networks has not been systematically explored, representing vast, unchartered territories within cellular signaling networks. Although a large number of in vivo phosphorylated residues have been identified by mass spectrometry (MS)‐based approaches, assigning the upstream kinases to these residues requires biochemical analysis of kinase‐substrate relationships (KSRs). Here, we developed a new strategy, called CEASAR, based on functional protein microarrays and bioinformatics to experimentally identify substrates for 289 unique kinases, resulting in 3656 high‐quality KSRs. We then generated consensus phosphorylation motifs for each of the kinases and integrated this information, along with information about in vivo phosphorylation sites determined by MS, to construct a high‐resolution map of phosphorylation networks that connects 230 kinases to 2591 in vivo phosphorylation sites in 652 substrates. The value of this data set is demonstrated through the discovery of a new role for PKA downstream of Btk (Brutons tyrosine kinase) during B‐cell receptor signaling. Overall, these studies provide global insights into kinase‐mediated signaling pathways and promise to advance our understanding of cellular signaling processes in humans.

Regulation of CK2 by phosphorylation and O-GlcNAcylation revealed by semisynthesis

Protein Ser/Thr kinase CK2 (casein kinase II) is involved in a myriad of cellular processes including cell growth and proliferation by phosphorylating hundreds of substrates, yet the regulation process of CK2 function is poorly understood. Here we report that the CK2 catalytic subunit CK2α is modified by O-GlcNAc on Ser347, proximal to a cyclin-dependent kinase phosphorylation site (Thr344) on the same protein. We use protein semisynthesis to show that Thr344 phosphorylation increases CK2α cellular stability via Pin1 interaction whereas Ser347 glycosylation appears to be antagonistic to Thr344 phosphorylation and permissive to proteasomal degradation. By performing kinase assays with the site-specifically modified phospho- and glyco-modified CK2α in combination with CK2β and Pin1 binding partners on human protein microarrays, we show that CK2 kinase substrate selectivity is modulated by these specific posttranslational modifications. This study suggests how a promiscuous protein kinase can be regulated at multiple levels to achieve particular biological outputs.

Rapid identification of monospecific monoclonal antibodies using a human proteome microarray

To broaden the range of tools available for proteomic research, we generated a library of 16,368 unique full-length human ORFs that are expressible as N-terminal GST-His6 fusion proteins. Following expression in yeast, these proteins were then individually purified and used to construct a human proteome microarray. To demonstrate the usefulness of this reagent, we developed a streamlined strategy for the production of monospecific monoclonal antibodies that used immunization with live human cells and microarray-based analysis of antibody specificity as its central components. We showed that microarray-based analysis of antibody specificity can be performed efficiently using a two-dimensional pooling strategy. We also demonstrated that our immunization and selection strategies result in a large fraction of monospecific monoclonal antibodies that are both immunoblot and immunoprecipitation grade. Our data indicate that the pipeline provides a robust platform for the generation of monoclonal antibodies of exceptional specificity.

Identification of New Autoantigens for Primary Biliary Cirrhosis Using Human Proteome Microarrays

Primary biliary cirrhosis (PBC) is a chronic cholestatic liver disease of unknown etiology and is considered to be an autoimmune disease. Autoantibodies are important tools for accurate diagnosis of PBC. Here, we employed serum profiling analysis using a human proteome microarray composed of about 17,000 full-length unique proteins and identified 23 proteins that correlated with PBC. To validate these results, we fabricated a PBC-focused microarray with 21 of these newly identified candidates and nine additional known PBC antigens. By screening the PBC microarrays with additional cohorts of 191 PBC patients and 321 controls (43 autoimmune hepatitis, 55 hepatitis B virus, 31 hepatitis C virus, 48 rheumatoid arthritis, 45 systematic lupus erythematosus, 49 systemic sclerosis, and 50 healthy), six proteins were confirmed as novel PBC autoantigens with high sensitivities and specificities, including hexokinase-1 (isoforms I and II), Kelch-like protein 7, Kelch-like protein 12, zinc finger and BTB domain-containing protein 2, and eukaryotic translation initiation factor 2C, subunit 1. To facilitate clinical diagnosis, we developed ELISA for Kelch-like protein 12 and zinc finger and BTB domain-containing protein 2 and tested large cohorts (297 PBC and 637 control sera) to confirm the sensitivities and specificities observed in the microarray-based assays. In conclusion, our research showed that a strategy using high content protein microarray combined with a smaller but more focused protein microarray can effectively identify and validate novel PBC-specific autoantigens and has the capacity to be translated to clinical diagnosis by means of an ELISA-based method.

