Asser Sloth Andersen

Soluble, fatty acid acylated insulins bind to albumin and show protracted action in pigs.

SummaryWe have synthesized insulins acylated by fatty acids in the ε-amino group of LysB29. Soluble preparations can be made in the usual concentration of 600 nmol/ml (100 IU/ml) at neutral pH. The time for 50% disappearance after subcutaneous injection of the corresponding TyrA14(125I)-labelled insulins in pigs correlated with the affinity for binding to albumin (r=0.97), suggesting that the mechanism of prolonged disappearance is binding to albumin in subcutis. Most protracted was LysB29-tetradecanoyl des-(B30) insulin. The time for 50% disappearance was 14.3±2.2 h, significantly longer than that of Neutral Protamine Hagedorn (NPH) insulin, 10.5±4.3 h (p<0.001), and with less inter-pig variation (p<0.001). Intravenous bolus injections of LysB29-tetradecanoyl des-(B30) human insulin showed a protracted blood glucose lowering effect compared to that of human insulin. The relative affinity of LysB29-tetradecanoyl des-(B30) insulin to the insulin receptor is 46%. In a 24-h glucose clamp study in pigs the total glucose consumptions for LysB29-tetradecanoyl des-(B30) insulin and NPH were not significantly different (p=0.88), whereas the times when 50% of the total glucose had been infused were significantly different, 7.9±1.0 h and 6.2±1.3 h, respectively (p<0.04). The glucose disposal curve caused by LysB29-tetradecanoyl des-(B30) insulin was more steady than that caused by NPH, without the pronounced peak at 3 h. Unlike the crystalline insulins, the soluble LysB29-tetradecanoyl des-(B30) insulin does not elicit invasion of macrophages at the site of injection. Thus, LysB29-tetradecanoyl des-(B30) insulin might be suitable for providing basal insulin in the treatment of diabetes mellitus.

Alanine Scanning Mutagenesis of Insulin

Alanine scanning mutagenesis has been used to identify specific side chains of insulin which strongly influence binding to the insulin receptor. A total of 21 new insulin analog constructs were made, and in addition 7 high pressure liquid chromatography-purified analogs were tested, covering alanine substitutions in positions B1, B2, B3, B4, B8, B9, B10, B11, B12, B13, B16, B17, B18, B20, B21, B22, B26, A4, A8, A9, A12, A13, A14, A15, A16, A17, A19, and A21. Binding data on the analogs revealed that the alanine mutations that were most disruptive for binding were at positions TyrA19, GlyB8, LeuB11, and GluB13, resulting in decreases in affinity of 1,000-, 33-, 14-, and 8-fold, respectively, relative to wild-type insulin. In contrast, alanine substitutions at positions GlyB20, ArgB22, and SerA9 resulted in an increase in affinity for the insulin receptor. The most striking finding is that B20Ala insulin retains high affinity binding to the receptor. GlyB20 is conserved in insulins from different species, and in the structure of the B-chain it appears to be essential for the shift from the α-helix B8–B19 to the β-turn B20–B22. Thus, replacing GlyB20 with alanine most likely modifies the structure of the B-chain in this region, but this structural change appears to enhance binding to the insulin receptor.

Hybrid Receptors Formed by Insulin Receptor (IR) and Insulin-like Growth Factor I Receptor (IGF-IR) Have Low Insulin and High IGF-1 Affinity Irrespective of the IR Splice Variant

Insulin receptor (IR) and insulin-like growth factor I receptor (IGF-IR) are both from the same subgroup of receptor tyrosine kinases that exist as covalently bound receptor dimers at the cell surface. For both IR and IGF-IR, the most described forms are homodimer receptors. However, hybrid receptors consisting of one-half IR and one-half IGF-IR are also present at the cell surface. Two splice variants of IR are expressed that enable formation of two isoforms of the IGF-IR/IR hybrid receptor. In this study, these two splice variants of hybrid receptors were studied with respect to binding affinities of insulin, insulin-like growth factor I (IGF-I), and insulin-like growth factor II (IGF-II). Unlike previously published data, in which semipurified receptors have been studied, we found that the two hybrid receptor splice variants had similar binding characteristics with respect to insulin, IGF-I, and IGF-II binding. We studied both semipurified and purified hybrid receptors. In all cases we found that IGF-I had at least 50-fold higher affinity than insulin, irrespective of the splice variant. The binding characteristics of insulin and IGF-I to both splice variants of the hybrid receptors were similar to classical homodimer IGF-IR.

