Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2020013

Authors: Taufiq Nawaz Shah Fahad Ruanbao Zhou

Protein phosphorylation serves as a fundamental regulatory mechanism to modulate cellular responses to environmental stimuli and plays a crucial role in orchestrating adaptation and metabolic homeostasis in various diverse organisms. In cyanobacteria, an ancient phylum of significant ecological and biotechnological relevance, protein phosphorylation emerges as a central regulatory axis mediating adaptive responses that are essential for survival and growth. This exhaustive review thoroughly explores the complex terrain of protein phosphorylation in cyanobacterial adaptation and metabolism, illustrating its diverse forms and functional implications. Commencing with an overview of cyanobacterial physiology and the historical trajectory of protein phosphorylation research in prokaryotes, this review navigates through the complex mechanisms of two-component sensory systems and their interplay with protein phosphorylation. Furthermore, it investigates the different feeding modes of cyanobacteria and highlights the complex interplay between photoautotrophy, environmental variables, and susceptibility to photo-inhibition. The significant elucidation of the regulatory role of protein phosphorylation in coordinating light harvesting with the acquisition of inorganic nutrients underscores its fundamental importance in the cyanobacterial physiology. This review highlights its novelty by synthesizing existing knowledge and proposing future research trajectories, thereby contributing to the deeper elucidation of cyanobacterial adaptation and metabolic regulation through protein phosphorylation.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2020012

Authors: Nourah Nayef Lakhan Ekal Ewald H. Hettema Kathryn R. Ayscough

Mitochondria are organelles involved in cellular energetics in all eukaryotes, and changes in their dynamics, fission, fusion, or localization can lead to cell defects and disease in humans. Budding yeast, Saccharomyces cerevisiae, has been shown to be an effective model organism in elucidating mechanisms underpinning these mitochondrial processes. In the work presented here, a genetic screen was performed to identify overexpressing kinases, phosphatases, and ubiquitin ligases, which resulted in mitochondrial defects. A total of 33 overexpressed genes showed mitochondrial phenotypes but without severe growth defects. These included a subset that affected the timing of mitochondrial inheritance and were the focus of further study. Using cell and biochemical approaches, the roles of the PAK-family kinase Cla4 and the E3-ubiquitin ligases Dma1 and Dma2 were investigated. Previous studies have indicated the roles of kinase Cla4 and ligases Dma1 and Dma2 in triggering the degradation of trafficking adaptors in the bud, which leads to disruption of the interaction with the transporting class V myosin, Myo2. Here, we map a key interface between Cla4 and the mitochondrial adaptor Mmr1 necessary for phosphorylation and identify a region of Mmr1 required for its degradation via Dma1 and Dma2. Together, our data provide insights into key regulatory regions of Mmr1 responsible for its function in mitochondrial inheritance.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2020011

Authors: Keli Lima João Agostinho Machado-Neto

Cancer, characterized by uncontrolled cell growth and metastasis, represents a significant challenge to public health. The IGF1/IGF1R axis plays a pivotal role in tumor proliferation and survival, presenting an attractive target for intervention. NT157, a small molecule tyrphostin, has emerged as a promising inhibitor of this axis, displaying potent antineoplastic effects across various cancer types. This review synthesizes the literature on NT157’s mechanism of action and its impact on cellular processes in experimental cancer models. Initially identified for inducing the serine phosphorylation of IRS1 and IRS2, leading to their degradation and inhibiting the IGF1R signaling cascade, subsequent studies revealed additional targets of NT157, including STAT3, STAT5, and AXL, suggesting a multifaceted mechanism. Experimental evidence demonstrates that NT157 effectively suppresses tumor growth, metastasis, and angiogenesis in diverse cancer models. Additionally, NT157 enhances chemotherapy efficacy in combination therapy. Moreover, NT157 impacts not only tumor cells but also the tumor microenvironment, modulating inflammation and immune responses by targeting cancer-associated fibroblasts, myeloid cells, and immune cells, creating a suppressive milieu hindering tumor progression and metastasis. In conclusion, NT157 exhibits remarkable versatility in targeting multiple oncogenic pathways and hallmarks of cancer, underscoring its potential as a promising therapeutic agent.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2020010

