Yinyin Li

A robust pipeline for rapid production of versatile nanobody repertoires

Nanobodies are single-domain antibodies derived from the variable regions of Camelidae atypical immunoglobulins. They show promise as high-affinity reagents for research, diagnostics and therapeutics owing to their high specificity, small size (∼15 kDa) and straightforward bacterial expression. However, identification of repertoires with sufficiently high affinity has proven time consuming and difficult, hampering nanobody implementation. Our approach generates large repertoires of readily expressible recombinant nanobodies with high affinities and specificities against a given antigen. We demonstrate the efficacy of this approach through the production of large repertoires of nanobodies against two antigens, GFP and mCherry, with Kd values into the subnanomolar range. After mapping diverse epitopes on GFP, we were also able to design ultrahigh-affinity dimeric nanobodies with Kd values as low as ∼30 pM. The approach presented here is well suited for the routine production of high-affinity capture reagents for various biomedical applications.

Escherichia coli condensin MukB stimulates topoisomerase IV activity by a direct physical interaction.

In contrast to the current state of knowledge in the field of eukaryotic chromosome segregation, relatively little is known about the mechanisms coordinating the appropriate segregation of bacterial chromosomes. In Escherichia coli, the MukB/E/F complex and topoisomerase IV (Topo IV) are both crucial players in this process. Topo IV removes DNA entanglements following the replication of the chromosome, whereas MukB, a member of the structural maintenance of chromosomes protein family, serves as a bacterial condensin. We demonstrate here a direct physical interaction between the dimerization domain of MukB and the C-terminal domain of the ParC subunit of Topo IV. In addition, we find that MukB alters the activity of Topo IV in vitro. Finally, we isolate a MukB mutant, D692A, that is deficient in its interaction with ParC and show that this mutant fails to rescue the temperature-sensitive growth phenotype of a mukB- strain. These results show that MukB and Topo IV are linked physically and functionally and indicate that the activities of these proteins are not limited to chromosome segregation but likely also play a key role in the control of higher-order bacterial chromosome structure.

Quantitative Chemical Proteomics Approach To Identify Post-translational Modification-Mediated Protein–Protein Interactions

Post-translational modifications (PTMs) (e.g., acetylation, methylation, and phosphorylation) play crucial roles in regulating the diverse protein-protein interactions involved in essentially every cellular process. While significant progress has been made to detect PTMs, profiling protein-protein interactions mediated by these PTMs remains a challenge. Here, we report a method that combines a photo-cross-linking strategy with stable isotope labeling in cell culture (SILAC)-based quantitative mass spectrometry to identify PTM-dependent protein-protein interactions. To develop and apply this approach, we focused on trimethylated lysine-4 at the histone H3 N-terminus (H3K4Me(3)), a PTM linked to actively transcribed gene promoters. Our approach identified proteins previously known to recognize this modification and MORC3 as a new protein that binds H3M4Me(3). This study indicates that our cross-linking-assisted and SILAC-based protein identification (CLASPI) approach can be used to profile protein-protein interactions mediated by PTMs, such as lysine methylation.

Cdk1 uncouples CtIP-dependent resection and Rad51 filament formation during M-phase double-strand break repair

M-phase DNA double-strand break repair differs from S-phase repair caused by the action of Cdk1, which prevents RPA-bound single-stranded DNA from activating classical DNA repair pathways.

Examining post‐translational modification‐mediated protein–protein interactions using a chemical proteomics approach

Post‐translational modifications (PTM) of proteins can control complex and dynamic cellular processes via regulating interactions between key proteins. To understand these regulatory mechanisms, it is critical that we can profile the PTM‐dependent protein–protein interactions. However, identifying these interactions can be very difficult using available approaches, as PTMs can be dynamic and often mediate relatively weak protein–protein interactions. We have recently developed CLASPI (cross‐linking‐assisted and stable isotope labeling in cell culture‐based protein identification), a chemical proteomics approach to examine protein–protein interactions mediated by methylation in human cell lysates. Here, we report three extensions of the CLASPI approach. First, we show that CLASPI can be used to analyze methylation‐dependent protein–protein interactions in lysates of fission yeast, a genetically tractable model organism. For these studies, we examined trimethylated histone H3 lysine‐9 (H3K9Me3)‐dependent protein–protein interactions. Second, we demonstrate that CLASPI can be used to examine phosphorylation‐dependent protein–protein interactions. In particular, we profile proteins recognizing phosphorylated histone H3 threonine‐3 (H3T3‐Phos), a mitotic histone “mark” appearing exclusively during cell division. Our approach identified survivin, the only known H3T3‐Phos‐binding protein, as well as other proteins, such as MCAK and KIF2A, that are likely to be involved in weak but selective interactions with this histone phosphorylation “mark”. Finally, we demonstrate that the CLASPI approach can be used to study the interplay between histone H3T3‐Phos and trimethylation on the adjacent residue lysine 4 (H3K4Me3). Together, our findings indicate the CLASPI approach can be broadly applied to profile protein–protein interactions mediated by PTMs.

