Carsten E. Stidsen

Development of selective antibodies against the human somatostatin receptor subtypes sst1-sst5

Antisera selective for five somatostatin receptor subtypes, human sst1-sst5, were raised in rabbits. C-terminal parts of human sst1-sst5 receptors were expressed as fusion proteins with glutathione S-transferase. Fusion proteins were affinity-purified and used for raising polyclonal antibodies. In Western blot analysis, all five antisera were tested on preparations of mammalian cell lines transfected with human sst1-sst5, respectively. sst1 antiserum reacted with a broad band of 53-72 kDa. A band of 71-95 kDa was detected with the antiserum raised against sst2, 65-85 kDa with sst3 antiserum, 45 kDa with sst4 antiserum and 52-66 kDa with sst5 antiserum. No cross-reactivity could be detected to any of the other four somatostatin receptor subtypes. Enzymatical deglycosylation of the receptors revealed that sst1, sst2, sst5 and possibly sst3 in this system are subjected to N-linked glycosylation, whereas sst4 is not. Two of the antisera (sst2 and sst5) were used for immunohistochemical localization of the receptors. sst2 and sst5 antisera labeled neurons in e.g. the amygdaloid complex, hippocampus, fascia dentata and the neocortex in rat and monkey tissue. This is the first report on antisera against all five somatostatin receptor subtypes and the first immunohistochemical visualization of sst5 receptors in the mammalian brain.

Y-receptor affinity modulation by the design of pancreatic polypeptide/neuropeptide Y chimera led to Y5-receptor ligands with picomolar affinity

Neuropeptide Y (NPY) and pancreatic polypeptide (PP) bind to the Y-receptors with very different affinities: NPY has high affinity for the receptors Y(1), Y(2) and Y(5), while PP binds only to Y(4)-receptor with picomolar affinity. By exchanging of specific amino acid positions between the two peptides, we developed 38 full-length PP/NPY chimeras with binding properties that are completely different from those of the two native ligands. Pig NPY (pNPY) analogs containing the segment 19-23 from human PP (hPP) bound to the Y-receptors with much lower affinity than NPY itself. The affinity of the hPP analog containing the pNPY segments 1-7 and 19-23 was comparable to that of pNPY at the Y(1)- and Y(5)-receptor subtypes, and to that of hPP at the Y(4)-receptor. Furthermore, the presence of the segments 1-7 from chicken PP (cPP) and 19-23 from pNPY within the hPP sequence led to a ligand with IC(50) of 40 pM at the Y(5)-receptor. This is the most potent Y(5)-receptor ligand known so far, with 15-fold higher affinity than NPY.

A potent antagonist of the strychnine insensitive glycine receptor has anticonvulsant properties

5.7-Dinitro-quinoxaline-2.3-dione (MNQX) displaced [3H]glycine binding to cortical membranes but had no effect n [3H]3-((+/-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid ([3H]CPP) binding. MNQX potently antagonized N-methyl-D-aspartate (NMDA)-evoked release of [3H]GABA from cultured cortical neurones, NMDA evoked spreading depression and NMDA depolarizations in the rat neo-cortex. All of these responses were reversed by addition of glycine to the perfusion media. These results suggested that MNQX is an antagonist at the strychnine-insensitive glycine receptor associated with the NMDA receptor/ionophore complex. Furthermore the compound was found to antagonise audiogenic seizures in DBA-2 mice indicating the potential of glycine antagonists of this type in anticonvulsant therapy.

Immunohistochemical localization of the somatostatin receptor subtype 2 (sst2) in the central nervous system of the golden hamster (Mesocricetus auratus).

The many actions of somatostatin in the central nervous system are mediated through specific membrane receptors of which five have been cloned. In this study, we have investigated the distribution of one of these receptors, the sst2 subtype, in the brain and spinal cord of the golden hamster (Mesocricetus auratus). Immunohistochemistry was carried out by using polyclonal antibodies raised against the C‐terminal part of the human sst2 receptor. sst2 immunoreactivity was found in the forebrain, brainstem, cerebellum, and spinal cord. In the forebrain, strong immunoreactivity was observed in the deep layers of the neocortex as well as in the endopiriform cortex, claustrum, and basolateral amygdaloid nucleus. Immunoreactivity was also found in the CA1 area of the hippocampus and in the subiculum. In the diencephalon, staining was observed in the periventricular area, the dorsomedial and arcuate nuclei of the hypothalamus, and the medial habenular nucleus. Other areas such as the thalamus, striatum, and globus pallidus were almost devoid of staining. In the brainstem, strong immunoreactivity was observed in the locus coeruleus and the parabrachial nucleus. In addition, immunostaining was observed in the cortex of the cerebellum. In the spinal cord, intense immunoreactivity was seen in lamina I and II of the dorsal horn. Finally, immunoreactive cells were widely distributed in the anterior pituitary. The localization of the sst2 receptor in many brain regions suggests that this receptor subtype is involved in different neuromodulatory actions of somatostatin such as somatosensory, motor, memory, and neuroendocrine functions. J. Comp. Neurol. 405:247–261, 1999.

