Gopala Krishna Aradhyam scite author profile

BackgroundG protein-coupled receptors (GPCRs) constitute a large family of integral transmembrane receptor proteins that play a central role in signal transduction in eukaryotes. The genome of the protochordate Ciona intestinalis has a compact size with an ancestral complement of many diversified gene families of vertebrates and is a good model system for studying protochordate to vertebrate diversification. An analysis of the Ciona repertoire of GPCRs from a comparative genomic perspective provides insight into the evolutionary origins of the GPCR signalling system in vertebrates.ResultsWe have identified 169 gene products in the Ciona genome that code for putative GPCRs. Phylogenetic analyses reveal that Ciona GPCRs have homologous representatives from the five major GRAFS (Glutamate, Rhodopsin, Adhesion, Frizzled and Secretin) families concomitant with other vertebrate GPCR repertoires. Nearly 39% of Ciona GPCRs have unambiguous orthologs of vertebrate GPCR families, as defined for the human, mouse, puffer fish and chicken genomes. The Rhodopsin family accounts for ~68% of the Ciona GPCR repertoire wherein the LGR-like subfamily exhibits a lineage specific gene expansion of a group of receptors that possess a novel domain organisation hitherto unobserved in metazoan genomes.ConclusionComparison of GPCRs in Ciona to that in human reveals a high level of orthology of a protochordate repertoire with that of vertebrate GPCRs. Our studies suggest that the ascidians contain the basic ancestral complement of vertebrate GPCR genes. This is evident at the subfamily level comparisons since Ciona GPCR sequences are significantly analogous to vertebrate GPCR subfamilies even while exhibiting Ciona specific genes. Our analysis provides a framework to perform future experimental and comparative studies to understand the roles of the ancestral chordate versions of GPCRs that predated the divergence of the urochordates and the vertebrates.

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Calcium binding studies of peptides of human phospholipid scramblases 1 to 4 suggest that scramblases are new class of calcium binding proteins in the cell

Sahu

Aradhyam

Gummadi

2009

Biochimica et Biophysica Acta (BBA) - General Subjects

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Ion‐binding properties of Calnuc, Ca²⁺ versus Mg²⁺– Calnuc adopts additional and unusual Ca²⁺‐binding sites upon interaction with G‐protein

Kanuru¹,

Samuel²,

Balivada³

et al. 2009

The FEBS Journal

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Calnuc is a novel, highly modular, EF‐hand containing, Ca2+‐binding, Golgi resident protein whose functions are not clear. Using amino acid sequences, we demonstrate that Calnuc is a highly conserved protein among various organisms, from Ciona intestinalis to humans. Maximum homology among all sequences is found in the region that binds to G‐proteins. In humans, it is known to be expressed in a variety of tissues, and it interacts with several important protein partners. Among other proteins, Calnuc is known to interact with heterotrimeric G‐proteins, specifically with the α‐subunit. Herein, we report the structural implications of Ca2+ and Mg2+ binding, and illustrate that Calnuc functions as a downstream effector for G‐protein α‐subunit. Our results show that Ca2+ binds with an affinity of 7 μm and causes structural changes. Although Mg2+ binds to Calnuc with very weak affinity, the structural changes that it causes are further enhanced by Ca2+ binding. Furthermore, isothermal titration calorimetry results show that Calnuc and the G‐protein bind with an affinity of 13 nm. We also predict a probable function for Calnuc, that of maintaining Ca2+ homeostasis in the cell. Using Stains‐all and terbium as Ca2+ mimic probes, we demonstrate that the Ca2+‐binding ability of Calnuc is governed by the activity‐based conformational state of the G‐protein. We propose that Calnuc adopts structural sites similar to the ones seen in proteins such as annexins, c2 domains or chromogrannin A, and therefore binds more calcium ions upon binding to Giα. With the number of organelle‐targeted G‐protein‐coupled receptors increasing, intracellular communication mediated by G‐proteins could become a new paradigm. In this regard, we propose that Calnuc could be involved in the downstream signaling of G‐proteins.

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The Differential Response to Ca²⁺from Vertebrate and Invertebrate Calumenin Is Governed by a Single Amino Acid Residue

Narayanasamy

Aradhyam

2018

Biochemistry

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Calumenin (Calu) is a well-conserved multi-EF-hand-containing Ca-binding protein. In this work, we focused on the alterations that calumenin has undergone during evolution. We demonstrate that vertebrate calumenin is significantly different from its invertebrate homologues with respect to its response to Ca binding. Human calumenin (HsCalu1) is intrinsically unstructured in the Ca free form and responds to Ca with a dramatic gain in structure. Calumenin from Caenorhabditis elegans (CeCalu) is structured even in the apo form, with no conformational change upon binding of Ca. We decode this structural and functional distinction by identifying a single "Leu" residue-based switch located in the fourth EF-hand of HsCalu1, occupied by "Gly" in the invertebrate homologues. We demonstrate that replacing Leu with Gly (L150G) in HsCalu1 enables the protein to adopt a structural fold even in the Ca free form, similar to CeCalu, leading to ligand compensation (adoption of structure in the absence of Ca). The fourth (of seven) EF-hand of HsCalu1 nucleates the structural fold of the protein depending on the switch residue (Gly or Leu). Our analyses reveal that the Leu that replaced Gly from fishes onward is absolutely conserved in higher vertebrates, while lower organisms have Gly, not only enlarging the scope of Ca-dependent structural transitions but also drawing a boundary between the invertebrate and vertebrate calumenin. The evolutionary selection of the switch residue strongly corroborates the change in the structure of the protein and its pleiotropic functions and seems like it can be extended to the presence or absence of a heart in that organism.

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