Method for identifying phosphorylated substrates of specific cyclin/cyclin-dependent kinase complexes

Significance During proliferation, eukaryotic cells go through a defined series of phases. The primary regulators of this process are kinases paired with protein partners called cyclins. Exactly how these specific cyclin–kinase pairs orchestrate the myriad cellular events during each cell phase has been difficult to define largely because it has proven challenging to identify their substrates. Here, we describe a method to identify cyclin- and phase-specific substrates with high confidence and also to pinpoint their sites of modification. The method enabled us to identify the phosphatase Cdc14 as a substrate of a cyclin–kinase pair that acts during DNA synthesis in budding yeast and to uncover a new means by which this major antagonist of the cyclin–kinase pair is itself controlled. In eukaryotes, cell cycle progression is controlled by cyclin/cyclin-dependent kinase (CDK) pairs. To better understand the details of this process, it is necessary to dissect the CDK’s substrate pool in a cyclin- and cell cycle stage-specific way. Here, we report a mass spectrometry-based method that couples rapid isolation of native kinase–substrate complexes to on-bead phosphorylation with heavy-labeled ATP (ATP-γ-18O4). This combined in vivo/in vitro method was developed for identifying cyclin/CDK substrates together with their sites of phosphorylation. We used the method to identify Clb5 (S-cyclin)/Cdc28 and Cln2 (G1/S-cyclin)/Cdc28 substrates during S phase in Saccharomyces cerevisiae (Cdc28 is the master CDK in budding yeast). During the work, we discovered that Clb5/Cdc28 specifically phosphorylates S429 in the disordered tail of Cdc14, an essential phosphatase antagonist of Cdc28. This phosphorylation severely decreases the activity of Cdc14, providing a means for modulating the balance of CDK and phosphatase activity.

Supervillin Binding to Myosin II and Synergism with Anillin Are Required for Cytokinesis

Supervillin binding to myosin II is crucial for cytokinetic fidelity. This function complements that of anillin in promoting myosin II localization and cleavage furrow ingression during mammalian cell cytokinesis. Interactor analyses show that these proteins act through separate but overlapping pathways.

Nuclear ARP2/3 drives DNA break clustering for homology-directed repair

DNA double-strand breaks repaired by non-homologous end joining display limited DNA end-processing and chromosomal mobility. By contrast, double-strand breaks undergoing homology-directed repair exhibit extensive processing and enhanced motion. The molecular basis of this movement is unknown. Here, using Xenopus laevis cell-free extracts and mammalian cells, we establish that nuclear actin, WASP, and the actin-nucleating ARP2/3 complex are recruited to damaged chromatin undergoing homology-directed repair. We demonstrate that nuclear actin polymerization is required for the migration of a subset of double-strand breaks into discrete sub-nuclear clusters. Actin-driven movements specifically affect double-strand breaks repaired by homology-directed repair in G2 cell cycle phase; inhibition of actin nucleation impairs DNA end-processing and homology-directed repair. By contrast, ARP2/3 is not enriched at double-strand breaks repaired by non-homologous end joining and does not regulate non-homologous end joining. Our findings establish that nuclear actin-based mobility shapes chromatin organization by generating repair domains that are essential for homology-directed repair in eukaryotic cells.Polymerization of actin in the cell nucleus, promoted by the ARP2/3 complex, drives the clustering of double-strand DNA breaks into nuclear compartments where they can undergo homology-directed repair.

Probing the Recognition Properties of the Antiparallel Coiled Coil Motif from PKN by Protein Grafting

Coiled coils have long been recognized as the major constituent of many fibrous proteins and also serve as oligomerization domains in a wide variety of proteins. More recently, it has become clear that the surfaces of two-stranded coiled coils are also involved in macromolecular recognition. Indeed, the helical hairpin or intramolecular antiparallel coiled coil (ACC) can serve as a protein or nucleic acid recognition motif. Protein kinase N (PKN) interacts with the small GTPase RhoA through ACC motifs. The crystal structure of RhoA with the N-terminal ACC motif (PKN-ACC1) is unusual in that these proteins interact through two distinct surfaces. Using the ACC domain of seryl tRNA synthetase (SRS-ACC) as a scaffold for protein grafting experiments, we show that RhoA interacts with only one face of PKN-ACC1. This result highlights the potential of the SRS-ACC scaffold for protein engineering applications and provides insight into the mechanism of RhoA-mediated signal transduction through PKN.