scholarly journals STOICHIOMETRY OF THE SODIUM PUMP-PHOSPHOLEMMAN REGULATORY COMPLEX

2021 ◽  
Author(s):  
Jaroslava Seflova ◽  
Nima R. Habibi ◽  
John Q. Yap ◽  
Sean R. Cleary ◽  
Xuan Fang ◽  
...  
Keyword(s):  
Structural Model ◽  
Alpha Subunit ◽  
Beta Subunits ◽  
Intact Cells ◽  
Sodium Potassium ◽  
Catalytic Subunits ◽  
Regulatory Subunits ◽  
Physiological Processes ◽  
Regulatory Complex ◽  
Dynamics Simulations

The sodium-potassium ATPase (NKA) establishes ion gradients that facilitate many physiological processes. In the heart, NKA activity is regulated by its interaction with phospholemman (PLM, FXYD1). Here we used a novel fluorescence lifetime-based assay to investigate the structure, stoichiometry, and affinity of the NKA-PLM regulatory complex. We observed concentration dependent association of the subunits of NKA-PLM regulatory complex, with avid association of the alpha subunit with the essential beta subunit followed by lower affinity alpha-alpha and alpha-PLM interactions. The data provide the first evidence that the regulatory complex is composed of two alpha subunits associated with two beta subunits, decorated with two PLM regulatory subunits in intact cells. Docking and molecular dynamics simulations generated a structural model of the complex that is consistent with our experimental observations. We propose that alpha-alpha subunit interactions support conformational coupling of the catalytic subunits, which may enhance NKA turnover rate. These observations provide insight into the pathophysiology of heart failure, wherein low NKA expression may be insufficient to support formation of the complete regulatory complex with stoichiometry (alpha-beta-PLM)2.

Isolation, sequencing, and disruption of the yeast CKA2 gene: casein kinase II is essential for viability in Saccharomyces cerevisiae

1990 ◽  
Vol 10 (8) ◽  
pp. 4089-4099 ◽  
Author(s):  
R Padmanabha ◽  
J L Chen-Wu ◽  
D E Hanna ◽  
C V Glover
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Growth Arrest ◽  
Casein Kinase Ii ◽  
Gene Replacement ◽  
Casein Kinase ◽  
Alpha Subunit ◽  
Beta Subunits ◽  
Catalytic Subunits ◽  
Yeast Strains ◽  
Cell Biol

Casein kinase II of Saccharomyces cerevisiae contains two distinct catalytic subunits, alpha and alpha', which are encoded by the CKA1 and CKA2 genes, respectively. Null mutations in the CKA1 gene do not confer a detectable phenotype (J. L.-P. Chen-Wu, R. Padmanabha, and C. V. C. Glover, Mol. Cell. Biol. 8:4981-4990, 1988), presumably because of the presence of the CKA2 gene. We report here the cloning, sequencing, and disruption of the CKA2 gene. The alpha' subunit encoded by the CKA2 gene is 60% identical to the CKA1-encoded alpha subunit and 55% identical to the Drosophila alpha subunit (A. Saxena, R. Padmanabha, and C. V. C. Glover, Mol. Cell. Biol. 7:3409-3417, 1987). Deletions of the CKA2 gene were constructed by gene replacement techniques. Haploid cells in which the CKA2 gene alone is disrupted show no detectable phenotype, but haploid cells carrying disruptions in both the CKA1 and CKA2 genes are inviable. Cells in which casein kinase II activity is depleted increase substantially in size prior to growth arrest, and a significant fraction of the arrested cells exhibit a pseudomycelial morphology. Disruption of the activity also results in flocculation. Yeast strains lacking both endogenous catalytic subunit genes can be rescued by expression of the alpha and beta subunits of Drosophila casein kinase II or by expression of the Drosophila alpha subunit alone, suggesting that casein kinase II function has been conserved through evolution.