Authors: Moeka Nakashima Naoko Suga Satoru Matsuda

It has been proposed that procedures which upregulate mitochondrial biogenesis and autophagy by replacing damaged mitochondria with healthy ones may prevent the development of several heart diseases. A member of serine and threonine kinases, adenosine monophosphate-activated protein kinase (AMPK), could play essential roles in the autophagy and/or mitophagy. AMPK is widely distributed in various cells, which might play diverse regulatory roles in different tissues and/or organs. In fact, changes in the kinase function of AMPK due to alteration of activity have been linked with diverse pathologies including cardiac disorders. AMPK can regulate mitochondrial biogenesis via peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PGC1α) signaling and also improve oxidative mitochondrial metabolism through inhibition of mechanistic/mammalian target of rapamycin (mTOR) pathway, which may also modulate the autophagy/mitophagy through autophagy activating kinase 1 (ULK1) and/or transforming growth factor beta (TGF-β) signaling. Therefore, the modulation of AMPK in autophagy/mitophagy pathway might probably be thought as a therapeutic tactic for several cardiac disorders. As kinases are amongst the most controllable proteins, in general, the design of small molecules targeting kinases might be an eye-catching avenue to modulate cardiac function. Some analyses of the molecular biology underlying mitophagy suggest that nutraceuticals and/or drugs including specific AMPK modulator as well as physical exercise and/or dietary restriction that could modulate AMPK may be useful against several heart diseases. These observations may virtually be limited to preclinical studies. Come to think of these, however, it is speculated that some nutraceutical regimens might have positive potential for managing some of cardiac disorders.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2020009

Authors: Sara Sadat Aghamiri Rada Amin

Cancer stem cells (CSCs), found within tumors, are powerful drivers of disease recurrence and metastasis. Their abilities to self-renew and maintain stem-like properties make treatment difficult, as their heterogeneity and metastatic properties can lead to resistance and limit the effectiveness of standard therapies. Given their significance, CSCs are typically isolated based on combinations of markers, which often indicate heterogeneous populations of CSCs. The lack of consensus in cell characterization poses challenges in defining and targeting these cells for effective therapeutic interventions. In this review, we suggest five promising molecules—ABCB5, CD26, CD66c, uPAR, and Trop-2—chosen specifically for their distinct distribution within cancer types and clinical relevance. These markers, expressed at the cell surface of CSCs, could significantly enhance the specificity of cancer stemness characterization. This review focuses on describing their pivotal roles as biomarker checkpoints for metastasis. Additionally, this review outlines existing literature on glycosylation modifications, which present intriguing epitopes aimed at modulating the stability and function of these markers. Finally, we summarize several promising in vivo and clinical trial approaches targeting the mentioned surface markers, offering potential solutions to overcome the therapeutic resistance of CSCs and addressing current gaps in treatment strategies.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2020008

Authors: Jiuhui Wang Yande Guo Xiangwei Fang Yuanqin Zhang Daotai Nie

Short-chain fatty acids (SCFAs), derived from fermentation of dietary fibers and resistant starch by the microbiota in the colon, exert multiple effects on colonic functions, including tumor suppressing activities. Our previous studies found that SCFAs induced autophagy in colon cancer cells via downregulating mTOR signaling, but the mechanism involved in mTOR suppression still needs to be defined. In this study, we identified rhabdomyosarcoma 2 associated transcript (RMST), a long non-coding RNA, as a key mediator for SCFAs to suppress mTOR activation in colon cancer cells. RMST could be significantly induced by SCFAs in a time- and dose-dependent manner. RMST, by itself, was sufficient to suppress mTOR signaling and augment autophagosome formation. Depletion of RMST, through siRNA or CRISPR knockdown, reduced the abilities of SCFAs to suppress mTOR activation or to induce autophagic responses. RMST increased the expression level of TSC2, a negative regulator of the mTOR signaling pathway. Our data delineate a novel RMST/TSC2 cellular pathway, enlisted by SCFAs, to modulate mTOR activities in colon cancer cells.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2020007

Authors: Sophie Day-Riley Rebekah M. West Paul D. Brear Marko Hyvönen David R. Spring

CK2 is a protein kinase that plays an important role in numerous cellular pathways involved in cell growth, differentiation, proliferation, and death. Consequently, upregulation of CK2 is implicated in many disease types, in particular cancer. As such, CK2 has gained significant attention as a potential therapeutic target in cancer, and over 40 chemical probes targeting CK2 have been developed in the past decade. In this review, we highlighted several chemical probes that target sites outside the conventional ATP-binding site. These chemical probes belong to different classes of molecules, from small molecules to peptides, and possess different mechanisms of action. Many of the chemical probes discussed in this review could serve as promising new candidates for drugs selectively targeting CK2.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2010006

