Insulin-like growth factor-I enhances the biological activity of brain-derived neurotrophic factor on cerebrocortical neurons.

Insulin-like growth factor (IGF)-I and brain-derived neurotrophic factor (BDNF) act within the brain to enhance neuronal survival and plasticity. We extend these findings by showing that the presence of both neurotrophins is required to depress the rise in intracellular Ca2+ caused by glutamate in primary cultures of cerebrocortical neurons. IGF-I enhanced expression of BDNF receptors (Trk-B) and increased the ability of BDNF to induce ERK1/2 phosphorylation. This IGF-I-induced increase in BDNF responsiveness describes a new interaction between these peptides in the brain.

C-jun N-terminal kinase mediates tumor necrosis factor-alpha suppression of differentiation in myoblasts.

The stress kinase c-jun N-terminal kinase (JNK) was recently shown to be involved in the pathophysiology of major inflammatory conditions, including Alzheimer's disease, stroke, obesity, and type II diabetes. However, the role of JNK in regulating inflammatory events in skeletal muscle is only beginning to be explored. IGF-I is the major hormone that promotes muscle growth and development. Here we used a novel, JNK interacting protein (JIP)-derived JNK peptide inhibitor to establish that JNK suppresses the biological activity of IGF-I in skeletal muscle progenitor cells. In these myoblasts, TNFalpha and its downstream receptor substrates, neutral-sphingomyelinase (N-SMase) and N-acetyl-d-sphingosine (C2-ceramide), induce JNK kinase activity in a time-dependent manner. Consistent with these results, TNFalpha induces JNK binding to insulin receptor substrate 1 (IRS-1) but is unable to inhibit IGF-I-induced IRS-1 tyrosine phosphorylation in myoblasts that are treated with the JNK peptide inhibitor. More importantly, JNK activation induced by TNFalpha, C2-ceramide, and N-SMase is associated with reduced expression of the critical muscle transcription factor myogenin as well as the differentiation marker myosin heavy chain (MHC). The JNK peptide inhibitor, but not the control peptide, completely reverses this inhibition of both myogenin and MHC. In the absence of IGF-I, TNFalpha, C2-ceramide, N-SMase and the JNK inhibitor are inactive, as shown by their inability to affect IRS tyrosine phosphorylation and protein expression of myogenin and MHC. These results establish that the resistance of muscle progenitor cells to IGF-I, which is caused by inflammatory stimuli, is mediated by the JNK stress kinase pathway.

Hyperammonemia increases sensitivity to LPS.

Metabolic and cognitive alterations occur during hyperammonemia. Here, we report that chronic hyperammonemia also leads to increased sensitivity to LPS. Sparse-fur mice were challenged i.p. with LPS or saline control and then tested for motivation to investigate a novel juvenile over 24 h. Cytokine, ammonia, and urea concentration were quantified at the peak of sickness (2 h post injection). Chronic hyperammonemic Otc(spf-ash) mice displayed more pronounced and prolonged sickness behavior in response to LPS (P=0.02). LPS significantly (P<0.0001) increased plasma concentrations of TNFalpha, IL-1 beta, IL-6, IL-15, IL-9, IL-2, IL-1 alpha, IL-1 beta, Rantes, MIP1 alpha, MIP1 beta, MCP-1, KC, GM-CSF, G-CSF, Eotaxin, IL-13, and IL-12 in both wild type and Otc(spf-ash) mice. No significant genotype/treatment interactions (P>0.1) were detected for any cytokine. Adult Otc(spf-ash) mice (168+/-41 microM) had four times higher plasma ammonia compared to wild type mice (40 +/- 6 microM) (P=0.002). Two hours after LPS injection, plasma ammonia concentrations tended (P=0.08) to decrease in both wild type and Otc(spf-ash) mice. Learning and memory behaviors were assessed in mice under basal conditions to determine the impact of chronic hyperammonemia on cognition. Otc(spf-ash) mice performed significantly poorer in the two trial Y-maze (P=0.02) and the Morris water maze (P=0.001) than their littermate wild type controls. Taken together, these data indicate that chronic hyperammonemia results in impaired cognition and creates a state of LPS hypersensitivity.

Proinflammatory cytokine impairment of insulin-like growth factor I-induced protein synthesis in skeletal muscle myoblasts requires ceramide.