Purification and characterisation of a new hypothalamic satiety peptide, cocaine and amphetamine regulated transcript (CART), produced in yeast

Cocaine and amphetamine regulated transcript (CART) is a newly discovered hypothalamic peptide with a potent appetite suppressing activity following intracerebroventricular administration. When the mature rat CART sequence encoding CART(1–102) was inserted in the yeast expression plasmid three CART peptides could be purified from the fermentation broth reflecting processing at dibasic sequences. None of these corresponded to the naturally occurring CART(55–102). In order to obtain CART(55–102) the precursor Glu‐Glu‐Ile‐Asp‐CART(55–102) has been produced and CART(55–102) was generated by digestion of the precursor with dipeptidylaminopeptidase‐1. All four generated CART peptides have been characterised by N‐terminal amino acid sequencing and mass spectrometry. The CART peptides contain six cysteine residues and using the yeast expressed CART(62–102) the disulphide bond configuration was found to be I–III, II–V and IV–VI. When the four CART peptides were intracerebroventricularly injected in fasted mice (0.1 to 2.0 μg) they all produced a dose dependent inhibition of food intake.

Assembly of high-affinity insulin receptor agonists and antagonists from peptide building blocks

Insulin is thought to elicit its effects by crosslinking the two extracellular α-subunits of its receptor, thereby inducing a conformational change in the receptor, which activates the intracellular tyrosine kinase signaling cascade. Previously we identified a series of peptides binding to two discrete hotspots on the insulin receptor. Here we show that covalent linkage of such peptides into homodimers or heterodimers results in insulin agonists or antagonists, depending on how the peptides are linked. An optimized agonist has been shown, both in vitro and in vivo, to have a potency close to that of insulin itself. The ability to construct such peptide derivatives may offer a path for developing agonists or antagonists for treatment of a wide variety of diseases.

A removable spacer peptide in an α-factor-leader/insulin precursor fusion protein improves processing and concomitant yield of the insulin precursor in Saccharomyces cerevisiae

An alpha-factor leader/insulin precursor fusion protein was produced in Saccharomyces cerevisiae and metabolically labeled in order to analyse the efficiency of maturation and secretion. A substantial fraction of the secreted material was found in a hyperglycosylated unprocessed form, indicating incomplete Kex2p endopeptidase maturation. Introduction of a spacer peptide (EAEAEAK) after the dibasic Kex2p site, creating a N-terminal extension of the insulin precursor, greatly increased the Kex2p catalytic efficiency and the fermentation yield of insulin precursor. The N-terminal extension features a Lys to allow subsequent proteolytic removal by trypsin or the Achromobacter lyticus Lys-specific protease. Dipeptidyl aminopeptidase A (DPAPA) activity removing Glu-Ala dipeptides from the extension was inhibited by adding a Glu N-terminally to the extension. Unexpectedly, this modified N-terminal extension (EEAEAEAK) was partially cleaved after the Lys during fermentation. This monobasic proteolytic activity was demonstrated to be associated with Yap3p. Yap3p cleavage could be prevented by insertion of a Pro before the Lys (EEAEAEAPK).

Expression and Characterization of a 70-kDa Fragment of the Insulin Receptor That Binds Insulin MINIMIZING LIGAND BINDING DOMAIN OF THE INSULIN RECEPTOR

In order to characterize regions of the insulin receptor that are essential for ligand binding and possibly identify a smaller insulin-binding fragment of the receptor, we have used site-directed mutagenesis to construct a series of insulin receptor deletion mutants. From 112 to 246 amino acids were deleted from the α-subunit region comprising amino acids 469–729. The receptor constructs were expressed as soluble insulin receptor IgG fusion proteins in baby hamster kidney cells and were characterized in binding assays by immunoblotting and chemical cross-linking with radiolabeled insulin. The shortest receptor fragment identified was a free monomeric α-subunit deleted of amino acids 469–703 and 718–729 (exon 11); the mass of this receptor fragment was found by mass spectrometry to be 70 kDa. This small insulin receptor fragment bound insulin with an affinity (K d ) of 4.4 nm, which is similar to what was found for the full-length ectodomain of the insulin receptor (5.0 nm). Cross-linking experiments confirmed that the 70-kDa receptor fragment specifically bound insulin. In summary we have minimized the insulin binding domain of the insulin receptor by identifying a 70-kDa fragment of the ectodomain that retains insulin binding affinity making this an interesting candidate for detailed structural analysis.