Molecular Characterisation of Long-Acting Insulin Analogues in Comparison with Human Insulin, IGF-1 and Insulin X10

Aims/Hypothesis There is controversy with respect to molecular characteristics of insulin analogues. We report a series of experiments forming a comprehensive characterisation of the long acting insulin analogues, glargine and detemir, in comparison with human insulin, IGF-1, and the super-mitogenic insulin, X10. Methods We measured binding of ligands to membrane-bound and solubilised receptors, receptor activation and mitogenicity in a number of cell types. Results Detemir and glargine each displayed a balanced affinity for insulin receptor (IR) isoforms A and B. This was also true for X10, whereas IGF-1 had a higher affinity for IR-A than IR-B. X10 and glargine both exhibited a higher relative IGF-1R than IR binding affinity, whereas detemir displayed an IGF-1R:IR binding ratio of ≤1. Ligands with high relative IGF-1R affinity also had high affinity for IR/IGF-1R hybrid receptors. In general, the relative binding affinities of the analogues were reflected in their ability to phosphorylate the IR and IGF-1R. Detailed analysis revealed that X10, in contrast to the other ligands, seemed to evoke a preferential phosphorylation of juxtamembrane and kinase domain phosphorylation sites of the IR. Sustained phosphorylation was only observed from the IR after stimulation with X10, and after stimulation with IGF-1 from the IGF-1R. Both X10 and glargine showed an increased mitogenic potency compared to human insulin in cells expressing many IGF-1Rs, whereas only X10 showed increased mitogenicity in cells expressing many IRs. Conclusions Detailed analysis of receptor binding, activation and in vitro mitogenicity indicated no molecular safety concern with detemir.

Stable expression of homomeric AMPA-selective glutamate receptors in BHK cells

cDNAs encoding glutamate receptor glu1, glu2 (Q and R) or glu4 under control of a constitutively active metallothionine promoter, were transfected into baby hamster kidney cells. Following the addition of selection agent, transfectants expressing high levels of glutamate receptor as measured by [3H]alpha-amino-3-hydroxyl-5-methyl-isoxalazole-4-propionate (AMPA) binding, were selected for further studies. Using glutamate receptor antibodies, the receptor proteins were visualized in Western blotting as having a molecular weight of approximately 100 kDa. [3H]AMPA binding to the glutamate receptor expressing cell lines revealed that glu1, glu2 (Q), and glu4 receptors displayed a single site in Scatchard analysis with Kd values of 12, 15.7 and 21 nM, respectively. However, the Ca2+ impermeable variant of the glu2 receptor, glu2 (R) displayed a curvilinear Scatchard plot. Computer resolution suggested the presence of a high and low affinity state (KH = 2.9 nM; KL = 40.7 nM). The pharmacological profile of the [3H]AMPA binding to these recombinant receptors resembled the high affinity [3H]AMPA binding site in rat brain showing high affinity for glutamate, quisqualate, and medium affinity for 6-cyano-7-nitro-quinoxaline-2,3-dione, CNQX; 6,7-dinitro-quinoxaline-2,3-dione, DNQX; and 6-nitro-7-sulphanyl-benzo(f)quinoxaline-2,3,dione, NBQX. Kainate displayed low affinity and N-methyl-D-aspartate (NMDA), was inactive in inhibiting specific [3H]AMPA binding. These cell lines will prove to be important tools in the study of glutamate receptors.