scholarly journals Protein kinase activity of the insulin receptor

1986 ◽  
Vol 235 (1) ◽  
pp. 1-11 ◽  
Author(s):  
S Gammeltoft ◽  
E Van Obberghen
Keyword(s):  
Insulin Receptor ◽  
Molecular Mechanisms ◽  
Kinase Activity ◽  
Beta Subunit ◽  
Alpha Subunit ◽  
Beta Subunits ◽  
Protein Kinase Activity ◽  
Intact Cells ◽  
Receptor Complexes ◽  
Alpha Subunits

The insulin receptor is an integral membrane glycoprotein (Mr approximately 300,000) composed of two alpha-subunits (Mr approximately 130,000) and two beta-subunits (Mr approximately 95,000) linked by disulphide bonds. This oligomeric structure divides the receptor into two functional domains such that alpha-subunits bind insulin and beta-subunits possess tyrosine kinase activity. The amino acid sequence deduced from cDNA of the single polypeptide chain precursor of human placental insulin receptor revealed that alpha- and beta-subunits consist of 735 and 620 residues, respectively. The alpha-subunit is hydrophilic, disulphide-bonded, glycosylated and probably extracellular. The beta-subunit consists of a short extracellular region which links the alpha-subunit through disulphide bridges, a hydrophobic transmembrane region and a longer cytoplasmic region which is structurally homologous with other tyrosine kinases like the src oncogene product and EGF receptor kinases. The cellular function of insulin receptors is dual: transmembrane signalling and endocytosis of hormone. The binding of insulin to its receptor on the cell membrane induces transfer of signal from extracellular to cytoplasmic receptor domains leading to activation of cell metabolism and growth. In addition, hormone-receptor complexes are internalized leading to intracellular proteolysis of insulin, whereas receptors are recycled to the membrane. These phenomena are kinetically well-characterized, but their molecular mechanisms remain obscure. Insulin receptor in different tissues and animal species are homologous in their structure and function, but show also significant differences regarding size of alpha-subunits, binding kinetics, insulin specificity and receptor-mediated degradation. We suggest that this heterogeneity of receptors may be linked to the diversity in insulin effects on metabolism and growth in various cell types. The purified insulin receptor phosphorylates its own beta-subunit and exogenous protein and peptide substrates on tyrosine residues, a reaction which is insulin-sensitive, Mn2+-dependent and specific for ATP. Tyrosine phosphorylation of the beta-subunit activates receptor kinase activity, and dephosphorylation with alkaline phosphatase deactivates the kinase. In intact cells or impure receptor preparations, a serine kinase is also activated by insulin. The cellular role of two kinase activities associated with the insulin receptor is not known, but we propose that the tyrosine- and serine-specific kinases mediate insulin actions on metabolism and growth either through dual-signalling or sequential pathways.(ABSTRACT TRUNCATED AT 400 WORDS)

scholarly journals Isolation, sequencing, and disruption of the yeast CKA2 gene: casein kinase II is essential for viability in Saccharomyces cerevisiae.

1990 ◽  
Vol 10 (8) ◽  
pp. 4089-4099 ◽  
Author(s):  
R Padmanabha ◽  
J L Chen-Wu ◽  
D E Hanna ◽  
C V Glover
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Growth Arrest ◽  
Casein Kinase Ii ◽  
Gene Replacement ◽  
Casein Kinase ◽  
Alpha Subunit ◽  
Beta Subunits ◽  
Catalytic Subunits ◽  
Yeast Strains ◽  
Cell Biol

