Cecilia Blikstad

High-throughput methods for identification of protein-protein interactions involving short linear motifs

Interactions between modular domains and short linear motifs (3–10 amino acids peptide stretches) are crucial for cell signaling. The motifs typically reside in the disordered regions of the proteome and the interactions are often transient, allowing for rapid changes in response to changing stimuli. The properties that make domain-motif interactions suitable for cell signaling also make them difficult to capture experimentally and they are therefore largely underrepresented in the known protein-protein interaction networks. Most of the knowledge on domain-motif interactions is derived from low-throughput studies, although there exist dedicated high-throughput methods for the identification of domain-motif interactions. The methods include arrays of peptides or proteins, display of peptides on phage or yeast, and yeast-two-hybrid experiments. We here provide a survey of scalable methods for domain-motif interaction profiling. These methods have frequently been applied to a limited number of ubiquitous domain families. It is now time to apply them to a broader set of peptide binding proteins, to provide a comprehensive picture of the linear motifs in the human proteome and to link them to their potential binding partners. Despite the plethora of methods, it is still a challenge for most approaches to identify interactions that rely on post-translational modification or context dependent or conditional interactions, suggesting directions for further method development.

Discovery of short linear motif-mediated interactions through phage display of intrinsically disordered regions of the human proteome

The intrinsically disordered regions of eukaryotic proteomes are enriched in short linear motifs (SLiMs), which are of crucial relevance for cellular signaling and protein regulation; many mediate interactions by providing binding sites for peptide‐binding domains. The vast majority of SLiMs remain to be discovered highlighting the need for experimental methods for their large‐scale identification. We present a novel proteomic peptide phage display (ProP‐PD) library that displays peptides representing the disordered regions of the human proteome, allowing direct large‐scale interrogation of most potential binding SLiMs in the proteome. The performance of the ProP‐PD library was validated through selections against SLiM‐binding bait domains with distinct folds and binding preferences. The vast majority of identified binding peptides contained sequences that matched the known SLiM‐binding specificities of the bait proteins. For SHANK1 PDZ, we establish a novel consensus TxF motif for its non‐C‐terminal ligands. The binding peptides mostly represented novel target proteins, however, several previously validated protein–protein interactions (PPIs) were also discovered. We determined the affinities between the VHS domain of GGA1 and three identified ligands to 40–130 μm through isothermal titration calorimetry, and confirmed interactions through coimmunoprecipitation using full‐length proteins. Taken together, we outline a general pipeline for the design and construction of ProP‐PD libraries and the analysis of ProP‐PD‐derived, SLiM‐based PPIs. We demonstrated the methods potential to identify low affinity motif‐mediated interactions for modular domains with distinct binding preferences. The approach is a highly useful complement to the current toolbox of methods for PPI discovery.

Substrate scope and selectivity in offspring to an enzyme subjected to directed evolution

We have analyzed the effects of mutations inserted during directed evolution of a specialized enzyme, Escherichia coli S‐1,2‐propanediol oxidoreductase (FucO). The kinetic properties of evolved variants have been determined and the observed differences have been rationalized by modeling the tertiary structures of isolated variants and the wild‐type enzyme. The native substrate, S‐1,2‐propanediol, as well as phenylacetaldehyde and 2S‐3‐phenylpropane‐1,2‐diol, which are new substrates accepted by isolated variants, were docked into the active sites. The study provides a comprehensive picture of how acquired catalytic properties have arisen via an intermediate generalist enzyme, which had acquired a single mutation (L259V) in the active site. Further mutagenesis of this generalist resulted in a new specialist catalyst. We have also been able to relate the native enzyme activities to the evolved ones and linked the differences to individual amino acid residues important for activity and selectivity. F254 plays a dual role in the enzyme function. First, mutation of F254 into an isoleucine weakens the interactions with the coenzyme thereby increasing its dissociation rate from the active site and resulting in a four‐fold increase in turnover number with S‐1,2‐propanediol. Second, F254 is directly involved in binding of aryl‐substituted substrates via π–π interactions. On the other hand, N151 is critical in determining the substrate scope since the side chain amide group stabilizes binding of 1,2‐substituted diols and is apparently necessary for enzymatic activity with these substrates. Moreover, the side chain of N151 introduces steric hindrance, which prevents high activity with phenylacetaldehyde. Additionally, the hydroxyl group of T149 is required to maintain the catalytically important hydrogen bonding network.

FtsZ degradation in the cyanobacterium Anabaena sp. strain PCC 7120

In prokaryotes, cell division is normally achieved by binary fission, and the key player FtsZ is considered essential for the complete process. In cyanobacteria, much remains unknown about several aspects of cell division, including the identity and mechanism of the various components involved in the division process. Here, we report results obtained from a search of the players implicated in cell division, directly associating to FtsZ in the filamentous, heterocyst-forming cyanobacterium Anabaena sp. PCC 7120. Histidine tag pull-downs were used to address this question. However, the main observation was that FtsZ is a target of proteolysis. Experiments using various cell-free extracts, an unrelated protein, and protein blot analyses further supported the idea that FtsZ is proteolytically cleaved in a specific manner. In addition, we show evidence that both FtsZ termini seem to be equally prone to proteolysis. Taken together, our data suggest the presence of an unknown player in cyanobacterial cell division, opening up the possibility to investigate novel mechanisms to control cell division in Anabaena PCC 7120.