Pasham Parameshwar Reddy

Encoding and Transducing the Synaptic or Extrasynaptic Origin of NMDA Receptor Signals to the Nucleus

The activation of N-methyl-D-aspartate-receptors (NMDARs) in synapses provides plasticity and cell survival signals, whereas NMDARs residing in the neuronal membrane outside synapses trigger neurodegeneration. At present, it is unclear how these opposing signals are transduced to and discriminated by the nucleus. In this study, we demonstrate that Jacob is a protein messenger that encodes the origin of synaptic versus extrasynaptic NMDAR signals and delivers them to the nucleus. Exclusively synaptic, but not extrasynaptic, NMDAR activation induces phosphorylation of Jacob at serine-180 by ERK1/2. Long-distance trafficking of Jacob from synaptic, but not extrasynaptic, sites depends on ERK activity, and association with fragments of the intermediate filament α-internexin hinders dephosphorylation of the Jacob/ERK complex during nuclear transit. In the nucleus, the phosphorylation state of Jacob determines whether it induces cell death or promotes cell survival and enhances synaptic plasticity.

Regulatory and Structural EF-Hand Motifs of Neuronal Calcium Sensor-1 : Mg2+ Modulates Ca2+ Binding, Ca2+-Induced Conformational Changes, and Equilibrium Unfolding Transitions

Neuronal calcium sensor-1 (NCS-1) is a major modulator of Ca(2+) signaling with a known role in neurotransmitter release. NCS-1 has one cryptic (EF1) and three functional (EF2, EF3, and EF4) EF-hand motifs. However, it is not known which are the regulatory (Ca(2+)-specific) and structural (Ca(2+)- or Mg(2+)-binding) EF-hand motifs. To understand the specialized functions of NCS-1, identification of the ionic discrimination of the EF-hand sites is important. In this work, we determined the specificity of Ca(2+) binding using NMR and EF-hand mutants. Ca(2+) titration, as monitored by [(15)N,(1)H] heteronuclear single quantum coherence, suggests that Ca(2+) binds to the EF2 and EF3 almost simultaneously, followed by EF4. Our NMR data suggest that Mg(2+) binds to EF2 and EF3, thereby classifying them as structural sites, whereas EF4 is a Ca(2+)-specific or regulatory site. This was further corroborated using an EF2/EF3-disabled mutant, which binds only Ca(2+) and not Mg(2+). Ca(2+) binding induces conformational rearrangements in the protein by reversing Mg(2+)-induced changes in Trp fluorescence and surface hydrophobicity. In a larger physiological perspective, exchanging or replacing Mg(2+) with Ca(2+) reduces the Ca(2+)-binding affinity of NCS-1 from 90 nM to 440 nM, which would be advantageous to the molecule by facilitating reversibility to the Ca(2+)-free state. Although the equilibrium unfolding transitions of apo-NCS-1 and Mg(2+)-bound NCS-1 are similar, the early unfolding transitions of Ca(2+)-bound NCS-1 are partially influenced in the presence of Mg(2+). This study demonstrates the importance of Mg(2+) as a modulator of calcium homeostasis and active-state behavior of NCS-1.

Calneurons provide a calcium threshold for trans-Golgi network to plasma membrane trafficking

Phosphatidylinositol 4-OH kinase IIIβ (PI-4Kβ) is involved in the regulated local synthesis of phospholipids that are crucial for trans-Golgi network (TGN)-to-plasma membrane trafficking. In this study, we show that the calcium sensor proteins calneuron-1 and calneuron-2 physically associate with PI-4Kβ, inhibit the enzyme profoundly at resting and low calcium levels, and negatively interfere with Golgi-to-plasma membrane trafficking. At high calcium levels this inhibition is released and PI-4Kβ is activated via a preferential association with neuronal calcium sensor-1 (NCS-1). In accord to its supposed function as a filter for subthreshold Golgi calcium transients, neuronal overexpression of calneuron-1 enlarges the size of the TGN caused by a build-up of vesicle proteins and reduces the number of axonal Piccolo-Bassoon transport vesicles, large dense core vesicles that carry a set of essential proteins for the formation of the presynaptic active zone during development. A corresponding protein knockdown has the opposite effect. The opposing roles of calneurons and NCS-1 provide a molecular switch to decode local calcium transients at the Golgi and impose a calcium threshold for PI-4Kβ activity and vesicle trafficking.

Intracellular Calcium Levels Determine Differential Modulation of Allosteric Interactions within G Protein-Coupled Receptor Heteromers

The pharmacological significance of the adenosine A2A receptor (A2AR)-dopamine D2 receptor (D2R) heteromer is well established and it is being considered as an important target for the treatment of Parkinson’s disease and other neuropsychiatric disorders. However, the physiological factors that control its distinctive biochemical properties are still unknown. We demonstrate that different intracellular Ca2+ levels exert a differential modulation of A2AR-D2R heteromer-mediated adenylyl-cyclase and MAPK signaling in striatal cells. This depends on the ability of low and high Ca2+ levels to promote a selective interaction of the heteromer with the neuronal Ca2+-binding proteins NCS-1 and calneuron-1, respectively. These Ca2+-binding proteins differentially modulate allosteric interactions within the A2AR-D2R heteromer, which constitutes a unique cellular device that integrates extracellular (adenosine and dopamine) and intracellular (Ca+2) signals to produce a specific functional response.

