Molecular Analysis of Human Beta-arrestin-1: Cloning, Tissue Distribution, and Regulation of Expression. Identification of Two Isoforms Generated by Alternative Splicing
Overview
Affiliations
The cDNA for human beta-arrestin-1 was cloned by polymerase chain reaction (PCR) and identified based on its remarkably high amino acid identity (98.6%) with the bovine sequence. Two alternatively spliced isoforms of human beta-arrestin-1, differing only in the presence or absence of 24 base pairs/8 amino acids within the sequence, were identified and called beta-arrestin-1A and beta-arrestin-1B, respectively. Both isoforms were found in all tissues tested. Southern blot analysis revealed the existence of a single gene for beta-arrestin-1, suggesting that the two isoforms are generated by alternative mRNA splicing. The possible presence of similar isoforms was investigated for the other members of the arrestin/beta-arrestin gene family by PCR. Two isoforms of arrestin were revealed in bovine peripheral blood leukocytes. The expression of beta-arrestin-1 was studied in several human tissues and cell types. High levels of beta-arrestin-1 mRNA and immunoreactivity were found in peripheral blood leukocytes. The possible regulation of the expression of beta-arrestin-1 was also investigated. Our work documents for the first time that the expression of beta-arrestin-1 is modulated by intracellular cAMP. Using two cell types, human endothelial cells and smooth muscle cells, we found that 6-8-h treatments with the cAMP-inducing agents cholera toxin, forskolin, iloprost, and isoproterenol raised beta-arrestin-1 mRNA by 2-4-fold. Forskolin preferentially increased beta-arrestin-1A expression in smooth muscle cells, as assessed by PCR. beta-Arrestin-1 immunoreactivity was 2-3-fold higher in smooth muscle cells exposed to forskolin for 8 h, compared with untreated controls. We conclude that (i) the finding of alternatively spliced isoforms of beta-arrestin-1 and arrestin documents a novel mechanism to generate diversity within the arrestin/beta-arrestin gene family; (ii) the abundant expression of beta-arrestin-1 in peripheral blood leukocytes further supports our previous suggestion of a major role for the beta ARK/beta-arrestin system in regulating receptor-mediated immune functions; (iii) the increased expression of beta-arrestin-1 by cAMP suggests a new mechanism for the regulation of receptor-mediated responses.
The Role of Individual Residues in the N-Terminus of Arrestin-1 in Rhodopsin Binding.
Vishnivetskiy S, Paul T, Gurevich E, Gurevich V Int J Mol Sci. 2025; 26(2).
PMID: 39859432 PMC: 11765510. DOI: 10.3390/ijms26020715.
Papadatou I, Geropeppa M, Piperi C, Spoulou V, Adamopoulos C, Papavassiliou A Int J Mol Sci. 2024; 25(13).
PMID: 39000206 PMC: 11240890. DOI: 10.3390/ijms25137095.
Arrestin beta 1 Regulates Alveolar Progenitor Renewal and Lung Fibrosis.
Huang G, Geng Y, Kulur V, Liu N, Liu X, Taghavifar F J Respir Biol Transl Med. 2024; 1(2).
PMID: 38736470 PMC: 11087074. DOI: 10.35534/jrbtm.2024.10006.
Kee T, Khan S, Neidhart M, Masters B, Zhao V, Kim Y Exp Mol Med. 2024; 56(1):129-141.
PMID: 38212557 PMC: 10834518. DOI: 10.1038/s12276-023-01144-4.
Zhang W, Cao L, Yang J, Zhang S, Zhao J, Shi Z J Clin Invest. 2023; 134(3).
PMID: 37988165 PMC: 10849765. DOI: 10.1172/JCI173299.