Authors: Paulo F. Santos António Francisco Ambrósio Hélène Léger

Kinases play crucial roles in the pathophysiology of retinal degenerative diseases. These diseases, such as diabetic retinopathy, age-related macular degeneration, glaucoma, and retinitis pigmentosa, are characterized by progressive degeneration of retinal cells, including photoreceptors, ganglion cells, vascular cells, and retinal pigment epithelium, among others. The involvement of kinases in cell survival and apoptosis, immune responses and inflammation regulation, mitochondrial functions and mitophagy, autophagy, and proteostasis is crucial for maintaining cellular homeostasis and responding to various stressors. This review highlights the importance of studying kinases to better understand their functions and, regulation permitting, enable the identification of novel molecular players or potential drug targets and, consequently, the development of more effective and precise treatments to slow or halt the progression of retinal degenerative diseases.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2010005

Authors: Neera Yadav Sun-Yeou Kim

Tissue transglutaminase2 (TG2) has emerged as a key enigmatic protein in the development of various metabolic and age-related diseases. It catalyzes covalent cross-linking of countless proteins and provides strength to the extracellular matrix and resistance to proteolytic degradation via different pathways, including NF-kβ, TGF-β and PI3K/Akt as the major signaling pathways. The etiology of diabetes and associated diseases has been found to be linked to unbalanced TG2 activity that may not only result in impaired or delayed wound healing in diabetics but also worsen degenerative and metabolic disease conditions. TG2 is usually overexpressed in diabetes, fibrosis, cancer, and neurodegenerative disorders. These TG2-linked diseases are usually associated with prolonged activation of inflammatory pathways. Therefore, reducing the inflammatory mechanisms and improving tissue remodeling appear to be the main treatment strategies to exterminate TG2-linked diseases. The present review aims to deliver a detailed overview of the existing understanding of TG2 in diabetes and associated diseases’ progression, as well as treatment strategies to regulate TG2 tightly and its potential clinical applications. Our research endorses the notion that TG2 can serve as an effective early-stage diagnostic biomarker for metabolic diseases and a therapeutic target for the development of potential drug.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2010004

Authors: Venu Pandit Kailey DeGeorge Anja Nohe

Protein kinase CK2 (CK2) influences one-fifth of the cellular phosphoproteome. It regulates almost all cellular pathways and is thus a critical switch between biological processes within a cell. Inhibition of CK2 reverses oncogene addiction of tumor and alters tumor microenvironment. The success of this strategy and its clinical translation opens new opportunities. Targeting CK2 in musculoskeletal disorders is promising. Clinical manifestations of these disorders include dysfunctional inflammation, dysregulated cell differentiation, and senescence. Processes regulated by CK2 include all of these. Its emerging role in senescence also indicates its function’s centrality in cellular metabolism. This review summarizes considerations for targeting CK2 in musculoskeletal disorders. We have discussed the implications of CK2-regulated processes in musculoskeletal disorders.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2010003

Authors: Omamuyovwi M. Ijomone Ann-Kathrin Weishaupt Vivien Michaelis Olayemi K. Ijomone Julia Bornhorst

Nickel (Ni) and vanadium (V) are characteristic heavy metal constituents of many crude oil blends in Sub-Saharan Africa, and we have previously demonstrated their neurotoxic impact. However, molecular mechanisms driving Ni and V neurotoxicity are still being elucidated. The p38- and ERKs-MAPK pathways, which are mostly known for their involvement in human immune and inflammatory signalling, have been shown to influence an array of neurodevelopmental processes. In the present study, we attempt to elucidate the role of p38- and ERK-MAPK in neurotoxicity after early life exposures to Ni and V using the Caenorhabditis elegans model. Synchronized larvae stage-1 (L1) worms were treated with varying concentrations of Ni and V singly or in combination for 1 h. Our results show Ni induces lethality in C. elegans even at very low concentrations, while much higher V concentrations are required to induce lethality. Furthermore, we identified that loss-of-function of pmk-1 and pmk-3, which are both homologous to human p38-α (MAPK14), is differentially affected by Ni and V exposures. Also, all exposure scenarios triggered significant developmental delays in both wild-type and mutant strains. We also see increased mitochondrial-derived reactive oxygen species following Ni and V exposures in wild-type worms with differential responses in the mutant strains. Additionally, we observed alterations in dopamine and serotonin levels after metal exposures, particularly in the pmk-1 strain. In conclusion, both Ni and V induce lethality, developmental delays, and mitochondrial-derived ROS in worms, with V requiring a much higher concentration. Further, the results suggest the p38- and ERK-MAPK signalling pathways may modulate Ni and V neurodevelopmental toxicity, potentially affecting mitochondrial health, metal bioavailability, and neurotransmitter levels.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2010002

