Intracellular signalling by the insulin receptor

The insulin receptor transduces insulin's biological signal through the tyrosine kinase present in the receptor's B subunit. The activated insulin receptor kinase then phosphorylates a series of intracellular substrate including insulin receptor substrate 1 (IRS-1), which has been shown to be the pivotal substrate for insulin receptor signal transduction. The phosphorylated tyrosine residues in IRS-1 can bind and activate the downstream effectors, many of which are SH2 domain containing proteins such as phosphotidylinositol 3-kinase, growth factor binding protein 2, and SH2 phosphotyrosine phosphatase 2. Phosphorylated synthetic IRS-1 peptides with the corresponding sequences of the IRS-1 have been shown to associate and activate their respective SH2 domain containing proteins. Another important event happening during insulin binding with the insulin receptor is that the insulin receptor rapidly undergoes internalization. However, the insulin receptor signalling and the receptor endocytosis have been studied as two independent processes. The hypothesis of the present thesis is that the insulin receptor endocytosis is involved in insulin receptor signalling and signal termination. The results of the present investigation demonstrate that insulin receptors in the earliest stage of endocytosis contain significantly greater kinase activity towards IRS-1 peptides than the receptors localized at the plasma membrane, indicating that they are potentially more capable of transducing signals. On the other hand, insulin receptors in the middle and late stage of endocytosis lose their kinase activity, suggesting that insulin receptor kinase activity inactivation and signal termination might take place in the late phase of the insulin receptor internalization. In addition, this study also found that the increased insulin receptor kinase activity in the endosomes is related to the tyrosyl phosphorylation of the specific domains of the receptor's $\beta$ subunit. ^

Insulin effects and receptor function in bovine aorta endothelial cells

The interaction of insulin with bovine aorta endothelial (BAE) cells has been studied to determine the effect of insulin on endothelial cells, and investigate the function of the insulin receptor in this cell type. BAE cell insulin receptor is similiar to insulin receptor in other cell types in the time to attain equilibrium binding, its physical properties in a solubilized assay system and affinity for insulin in the low nanomolar range. However, BAE cell insulin receptor has unusual properties in its interaction with insulin at 4$\sp\circ$C that include: (1) the inability to completely dissociate prebound $\sp{125}$I-insulin by dilution with excess insulin or acid rinse treatment, indicating that binding is not completely reversible (2) the inability to remove prebound insulin with trypsin and other proteases (3) the implication of disulfide complex formation during binding (4) the inability of pretreatment with trypsin to lower cell surface binding capacity and (5) the suppression of insulin binding by bacitracin. Interactions of insulin with the receptor at 37$\sp\circ$C showed that (1) BAE cells degrade insulin, but not as extensively as other cell types, and (2) an unusual biphasic interaction of insulin with the BAE cells is observed which is indicative of some regulatory mechanism which modulates binding affinity. Functional characterization of the BAE cell insulin receptor revealed that insulin-induced downregulation and phosphorylation of the receptor was observed, and the extent of these processes were comparable to that demonstrated in non-endothelial cell types. However, in contrast to other cell types, insulin did not stimulate deoxyglucose uptake in BAE cells. We were unable to confirm the receptor-mediated transport of insulin by the receptor across the endothelial cell monolayer as reported by a previous investigator. We could not demonstrate a role for the receptor to promote acute intracellular accumulation of insulin as postulated by several investigators. Thus, while BAE cell insulin receptor has many properties that are similiar to those in other cell types, it is distinctly different in its nondissociable binding at 4$\sp\circ$C, its interaction with insulin at 37$\sp\circ$C, and its functional role in the BAE cell. ^

Molecular mechanisms for the insulin sensitizing activity of rexinoids in skeletal muscle of diabetic (Db/Db) mice