Bcl2-associated Athanogene 3 Interactome Analysis Reveals a New Role in Modulating Proteasome Activity

Bcl2-associated athanogene 3 (BAG3), a member of the BAG family of co-chaperones, plays a critical role in regulating apoptosis, development, cell motility, autophagy, and tumor metastasis and in mediating cell adaptive responses to stressful stimuli. BAG3 carries a BAG domain, a WW domain, and a proline-rich repeat (PXXP), all of which mediate binding to different partners. To elucidate BAG3s interaction network at the molecular level, we employed quantitative immunoprecipitation combined with knockdown and human proteome microarrays to comprehensively profile the BAG3 interactome in humans. We identified a total of 382 BAG3-interacting proteins with diverse functions, including transferase activity, nucleic acid binding, transcription factors, proteases, and chaperones, suggesting that BAG3 is a critical regulator of diverse cellular functions. In addition, we characterized interactions between BAG3 and some of its newly identified partners in greater detail. In particular, bioinformatic analysis revealed that the BAG3 interactome is strongly enriched in proteins functioning within the proteasome-ubiquitination process and that compose the proteasome complex itself, suggesting that a critical biological function of BAG3 is associated with the proteasome. Functional studies demonstrated that BAG3 indeed interacts with the proteasome and modulates its activity, sustaining cell survival and underlying resistance to therapy through the down-modulation of apoptosis. Taken as a whole, this study expands our knowledge of the BAG3 interactome, provides a valuable resource for understanding how BAG3 affects different cellular functions, and demonstrates that biologically relevant data can be harvested using this kind of integrated approach.

A nuclease that mediates cell death induced by DNA damage and poly(ADP-ribose) polymerase-1

DNA damage-activated nuclease identified Cells that experience stresses and accumulate excessive damage to DNA undergo cell death mediated by a nuclear enzyme known as PARP-1. During this process, apoptosis-inducing factor (AIF) translocates to the nucleus and activates one or more nucleases to cleave DNA. Wang et al. found that macrophage migration inhibitory factor (MIF) is an AIF-associated endonuclease that contributes to PARP-1-induced DNA fragmentation (see the Perspective by Jonas). In mouse neurons in culture, loss of MIF protected neurons from cell death caused by excessive stimulation. Targeting MIF could thus provide a therapeutic strategy against diseases in which PARP-1 activation is excessive. Science, this issue p. 82; see also p. 36 An endonuclease that functions in a disease-associated form of cell death is identified. [Also see Perspective by Jonas] INTRODUCTION Poly(ADP-ribose) (PAR) polymerase-1 (PARP-1) is a nuclear enzyme responding to oxidative stress and DNA damage. Excessive activation of PARP-1 causes an intrinsic caspase-independent cell death program designated parthanatos, which occurs in many organ systems because of toxic or stressful insults, including ischemia-reperfusion injury after stroke and myocardial infarction, inflammatory injury, reactive oxygen species–induced injury, glutamate excitotoxicity, and neurodegenerative diseases. Inhibition or genetic deletion of PARP-1 is profoundly protective against such cellular injury in models of human disease. RATIONALE The molecular mechanisms underlying parthanatos involve release of mitochondrial apoptosis-inducing factor (AIF) and its translocation to the nucleus, which results in chromatinolysis into 20- to 50-kb large DNA fragments—a commitment point for parthanatos. Because AIF itself has no obvious nuclease activity, we propose that AIF recruits a nuclease or a nuclease complex to the nucleus to trigger DNA cleavage and parthanatos. Although the endonuclease G (EndoG) homolog may promote DNA degradation in Caenorhabditis elegans through cooperating with the AIF homolog, our group and others showed that EndoG does not have an essential role in PARP-dependent chromatinolysis and cell death in mammals. Thus, the identity of the nuclease responsible for large DNA fragmentation following AIF entry to the nucleus during parthanatos has been a long-standing mystery. RESULTS Using two sequential unbiased screens, including a human protein array and a small interfering RNA screen, we discovered that macrophage migration inhibitory factor (MIF) binds AIF and is required for parthanatos. Three-dimensional modeling of MIF revealed that the MIF trimer has the same core topology structure as PD-D/E(X)K superfamily nucleases. In the presence of Mg2+ or Ca2+, MIF has both 3′ exonuclease and endonuclease activity. It binds to 5′ unpaired bases of single-stranded DNA with stem loop structure and cleaves its 3′ unpaired bases. These nuclease activities allow MIF to cleave genomic DNA into large fragments. Depletion of MIF markedly reduced chromatinolysis and cell death induced by N-methyl-d-aspartate (NMDA) receptor–activated glutamate excitotoxicity in primary neuronal cultures, DNA damage caused by N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) or focal stroke in mice. Mutating key amino acid residues in the PD-D/E(X)K nuclease domain of MIF eliminated its nuclease activity and prevented parthanatos. Disrupting the AIF and MIF interaction prevented the translocation of MIF from the cytosol to the nucleus and protected against parthanatos. Moreover, depletion of MIF, disruption of AIF and MIF interaction, and eliminating MIF’s nuclease activity has long-lasting histological and behavioral rescue in the focal ischemia model of stroke. CONCLUSION We identified MIF as a PARP-1–dependent AIF-associated nuclease that is required for parthanatos. In response to oxidative stress or DNA damage, PARP-1 activation triggers AIF release from the mitochondria. AIF then recruits MIF to the nucleus where MIF cleaves genomic DNA into large fragments and causes cell death. Depletion of MIF, disruption of AIF and MIF interaction, or blocking MIF nuclease activity inhibited chromatinolysis and parthanatos. Targeting MIF nuclease activity may offer an important therapeutic opportunity for a variety of disorders with excessive PARP-1 activation. Stressors lead to DNA damage, PARP-1 activation, and PAR formation. PAR facilitates the release of AIF from mitochondria where it binds MIF. This complex translocates to the nucleus to bind DNA; the result is DNA fragmentation and cell death. Interference with this cascade by preventing the formation of the AIF-MIF complex or by a nuclease-deficient MIF prevents DNA fragmentation and promotes cell survival. Inhibition or genetic deletion of poly(ADP-ribose) (PAR) polymerase-1 (PARP-1) is protective against toxic insults in many organ systems. The molecular mechanisms underlying PARP-1–dependent cell death involve release of mitochondrial apoptosis-inducing factor (AIF) and its translocation to the nucleus, which results in chromatinolysis. We identified macrophage migration inhibitory factor (MIF) as a PARP-1–dependent AIF-associated nuclease (PAAN). AIF was required for recruitment of MIF to the nucleus, where MIF cleaves genomic DNA into large fragments. Depletion of MIF, disruption of the AIF-MIF interaction, or mutation of glutamic acid at position 22 in the catalytic nuclease domain blocked MIF nuclease activity and inhibited chromatinolysis, cell death induced by glutamate excitotoxicity, and focal stroke. Inhibition of MIF’s nuclease activity is a potential therapeutic target for diseases caused by excessive PARP-1 activation.