GH and IGF-I control over 80% of postnatal growth. We recently established that TNFalpha impairs the ability of IGF-I to increase protein synthesis and promote expression of myogenin in myoblasts. Here we extend these results by showing that ceramide, a second messenger in both TNFalpha and IL-1beta receptor signaling pathways, is a key downstream sphingosine-based lipid that leads to IGF-I resistance. A cell-permeable ceramide analog, C2-ceramide, inhibits IGF-I-induced protein synthesis by 65% and blocks the ability of IGF-I to increase expression of two key myogenic factors, myogenin and MyoD. Identical results were obtained with both TNFalpha and IL-1beta (1 ng/ml). Consistent with these data, neutral sphingomyelinase (N-SMase), an enzyme that catalyzes formation of ceramide from sphingomyelin, blocks IGF-I-induced protein synthesis and expression of both myogenin and MyoD. The possibility that cytokine-induced ceramide production is required for disruption of IGF-I biologic activity was confirmed by treating C2C12 myoblasts with inhibitors of all three ceramide-generating pathways. A N-SMase inhibitor, glutathione, as well as an acidic sphingomyelinase (A-SMase) inhibitor, D609, reverse the cytokine inhibition of IGF-I-induced protein synthesis by 80% and 45%, respectively. Likewise, an inhibitor of de novo ceramide synthesis, FB1, causes a 50% inhibition. Similarly, all three inhibitors significantly impair the ability of both TNFalpha and IL-1beta to suppress IGF-I-driven expression of myogenin. These experiments establish that ceramide, derived both from sphingomyelin and de novo synthesis, is a key intermediate by which proinflammatory cytokines impair the ability of IGF-I to promote protein synthesis and expression of critical muscle-specific transcription factors.

IL-1beta suppresses prolonged Akt activation and expression of E2F-1 and cyclin A in breast cancer cells.

Cell cycle aberrations occurring at the G(1)/S checkpoint often lead to uncontrolled cell proliferation and tumor growth. We recently demonstrated that IL-1beta inhibits insulin-like growth factor (IGF)-I-induced cell proliferation by preventing cells from entering the S phase of the cell cycle, leading to G(0)/G(1) arrest. Notably, IL-1beta suppresses the ability of the IGF-I receptor tyrosine kinase to phosphorylate its major docking protein, insulin receptor substrate-1, in MCF-7 breast carcinoma cells. In this study, we extend this juxtamembrane cross-talk between cytokine and growth factor receptors to downstream cell cycle machinery. IL-1beta reduces the ability of IGF-I to activate Cdk2 and to induce E2F-1, cyclin A, and cyclin A-dependent phosphorylation of a retinoblastoma tumor suppressor substrate. Long-term activation of the phosphatidylinositol 3-kinase/Akt signaling pathway, but not the mammalian target of rapamycin or mitogen-activated protein kinase pathways, is required for IGF-I to hyperphosphorylate retinoblastoma and to cause accumulation of E2F-1 and cyclin A. In the absence of IGF-I to induce Akt activation and cell cycle progression, IL-1beta has no effect. IL-1beta induces p21(Cip1/Waf1), which may contribute to its inhibition of IGF-I-activated Cdk2. Collectively, these data establish a novel mechanism by which prolonged Akt phosphorylation serves as a convergent target for both IGF-I and IL-1beta; stimulation by growth factors such as IGF-I promotes G(1)-S phase progression, whereas IL-1beta antagonizes IGF-I-induced Akt phosphorylation to induce cytostasis. In this manner, Akt serves as a critical bridge that links proximal receptor signaling events to more distal cell cycle machinery.

IL-1beta impairs insulin-like growth factor i-induced differentiation and downstream activation signals of the insulin-like growth factor i receptor in myoblasts.