Rexinoids are synthetic agonists for the retinoid X receptors (RXRs), a member of the nuclear receptor family of ligand-activated transcription factors. Rexinoids have been shown to lower serum glucose and insulin levels in animal models of type 2 diabetes. However the mechanisms that are responsible for the insulin-sensitizing action of rexinoids are largely unknown. Skeletal muscle accounts for the majority of insulin-regulated whole-body glucose disposal and impaired insulin action in muscle is an important contributor to the pathophysiology of type 2 diabetes. Glucose transport is a rate-limiting step in glucose utilization. The goal of these studies is to examine the mechanisms of the anti-diabetic activity of rexinoids in skeletal muscle of diabetic db/db mice. The results we have obtained showed that treatment of db/db mice with rexinoids for two weeks resulted in a significant increase in insulin-stimulated glucose transport activity in skeletal muscle. Insulin stimulates glucose transport in muscle via the regulation of both the insulin receptor substrate-1 (IRS-1)/Akt pathway and the Cbl-associated protein (CAP)/Cbl pathway. Rexinoids increased the insulin-stimulated IRS-1 tyrosine phosphorylation and Akt phosphorylation without effects on the activity of the CAP/Cbl pathway. The effects of rexinoids on the IRS-1/Akt pathway were associated with a decrease in the level of IRS-1 Serine 307 phosphorylation as well as qualitative and quantitative alterations in the fatty acyl-CoAs present within the muscle cells. In addition, rexinoids increased the expression of uncoupling protein 3 (UCP3) and activation of AMPK in diabetic muscle. This effect may also enhance the IRS-1/Akt signaling. We believe that it is the concerted activation of the IRS-1/Akt and AMPK signaling systems, a pharmacological mechanism that as far as we know, is unique to rexinoids, that results in the anti-diabetic effects of these drugs. Our results also suggest that the glucose-lowering mechanism of rexinoids is distinct from that of the thiazolidinediones (TZDs), peroxisome proliferator-activated receptor γ (PPARγ) agonists with well-characterized anti-diabetic activity. Rexinoids appear to represent a novel class of insulin sensitizers, with potential applications for the treatment of type 2 diabetes. ^

Mechanotransduction pathway activation in familial thoracic aortic aneurysms and dissections

Thoracic aortic aneurysms and dissections (TAAD) are autosomal dominantly inherited in 19% of patients. Mapping studies determined that the disease is genetically heterogeneous with multiple loci and genetic mutations accounting for familial TAAD. However, regardless of the specific mutation, resulting pathology is consistently medial degeneration, characterized by increased proteoglycans and loss of elastic fibers. We tested the hypothesis that genetic mutations leading to familial TAAD alter common pathways in aortic smooth muscle cells (SMCs). Identification of mutations at R460 in TGFBR2 reveals a 5% contribution to TAAD, however downstream analysis of Smad2 phosphorylation in the TGF-β pathway is not commonly altered in familial or sporadic disease when compared to controls. Expression profiling using Illumina's Sentrix HumanRef 8 Expression Beadchip array was done on RNA isolated from SMCs explanted from 6 patients with inherited TAAD with no identified mutation and 3 healthy controls obtained from the International Institute for the Advancement of Medicine. Significant increases in expression of proteoglycan genes in patients' SMCs, specifically lumican, podocan, and decorin were confirmed using Q-PCR and tissue immunofluorescence. NCI's Ingenuity Pathway Analysis predicted alterations in the ERK, insulin receptor and SAPK/JNK pathways (p<0.001), which SMCs activate in response to cyclic stretch. Immunoblotting indicated increased phosphorylation of ERK and GSK-3β, a protein from the insulin receptor pathway, in explanted patient SMCs, also confirmed by increased immunoreactivity against phosphorylated ERK and GSK-3β in the sub-intimal SMCs from patient tissue compared to controls. To determine if mechanotransduction pathway activation was responsible for the medial degeneration a specific inhibitor of GSK-3β, SB216763 was incubated with control cells and significantly increased the expression levels of proteoglycans. Mechanical strain was also applied to control SMCs confirming pathways stimulation with stretch. Incubation with pathway inhibitors against insulin receptor and ERK pathways identify, for the first time that stretch induced GSK-3β phosphorylation may increase proteoglycan expression, and ERK phosphorylation may regulate the expression of MMP2, a protein known to degrade elastic fibers. Furthermore, specific mutations in SMC-specific β-myosin heavy chain and α-actin, in addition to upregulation of pathways activated by cyclic stretch suggest that SMC response to hemodynamic factors, play a role in this disease. ^