Authors: Abdalla M. Abdrabou

IκB kinases (IKKs), specifically IKKα and IKKβ, have long been recognized for their pivotal role in the NF-κB pathway, orchestrating immune and inflammatory responses. However, recent years have unveiled their dual role in cancer, where they can act as both promoters and suppressors of tumorigenesis. In addition, the interplay with pathways such as the MAPK and PI3K pathways underscores the complexity of IKK regulation and its multifaceted role in both inflammation and cancer. By exploring the molecular underpinnings of these processes, we can better comprehend the complex interplay between IKKs, tumor development, immune responses, and the development of more effective therapeutics. Ultimately, this review explores the dual role of IκB kinases in cancer, focusing on the impact of phosphorylation events and crosstalk with other signaling pathways, shedding light on their intricate regulation and multifaceted functions in both inflammation and cancer.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases2010001

Authors: Karla Villalobos-Nova María de los Ángeles Toro Pablo Pérez-Moreno Ignacio Niechi Julio C. Tapia

The endothelin-1 (ET1) peptide has a pathological role in the activation of proliferation, survival and invasiveness pathways in different cancers. ET1’s effects rely on its activation by the endothelin-converting enzyme-1 (ECE1), which is expressed as four isoforms, differing only in their cytoplasmic N-terminuses. We already demonstrated in colorectal cancer, glioblastoma, and preliminarily lung cancer, that the isoform ECE1c heightens aggressiveness by promoting cancer stem cell traits. This is achieved through a non-canonical ET1-independent mechanism of enhancement of ECE1c’s stability upon CK2-dependent phosphorylation at S18 and S20. Here, a K6 residue is presumably responsible for ECE1c ubiquitination as its mutation to R impairs proteasomal degradation. However, how phosphorylation enhances ECE1c’s stability and how this translates into aggressiveness are still open questions. In this brief report, by swapping residues to either phospho-mimetic or phospho-resistant amino acids, we propose that the N-terminus may also be phosphorylated at Y5 and/or T9 by an unknown kinase(s). In addition, N-terminus phosphorylation may lead to a blockage of K6 ubiquitination, increasing ECE1c’s stability and presumably activating the Wnt/β-catenin signaling pathway. Thus, a novel CK2/ECE1c partnership may be emerging to promote aggressiveness and thus become a biomarker of poor prognosis and a potential therapeutic target for several cancers.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1040018

Authors: Christian Werner Dirk Lindenblatt Kaido Viht Asko Uri Karsten Niefind

The structural knowledge about protein kinase CK2 is dominated by crystal structures of human CK2α, the catalytic subunit of human CK2, and the product of the CSNK2A1 gene. In contrast, far fewer structures of CK2α′, its paralogous isoform and the product of the CSNK2A2 gene, have been published. However, according to a PDB survey, CK2α′ is the superior alternative for crystallographic studies because of the inherent potential of the single mutant CK2α′Cys336Ser to provide crystal structures with atomic resolution. In particular, a triclinic crystal form of CK2α′Cys336Ser is a robust tool to determine high-quality enzyme-ligand complex structures via soaking. In this work, further high-resolution CK2α′Cys336Ser structures in complex with selected ligands emphasizing this trend are described. In one of these structures, the “N-terminal segment site”, a small-molecule binding region never found in any eukaryotic protein kinase and holding the potential for the development of highly selective substrate-competitive CK2 inhibitors, was discovered. In order to also address the binding site for the non-catalytic subunit CK2β, which is inaccessible in these triclinic CK2α′Cys336Ser crystals for small molecules, a reliable path to a promising monoclinic crystal form of CK2α′Cys336Ser is presented. In summary, the quality of CK2α′Cys336Ser as an exquisite crystallographic tool is solidified.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1040017

Authors: Han Wee Ong David H. Drewry Alison D. Axtman

Protein kinase casein kinase 2 (CK2/CSNK2) is a pleiotropic kinase involved in many cellular processes and, accordingly, has been identified as a potential target for therapeutic intervention for multiple indications. Significant research effort has been invested into identifying CK2 inhibitors as potential drug candidates and potent and selective CK2 chemical probes to interrogate CK2 function. Here, we review the small molecule inhibitors reported for CK2 and discuss various orthosteric, allosteric, and bivalent inhibitors of CK2. We focus on the pyrazolo[1,5-a]pyrimidines and naphthyridines, two chemotypes that have been extensively explored for chemical probe development. We highlight the uptake and demonstrated utility of the pyrazolo[1,5-a]pyrimidine chemical probe SGC-CK2-1 by the scientific community in cellular studies. Finally, we propose criteria for an ideal in vivo chemical probe for investigating CK2 function in a living organism. While no compound currently meets these metrics, we discuss ongoing and future directions in the development of in vivo chemical probes for CK2.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1040016