Specificity of Insulin and Insulin-like Growth Factor I Receptors Investigated using Chimeric Mini-Receptors ROLE OF C-TERMINAL OF RECEPTOR α SUBUNIT

We have investigated the role of the C-terminal of the α-subunit in the insulin receptor family by characterizing chimeric mini-receptor constructs comprising the first three domains (468 amino acids) of insulin receptor (IR) or insulin-like growth factor I receptor (IGFIR) combined with C-terminal domain from either insulin receptor (IR) (residues 704–719), IGFIR, or insulin receptor-related receptor (IRRR). The constructs were stably expressed in baby hamster kidney cells and purified, and binding affinities were determined for insulin, IGFI, and a single chain insulin/IGFI hybrid. The C-terminal domain of IRRR was found to abolish binding in IR and IGFIR context, whereas other constructs bound ligands. The two constructs with first three domains of the IR demonstrated low specificity for ligands, all affinities ranging from 3.0 to 15 nm. In contrast, the constructs with the first three domains of the IGFIR had high specificity, the affinity of the novel minimized IGFIR for IGFI was 1.5 nm,whereas the affinity for insulin was more than 3000 nm. When swapping the C-terminal domains in either receptor context only minor changes were observed in affinities (<3-fold), demonstrating that the carboxyl-terminal of IR and IGFIR α-subunits are interchangeable and suggesting that this domain is part of the common binding site.

Structural basis for the lower affinity of the insulin-like growth factors for the insulin receptor.

Insulin and the insulin-like growth factors (IGFs) bind with high affinity to their cognate receptor and with lower affinity to the noncognate receptor. The major structural difference between insulin and the IGFs is that the IGFs are single chain polypeptides containing A-, B-, C-, and D-domains, whereas the insulin molecule contains separate A- and B-chains. The C-domain of IGF-I is critical for high affinity binding to the insulin-like growth factor I receptor, and lack of a C-domain largely explains the low affinity of insulin for the insulin-like growth factor I receptor. It is less clear why the IGFs have lower affinity for the insulin receptor. In this study, 24 insulin analogues and four IGF analogues were expressed and analyzed to explore the role of amino acid differences in the A- and B-domains between insulin and the IGFs in binding affinity for the insulin receptor. Using the information obtained from single substituted analogues, four multiple substituted analogues were produced. A “quadruple insulin” analogue ([PheA8, SerA10, ThrB5, GlnB16]Ins) showed affinity as IGF-I for the insulin receptor, and a “sextuple insulin” analogue ([PheA8, SerA10, ThrA18, ThrB5, ThrB14, GlnB16]Ins) showed an affinity close to that of IGF-II for the insulin receptor, whereas a “quadruple IGF-I” analogue ([His4, Tyr15, Thr49, Ile51]IGF-I) and a “sextuple IGF-II” analogue ([His7, Ala16, Tyr18, Thr48, Ile50, Asn58]IGF-II) showed affinities similar to that of insulin for the insulin receptor. The mitogenic potency of these analogues correlated well with the binding properties. Thus, a small number of A- and B-domain substitutions that map to the IGF surface equivalent to the classical binding surface of insulin weaken two hotspots that bind to the insulin receptor site 1.

Dimeric fragment of the insulin receptor alpha-subunit binds insulin with full holoreceptor affinity.

The insulin receptor (IR) is a dimeric receptor, and its activation is thought to involve cross-linking between monomers initiated by binding of a single insulin molecule to separate epitopes on each monomer. We have previously shown that a minimized insulin receptor consisting of the first three domains of the human IR fused to 16 amino acids from the C-terminal of the α-subunit was monomeric and bound insulin with nanomolar affinity (Kristensen, C., Wiberg, F. C., Schäffer, L., and Andersen, A. S. (1998) J. Biol. Chem. 273, 17780–17786). To investigate the insulin binding properties of dimerized α-subunits, we have reintroduced the domains containing α-α disulfide bonds into this minireceptor. When inserting either the first fibronectin type III domain or the full-length sequence of exon 10, the receptor fragments were predominantly secreted as disulfide-linked dimers that both had nanomolar affinity for insulin, similar to the affinity found for the minireceptor. However, when both these domains were included we obtained a soluble dimeric receptor that bound insulin with 1000-fold higher affinity (4–8 pm) similar to what was obtained for the solubilized holoreceptor (14–24 pm). Moreover, dissociation of labeled insulin from this receptor was accelerated in the presence of unlabeled insulin, demonstrating another characteristic feature of the holoreceptor. This is the first direct demonstration showing that the α-subunit of IR contains all the epitopes required for binding insulin with full holoreceptor affinity.