Casein kinase II of Saccharomyces cerevisiae contains two distinct catalytic subunits, alpha and alpha', which are encoded by the CKA1 and CKA2 genes, respectively. Null mutations in the CKA1 gene do not confer a detectable phenotype (J. L.-P. Chen-Wu, R. Padmanabha, and C. V. C. Glover, Mol. Cell. Biol. 8:4981-4990, 1988), presumably because of the presence of the CKA2 gene. We report here the cloning, sequencing, and disruption of the CKA2 gene. The alpha' subunit encoded by the CKA2 gene is 60% identical to the CKA1-encoded alpha subunit and 55% identical to the Drosophila alpha subunit (A. Saxena, R. Padmanabha, and C. V. C. Glover, Mol. Cell. Biol. 7:3409-3417, 1987). Deletions of the CKA2 gene were constructed by gene replacement techniques. Haploid cells in which the CKA2 gene alone is disrupted show no detectable phenotype, but haploid cells carrying disruptions in both the CKA1 and CKA2 genes are inviable. Cells in which casein kinase II activity is depleted increase substantially in size prior to growth arrest, and a significant fraction of the arrested cells exhibit a pseudomycelial morphology. Disruption of the activity also results in flocculation. Yeast strains lacking both endogenous catalytic subunit genes can be rescued by expression of the alpha and beta subunits of Drosophila casein kinase II or by expression of the Drosophila alpha subunit alone, suggesting that casein kinase II function has been conserved through evolution.

scholarly journals PRKAR2A deficiency protects mice from experimental colitis by increasing IFN-stimulated gene expression and modulating the intestinal microbiota

2021 ◽  
Author(s):  
Lumin Wei ◽  
Rongjing Zhang ◽  
Jinzhao Zhang ◽  
Juanjuan Li ◽  
Deping Kong ◽  
...  
Keyword(s):  
Experimental Colitis ◽  
Regulatory Subunit ◽  
Protective Effects ◽  
Intestinal Epithelial ◽  
Catalytic Subunits ◽  
Regulatory Subunits ◽  
Pka Regulatory Subunit ◽  
Cross Fostering ◽  
Specific Deletion

AbstractProtein kinase A (PKA) plays an important role in regulating inflammation via its catalytic subunits. Recently, PKA regulatory subunits have been reported to directly modulate some signaling pathways and alleviate inflammation. However, the role of PKA regulatory subunits in colonic inflammation remains unclear. Therefore, we conducted this study to investigate the role of the PKA regulatory subunit PRKAR2A in colitis. We observed that PRKAR2A deficiency protected mice from dextran sulfate sodium (DSS)-induced experimental colitis. Our experiments revealed that the intestinal epithelial cell-specific deletion of Prkar2a contributed to this protection. Mechanistically, the loss of PRKAR2A in Prkar2a−/− mice resulted in an increased IFN-stimulated gene (ISG) expression and altered gut microbiota. Inhibition of ISGs partially reversed the protective effects against DSS-induced colitis in Prkar2a−/− mice. Antibiotic treatment and cross-fostering experiments demonstrated that the protection against DSS-induced colitis in Prkar2a−/− mice was largely dependent on the gut microflora. Altogether, our work demonstrates a previously unidentified function of PRKAR2A in promoting DSS-induced colitis.

scholarly journals Interaction with Tap42 Is Required for the Essential Function of Sit4 and Type 2A Phosphatases

2003 ◽  
Vol 14 (11) ◽  
pp. 4342-4351 ◽  
Author(s):  
Huamin Wang ◽  
Xiaodong Wang ◽  
Yu Jiang
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Amino Acid ◽  
Amino Acid Substitution ◽  
Binding Domain ◽  
Charge Amino Acid ◽  
Catalytic Subunits ◽  
Regulatory Subunits ◽  
Terminal Domain ◽  
Major Form ◽  
Essential Function