Proinflammatory cytokines are elevated in disorders characterized by muscle wasting and weakness, such as inflammatory myopathies and AIDS wasting. We recently demonstrated that TNF-alpha impairs the ability of insulin-like growth factor (IGF)-I to promote protein synthesis in muscle precursor cells. In this study we extend these findings by showing that low concentrations of IL-1beta impair IGF-I-dependent differentiation of myoblasts, as assessed by expression of the muscle specific protein, myosin heavy chain. In the absence of exogenous IGF-I, IL-1beta (1 ng/ml) did not impair muscle cell development. However, in the presence of IGF-I, 100-fold lower concentrations of IL-1beta (0.01 ng/ml) significantly suppressed myoblast differentiation, protein synthesis, and myogenin expression. Increasing IL-1beta to 1 ng/ml completely blocked the anabolic actions of IGF-I in murine C(2)C(12) myoblasts. Similarly, IL-1beta inhibited IGF-I-stimulated protein synthesis in primary porcine myoblasts. IL-1beta impaired the actions of IGF-I at a point distal to the IGF receptor, and this was not due to IL-1beta-induced cell death. Instead, IL-1beta inhibited the ability of IGF-I to phosphorylate tyrosine residues on both of its downstream docking proteins, insulin receptor substrate 1 and insulin receptor substrate 2. These data establish that physiological concentrations of IL-1beta block the ability of IGF-I to promote protein synthesis, leading to reduced expression of the myogenic transcription factor, myogenin, and the subsequent development of more mature differentiated cells that express myosin heavy chain. Collectively, the results are consistent with the notion that very low concentrations of IL-1beta significantly impair myogenesis, but they are unable to do so in the absence of the growth factor IGF-I.

Tumor necrosis factor alpha inhibits insulin-like growth factor I-induced hematopoietic cell survival and proliferation.

Proinflammatory cytokines, such as TNFalpha and IL-1beta, are both cytostatic and cytotoxic. In contrast, IGF-I promotes proliferation and survival of hematopoietic progenitor cells. In this report, we establish that both the cytostatic and cytotoxic activity of TNFalpha on murine myeloid progenitor cells is only evident in the presence of IGF-I. We first confirmed that IGF-I (100 ng/ml) increases DNA synthesis and reduces apoptosis in murine myeloid progenitor cells induced to die by growth factor withdrawal. TNFalpha inhibits, in a dose-dependent fashion from 0.1 to 10 ng/ml, both activities of IGF-I. TNFalpha activity was not detected in the absence of IGF-I. Another proinflammatory cytokine, IL-1beta, did not inhibit IGF-I-induced activity in murine factor-dependent cell progenitor-1/Mac-1 cells. However, the ability of TNFalpha to impair IGF-I-induced DNA synthesis in human promyeloid cells extends to IL-1beta. Statistically significant inhibition of all these events occurs at very low concentrations of 1 ng/ml or less. These results support the general concept that proinflammatory cytokines impair the actions of hormones on hematopoietic cells, leading to IGF-I receptor resistance.

Tumor necrosis factor alpha inhibits cyclin A expression and retinoblastoma hyperphosphorylation triggered by insulin-like growth factor-I induction of new E2F-1 synthesis.

Cyclin A is required for cell cycle S phase entry, and its overexpression contributes to tumorigenesis. Release of pre-existing E2Fs from inactive complexes of E2F and hypophosphorylated retinoblastoma (RB) is the prevailing dogma for E2F transcriptional activation of target genes such as cyclin A. Here we explored the hypothesis that new synthesis of E2F-1 is required for insulin-like growth factor-I (IGF-I) to induce cyclin A accumulation and RB hyperphosphorylation, events that are targeted by tumor necrosis factor alpha (TNFalpha) to arrest cell cycle progression. We first established that IGF-I increases expression of cyclin A, causes hyperphosphorylation of RB, and augments the mass of E2F-1 in a time-dependent manner. As expected, E2F-1 small interfering RNA blocks the ability of IGF-I to increase synthesis of E2F-1. Most important, this E2F-1 small interfering RNA also blocks the ability of IGF-I to increase cyclin A accumulation and to hyperphosphorylate RB. We next established that TNFalpha dose-dependently inhibits IGF-I-induced phosphorylation of both RB and histone H1 by cyclin A-dependent cyclin-dependent kinases. Cyclin-dependent kinase 2 (Cdk2) mediates this suppression because co-immunoprecipitation experiments revealed that TNFalpha reduces the amount of IGF-I-induced cyclin A that binds Cdk2, leading to a reduction in Cdk2 enzymatic activity. TNFalpha antagonizes the ability of IGF-I to increase mass of both E2F-1 and cyclin A but not cyclin E or D1. The cytostatic property of TNFalpha is also shown by its ability to block IGF-I-stimulated luciferase activity of a cyclin A promoter reporter. Deletion of an E2F recognition site from this reporter eliminates the regulatory effects of both IGF-I and TNFalpha on cyclin A transcription, indicating the essential role of E2F-1 in mediating their cross-talk. Collectively, these results establish that TNFalpha targets IGF-I-induced E2F-1 synthesis, leading to inhibition of the subsequent accumulation in cyclin A, formation of cyclin A-Cdk2 complexes, hyperphosphorylation of RB, and cell cycle arrest.