Cellular Uptake of Neutrohpil Elastase Links Inflammation to Adaptive Immunity

Many tumors arise from sites of inflammation providing evidence that innate immunity is a critical component in the development and progression of cancer. Neutrophils are primary mediators of the innate immune response. Upon activation, an important function of neutrophils is release of an assortment of proteins from their granules including the serine protease neutrophil elastase (NE). The effect of NE on cancer has been attributed primarily to its ability to degrade the extracellular matrix thereby promoting invasion and metastasis. Recently, it was shown that NE could be taken up by lung cancer cells leading to degradation of insulin receptor substrate-1 thereby promoting hyperactivity of the phosphatidylinositol-3 kinase (PI3K) pathway and tumor cell proliferation. To our knowledge, nobody has investigated uptake of NE by other tumor types. In addition, NE has broad substrate specificity suggesting that uptake of NE by tumor cells could impact processes regulating tumorigenensis other than activation of the PI3K pathway. Neutrophil elastase has been identified in breast cancer specimens where high levels of NE have prognostic significance. These studies have assessed NE levels in whole tumor lysates. Because the major source of NE is from activated neutrophils, we hypothesized that breast cancer cells do not have endogenous NE but may take up NE released by tumor associated neutrophils in the tumor microenvironment and that this could provide a link between the innate immune response to tumors and specific adaptive immune responses. In this thesis, we show that breast cancer cells lack endogenous NE expression and that they are able to take up NE resulting in increased generation of low molecular weight cyclin E (CCNE) and enhanced susceptibility to lysis by CCNE-specific cytotoxic T lymphocytes. We also show that after taking up NE and proteinase 3 (PR3), a second primary granule protease with significant homology to NE, breast cancer cells cross-present the NE- and PR3-derived peptide PR1 rendering them susceptible to PR1-targeted therapies. Taken together, our data support a role for NE uptake in modulating adaptive immune responses against breast cancer.

TYPE I INSULIN-LIKE GROWTH FACTOR RECEPTOR TYROSINE KINASE AS A MOLECULAR TARGET IN MANTLE CELL LYMPHOMA

Mantle cell lymphoma (MCL) is an aggressive B-cell lymphoid malignancy representing 5-10% of all non-Hodgkin’s lymphomas. It is distinguished by the t(11;14)(q13;q32) chromosomal translocation that juxtaposes the proto-oncogene CCND1, which encodes cyclin D1 at 11q13 to the IgH gene at 14q32. MCL patients represent about 6% of all new cases of Non-Hodgkin’s lymphomas per year or about 3,500 new cases per year. MCL occurs more frequently in older adults – the average age at diagnosis is the mid-60s with a male-to-female ratio of 2-3:1. It is typically characterized by the proliferation of neoplastic B-lymphocytes in the mantle zone of the lymph node follicle that have a prominent inclination to disseminate to other lymphoid tissues, bone marrow, peripheral blood and other organs. MCL patients have a poor prognosis because they develop resistance/relapse to current non-specific therapeutic regimens. It is of note that the exact molecular mechanisms underlying the pathogenesis of MCL are not completely known. It is reasonable to anticipate that better characterization of these mechanisms could lead to the development of specific and likely more effective therapeutics to treat this aggressive disease. The type I insulin-like growth factor receptor (IGF-IR) is thought to be a key player in several different solid malignancies such as those of the prostate, breast, lung, ovary, skin and soft tissue. In addition, recent studies in our lab showed evidence to support a pathogenic role of IGF-IR in some types of T-cell lymphomas and chronic myeloid leukemia. Constitutively active IGF-IR induces its oncogenic effects through the inhibition of apoptosis and induction of transformation, metastasis, and angiogenesis. Previous studies have shown that signaling through IGF-IR leads to the vi activation of multiple signaling transduction pathways mediated by the receptor-associated tyrosine kinase domain. These pathways include PI3K/Akt, MAP kinase, and Jak/Stat. In the present study, we tested the possible role of IGF-IR in MCL. Our results demonstrate that IGF-IR is over-expressed in mantle cell lymphoma cell lines compared with normal peripheral blood B- lymphocytes. Furthermore, inhibition of IGF-IR by the cyclolignan picropodophyllin (PPP) decreased cell viability and cell proliferation in addition to induction of apoptosis and G2/M cell cycle arrest. Screening of downstream oncogenes and apoptotic proteins that are involved in both IGF-IR and MCL signaling after treatment with PPP or IGF-IR siRNA showed significant alterations that are consistent with the cellular changes observed after PPP treatment. Therefore, our findings suggest that IGF-IR signaling contributes to the survival of MCL and thus may prove to be a legitimate therapeutic target in the future.