Authors: Colin L. Welsh Abigail E. Conklin Lalima K. Madan

Protein kinase A (PKA) signaling exemplifies phosphorylation-based signaling as we understand it today. Its catalytic-subunit structure and dynamics continue to advance our understanding of kinase mechanics as the first protein kinase catalytic domain to be identified, sequenced, cloned, and structurally detailed. The PKA holoenzyme elaborates on the role of its regulatory subunits and maintains our understanding of cAMP-dependent cellular signaling. The activation of PKA holoenzymes by cAMP is an example of specialized protein allostery, emphasizing the relevance of protein binding interfaces, unstructured regions, isoform diversity, and dynamics-based allostery. This review provides the most up-to-date overview of PKA structure and function, including a description of the catalytic and regulatory subunits’ structures. In addition, the structure, activation, and allostery of holoenzymes are covered.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1040015

Authors: Luca Cesaro Angelica Maria Zuliani Valentina Bosello Travain Mauro Salvi

Protein kinase CK2 (formerly known as casein kinase 2 or II), a ubiquitous and constitutively active enzyme, is widely recognized as one of the most pleiotropic serine/threonine kinases. It plays a critical role in numerous signaling pathways, with hundreds of bona fide substrates. However, despite considerable research efforts, our understanding of the entire CK2 substratome and its functional associations with the majority of these substrates is far from being completely deciphered. In this context, we aim to provide an overview of how CK2 recognizes its substrates. We will discuss the pros and cons of the existing methods to manipulate CK2 activity in cells, as well as exploring the dynamic response of substrate phosphorylation to CK2 modulation.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1040014

Authors: Julie Ledoux Marina Botnari Luba Tchertanov

Receptor tyrosine kinase (RTK) KIT is key regulator of cellular signalling, and its deregulation contributes to the development and progression of many serious diseases. Several mutations lead to the constitutive activation of the cytoplasmic domain of KIT, causing the aberrant intracellular signalling observed in malignant tumours. Elucidating the molecular basis of mutation-induced effects at the atomistic level is absolutely required. We report the first dynamic 3D model (DYNASOME) of the full-length cytoplasmic domain of the oncogenic mutant KITD816V generated through unbiased long-timescale MD simulations under conditions mimicking the natural environment of KIT. The comparison of the structural and dynamical properties of multidomain KITD816V with those of wild type KIT (KITWT) allowed us to evaluate the impact of the D816V mutation on each protein domain, including multifunctional well-ordered and intrinsically disordered (ID) regions. The two proteins were compared in terms of free energy landscape and intramolecular coupling. The increased intrinsic disorder and gain of coupling within each domain and between distant domains in KITD816V demonstrate its inherent self-regulated constitutive activation. The search for pockets revealed novel allosteric pockets (POCKETOME) in each protein, KITD816V and KITWT. These pockets open an avenue for the development of new highly selective allosteric modulators specific to KITD816V.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1030013

Authors: Thanih Balbaied Eric Moore

Alkaline phosphatase is a vital enzyme used in separation studies and as a biomarker for liver, bone, and certain cancer conditions. Its stability and specific properties enable insights into enzyme behavior, aiding in the development of detection methods with broader applications in various scientific fields. Alkaline phosphatase has four main isoenzymes: GCAP, IAP, PLAP, and TNAP, each with distinct roles. TNAP is found in the liver, kidney, and bones, playing a role in bone mineralization. The functions of the other isoenzymes are not fully known. Separation techniques like electrophoresis and chromatography are valuable for studying enzymes and proteins, revealing insights into their structure and function in pharmaceutical research and PTM studies. The main goal of this review paper is to thoroughly evaluate how capillary electrophoresis is applied to analyze alkaline phosphatase. It seeks to investigate the latest advancements in capillary electrophoresis and how they can improve the sensitivity, selectivity, and efficiency of alkaline phosphatase analysis.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1030012

Authors: Verónica Rey Isaac Tamargo-Gómez

Adenosine Monophosphate-Activated Protein Kinase (AMPK) is the major conserved regulator of cellular metabolism in eukaryotic cells, from yeast to mammals. Given its pivotal role, it is not surprising that alterations in its function may contribute to the pathogenesis of numerous human diseases. Indeed, AMPK has become a promising therapeutic target for several pathologies. In this context, significant efforts have been dedicated to discovering new pharmacological agents capable of activating AMPK based on next-generation sequencing (NGS) technology and personalized medicine. Thanks to computational methodologies and high-throughput screening, the identification of small molecules and compounds with the potential to directly activate AMPK or modulate its intricate signaling network has become viable. However, the most widely used drug to activate AMPK in human patients is still metformin, which has shown promising results in the treatment of various diseases, such as type II diabetes, atherosclerosis, Alzheimer’s disease, Huntington’s disease, and several types of cancer. In this review, we present a comprehensive analysis of the involvement of AMPK in human pathology, emphasizing its significant potential as a therapeutic target.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1030011

