Trend-based analysis of a population model of the AKAP scaffold protein

We formalise a continuous-time Markov chain with multi-dimensional discrete state space model of the AKAP scaffold protein as a crosstalk mediator between two biochemical signalling pathways. The analysis by temporal properties of the AKAP model requires reasoning about whether the counts of individuals of the same type (species) are increasing or decreasing. For this purpose we propose the concept of stochastic trends based on formulating the probabilities of transitions that increase (resp. decrease) the counts of individuals of the same type, and express these probabilities as formulae such that the state space of the model is not altered. We define a number of stochastic trend formulae (e.g. weakly increasing, strictly increasing, weakly decreasing, etc.) and use them to extend the set of state formulae of Continuous Stochastic Logic. We show how stochastic trends can be implemented in a guarded-command style specification language for transition systems. We illustrate the application of stochastic trends with numerous small examples and then we analyse the AKAP model in order to characterise and show causality and pulsating behaviours in this biochemical system

A Flagellar A-Kinase Anchoring Protein with Two Amphipathic Helices Forms a Structural Scaffold in the Radial Spoke Complex

A-kinase anchoring proteins (AKAPs) contain an amphipathic helix (AH) that binds the dimerization and docking (D/D) domain, RIIa, in cAMP-dependent protein kinase A (PKA). Many AKAPs were discovered solely based on the AH–RIIa interaction in vitro. An RIIa or a similar Dpy-30 domain is also present in numerous diverged molecules that are implicated in critical processes as diverse as flagellar beating, membrane trafficking, histone methylation, and stem cell differentiation, yet these molecules remain poorly characterized. Here we demonstrate that an AKAP, RSP3, forms a dimeric structural scaffold in the flagellar radial spoke complex, anchoring through two distinct AHs, the RIIa and Dpy-30 domains, in four non-PKA spoke proteins involved in the assembly and modulation of the complex. Interestingly, one AH can bind both RIIa and Dpy-30 domains in vitro. Thus, AHs and D/D domains constitute a versatile yet potentially promiscuous system for localizing various effector mechanisms. These results greatly expand the current concept about anchoring mechanisms and AKAPs

Protein kinase A (PKA) phosphorylation of Shp2 inhibits its phosphatase activity and modulates ligand specificity.

Pathological cardiac hypertrophy (an increase in cardiac mass resulting from stress-induced cardiac myocyte growth) is a major factor underlying heart failure. Src homology 2 domain-containing phosphatase (Shp2) is critical for cardiac function as mutations resulting in loss of Shp2 catalytic activity are associated with congenital cardiac defects and hypertrophy. We have identified a novel mechanism of Shp2 inhibition that may promote cardiac hypertrophy. We demonstrate that Shp2 is a component of the A-kinase anchoring protein (AKAP)-Lbc complex. AKAP-Lbc facilitates protein kinase A (PKA) phosphorylation of Shp2, which inhibits Shp2 phosphatase activity. We have identified two key amino acids in Shp2 that are phosphorylated by PKA: Thr73 contributes a helix-cap to helix αB within the N-terminal SH2 domain of Shp2, whereas Ser189 occupies an equivalent position within the C-terminal SH2 domain. Utilizing double mutant PKA phospho-deficient (T73A/S189A) and phospho-mimetic (T73D/S189D) constructs, in vitro binding assays, and phosphatase activity assays, we demonstrate that phosphorylation of these residues disrupts Shp2 interaction with tyrosine-phosphorylated ligands and inhibits its protein tyrosine phosphatase activity. Overall, our data indicate that AKAP-Lbc integrates PKA and Shp2 signaling in the heart and that AKAP-Lbc-associated Shp2 activity is reduced in hypertrophic hearts in response to chronic β-adrenergic stimulation and PKA activation. Thus, while induction of cardiac hypertrophy is a multifaceted process, inhibition of Shp2 activity through AKAP-Lbc-anchored PKA is a previously unrecognized mechanism that may promote this compensatory response

