Marvin L. Bayne

Molecular identification and characterization of the platelet ADP receptor targeted by thienopyridine antithrombotic drugs

ADP plays a critical role in modulating thrombosis and hemostasis. ADP initiates platelet aggregation by simultaneous activation of two G protein-coupled receptors, P2Y1 and P2Y12. Activation of P2Y1 activates phospholipase C and triggers shape change, while P2Y12 couples to Gi to reduce adenylyl cyclase activity. P2Y12 has been shown to be the target of the thienopyridine drugs, ticlopidine and clopidogrel. Recently, we cloned a human orphan receptor, SP1999, highly expressed in brain and platelets, which responded to ADP and had a pharmacological profile similar to that of P2Y12. To determine whether SP1999 is P2Y12, we generated SP1999-null mice. These mice appear normal, but they exhibit highly prolonged bleeding times, and their platelets aggregate poorly in responses to ADP and display a reduced sensitivity to thrombin and collagen. These platelets retain normal shape change and calcium flux in response to ADP but fail to inhibit adenylyl cyclase. In addition, oral clopidogrel does not inhibit aggregation responses to ADP in these mice. These results demonstrate that SP1999 is indeed the elusive receptor, P2Y12. Identification of the target receptor of the thienopyridine drugs affords us a better understanding of platelet function and provides tools that may lead to the discovery of more effective antithrombotic therapies.

Cloning and Expression of a Novel Neuropeptide Y Receptor

The neuropeptide Y family of peptides, which includes neuropeptide Y (NPY), peptide YY (PYY), and pancreatic polypeptide (PP), are found in the central and peripheral nervous system and display a wide array of biological activities. These actions are believed to be mediated through pharmacologically distinct G protein-coupled receptors, and, to date, three members of the NPY receptor family have been cloned. In this study we describe the cloning and expression of a novel NPY receptor from mouse genomic DNA. This receptor, designated NPY Y5, shares 60% amino acid identity to the murine NPY Y1 receptor. The pharmacology of this novel receptor resembles that of the NPY Y1 receptor and is distinct from that described for the NPY Y2, Y3, and Y4 receptors. In situ hybridization of mouse brain sections reveals expression of this receptor within discrete regions of the hypothalamus including the suprachiasmatic nucleus, anterior hypothalamus, bed nucleus stria terminalis, and the ventromedial nucleus with no localization apparent elsewhere in the brain.

Expression, purification and characterization of recombinant human insulin-like growth factor I in yeast

Insulin-like growth factor I (IGF-I) is a 70 amino acid (aa) protein that is structurally similar and functionally related to insulin. We have inserted a synthetic gene coding for human IGF-I into a Saccharomyces cerevisiae expression vector utilizing the MF alpha 1 promoter and pre-pro leader peptide. This vector directs the expression and secretion of native, biologically active growth factor. Cleavage of the pre-pro alpha factor leader sequence in vivo results in the secretion of a 70-aa recombinant IGF-I molecule with the native N-terminal glycine residue. Human IGF-I purified from yeast culture supernatant is equipotent to serum-derived IGF-I in inhibiting [125I]IGF-I binding to type-I IGF receptors and crude human serum-binding proteins. Recombinant IGF-I is also equipotent to human IGF-I in the stimulation of DNA synthesis in rat aortic smooth-muscle cells. In contrast, yeast recombinant IGF-I is less potent than serum-derived IGF-I in binding to type-2 IGF receptors. The ability to produce native, biologically active IGF-I in yeast will allow the elucidation of binding domains through the expression and characterization of specific structural analogs.

Proprotein convertase subtilisin/kexin type 9 (PCSK9) affects gene expression pathways beyond cholesterol metabolism in liver cells.

Proprotein convertase subtilisin/kexin type 9 (PCSK9) induces degradation of low‐density lipoprotein receptor (LDLR) in the liver. It is being pursued as a therapeutic target for LDL‐cholesterol reduction. Earlier genome‐wide gene expression studies showed that PCSK9 over‐expression in HepG2 cells resulted in up‐regulation of genes in cholesterol biosynthesis and down‐regulation of genes in stress response pathways; however, it was not known whether these changes were directly regulated by PCSK9 or were secondary to PCSK9‐induced changes to the intracellular environment. In order to further understand the biological function of PCSK9 we treated HepG2 cells with purified recombinant wild type (WT) and D374Y gain‐of‐function PCSK9 proteins for 8, 24, and 48 h, and used microarray analysis to identify genome‐wide expression changes and pathways. These results were compared to the changes induced by culturing HepG2 cells in cholesterol‐free medium, mimicking the intracellular environment of cholesterol starvation. We determined that PCSK9‐induced up‐regulation of cholesterol biosynthesis genes resulted from intracellular cholesterol starvation. In addition, we identified novel pathways that are presumably regulated by PCSK9 and are independent of its effects on cholesterol uptake. These pathways included “protein ubiquitination,” “xenobiotic metabolism,” “cell cycle,” and “inflammation and stress response.” Our results indicate that PCSK9 affects metabolic pathways beyond cholesterol metabolism in HepG2 cells. J. Cell. Physiol. 224:273–281, 2010

Characterization of specific binding of [125I]L-762,459, a selective α1A-adrenoceptor radioligand to rat and human tissues