Cytokine-hormone interactions: tumor necrosis factor alpha impairs biologic activity and downstream activation signals of the insulin-like growth factor I receptor in myoblasts.

TNFalpha is elevated following damage to skeletal muscle. Here we provide evidence that TNFalpha acts on muscle cells to induce a state of IGF-I receptor resistance. We establish that TNFalpha inhibits IGF-I-stimulated protein synthesis in primary porcine myoblasts. Similar results were observed in C(2)C(12) murine myoblasts, where as little as 0.01 ng/ml TNFalpha significantly inhibits protein synthesis induced by IGF-I. TNFalpha also impairs the ability of IGF-I to induce expression of a key myogenic transcription factor, myogenin. The inhibition by TNFalpha of IGF-I-induced protein synthesis and expression of myogenin is not due to direct killing of myoblasts by TNFalpha. Although IGF-I induces an approximately 19-fold induction in tyrosine phosphorylation of the beta-chains of its receptor, TNFalpha does not inhibit this autophosphorylation. Instead, TNFalpha significantly reduces by approximately 50% IGF-I-stimulated tyrosine phosphorylation of two of the major downstream receptor docking molecules, insulin receptor substrate (IRS)-1 and IRS-2. These results establish that low picogram concentrations of TNFalpha acts on both porcine and murine myoblasts to impair tyrosine phosphorylation of both IRS-1 and IRS-2, but not the receptor itself. These data are consistent with the notion that very low physiological concentrations of TNFalpha interfere with both protein synthesis and muscle cell development by inducing a state of IGF-I receptor resistance.

Cytokine-induced sickness behavior.

The behavioral repertoire of humans and animals changes dramatically following infection. Sick individuals have little motivation to eat, are listless, complain of fatigue and malaise, loose interest in social activities and have significant changes in sleep patterns. They display an inability to experience pleasure, have exaggerated responses to pain and fail to concentrate. Proinflammatory cytokines acting in the brain cause sickness behaviors. These nearly universal behavioral changes are a manifestation of a central motivational state that is designed to promote recovery. Exaggerated symptoms of sickness in cancer patients, such as cachexia, can be life-threatening. However, quality of life is often drastically impaired before the cancer becomes totally debilitating. Although basic studies in psychoneuroimmunology have defined proinflammatory cytokines as the central mediators of sickness behavior, a much better understanding of how cytokine and neurotransmitter receptors communicate with each other is needed. Advances that have been made during the past decade should now be extended to clinical studies in an attempt to alleviate sickness symptoms and improve quality of life for cancer patients.

Insulin-like growth factor-I and the cytokines IL-3 and IL-4 promote survival of progenitor myeloid cells by different mechanisms.

Hormones, such as insulin-like growth factor-I (IGF-I), and cytokines, like IL-3 and IL-4, promote survival of progenitor myeloid cells. Here we demonstrate that IGF-I, IL-3 and IL-4 all significantly block activation of caspase-3 in promyeloid cells following growth factor deprivation. However, only IL-3 and IGF-I increase enzymatic activity and phosphorylation of the survival-promoting kinase Akt. IGF-I fails to reduce caspase-3 activity and cell death in the presence of the PI 3-kinase inhibitors, wortmannin and LY294002, whereas these blockers do not affect the ability of IL-3 to maintain cell survival. IL-4 inhibits caspase-3 activity and promotes promyeloid cell survival by a substrate for PI 3-kinase that is not Akt. These data establish that IGF-I inhibits activation of caspase-3 and promotes promyeloid cell survival through a PI 3-kinase-dependent pathway, whereas IL-3 does not. It therefore appears that signal transduction pathways for all three receptors converge upstream of caspase-3 to prevent apoptosis of progenitor myeloid cells, but their receptors differ in the intracellular substrates that are used to promote cell survival.