ADENYLYL CYCLASE TYPE 9: REGULATION AND CARDIAC FUNCTION

Abnormalities in cardiac stress signaling underlie a number of cardiovascular diseases (e.g. arrhythmias and heart failure). Cardiac stress signaling pathways normally integrate signals from the sympathetic nervous system to promote efficient contraction and relaxation under stress. Sympathetic control through β-adrenergic stimulation is propagated by adenylyl cyclase (AC). AC synthesizes cyclic AMP (cAMP), an important second messenger that initiates signaling pathways to modulate physiological and pathophysiological functions of the heart, including the activation of PKA and subsequent phosphorylation of ion channels, contractile machinery, and stress response proteins that enhance cardiac function. Alterations of cAMP signaling occur in the failing heart and contribute to impaired function. Of the AC isoforms present in adult cardiomyocytes (AC 4, 5, 6, and 9), AC9 is the most divergent in sequence and understudied. The work presented in this dissertation sought to evaluate the direct regulatory properties of AC9 and explores roles for AC9 in heart. To clarify conflicting reports for AC9 regulation, proposed regulators were systematically evaluated, including G-proteins, protein kinases, and forskolin utilizing in vitro and cell based assays. Overall, I conclude that most G-proteins or protein kinases do not directly regulate AC9, except Gαs, in vitro. Although AC9 is forskolin insensitive alone, weak activation by forskolin in the presence of Gαs is possible. AC9 shows significant homodimerization and modest heterodimerization with AC5/6, which may account for the conflicting reports surrounding the regulation of this AC isoform. viii To study the role of AC9 in heart, a mouse model of AC9 genetic deletion was utilized. Although deletion of AC9 reduces less than 3% of total AC activity in heart, Yotiao-associated AC activity is eliminated. AC9-/- mice exhibit no structural abnormalities but show a significant bradycardia and alterations in Doppler echocardiography indicative of grade 1 diastolic dysfunction with preserved ejection fraction. Identification of novel AC9 binding partners, including the small heat shock protein 20 (Hsp20) and Popeye domain containing (Popdc) proteins may contribute to the underlying mechanisms of AC9-/- phenotypes. Collectively, this work suggests that AC9 forms distinct macromolecular complexes that contribute to local cAMP pools important for driving physiological function of the heart

Targeting protein–protein interactions within the cyclic AMP signaling system as a therapeutic strategy for cardiovascular disease

The cAMP signaling system can trigger precise physiological cellular responses that depend on the fidelity of many protein–protein interactions, which act to bring together signaling intermediates at defined locations within cells. In the heart, cAMP participates in the fine control of excitation–contraction coupling, hence, any disregulation of this signaling cascade can lead to cardiac disease. Due to the ubiquitous nature of the cAMP pathway, general inhibitors of cAMP signaling proteins such as PKA, EPAC and PDEs would act non-specifically and universally, increasing the likelihood of serious ‘off target’ effects. Recent advances in the discovery of peptides and small molecules that disrupt the protein–protein interactions that underpin cellular targeting of cAMP signaling proteins are described and discussed

Reciprocal regulation of PKA and rac signaling

Activated G protein-coupled receptors (GPCRs) and receptor tyrosine kinases relay extracellular signals through spatial and temporal controlled kinase and GTPase entities. These enzymes are coordinated by multifunctional scaffolding proteins for precise intracellular signal processing. The cAMP-dependent protein kinase A (PKA) is the prime example for compartmentalized signal transmission downstream of distinct GPCRs. A-kinase anchoring proteins tether PKA to specific intracellular sites to ensure precision and directionality of PKA phosphorylation events. Here, we show that the Rho-GTPase Rac contains A-kinase anchoring protein properties and forms a dynamic cellular protein complex with PKA. The formation of this transient core complex depends on binary interactions with PKA subunits, cAMP levels and cellular GTP-loading accounting for bidirectional consequences on PKA and Rac downstream signaling. We show that GTP-Rac stabilizes the inactive PKA holoenzyme. However, β-adrenergic receptor-mediated activation of GTP-Rac–bound PKA routes signals to the Raf-Mek-Erk cascade, which is critically implicated in cell proliferation. We describe a further mechanism of how cAMP enhances nuclear Erk1/2 signaling: It emanates from transphosphorylation of p21-activated kinases in their evolutionary conserved kinase-activation loop through GTP-Rac compartmentalized PKA activities. Sole transphosphorylation of p21-activated kinases is not sufficient to activate Erk1/2. It requires complex formation of both kinases with GTP-Rac1 to unleash cAMP-PKA–boosted activation of Raf-Mek-Erk. Consequently GTP-Rac functions as a dual kinase-tuning scaffold that favors the PKA holoenzyme and contributes to potentiate Erk1/2 signaling. Our findings offer additional mechanistic insights how β-adrenergic receptor-controlled PKA activities enhance GTP-Rac–mediated activation of nuclear Erk1/2 signaling