In Saccharomyces cerevisiae, Pph21 and Pph22 are the two catalytic subunits of type 2A phosphatase (PP2Ac), and Sit4 is a major form of 2A-like phosphatase. The function of these phosphatases requires their association with different regulatory subunits. In addition to the conventional regulatory subunits, namely, the A and B subunits for Pph21/22 and the Sap proteins for Sit4, these phosphatases have been found to associate with a protein termed Tap42. In this study, we demonstrated that Sit4 and PP2Ac interact with Tap42 via an N-terminal domain that is conserved in all type 2A and 2A-like phosphatases. We found that the Sit4 phosphatase in the sit4-102 strain contains a reverse-of-charge amino acid substitution within its Tap42 binding domain and is defective for formation of the Tap42-Sit4 complex. Our results suggest that the interaction with Tap42 is required for the activity as well as for the essential function of Sit4 and PP2Ac. In addition, we showed that Tap42 is able to interact with two other 2A-like phosphatases, Pph3 and Ppg1.

scholarly journals Nothing Regular about the Regulins: Distinct Functional Properties of SERCA Transmembrane Peptide Regulatory Subunits

2021 ◽  
Vol 22 (16) ◽  
pp. 8891
Author(s):  
Nishadh Rathod ◽  
Jessi J. Bak ◽  
Joseph O. Primeau ◽  
M’Lynn E. Fisher ◽  
Lennane Michel Espinoza-Fonseca ◽  
...  
Keyword(s):  
Endoplasmic Reticulum ◽  
Functional Properties ◽  
Transmembrane Helices ◽  
Regulatory Subunits ◽  
Reading Frame ◽  
Endoplasmic Reticulum Calcium ◽  
Cellular Processes ◽  
Functional Consequences ◽  
Differential Binding ◽  
Dynamics Simulations

The sarco-endoplasmic reticulum calcium ATPase (SERCA) is responsible for maintaining calcium homeostasis in all eukaryotic cells by actively transporting calcium from the cytosol into the sarco-endoplasmic reticulum (SR/ER) lumen. Calcium is an important signaling ion, and the activity of SERCA is critical for a variety of cellular processes such as muscle contraction, neuronal activity, and energy metabolism. SERCA is regulated by several small transmembrane peptide subunits that are collectively known as the “regulins”. Phospholamban (PLN) and sarcolipin (SLN) are the original and most extensively studied members of the regulin family. PLN and SLN inhibit the calcium transport properties of SERCA and they are required for the proper functioning of cardiac and skeletal muscles, respectively. Myoregulin (MLN), dwarf open reading frame (DWORF), endoregulin (ELN), and another-regulin (ALN) are newly discovered tissue-specific regulators of SERCA. Herein, we compare the functional properties of the regulin family of SERCA transmembrane peptide subunits and consider their regulatory mechanisms in the context of the physiological and pathophysiological roles of these peptides. We present new functional data for human MLN, ELN, and ALN, demonstrating that they are inhibitors of SERCA with distinct functional consequences. Molecular modeling and molecular dynamics simulations of SERCA in complex with the transmembrane domains of MLN and ALN provide insights into how differential binding to the so-called inhibitory groove of SERCA—formed by transmembrane helices M2, M6, and M9—can result in distinct functional outcomes.

scholarly journals Molecular Determinants of μ-Conotoxin KIIIA Interaction with the Voltage-Gated Sodium Channel Nav1.7

2019 ◽  
Author(s):  
Ian H. Kimball ◽  
Phuong T. Nguyen ◽  
Baldomero M. Olivera ◽  
Jon T. Sack ◽  
Vladimir Yarov-Yarovoy
Keyword(s):  
Computational Modeling ◽  
Rational Design ◽  
Structural Model ◽  
Critical Role ◽  
Structural Data ◽  
Molecular Probes ◽  
Integrative Approach ◽  
In Silico Docking ◽  
Voltage Gated ◽  
Dynamics Simulations

AbstractThe voltage-gated sodium (Nav) channel subtype Nav1.7 plays a critical role in pain signaling, making it an important drug target. Here we studied the molecular interactions between μ-conotoxin KIIIA (KIIIA) and the human Nav1.7 channel (hNav1.7). We developed a structural model of hNav1.7 using Rosetta computational modeling and performed in silico docking of KIIIA using RosettaDock to predict residues forming specific pairwise contacts between KIIIA and hNav1.7. We experimentally validated these contacts using mutant cycle analysis. Comparison between our KIIIA-hNav1.7 model and the recently published cryo-EM structure of KIIIA-hNav1.2 revealed key similarities and differences between channel subtypes with potential implications for the molecular mechanism of toxin block. Our integrative approach, combining structural data with computational modeling, experimental validation, and molecular dynamics simulations will be useful for engineering molecular probes to study Nav channel function, and for rational design of novel biologics targeting specific Nav channels.