Proinflammatory cytokines block growth of breast cancer cells by impairing signals from a growth factor receptor.

Neutralization of endogenous growth factors and administration of exogenous bioactive cytokines are two distinct biological antitumor strategies that show promise for treatment of cancer patients. In this report, we provide evidence to link both strategies as an integrative approach to cancer therapy. We tested the hypothesis that proinflammatory cytokines block growth of transformed cells by inhibiting key intracellular signaling events after activation of the insulin-like growth factor-I (IGF-I) tyrosine kinase receptor. IGF-I stimulates DNA synthesis in MCF-7 cells by 15-fold. This increase is significantly inhibited by TNF (tumor necrosis factor) -alpha at 0.1 ng/ml and is reduced by 80% at 100 ng/ml. Similarly, both IL (interleukin) -1beta and IL-6 significantly reduce the ability of IGF-I to promote DNA synthesis. Flow cytometry confirmed that all three of the cytokines inhibit IGF-I-induced DNA synthesis by preventing cells from entering the S phase of the cell cycle, leading to G(0)/G(1) arrest. Although none of the cytokines alone are cytotoxic to transformed epithelial cells in the absence of serum, TNF-alpha significantly inhibits the antiapoptotic property of IGF-I in protecting MCF-7 cells from DNA fragmentation. TNF-alpha and IL-1beta act by inhibiting the IGF-I receptor from tyrosine phosphorylating insulin receptor substrate-1 without affecting tyrosine kinase activity of the IGF-IR itself. These data support the novel idea that the major inhibitory properties of proinflammatory cytokines on growth of breast cancer cells are manifested prominently in the presence of growth factors. These data also highlight growth factor receptor adaptor molecules, such as insulin receptor substrate-1, rather than the receptors themselves as targets for antitumor therapeutic strategies.

Age-associated loss of bone marrow hematopoietic cells is reversed by GH and accompanies thymic reconstitution.

Deterioration of the thymus gland during aging is accompanied by a reduction in plasma GH. Here we report gross and microscopic results from 24-month-old Wistar-Furth rats treated with rat GH derived from syngeneic GH3 cells or with recombinant human GH. Histological evaluation of aged rats treated with either rat or human GH displayed clear morphologic evidence of thymic regeneration, reconstitution of hematopoietic cells in the bone marrow, and multiorgan extramedullary hematopoiesis. Quantitative evaluation of formalin-fixed, hematoxylin and eosin-stained sections of bone marrow from aged rats revealed at least a 50% reduction in the number hematopoietic bone marrow cells, compared with that of young 3-month-old rats. This age-associated decline in bone marrow leukocytes, as well as the increase in bone marrow adipocytes, was significantly reversed by in vivo treatment with GH. Restoration of bone marrow cellularity was caused primarily by erythrocytic and granulocytic cells, but all cell lineages were represented and their proportions were similar to those in aged control rats. On a per-cell basis, GH treatment in vivo significantly increased the number of in vitro myeloid colony forming units in both bone marrow and spleen. Morphological evidence of enhanced extramedullary hematopoiesis was observed in the spleen, liver, and adrenal glands from animals treated with GH. These results confirm that GH prevents thymic aging. Furthermore, these data significantly extend earlier findings by establishing that GH dramatically promotes reconstitution of another primary hematopoietic tissue by reversing the accumulation of bone marrow adipocytes and by restoring the number of bone marrow myeloid cells of both the erythrocytic and granulocytic lineages.

IL-10 promotes survival of microglia without activating Akt.

IL-10 is an anti-inflammatory cytokine that has recently been shown to promote survival of neurons and glia. Here we establish that IL-10 induces phosphorylation of Stat3 on Tyr(705) and serves as a survival factor for N13 microglial cells. Recombinant IL-10 (10 ng/ml) decreases growth factor withdrawal-induced apoptosis by 50%, as assessed by TUNEL. In contrast to IL-10, IGF-I increases enzymatic activity of PI 3-kinase and causes phosphorylation on serine(473) of Akt but does not prevent microglial apoptosis. These data establish that IL-10 activates Stat3 and inhibits the mitochondrial pathway of cell death without activating the Akt cell survival pathway.