Authors: Samantha Y. Hayashi Barbara P. Craddock W. Todd Miller

Ack1 is a nonreceptor tyrosine kinase that is associated with cellular proliferation and survival. The receptor tyrosine kinase Mer, a member of the TAM family of receptors, has previously been reported to be an upstream activator of Ack1 kinase. The mechanism linking the two kinases, however, has not been investigated. We confirmed that Ack1 and Mer interact by co-immunoprecipitation experiments and found that Mer expression led to increased Ack1 activity. The effect on Ack1 was dependent on the kinase activity of Mer, whereas mutation of the Mer C-terminal tyrosines Y867 and Y924 did not significantly decrease the ability of Mer to activate Ack1. Ack1 possesses a Mig6 Homology Region (MHR) that contains adjacent regulatory tyrosines (Y859 and Y860). Using synthetic peptides, we showed that Mer preferentially binds and phosphorylates the MHR sequence containing phosphorylated pY860, as compared to the pY859 sequence. This suggested the possibility of sequential phosphorylation within the MHR of Ack1, as has been observed previously for other kinases. In cells co-expressing Mer and Ack1 MHR mutants, the Y859F mutant had higher activity than the Y860F mutant, consistent with this model. The interaction between Mer and Ack1 could play a role in immune cell signaling in normal physiology and could also contribute to the hyperactivation of Ack1 in prostate cancer and other tumors.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1030010

Authors: Andréa Hemmerlin

The recycling of metabolic products is a major way to reduce the energy cost of de novo biosynthesis. The salvage pathways involved not only regain a metabolic product but also generate additional molecules that might serve specific physiological, developmental and/or defensive functions. The isoprenoid pathway is a perfect example of a fine-regulated biosynthetic pathway, by virtue of the large number of molecules with different functions that must be synthesized simultaneously. Additionally, isoprenoid salvage pathways have been characterized. Thus, to produce isoprenoid precursors such as farnesyl diphosphate or phytyl diphosphate, short-chain isoprenols recovered from end-chain metabolites are phosphorylated. In the first instance, the so-called FPP-salvage machinery recycles farnesyl diphosphate from proteolyzed farnesylated proteins. In a second example, phytyl diphosphate is recycled from degraded chlorophyll, to be used for the biosynthesis of vitamin E. Both compounds are recovered as alcohols and require two phosphorylation events to be reactivated and reintegrated into the isoprenoid biosynthetic pathway. This review covers current knowledge of isoprenol biosynthesis, metabolism and function, as well as potential benefits of recycling pathways for plants, with a particular focus on stress responses.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1020009

Authors: Camila Paz Quezada Meza Maria Ruzzene

Protein kinase CK2 is a Ser/Thr protein kinase that phosphorylates hundreds of substrates mainly related to survival and proliferation pathways. It has long been considered an anti-cancer drug target. However, during the recent COVID-19 pandemic, CK2 inhibitors have been repurposed as anti-SARS-CoV-2 drugs. This was based on the initial finding of CK2 among the proteins of the host cell that interact with the viral proteins and modulate the infection. Since then, several studies have deepened our understanding of the CK2/COVID-19 connection, and we deem it is time to review all the findings. Interestingly, other coronaviruses cross-talk with CK2 as well, with similarities and differences compared to the SARS-CoV-2 case. Therefore, we believe that the analysis of the effects obtained by targeting CK2 in case of coronavirus infections, both at the molecular and phenomenological level, will help in extrapolating information that could be useful not only for COVID-19 (whose pandemic emergency is hopefully turning off) but also for other infections.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1020008

Authors: Soham Choudhuri Manas Yendluri Sudip Poddar Aimin Li Koushik Mallick Saurav Mallik Bhaswar Ghosh

