Rengarajan Balamurugan scite author profile

Summary The microRNA pathway has been implicated in the regulation of synaptic protein synthesis and ultimately dendritic spine morphogenesis, a phenomenon associated with long-lasting forms of memory. However, the particular microRNAs (miRNAs) involved are largely unknown. We performed a functional screen to identify specific miRNAs that function at synapses to control dendritic spine structure. One of the identified miRNAs, miR-138, is highly enriched in the brain, localized within dendrites and negatively regulates the size of dendritic spines in rat hippocampal neurons. miR-138 controls the expression of Acyl protein thioesterase 1 (APT1), an enzyme regulating the palmitoylation status of proteins that are known to function at the synapse, including G protein alpha subunits (Gα). RNAi-mediated knockdown of APT1 and expression of membrane-localized Gα both suppress spine enlargement caused by miR-138 inhibition, suggesting that APT1-regulated depalmitoylation of Gα might be an important downstream event of miR-138 function. Our results uncover a novel miRNA-dependent mechanism in neurons and demonstrate a previously unrecognized complexity of miRNA-dependent control of dendritic spine morphogenesis.

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Small-molecule inhibition of APT1 affects Ras localization and signaling

Dekker

et al. 2010

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Cycles of depalmitoylation and repalmitoylation critically control the steady-state localization and function of various peripheral membrane proteins, such as Ras proto-oncogene products. Interference with acylation using small molecules is a strategy to modulate cellular localization--and thereby unregulated signaling--caused by palmitoylated Ras proteins. We present the knowledge-based development and characterization of a potent inhibitor of acyl protein thioesterase 1 (APT1), a bona fide depalmitoylating enzyme that is, so far, poorly characterized in cells. The inhibitor, palmostatin B, perturbs the cellular acylation cycle at the level of depalmitoylation and thereby causes a loss of the precise steady-state localization of palmitoylated Ras. As a consequence, palmostatin B induces partial phenotypic reversion in oncogenic HRasG12V-transformed fibroblasts. We identify APT1 as one of the thioesterases in the acylation cycle and show that this protein is a cellular target of the inhibitor.

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β-Lactone probes identify a papain-like peptide ligase in Arabidopsis thaliana

Wang

Colby

et al. 2008

Nat Chem Biol

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New activity-based probes are essential for expanding studies on the hundreds of serine and cysteine proteases encoded by the genome of Arabidopsis thaliana. To monitor protease activities in plant extracts, we generated biotinylated peptides containing a beta-lactone reactive group. These probes cause strong labeling in leaf proteomes. Unexpectedly, labeling was detected at the N terminus of PsbP, nonproteolytic protein of photosystem II. Inhibitor studies and reverse genetics led to the discovery that this unusual modification is mediated by a single plant-specific, papain-like protease called RD21. In cellular extracts, RD21 accepts both beta-lactone probes and peptides as donor molecules and ligates them, probably through a thioester intermediate, to unmodified N termini of acceptor proteins.

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A facile access to substituted benzo[a]fluorenes from o-alkynylbenzaldehydes via in situ formed acetals

Manojveer

Balamurugan

2014

Chem. Commun.

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In situ formed acetal changes the course of Brønsted acid-catalyzed reaction of ortho-alkynylbenzaldehydes with arylalkynes altogether. By utilizing this, an efficient domino approach for the regioselective synthesis of substituted benzo[a]fluorenes has been developed under mild reaction conditions. In situ formed acetal facilitates the intermolecular heteroalkyne metathesis and subsequent trans to cis isomerization of a double bond to effect the intramolecular annulation.

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Design of compound libraries based on natural product scaffolds and protein structure similarity clustering (PSSC)

2005

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Recent advances in structural biology, bioinformatics and combinatorial chemistry have significantly impacted the discovery of small molecules that modulate protein functions. Natural products which have evolved to bind to proteins may serve as biologically validated starting points for the design of focused libraries that might provide protein ligands with enhanced quality and probability. The combined application of natural product derived scaffolds with a new approach that clusters proteins according to structural similarity of their ligand sensing cores provides a new principle for the design and synthesis of such libraries. This article discusses recent advances in the synthesis of natural product inspired compound collections and the application of protein structure similarity clustering for the development of such libraries.

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Scope of AuCl3 in the activation of per-O-acetylglycals

Balamurugan

Koppolu

2009

Tetrahedron

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Silicon-Assisted Ring Opening of Donor−Acceptor Substituted Cyclopropanes. An Expedient Entry to Substituted Dihydrofurans

Yadav

Balamurugan

2001

Org. Lett.

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Nonglycosidic Agonists of Invariant NKT Cells for Use as Vaccine Adjuvants

et al. 2009

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