Kinase-catalyzed Biotinylation with Inactivated Lysates for Discovery of Substrates (K-BILDS)

Protein phosphorylation is catalyzed by kinases to regulate a large variety of cellular activities, including growth and signal transduction. Methods to identify kinase substrates are crucial to fully understand phosphorylation-mediated cellular events and disease states. Here, we report a set of protocols to identify substrates of a target kinase using Kinase-catalyzed Biotinylation with Inactivated Lysates for Discovery of Substrates (K-BILDS). As described in these protocols, K-BILDS involves inactivation of endogenous kinases in lysates, followed by addition of an active exogenous kinase and the γ-phosphate-modified ATP analog ATP-biotin for kinase-catalyzed biotinylation of cellular substrates. Avidin enrichment isolates biotinylated substrates of the active kinase, which can be monitored by western blot. Substrates of the target kinase can also be discovered using mass spectrometry analysis. Key advantages of K-BILDS include compatibility with any lysate, tissue homogenate, or complex mixture of biological relevance and any active kinase of interest. K-BILDS is a versatile method for studying or discovering substrates of a kinase of interest to characterize biological pathways thoroughly. © 2023 Wiley Periodicals LLC. Basic Protocol 1: FSBA treatment of lysates to inactivate kinases Basic Protocol 2: Kinase-catalyzed Biotinylation with Inactivated Lysates for Discovery of Substrates (K-BILDS).

An Affinity-Based, Cysteine-Specific ATP Analog for Kinase-Catalyzed Crosslinking

Kinases mediate cell signaling pathways by catalyzing protein phosphorylation. Irregularities in kinase activity are directly associated with disease conditions. Therefore, methods to identify substrates of a particular kinase are needed to understand signaling cascades in normal and diseased states. Photocrosslinking ATP analogs provide powerful tools to study kinases by covalently linking kinases with substrates. However, the involvement of UV light and nonspecific reactivity of current ATP-photocrosslinkers challenge kinase-substrate identification. We report here an affinity-based crosslinking ATP analog, ATP-methylacrylamide (ATP-MAc), that contains a cysteine-reactive acrylamide crosslinking group, which avoids the UV irradiation and non-specific reactivity of prior analogs. Using in vitro kinase assays, ATP-MAc acts as a kinase co-substrate and covalently crosslinks only kinases containing cysteines in the active site. ATP-MAc was also able to crosslink cellular proteins in lysates, documenting compatibility with cell-based studies.

Different Enzymatic Processing of γ-Phosphoramidate and γ-Phosphoester-Modified ATP Analogues

Monitoring the activity of ATP-consuming enzymes provides the basis for elucidating their modes of action and regulation. Although a number of ATP analogues have been developed for this, their scope is restricted because of the limited acceptance by respective enzymes. In order to clarify which kind of phosphate-modified ATP analogues are accepted by the α-β-phosphoanhydride-cleaving ubiquitin-activating enzyme 1 (UBA1) and the β-γ-phosphoanhydride-cleaving focal adhesion kinase (FAK), we tested phosphoramidate- and phosphoester-modified ATP analogues. UBA1 and FAK were able to convert phosphoramidate-modified ATP analogues, even with a bulky modification like biotin. In contrast, a phosphoester-modified analogue was poorly accepted. These results demonstrate that minor variations in the design of ATP analogues for monitoring ATP utilization have a significant impact on enzymatic acceptance.

K-BILDS: A Kinase Substrate Discovery Tool

Kinases catalyze protein phosphorylation to regulate cell signaling events. However, identifying kinase substrates is challenging due to the often low abundance and dynamic nature of protein phosphorylation. Development of novel techniques to identify kinase substrates is necessary. Here, we report kinase-catalyzed biotinylation with inactivated lysates for discovery of substrates (K-BILDS) as a tool to identify direct substrates of a kinase. As a proof of concept, K-BILDS was applied to cAMP-dependent protein kinase A (PKA) with HeLa cell lysates. Subsequent enrichment and MS/MS analysis identified 279 candidate PKA substrates, including 56 previously known PKA substrates. Of the candidate substrates, nuclear autoantigenic sperm protein (NASP), BCL2-associated athanogene 3 (BAG3), and 14-3-3 protein Tau (YWHAQ) were validated as novel PKA substrates. K-BILDS provides a valuable tool to identify direct substrates of any protein kinase.