The goal of drug discovery is to uncover new molecules with specific chemical properties that can be used to cure diseases. With the accessibility of machine learning techniques, the approach used in this search has become a significant component in computer science in recent years. To meet the Precision Medicine Initiative’s goals and the additional obstacles that they have created, it is vital to develop strong, consistent, and repeatable computational approaches. Predictive models based on machine learning are becoming increasingly crucial in preclinical investigations. In discovering novel pharmaceuticals, this step substantially reduces expenses and research times. The human kinome contains various kinase enzymes that play vital roles through catalyzing protein phosphorylation. Interestingly, the dysregulation of kinases causes various human diseases, viz., cancer, cardiovascular disease, and several neuro-degenerative disorders. Thus, inhibitors of specific kinases can treat those diseases through blocking their activity as well as restoring normal cellular signaling. This review article discusses recent advancements in computational drug design algorithms through machine learning and deep learning and the computational drug design of kinase enzymes. Analyzing the current state-of-the-art in this sector will offer us a sense of where cheminformatics may evolve in the near future and the limitations and beneficial outcomes it has produced. The approaches utilized to model molecular data, the biological problems addressed, and the machine learning algorithms employed for drug discovery in recent years will be the emphasis of this review.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1020007

Authors: Arathi Nair Bhaskar Saha

Ras, a GTP-GDP binary switch protein, transduces signals from diverse receptors to regulate various signaling networks. Three Ras genes encode for protein isoforms, namely, Harvey Ras (H-Ras), Kirsten Ras (K-Ras, with two splice variants, K-Ras4A and K-Ras4B), and Neuroblastoma Ras (N-Ras). The isoforms undergo a series of post-translational modifications that enable their membrane attachment and biological activity. The activation of Ras isoforms is tightly regulated, and any dysregulation affects cellular processes, such as cell division, apoptosis, differentiation, cell migration, etc. The Ras gene is highly prone to mutation, and ~30% of cancers carry somatic mutations in Ras, whereas germline mutations clinically manifest as various rasopathies. In addition to regulation by the Guanine nucleotide exchange factors and the GTPase activation proteins, Ras signaling, and localization are also regulated by phosphorylation-dephosphorylation, ubiquitination, nitrosylation, and acetylation. Herein, we review the regulation of Ras signaling and localization by various regulatory enzymes in depth and assess the current status of Ras drug discovery targeting these regulatory enzymes.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1010006

Authors: Tadeu L. Montagnoli Daniela R. de Oliveira Carlos A. Manssour Fraga

Cerebral cavernous malformations (CCM) are developmental venous dysplasias which present as abnormally dilated blood vessels occurring mainly in the brain. Alterations in vascular biology originate from somatic mutations in genes regulating angiogenesis and endothelial-to-mesenchymal transition. Vascular lesions may occur at any time and develop silently, remaining asymptomatic for years. However, symptomatic disease is often debilitating, and patients are prone to develop drug-resistant epilepsy and hemorrhages. There is no cure, and surgical treatment is recommended only for superficial lesions on cortical areas. The study of lesion biology led to the identification of different pathways related to disease onset and progression, of which RhoA/Rho-associated protein kinase (ROCK) shows activation in different subsets of patients. This work will explore the current knowledge about the involvement of ROCK in the many aspects of CCM disease, including isoform-specific actions, and delineate the recent development of ROCK inhibitors for CNS-targeted diseases.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1010005

Authors: Julie Ledoux Luba Tchertanov

The kinase insert domain (KID) of RTK KIT is a key recruitment region for downstream signalling proteins (DSPs). KID, as a multisite phosphorylation region, provides alternative recognition sites for DSPs and activates them by binding a phosphotyrosine (pY) to their SH2 domains. Significant steric, biochemical, and biophysical requirements must be fulfilled by each pair of interacting proteins as the adaptation of their configurations is mandatory for the selective activation of DSPs. The accurate 3D atomistic models obtained by modelling and molecular dynamics (MD) simulations of phosphorylated KID (p-KID) have been delivered to describe KID INTERACTOME. By taking phosphorylated KIDpY721 and the N-terminal SH2 domain of phosphatidylinositol 3-kinase (PI3K), a physiological partner of KID, we showed the two proteins are intrinsically disordered. Using 3D models of both proteins, we probe alternative orientations of KIDpY721 relative to the SH2 binding pocket using automatic docking (HADDOCK) and intuitive user-guided docking. This modelling yields to two possible models of the functionally related non-covalent complex KIDpY721/SH2, where one can be regarded as the first precursor to probe PI3K activation via KIT KID. We suggest that such generation of a KID/SH2 complex is best suited for future studies of the post-transduction effects of RTK KIT.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1010004

