Project description:The involvement of G-Protein-Coupled Receptors’ (GPCR) location bias in diverse cellular functions and their misregulation in pathology is an underexplored territory. HCAR1, a GPCR for lactate is linked to cancer progression, mainly due to Warburg effect, but its mechanism of action remains elusive. Here, we show HCAR1 has a nuclear localization, capable of signaling intranuclearly to induce nuclear-ERK and AKT phosphorylation concomitant with higher cancer cell proliferation and survival. We determine its nuclear interactome, proving its involvement in protein-translation and DNA-damage repair. Nuclear HCAR1 (N-HCAR1) directly interacts with chromatin/DNA promoting expression of genes involved in cellular migration. Notably, we show N-HCAR1 particularly regulates a broader transcriptomic signature than its PM counterpart, emphasizing on the facts that functional output of N-HCAR1 is larger than PM localized HCAR1. Our study presents several unprecedented processes by which a GPCR through location-biased activity regulate various cellular functions and how cancer cells exploit these.

Project description:Nuclear Location Bias of HCAR1 Drives Cancer Malignancy through Numerous Routes

Project description:Nuclear Location Bias of HCAR1 Drives Cancer Malignancy through Numerous Routes [ChIP-seq]

Project description:Nuclear Location Bias of HCAR1 Drives Cancer Malignancy through Numerous Routes [RNA-seq]

Project description:Membrane receptor nuclear translocation play some novel role in cancer pathology. In the current studies, we demonstrate HCAR1 distributes in cancer cell nucleus in Lung cancer; Lactate promote HCAR1 nuclear translocation. Proteomics analysis found there are a set of nuclear proteins binds with HCAR1; interaction of HCAR1 with SFPQ etc other proteins promote cell self-renewal and cell invasion in lung cancer. ChIP sequencing analysis discovered there are a set of genes were targeted by HCAR1.

Project description:Subcellular location defines GPCR signal transduction

Project description:RNAseq was performed on hcar1-4+/+ and hcar1-4-/- zebrafish larvae with (2 h and 4 h) or without (0 h) Pseudomonas aeruginosa (PA) ear infection. The transcriptome profile generated here reveals PA14 infection-induced differential gene expression patterns between hcar1-4-/- and hcar1-4+/+ siblings.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:HCAR1 nuclear transportation is critical for cell function

Project description:G protein-coupled receptors (GPCRs) regulate many aspects of physiology and represent actionable targets for drug discovery. Activation of specific signaling pathways downstream of G-protein coupled receptors (GPCRs) or targeting the receptors at selected cellular locations has the potential to provide therapeutic actions with fewer side effects. However, the understanding of the molecular mechanisms underlying GPCR function is limited in the dynamic cellular environment, hampering drug discovery efforts towards selective ligands. Proximity biotin labeling based on an engineered ascorbic acid peroxidase (APEX) combined with quantitative mass spectrometry is a powerful method to delineate these mechanisms given its capacity to simultaneously capture proximal protein interaction networks and the cellular location of the receptor. However, a major challenge is to extract the various information from these complex datasets. Here, we describe a computational framework for proximity labeling datasets which predicts ligand-dependent subcellular location of GPCRs and quantitatively deconvolutes the effect of receptor location and proximal interactors. We applied this approach to the mu-opioid receptor and not only monitored distinct effects of ligands on receptor trafficking, but also discovered two novel regulators, EYA4 and KCTD12, which modulate MOR-driven G protein-dependent signaling.