We report the crystal structure of two variants of Drosophila melanogaster insulin-like peptide 5 (DILP5) at a resolution of 1.85 Å . DILP5 shares the basic fold of the insulin peptide family (T conformation) but with a disordered B-chain C terminus. DILP5 dimerizes in the crystal and in solution. The dimer interface is not similar to that observed in vertebrates, i.e. through an anti-parallel -sheet involving the B-chain C termini but, in contrast, is formed through an anti-parallel -sheet involving the B-chain N termini. DILP5 binds to and activates the human insulin receptor and lowers blood glucose in rats. It also lowers trehalose levels in Drosophila. Reciprocally, human insulin binds to the Drosophila insulin receptor and induces negative cooperativity as in the human receptor. DILP5 also binds to insect insulin-binding proteins. These results show high evolutionary conservation of the insulin receptor binding properties despite divergent insulin dimerization mechanisms.The ligands and receptors of the insulin peptide family constitute an ancient metazoan signaling system that plays a crucial pleiotropic role in cell growth, metabolism, reproduction, and longevity (1-7).The mammalian insulin receptor belongs to the family of receptor-tyrosine kinases and is composed of two ␣ subunits and two  subunits linked together by disulfide bonds (for review, see Refs. 4 and 8 -10). The existence of a homologue of the mammalian insulin receptor in Drosophila melanogaster (DIR) 2 was suggested in 1985 by Petruzzelli et al. (11), who identified a glycoprotein of 350 -400 kDa that binds bovine insulin specifically with moderate affinity (15 nM). The cDNA sequence of the DIR is remarkably similar to that of the mammalian insulin and IGF-I receptors (with 33% sequence identity) except for substantial N-and C-terminal extensions (12, 13).In evolution, there is a single receptor from Cnidarians up to and including Amphioxus (Branchiostoma californiense), the phylum closest to vertebrates (for review see Refs. 1, 4 -6). In vertebrates, gene duplications resulted in three related receptors; that is, the insulin receptor, the type I IGF receptor, and the orphan insulin receptor-related receptor (1, 5).In humans, members of the insulin peptide family include insulin, the insulin-like growth factors I and II, and seven relaxin-related peptides (for review, see Ref. 14). The same basic fold is shared for all molecules in the superfamily whose structure is known; the B domain contains a single ␣-helix that lies across the two ␣-helices of the A domain (15) and two canonical disulfide bridges that connect the A-and Bchains, whereas an intrachain disulfide bridge is present in the A-chain.The D. melanogaster genome contains seven insulin-like genes that are expressed in a highly tissue-and stage-specific patterns, dilp1-7 (16). dilp2 is the most related to human insulin with 35% sequence identity, whereas dilp5 has 27.8% identity (16).So far, the structures of only two invertebrate insulin-like peptides have been determined by N...
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Insulin-like peptide 3 (INSL3) binds to a G protein-coupled receptor (GPCR) called relaxin family peptide receptor 2 (RXFP2). RXFP2 belongs to the leucine-rich repeat-containing subgroup (LGR) of class A GPCRs. Negative cooperativity has recently been demonstrated in other members of the LGR subgroup. In this work, the kinetics of INSL3 binding to HEK293 cells stably transfected with RXFP2 (HEK293-RXFP2) have been investigated in detail to study whether negative cooperativity occurs and whether this receptor functions as a dimer. Our results show that negative cooperativity is present and that INSL3-RXFP2 binding shows both similarities and differences with insulin binding to the insulin receptor. A dose-response curve for the negative cooperativity of INSL3 binding had a reverse bell shape reminiscent of that seen for the negative cooperativity of insulin binding to its receptor. This suggests that binding of INSL3 may happen in a trans rather than in a cis way in a receptor dimer. Bioluminescence resonance energy transfer (BRET(2)) experiments confirmed that RXFP2 forms constitutive homodimers. Heterodimerization between RXFP2 and RXFP1 was also observed.
The mechanisms whereby insulin analogues may cause enhanced mitogenicity through activation of either the IR (insulin receptor) or the IGF-IR (insulin-like growth factor 1 receptor) are incompletely understood. We demonstrate that in L6 myoblasts expressing only IGF-IRs as well as in the same cells overexpressing the IR, IGF-I (insulin-like growth factor 1), insulin and X10 (AspB10 insulin) down-regulate the mRNA expression level of the cell cycle inhibitor cyclin G2, as measured by qRT-PCR (quantitative reverse transcription-PCR), and induce cell growth measured by [6-(3)H]thymidine incorporation into DNA. Western blotting showed a marked down-regulation of cyclin G2 at the protein level in both cell lines. Overexpression of cyclin G2 in the two cell lines diminished the mitogenic effect of all three ligands. The use of specific inhibitors indicated that both the MAPK (mitogen-activated protein kinase) and the PI3K (phosphoinositide 3-kinase) pathways mediate the down-regulation of Ccng2. The down-regulation of CCNG2 by the three ligands was also observed in other cell lines: MCF-7, HMEC, Saos-2, R(-)/IR and INS-1. These results indicate that regulation of cyclin G2 is a key mechanism whereby insulin, insulin analogues and IGF-I stimulate cell proliferation.
The insulin/relaxin superfamily of peptide hormones comprises 10 members in humans. The three members of the insulin-related subgroup bind to receptor tyrosine kinases (RTKs), while four of the seven members of the relaxin-like subgroup are now known to bind to G-protein-coupled receptors (GPCRs), the so-called relaxin family peptide receptors (RXFPs). Both systems have a long evolutionary history and play a critical role in fundamental biological processes, such as metabolism, growth, survival and longevity, and reproduction. The structural biology and ligand-binding kinetics of the insulin and insulin-like growth factor I receptors have been studied in great detail, culminating in the recent crystal structure of the insulin receptor extracellular domain. Some of the fundamental properties of these receptors, including constitutive dimerization and negative cooperativity, have recently been shown to extend to other RTKs and GPCRs, including RXFPs, confirming kinetic observations made over 30 years ago.
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