A Cell-Permeable ATP Analogue for Kinase-Catalyzed Biotinylation

ATP analogues have been powerful compounds for the study of kinase-catalyzed phosphorylation. However, the cell impermeability of ATP analogues has largely limited their use to in vitro lysate-based experiments. Herein, we report the first cell-permeable ATP analogue, ATP-polyamine-biotin (APB). APB is shown to promote biotin labeling of kinase substrates in live cells and has future applications in phosphoprotein purification and analysis. More generally, these studies provide a foundation for the development of additional cell-permeable ATP analogues for cell-signaling research.

Biotinylated phosphoproteins from kinase-catalyzed biotinylation are stable to phosphatases: implications for phosphoproteomics

Kinase-catalyzed protein phosphorylation is involved in a wide variety of cellular events. Development of methods to monitor phosphorylation is critical to understand cell biology. Our lab recently discovered kinase-catalyzed biotinylation, where ATP-biotin is utilized by kinases to label phosphopeptides or phosphoproteins with a biotin tag. To exploit kinase-catalyzed biotinylation for phosphoprotein purification and identification in a cellular context, the susceptibility of the biotin tag to phosphatases was characterized. We found that the phosphorylbiotin group on peptide and protein substrates was relatively insensitive to protein phosphatases. To understand how phosphatase stability would impact phosphoproteomics research applications, kinase-catalyzed biotinylation of cell lysates was performed in the presence of kinase or phosphatase inhibitors. We found that biotinylation with ATP-biotin was sensitive to inhibitors, although with variable effects compared to ATP phosphorylation. The results suggest that kinase-catalyzed biotinylation is well suited for phosphoproteomics studies, with particular utility towards monitoring low-abundance phosphoproteins or characterizing the influence of inhibitor drugs on protein phosphorylation.

Current chemical biology tools for studying protein phosphorylation and dephosphorylation

Amongst different posttranslational events involved in cellular-signaling pathways, phosphorylation and dephosphorylation of proteins are the most prevalent. Aberrant regulations in the cellular phosphoproteome network are implicated in most major human diseases. Consequently, kinases and phosphatases are two of the most important groups of drug targets in medicinal research today. A major challenge in the understanding of protein phosphorylation and dephosphorylation is the sheer complexity of the phosphoproteome network and the lack of tools capable of studying protein phosphorylation and dephosphorylation as they occur in cells. We highlight herein various chemical biology tools that have emerged in the last decade for such studies. First, we discuss the use of small-molecule mimics of phosphoamino acids and their use in elucidating the function of protein phosphorylation and dephosphorylation. We also introduce recent advances in the field of activity-based protein profiling (ABPP) for proteome-wide detection of protein phosphorylation and dephosphorylation. We next discuss the key concepts in the design of peptide- and protein-based biosensors capable of real-time reporting of phosphorylation/dephosphorylation events. Finally, we highlight the application of peptide and small-molecule microarrays (SMMs), and their applications in high-throughput screening and discovery of new compounds related to phosphorylation/dephosphorylation.

Probing the role of the linker in ferrocene-ATP conjugates: monitoring protein kinase catalyzed phosphorylations electrochemically

The synthesis and electrochemical properties of ferrocene conjugates are presented for the purpose of investigating adenosine 5'-[γ-ferrocenoylalkyl] triphosphate (1 a-4 a, ferrocene (Fc)-ATP) as co-substrates for phosphorylation reactions. Compounds 1 a-4 a were synthesized, purified by HPLC, and characterized by NMR spectroscopy and mass spectrometry. In solution, all Fc-ATP bioconjugates exhibit a reversible one-electron redox process with a half-wave potential (E(1/2)) in the 390-430 mV range, peak separations (ΔE(p)) in the 40-70 mV range, and the peak current ratio (i(pa)/i(pc)) near unity. The peptide-modified surface Glu-Gly-Ile-Tyr-Asp-Val-Pro was used to study the sarcoma-related protein (Src) kinase activity by employing the Fc-ATP bioconjugates as co-substrates. Subsequent kinase-catalyzed transfer of the γ-Fc-phosphate group to the tyrosine residues of the surface-bound peptides was characterized by a formal potential (E°) ≈390 mV (vs. Ag/AgCl). The Fc-coverage, estimated by time-of-flight secondary-ion mass spectrometry (TOF-SIMS) and cyclic voltammetry (CV), suggested validity of Fc-ATP conjugates as kinase co-substrates. Depending on the length of the alkyl spacer of the Fc-ATP conjugate, different current densities were obtained, pointing to a direct correlation between the two. Molecular modeling revealed that the structural constraint imposed by the short alkyl spacer (1 a) causes a steric congestion and negatively affects the outcome of phosphorylation reaction. An optimal analytical response was obtained with the Fc-ATP conjugates with linker lengths longer than six CH(2) groups.