The Role of Type I Insulin-Like Growth Factor Receptor Signaling in Breast Cancer Brain Metastasis

Brain metastasis is a common cause of mortality in cancer patients. Approximately 20-30% of breast cancer patients acquire brain metastasis, yet potential therapeutic targets remain largely unknown. The type I insulin-like growth factor receptor (IGF- IR) is known to play a role in the progression of breast cancer and is currently being investigated in the clinical setting for various types of cancer. The present study demonstrates that the IGF-IR signaling axis is constitutively active in brain-seeking sublines of breast cancer cells, driving an increase in in vitro metastatic properties. We demonstrate that IGF-IR signaling is activated in an autocrine manner as a result of IGFBP3 overexpression in brain-seeking cells. Transient and stable knockdown of IGF-IR results in a downregulation of IGF-IR downstream signaling through phospho-AKT, as well as decreased in vitro migration and invasion of MDA- MB-231Br brain-seeking cells. Using an in vivo experimental brain metastasis model, we show that IGF-IR ablation attenuates the establishment of brain metastases and prolongs survival. Finally, we demonstrate that the malignancy of brain-seeking cells is attenuated by pharmacological inhibition with picropodophyllin, an IGF-IR-specific tyrosine kinase inhibitor. Together, our data suggest that the IGF-IR is an important mediator of brain metastasis and its ablation delays the onset of brain metastases in our model system.

Insulin-associated changes in carnitine palmitoyltransferase activity are mediated through the insulin-like growth factor I pathway in the cultured neonatal rat cardiac myocyte