Yeast one-hybrid assays for gene-centered human gene regulatory network mapping

Gateway-compatible yeast one-hybrid (Y1H) assays provide a convenient gene-centered (DNA to protein) approach to identify transcription factors that can bind a DNA sequence of interest. We present Y1H resources, including clones for 988 of 1,434 (69%) predicted human transcription factors, that can be used to detect both known and new interactions between human DNA regions and transcription factors.

Protein Microarray Characterization of the S-Nitrosoproteome

Nitric oxide (NO) mediates a substantial part of its physiologic functions via S-nitrosylation, however the cellular substrates for NO-mediated S-nitrosylation are largely unknown. Here we describe the S-nitrosoproteome using a high-density protein microarray chip containing 16,368 unique human proteins. We identified 834 potentially S-nitrosylated human proteins. Using a unique and highly specific labeling and affinity capture of S-nitrosylated proteins, 138 cysteine residues on 131 peptides in 95 proteins were determined, defining critical sites of NOs actions. Of these cysteine residues 113 are novel sites of S-nitrosylation. A consensus sequence motif from these 834 proteins for S-nitrosylation was identified, suggesting that the residues flanking the S-nitrosylated cysteine are likely to be the critical determinant of whether the cysteine is S-nitrosylated. We identify eight ubiquitin E3 ligases, RNF10, RNF11, RNF41, RNF141, RNF181, RNF208, WWP2, and UBE3A, whose activities are modulated by S-nitrosylation, providing a unique regulatory mechanism of the ubiquitin proteasome system. These results define a new and extensive set of proteins that are susceptible to NO regulation via S-nitrosylation. Similar approaches could be used to identify other post-translational modification proteomes.

Activation of diverse signalling pathways by oncogenic PIK3CA mutations

The PIK3CA gene is frequently mutated in human cancers. Here we carry out a SILAC-based quantitative phosphoproteomic analysis using isogenic knockin cell lines containing ‘driver’ oncogenic mutations of PIK3CA to dissect the signaling mechanisms responsible for oncogenic phenotypes induced by mutant PIK3CA. From 8,075 unique phosphopeptides identified, we observe that aberrant activation of PI3K pathway leads to increased phosphorylation of a surprisingly wide variety of kinases and downstream signaling networks. Here, by integrating phosphoproteomic data with human protein microarray-based AKT1 kinase assays, we discover and validate six novel AKT1 substrates, including cortactin. Through mutagenesis studies, we demonstrate that phosphorylation of cortactin by AKT1 is important for mutant PI3K enhanced cell migration and invasion. Our study describes a quantitative and global approach for identifying mutation-specific signaling events and for discovering novel signaling molecules as readouts of pathway activation or potential therapeutic targets.