L-762,459 ((+/-)1-(3-¿[5-carbamoyl-2-2-[(4-hydroxy-3-iodobenzimidoyl)-amino] -ethoxy-methy¿-6-methyl-4-(4-nitropheny)-1,4-dihydropyridine -3-carbonyl]-amino¿-propyl)-4-phenyl-1-piperidine-4-carboxylic acid methyl ester), an analog of a series of dihydropyridines previously reported to be selective alpha1A-adrenoceptor subtype antagonists was found to have alpha1A-adrenoceptor subtype selectivity (Ki (nM), la = 1.3, lb = 240, Id = 280). Specific [125I]L-762,459 binding was detected in rat cerebral cortex, hippocampus, vas deferens, kidney, heart and prostate tissues known to contain the alpha1A-adrenoceptor subtype, but not in tissues known to contain alpha1B-adrenoceptor (spleen, liver) and alpha1D-adrenoceptor (aorta). Scatchard analysis of [125I]L-762,459 binding in rat cerebral cortex and prostate indicated a single binding site with a Kd of 0.7 nM and Bmax of 11 (cerebral cortex) and 1 (prostate) pmole/g tissue. Specific and saturable [125I]L-762,459 binding was also found in human cerebral cortex, liver, prostate and vas deferens (Kd = 0.2-0.4 nM, Bmax = 0.4-4 pmole/g tissue). The specific binding in rat and human tissues was competed by non-selective alpha1-adrenoceptor compounds (Ki values in nM: prazosin (0.14-1.2), terazosin (1.8-5.9) and phentolamine (2.4-11)) and selective alpha1A-adrenoceptor compounds [Ki values in nM: (+) niguldipine (0.04-1.2) and SNAP 5399 ((+/-)-2-((2-aminoethyl)oxy)methyl-5-carboxamido-6-ethyl-4-(4-nitropheny l)-3-N-(3-(4,4-diphenylpiperidin-1-yl)propyl)carboxamido-1,4-dihyd ropyridine hydrate (0.5-4.8)]. The results were consistent with the selective binding of [125I]L-762,459 to the alpha1A-adrenoceptor. The specific labeling of the alpha1A-adrenoceptor subtype by [125I]L-762,459 may make it a useful tool to localize the distribution of the alpha1A-adrenoceptor.

Analysis of the Interaction of IGF-I Analogs with the IGF-I Receptor and IGF Binding Proteins

Distinct domains of IGF-I are important for maintaining high affinity for the IGF-I receptor and for the various species of IGFBPs. The analogs that selectively bind the receptor have proven useful in determining the relative importance of IGFBPs in the regulation of the biological activity of IGF-I. Analogs with poor affinity for the receptor have also been useful in order to demonstrate that a given activity of IGF-I is mediated by the type 1 IGF receptor. These studies confirm that the role of these various proteins in IGF-I action is complex, and may be cell or tissue-type specific.

Impaired insulin-like growth factor I-mediated stimulation of glucose incorporation into glycogen in vivo in the ob/ob mouse

SummaryThe ability of insulin to modulate glucose metabolism is impaired in insulin resistant ob/ob mice. It has been shown that insulin-like growth factor I stimulates the uptake and metabolism of glucose in muscle through the insulin-like growth factor receptor not the insulin receptor. Thus, we have compared the abilities of insulin-like growth factor I and insulin to stimulate the in vivo incorporation of [14C]-glucose into glycogen in the diaphragm of ob/ob mice and their lean littermates. The animals used in these studies were 12–14 weeks old and the serum insulin levels of the ob/ob mice were 16-fold higher than in their lean littermates. There were no differences in the serum levels of glucose or insulin-like growth factor I. Both insulin and insulin-like growth factor I stimulate the incorporation of [14C]-glucose into glycogen in lean mice. Significant stimulation occurs at doses as low as 1 μg/kg of either peptide. The effective doses of insulin and insulin-like growth factor I are quite similar, which indicates that the effect of insulin-like growth factor I is mediated by the insulin-like growth factor receptor and not the insulin receptor. In contrast, greater than 100 μg/kg of insulin-like growth factor I is required to stimulate [14C]-glucose incorporation into glycogen in the diaphragm of ob/ob mice. Thus, ob/ob mice are resistant to the action of both insulin and insulin-like growth factor I. In contrast to the decrease in the number of insulin receptors which occurs in ob/ob mice, there is no significant difference in the number of type 1 insulin-like growth factor receptors or in their affinity for insulin-like growth factor I in muscle membranes prepared from lean and ob/ob mice. In addition, the ability of insulin-like growth factor I to stimulate the catalysis of Val5-angiotensin II phosphorylation by the partially purified muscle type 1 insulin-like growth factor receptor is not decreased in ob/ob mice as compared with their lean littermates. These data indicate that the loss in sensitivity of the ob/ob mouse of both insulin and insulin-like growth factor I is most likely mediated by a post-receptor defect in metabolism and not by receptor down-regulation or desensitisation.

Characterization of the Biological Activity of IGF I Analogs with Reduced Affinity for IGF Receptors and Binding Proteins

We have prepared a series of IGF I analogs in order to determine the structural requirements for binding to the types 1 and 2 IGF receptors and to IGF binding proteins (1-5). These analogs were designed by substituting regions of IGF I with analogous regions of insulin, by deleting or replacing regions of IGF I that are absent in insulin, or by replacing specific residues of IGF I. The binding data for these analogs is summarized in Table 1.

Identification of the Domains of IGF I which Interact with the IGF Receptors and Binding Proteins

The elucidation of the primary sequence of human insulin-like growth factor I (IGF I) (1) and the subsequent modeling of its secondary and tertiary structure based on its homology with insulin (2,3) have made it possible to predict which structural features of this peptide are involved in its binding to the types 1 and 2 IGF receptors and to soluble IGF binding proteins. The amino terminal 29 amino acids of IGF I (B-region) are homologous with the B-chain of insulin. A 12 amino acid linking sequence (C-region) joins the B-region with a 21 amino acid A-region which is homologous to the A-chain of insulin. The molecule terminates with an 8 amino acid sequence termed the D-region (Figure 1).