Abstract 231: Uncovering the Mechanism and Function of Newly Discovered KCNQ1-Transporter Complexes

2014 ◽  
Vol 115 (suppl_1) ◽  
Author(s):  
Daniel L Neverisky ◽  
Geoffrey W Abbott
Keyword(s):  
Complex Formation ◽  
Cardiac Function ◽  
Glucose Transporter ◽  
Beta Subunits ◽  
Lone Atrial Fibrillation ◽  
Potassium Efflux ◽  
Regulatory Subunits ◽  
And Function ◽  
Solute Transporters ◽  
Normal Cardiac Function

The KCNQ1 voltage-gated potassium channel is essential for human ventricular repolarization, permitting potassium efflux from excited cardiomyocytes to end each action potential and repolarize the heart. In cardiomyocytes, KCNQ1 is modulated by interaction with beta-subunits from the KCNE gene family, each of which significantly alters KCNQ1 channel function. KCNQ1 mutations are the most common identified genetic basis for Long QT syndrome (LQTS) and are also associated with lone atrial fibrillation (AF). The sodium-dependent myo-inositol transporter 1 (SMIT1) mediates cellular uptake of myo-inositol, an essential osmolyte that also represents an important substrate for phosphatidylinositol signaling pathways that regulate a plethora of ion channels including those essential for human cardiac function. We recently discovered that KCNQ1 can form heteromeric, co-regulatory complexes with Na+-coupled solute transporters including SMIT1, SMIT2 and glucose transporter SGLT1. These findings represent the first reported example of formation of an ion channel-solute transporter complex. Having discovered KCNQ1-SMIT1 complexes in mouse choroid plexus epithelium, we are currently investigating whether these types of complexes occur in the heart, how their function is altered by the various cardiac-expressed KCNE regulatory subunits or by arrhythmia-associated mutations, and which parts of KCNQ1 coordinate complex formation. Here, we present evidence of KCNQ1-SMIT1 co-assembly in pig heart based on co-immunoprecipitation experiments. Using KCNQ1-KCNQ4 chimeras we also begin to define which specific regions of KCNQ1 are required for complex formation with SMIT1. Finally, we present data showing the effects of SMIT1 on complexes formed by KCNQ1 and KCNE1, 2 and 3. KCNQ1-transporter complexes provide a potential hub for electrochemical crosstalk in normal cardiac function and in arrhythmogenesis.

Mutational analysis of the functional domains of yeast K1 killer toxin

1991 ◽  
Vol 11 (1) ◽  
pp. 175-181
Author(s):  
H Zhu ◽  
H Bussey
Keyword(s):  
Cell Wall ◽  
Receptor Binding ◽  
Mutational Analysis ◽  
Killer Toxin ◽  
Alpha Subunit ◽  
Functional Domains ◽  
Beta Subunits ◽  
Channel Formation ◽  
Beta Glucan ◽  
Beta Toxin

To determine the functional domains of K1 killer toxin, we analyzed the phenotypes of a set of mutations throughout regions encoding the alpha- and beta-toxin subunits that allow secretion of mutant toxins. A range of techniques have been used to examine the ability of mutant toxins to bind to beta-glucan cell wall receptor and to form lethal ion channels. Our results indicate that both the alpha and beta subunits are involved in beta-glucan receptor binding. Defects in ion channel formation and toxin immunity are confined to the hydrophobic alpha subunit of the toxin.

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