Authors: Pathum M. Weerawarna Timothy I. Richardson

LYN proto-oncogene, Src family tyrosine kinase (Lyn) is a tyrosine kinase that belongs to the Src family (SFK). It is expressed as two isoforms in humans, LynA and LynB. Like other SFKs, Lyn consists of five protein domains, an N-terminal SH4 domain followed by a unique domain, the SH3 and SH2 domains, and a catalytic SH1 domain. The autophosphorylation of Tyr397 activates the protein, while the phosphorylation of the C-terminal inhibitory Tyr508 by C-terminal Src kinase (Csk) or Csk homologous kinase (Chk) inhibits the catalytic activity. The interaction of the SH2 domain with the phosphorylated Tyr508 stabilizes a compact, self-inhibited state. The interaction of the SH3 domain with a linker between the SH2 and catalytic domains further stabilizes this inactive conformation. The two critical structural features of the catalytic domain are a conserved DFG moiety and the αC helix, which can adopt in or out conformations. In the active state, both the DFG moiety and αC helix adopt in conformations, while in the inactive state, they adopt out conformations. Lyn has well-established functions in various hematopoietic cell types and more recent studies have revealed its roles in non-hematopoietic cells. At the molecular level, these functions are mainly exerted by phosphorylating specific tyrosine residues in immunoreceptor tyrosine-based inhibitory motifs (ITIMs) and immunoreceptor tyrosine-based activator motifs (ITAMs) associated with cell surface receptors. The phosphorylation of ITAMs by Lyn can initiate either activating or inhibitory (ITAMi) cell signaling depending on the receptor, targeting mode (crosslinking or monovalent targeting), and the cellular context. The phosphorylation of ITIMs by Lyn initiates inhibitory cell signaling via the recruitment of phosphatases to the ITIM-bearing receptor. The role of Lyn in cancer and autoimmune diseases has been extensively discussed in the literature. The involvement of Lyn in neurodegenerative diseases has been described more recently and, as such, it is now an emerging target for the treatment of neurodegenerative diseases.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1010003

Authors: Susumu Tanaka Yoshiko Honda Misa Sawachika Kensuke Futani Namika Yoshida Tohru Kodama

Serine/threonine-protein kinase 16 (STK16) is a novel member of the Numb-associated family of protein kinases with an atypical kinase domain. In this study, we aimed to investigate the involvement of STK16 in sleep–wake mechanisms. We confirmed the expression of Stk16 in the murine hypothalamus, the sleep–wake center, and found considerable changes in STK16 protein levels in the anterior hypothalamus during the light–dark cycle. We found that the coexistence of the potassium channel tetramerization domain containing 17 (KCTD17), an STK16 interactor, caused STK16 degradation. In contrast, the proteasome inhibitor MG132 inhibited the degradation of STK16. In addition, polyubiquitinated STK16 was observed, suggesting that KCTD17 acts as an adapter for E3 ligase to recognize STK16 as a substrate, leading to STK16 degradation via the ubiquitin–proteasome system. The vast changes in STK16 in the anterior hypothalamus, a mammalian sleep center, as well as the reported sleep abnormalities in the ubiquitin B knockout mice and the Drosophila with the inhibition of the KCTD17 homolog or its E3 ligase cullin-3, suggest that STK16 plays a major role in sleep–wake regulation.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1010002

Authors: Hajar Yaakoub Sara Mina Agnès Marot Nicolas Papon Alphonse Calenda Jean-Philippe Bouchara

Scedosporium species are opportunistic filamentous fungi found in human-impacted areas. Clinically relevant species, such as S. apiospermum, rank as the second most frequent colonizers of the airways of patients with cystic fibrosis (CF), which are characterized by persistent oxidative stress. This raises the question of how Scedosporium species abate conditions imposed in hostile environments. Since the High Osmolarity Glycerol (HOG) pathway plays a central role in fungal adaptation to stress, we aimed to pheno-profile the involvement of the pathway in response to stress in S. apiospermum using Western blot. We show for the first time that a wide range of stress distinctively activates the HOG pathway in S. apiospermum, including oxidants (H2O2, menadione, cumene hydroperoxide, diamide, paraquat, and honokiol), osmotic agents (sorbitol and KCl), cell-wall stress agents (caffeine, calcofluor white, and Congo Red), heavy metals (cadmium and arsenite), fungicides (fludioxonil and iprodione), antifungals (voriconazole and amphotericin B), and acid stress (pH 4). We suggest that the function of the HOG pathway as a general stress regulator is also conserved in S. apiospermum.

Kinases and Phosphatases doi: 10.3390/kinasesphosphatases1010001

Authors: Mauro Salvi

On behalf of all the Editorial Board members and the MDPI staff, I’m pleased to announce the publishing of the inaugural issue of the Kinases and Phosphatases journal [...]