PORGY: Strategy-Driven Interactive Transformation of Graphs

This paper investigates the use of graph rewriting systems as a modelling tool, and advocates the embedding of such systems in an interactive environment. One important application domain is the modelling of biochemical systems, where states are represented by port graphs and the dynamics is driven by rules and strategies. A graph rewriting tool's capability to interactively explore the features of the rewriting system provides useful insights into possible behaviours of the model and its properties. We describe PORGY, a visual and interactive tool we have developed to model complex systems using port graphs and port graph rewrite rules guided by strategies, and to navigate in the derivation history. We demonstrate via examples some functionalities provided by PORGY.Comment: In Proceedings TERMGRAPH 2011, arXiv:1102.226

Radial Spoke Proteins of \u3cem\u3eChlamydomonas\u3c/em\u3e Flagella

The radial spoke is a ubiquitous component of `9+2\u27 cilia and flagella, and plays an essential role in the control of dynein arm activity by relaying signals from the central pair of microtubules to the arms. The Chlamydomonas reinhardtii radial spoke contains at least 23 proteins, only 8 of which have been characterized at the molecular level. Here, we use mass spectrometry to identify 10 additional radial spoke proteins. Many of the newly identified proteins in the spoke stalk are predicted to contain domains associated with signal transduction, including Ca2+-, AKAP- and nucleotide-binding domains. This suggests that the spoke stalk is both a scaffold for signaling molecules and itself a transducer of signals. Moreover, in addition to the recently described HSP40 family member, a second spoke stalk protein is predicted to be a molecular chaperone, implying that there is a sophisticated mechanism for the assembly of this large complex. Among the 18 spoke proteins identified to date, at least 12 have apparent homologs in humans, indicating that the radial spoke has been conserved throughout evolution. The human genes encoding these proteins are candidates for causing primary ciliary dyskinesia, a severe inherited disease involving missing or defective axonemal structures, including the radial spokes

The discovery and exploration of a universal targeting mechanism in eukaryotic cells

A wide range of eukaryotic organisms generate motile cilia and flagella. These slender organelles beat rhythmically to move the surrounding fluid or to propel cells in aqueous environment. Organisms use these powerful yet nimble organelles to forage, evade, adapt and mate. The machinery that drives this tightly controlled movement is the sophisticated microtubule-based axoneme. As it is critical for the survival of individual species, this machinery has largely been preserved to the molecular level throughout evolution. Proteomic studies have shown that most proteins in this biological machine consist of molecular modules commonly used in the cell body. But the usage of these modules is clearly diverged in many cases. This defined machinery with diverged applications provides an opportunity to understand the true capacity of the conserved modules. One example is the radial spoke (RS) that controls the oscillatory beating. This macromolecular complex contains complementary molecular modules that are responsible for localizing cAMP-dependent protein kinase (PKA) in the cell body. However, the RS does not have the features that account for the effector mechanisms of PKA and thus the mechanism discovered for localizing PKA has a broader role that has previously not been recognized. The work described in this dissertation discovered that the core of the RS utilizes two similar sets of PKA anchoring modules for four distinct effector mechanisms that underlie the assembly and function of this regulatory complex. These results elucidate the function of this complex and are applicable to more than 600 diverged proteins that also share the docking module of PKA. Some of them have been shown to play vital roles in myriads of cellular reactions ranging from flagellar beating to trans-Golgi trafficking to chromosome modifications. Founded on this discovery, new reagents and assays were engineered. These tools could be used for the exploration of proteins with similar docking and anchoring modules. Together, these findings will accelerate the advancements in the field of anchoring and docking of proteins in the cell