AKAP79/150 interacts with the neuronal calcium‐binding protein caldendrin

J. Neurochem. (2012) 122, 714–726.

Dynamic cellular translocation of caldendrin is facilitated by the Ca2+‐myristoyl switch of recoverin

J. Neurochem. (2010) 113, 1150–1162.

Molecular dynamics of the neuronal EF-hand CA2+-sensor Caldendrin

Caldendrin, L- and S-CaBP1 are CaM-like Ca2+-sensors with different N-termini that arise from alternative splicing of the Caldendrin/CaBP1 gene and that appear to play an important role in neuronal Ca2+-signaling. In this paper we show that Caldendrin is abundantly present in brain while the shorter splice isoforms L- and S-CaBP1 are not detectable at the protein level. Caldendrin binds both Ca2+ and Mg2+ with a global Kd in the low µM range. Interestingly, the Mg2+-binding affinity is clearly higher than in S-CaBP1, suggesting that the extended N-terminus might influence Mg2+-binding of the first EF-hand. Further evidence for intra- and intermolecular interactions of Caldendrin came from gel-filtration, surface plasmon resonance, dynamic light scattering and FRET assays. Surprisingly, Caldendrin exhibits very little change in surface hydrophobicity and secondary as well as tertiary structure upon Ca2+-binding to Mg2+-saturated protein. Complex inter- and intramolecular interactions that are regulated by Ca2+-binding, high Mg2+- and low Ca2+-binding affinity, a rigid first EF-hand domain and little conformational change upon titration with Ca2+ of Mg2+-liganted protein suggest different modes of binding to target interactions as compared to classical neuronal Ca2+-sensors.

Kinetic and mechanistic differences in the interactions between caldendrin and calmodulin with AKAP79 suggest different roles in synaptic function.

The kinetic and mechanistic details of the interaction between caldendrin, calmodulin and the B‐domain of AKAP79 were determined using a biosensor‐based approach. Caldendrin was found to compete with calmodulin for binding at AKAP79, indicating overlapping binding sites. Although the AKAP79 affinities were similar for caldendrin (KD = 20 n m) and calmodulin (KD = 30 n m), their interaction characteristics were different. The calmodulin interaction was well described by a reversible one‐step model, but was only detected in the presence of Ca2+. Caldendrin interacted with a higher level of complexity, deduced to be an induced fit mechanism with a slow relaxation back to the initial encounter complex. It interacted with AKAP79 also in the absence of Ca2+, but with different kinetic rate constants. The data are consistent with a similar initial Ca2+‐dependent binding step for the two proteins. For caldendrin, a second Ca2+‐independent rearrangement step follows, resulting in a stable complex. The study shows the importance of establishing the mechanism and kinetics of protein–protein interactions and that minor differences in the interaction of two homologous proteins can have major implications in their functional characteristics. These results are important for the further elucidation of the roles of caldendrin and calmodulin in synaptic function. Copyright

Role of neuronal Ca2+-sensor proteins in Golgi-cell-surface membrane traffic.

The regulated local synthesis of PtdIns4P and PtdIns(4,5)P(2) is crucial for TGN (trans-Golgi network)-plasma membrane trafficking. The activity of PI4Kbeta (phosphoinositide 4-kinase IIIbeta) at the Golgi membrane is a first mandatory step in this process. In addition to PI4Kbeta activity, elevated Ca(2+) levels are also needed for the exit of vesicles from the TGN. The reason for this Ca(2+) requirement is at present unclear. In the present review, we discuss the role of neuronal Ca(2+)-sensor proteins in the regulation of PI4Kbeta and suggest that this regulation might impose a need for elevated Ca(2+) levels for a late step of vesicle assembly.

Caldendrin Directly Couples Postsynaptic Calcium Signals to Actin Remodeling in Dendritic Spines

Compartmentalization of calcium-dependent plasticity allows for rapid actin remodeling in dendritic spines. However, molecular mechanisms for the spatio-temporal regulation of filamentous actin (F-actin) dynamics by spinous Ca2+-transients are still poorly defined. We show that the postsynaptic Ca2+ sensor caldendrin orchestrates nano-domain actin dynamics that are essential for actin remodeling in the early phase of long-term potentiation (LTP). Steep elevation in spinous [Ca2+]i disrupts an intramolecular interaction of caldendrin and allows cortactin binding. The fast on and slow off rate of this interaction keeps cortactin in an active conformation, and protects F-actin at the spine base against cofilin-induced severing. Caldendrin gene knockout results in higher synaptic actin turnover, altered nanoscale organization of spinous F-actin, defects in structural spine plasticity, LTP, and hippocampus-dependent learning. Collectively, the data indicate that caldendrin-cortactin directly couple [Ca2+]i to preserve a minimal F-actin pool that is required for actin remodeling in the early phase of LTP.