Engineering of Insulin Receptor Isoform-Selective Insulin Analogues

Background The insulin receptor (IR) exists in two isoforms, A and B, and the isoform expression pattern is tissue-specific. The C-terminus of the insulin B chain is important for receptor binding and has been shown to contact the IR just adjacent to the region where the A and B isoforms differ. The aim of this study was to investigate the importance of the C-terminus of the B chain in IR isoform binding in order to explore the possibility of engineering tissue-specific/liver-specific insulin analogues. Methodology/Principal Findings Insulin analogue libraries were constructed by total amino acid scanning mutagenesis. The relative binding affinities for the A and B isoform of the IR were determined by competition assays using scintillation proximity assay technology. Structural information was obtained by X-ray crystallography. Introduction of B25A or B25N mutations resulted in analogues with a 2-fold preference for the B compared to the A isoform, whereas the opposite was observed with a B25Y substitution. An acidic amino acid residue at position B27 caused an additional 2-fold selective increase in affinity for the receptor B isoform for analogues bearing a B25N mutation. Furthermore, the combination of B25H with either B27D or B27E also resulted in B isoform-preferential analogues (2-fold preference) even though the corresponding single mutation analogues displayed no differences in relative isoform binding affinity. Conclusions/Significance We have discovered a new class of IR isoform-selective insulin analogues with 2–4-fold differences in relative binding affinities for either the A or the B isoform of the IR compared to human insulin. Our results demonstrate that a mutation at position B25 alone or in combination with a mutation at position B27 in the insulin molecule confers IR isoform selectivity. Isoform-preferential analogues may provide new opportunities for developing insulin analogues with improved clinical benefits.

Receptor-isoform-selective insulin analogues give tissue-preferential effects.

The relative expression patterns of the two IR (insulin receptor) isoforms, +/- exon 11 (IR-B/IR-A respectively), are tissue-dependent. Therefore we have developed insulin analogues with different binding affinities for the two isoforms to test whether tissue-preferential biological effects can be attained. In rats and mice, IR-B is the most prominent isoform in the liver (> 95%) and fat (> 90%), whereas in muscles IR-A is the dominant isoform (> 95%). As a consequence, the insulin analogue INS-A, which has a higher relative affinity for human IR-A, had a higher relative potency [compared with HI (human insulin)] for glycogen synthesis in rat muscle strips (26%) than for glycogen accumulation in rat hepatocytes (5%) and for lipogenesis in rat adipocytes (4%). In contrast, the INS-B analogue, which has an increased affinity for human IR-B, had higher relative potencies (compared with HI) for inducing glycogen accumulation (75%) and lipogenesis (130%) than for affecting muscle (45%). For the same blood-glucose-lowering effect upon acute intravenous dosing of mice, INS-B gave a significantly higher degree of IR phosphorylation in liver than HI. These in vitro and in vivo results indicate that insulin analogues with IR-isoform-preferential binding affinity are able to elicit tissue-selective biological responses, depending on IR-A/IR-B expression.

Systematic Evaluation of the Metabolic to Mitogenic Potency Ratio for B10-Substituted Insulin Analogues

Background Insulin analogues comprising acidic amino acid substitutions at position B10 have previously been shown to display increased mitogenic potencies compared to human insulin and the underlying molecular mechanisms have been subject to much scrutiny and debate. However, B10 is still an attractive position for amino acid substitutions given its important role in hexamer formation. The aim of this study was to investigate the relationships between the receptor binding properties as well as the metabolic and mitogenic potencies of a series of insulin analogues with different amino acid substitutions at position B10 and to identify a B10-substituted insulin analogue without an increased mitogenic to metabolic potency ratio. Methodology/Principal Findings A panel of ten singly-substituted B10 insulin analogues with different amino acid side chain characteristics were prepared and insulin receptor (both isoforms) and IGF-I receptor binding affinities using purified receptors, insulin receptor dissociation rates using BHK cells over-expressing the human insulin receptor, metabolic potencies by lipogenesis in isolated rat adipocytes, and mitogenic potencies using two different cell types predominantly expressing either the insulin or the IGF-I receptor were systematically investigated. Only analogues B10D and B10E with significantly increased insulin and IGF-I receptor affinities as well as decreased insulin receptor dissociation rates displayed enhanced mitogenic potencies in both cell types employed. For the remaining analogues with less pronounced changes in receptor affinities and insulin receptor dissociation rates, no apparent correlation between insulin receptor occupancy time and mitogenicity was observed. Conclusions/Significance Several B10-substituted insulin analogues devoid of disproportionate increases in mitogenic compared to metabolic potencies were identified. In the present study, receptor binding affinity rather than insulin receptor off-rate appears to be the major determinant of both metabolic and mitogenic potency. Our results also suggest that the increased mitogenic potency is attributable to both insulin and IGF-I receptor activation.

Somatostatin Receptor Subtype 4 (sst4) Ligands: Synthesis and Evaluation of Indol-3-yl- and 2-Pyridyl-Thioureas

Thiourea analogues of NNC 26-9100 (2) were prepared as somatostatin receptor subtype 4 (sst4) ligands. The indole 9 exhibited high affinity (Ki = 23 nM) and about a 100-fold selectivity at sst4 compared to sst2 receptors. The (imidazol-4-yl) propyl group appears to play a major role in the affinity and selectivity of these thioureas at sst4.