The mitochondrial carnitine palmitoyltransferase (CPT) system is composed of two proteins, CPT-I and CPT-II, involved in the transport of fatty acids into the mitochondrial matrix to undergo $\beta$-oxidation. CPT-I is located outside the inner membrane and CPT-II is located on the inner aspect of the inner membrane. The CPT proteins are distinct with different molecular weights and activities. The malonyl-CoA sensitivity of CPT-I has been proposed as a regulatory step in $\beta$-oxidation. Using the neonatal rat cardiac myocyte, assays were designed to discriminate between these activities in situ using digitonin and Triton X-100. With this methodology, we are able to determine the involvement of the IGF-I pathway in the insulin-mediated increase in CPT activities. Concentrations of digitonin up to 25 $\mu$M fail to release citrate synthase from the mitochondrial matrix or alter the malonyl-CoA sensitivity of CPT-I. If the mitochondrial matrix was exposed, malonyl-CoA insensitive CPT-II would reduce malonyl-CoA sensitivity. In contrast to digitonin, Triton X-100 (0.15%) releases citrate synthase from the matrix and exposes CPT-II. CPT-II activity is confirmed by the absence of malonyl-CoA sensitivity. To examine the effects of various agents on the expression and/or activity of CPT, it is necessary to use serum-free medium to eliminate mitogenic effects of serum proteins. Comparison of different media to optimize CPT activity and cell viability resulted in the decision to use Dulbecco's Modified Eagle medium supplemented with transferrin. In three established models of cardiac hypertrophy using the neonatal rat cardiac myocyte there is a significant increase in CPT-I and CPT-II activity in the treated cells. Analogous to the situation seen in the hypertrophy model, insulin also significantly increases the activity of the mitochondrial proteins CPT-I, CPT-II and cytochrome oxidase with a coinciding increase the expression of CPT-II and cytochrome oxidase mRNA. The removal of serum increases the I$\sb{50}$ (concentration of inhibitor that halves enzyme activity) of CPT-I for malonyl-CoA by four-fold. Incubation with insulin returns I$\sb{50}$ values to serum levels. Incubation with insulin significantly increases malonyl-CoA and ATP levels in the cells with a resulting reduction in palmitate oxidation. Once malonyl-CoA inhibition of CPT-I is removed by permeabilizing the cells, insulin significantly increases the oxidation of palmitoyl-CoA in a manner which parallels the increase in CPT-I activity. Interestingly, CPT-II activity increases significantly only at the tissue culture concentration (1.7 $\mu$M) of insulin suggesting that the IGF-I pathway may be involved. Supporting a role for the IGF-I pathway in the insulin-induced increase in CPT activity is the significant increase in the synthesis of both cellular and mitochondrial proteins as well as increased synthesis of CPT-II. Consistent with an IGF-mediated pathway for the effect of insulin, IGF-I (10 ng/ml) significantly increases the activities of both CPT-I and -II. An IGF-I analogue which inhibits the autophosphorylation of the IGF-I receptor blunts the insulin-mediated increase in CPT-I and -II activity by greater than 70% and virtually eliminates the IGF-I response by greater than 90%. This is the first study to demonstrate the involvement of the IGF-I pathway in the regulation of mitochondrial protein expression, e.g. CPT. ^

Insulin-like growth factor binding protein 2 (IGFBP2) promotes glioma development and progression

Overexpression of insulin-like growth factor binding protein 2 (IGFBP2) is associated with progression and poor survival in many types of human cancer (such as prostate, ovarian, adrenocortical, breast, colorectal carcinomas, leukemia, and high-grade gliomas). We therefore hypothesize that IGFBP2 is a key regulator of tumor progression. We tested our hypothesis in gliomas using the somatic gene transfer RCAS-tva mouse model system, which permits the introduction of specific genes into specific, cell lineages, in this case glial cells (RCAS: Replication competent avian sarcomavirus, tv-a: avian RCAS virus receptor). Mice are transgenic and harbor the tv-a receptor under the control of a glial-specific promoter and study genes are cloned into the RCAS vector for post-natal intracranial delivery. For these experiments, the study genes were IGFBP2, platelet-derived growth factor B (PDGFB), K-Ras, Akt, and IIp45 (invasion inhibitory protein 45 kDa; known to bind and block IGFBP2 activity), which were delivered separately and in combination. Our results show that PDGFB signaling leads exclusively to the formation of low-grade (WHO grade II) oligodendrogliomas. PDGFB delivered in combination with IGFBP2 results in the formation of anaplastic oligodendrogliomas (WHO grade III), which are characterized by increased cellularity, vascular proliferation, small regions of necrosis, increased mitotic activity, and increased activation of the Akt pathway. IIp45 injected in combination with PDGFB and IGFBP2 ablates IGFBP2-induced tumor progression, which results in formation of low-grade oligodendrogliomas, and an overall reduction in tumor incidence. K-Ras expression was required to form astrocytomas with either IGFBP2 or Akt, indicating the activation of two separate pathways is necessary for gliomagenesis. In ex vivo experiments, blockade of Akt by an inhibitor led to decreased viability of cells co-expressing IGFBP2 versus PDGFB expression alone. This study provides definitive evidence, for the first time, that: (1) IGFBP2 plays a role in activation of the Akt pathway, (2) IGFBP2 collaborates with K-Ras or PDGFB in the development and progression of two major types of glioma, and (3) IGFBP2-induced tumor progression can be ablated by IIp45 or by specific inhibition of the Akt pathway. ^