Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.1.1.34 (lipoprotein lipase)
 7,025 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cachectin/tumor necrosis factor (TNF-alpha) is a macrophage-secreted cytokine initially found to be a lipoprotein lipase-suppressing serum factor in cachectic, parasite-infected animals. Cloning of the cDNA encoding the gene for cachectin enabled biosynthesis of recombinant human cachectin and proof that the protein is identical to TNF-alpha. Numerous biological activities have subsequently been attributed to this pluripotent cytokine. In addition to suppressing LPL, cachectin/TNF mediates decreased lipogenic enzyme synthesis in adipocytes, causing a state of "cellular cachexia" in vitro. Similarly, catabolic cellular energy responses are induced by cachectin/TNF in cultured skeletal muscle cells which exhibit accelerated glycogenolysis, enhanced lactate production, and increased expression of hexose transporters. Persistent cachectin/TNF production occurs in chronic infection and malignancy, and chronic exposure induces a cachexia syndrome characterized by anorexia, weight loss, and anemia. Acute systemic appearance of cachectin/TNF is capable of inducing a state of lethal shock, disseminated hemorrhagic necrosis, catabolic hormone release, and multiple organ injury. Inhibiting the toxic effects of cachectin/TNF with monoclonal anti-cachectin antibodies during overwhelming Gram-negative bacteremia confers protection against septic shock. In these studies, the unprotected controls succumbed within hours, but baboons immunized against cachectin/TNF did not develop the characteristic increases of IL-1, IL-6, or catabolic stress hormones and did not die, suggesting that cachectin/TNF is a pivotal, proximal factor in the humoral cascade mediating septic shock syndrome. Recent evidence indicates that when produced in lesser quantities, cachectin/TNF may participate in the degradative and reparative mechanisms of physiological tissue remodelling and homeostasis. Future studies of the immunological and metabolic effects of cachectin/TNF should lead to a better understanding of the pathogenesis of infection and inflammation.
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PMID:Metabolic responses to cachectin/TNF. A brief review. 219 78

The administration of a single injection of tumor necrosis factor (TNF) produces a variety of acute and sustained biological effects, including hyperlipidemia, stimulation of hepatic lipogenesis, decreases in adipose tissue lipoprotein lipase activity, and anorexia with weight loss. Chronic administration of a fixed dose of TNF produces tachyphylaxis to the anorectic/cachectic effects of TNF. We now report that the hyperlipidemic effect of TNF persists during chronic TNF administration in the absence of any cachectic effect of TNF. Sprague-Dawley rats injected with TNF (250 micrograms/kg) show a significant decrease in weight over the next 24 h which can be accounted for by decreases in food and water intake accompanied by an increase in urine output. With subsequent daily injections of TNF, treated rats begin eating and rapidly regain weight. Hypertriglyceridemia persists for up to 10 days of daily injections of TNF. After three daily injections of TNF, no decreases were seen in lipoprotein lipase activity in a wide variety of tissues. De novo hepatic lipogenesis remained increased in TNF-treated animals after four daily injections, but by the fifth day hepatic lipogenesis returned to normal. After 5 days of TNF treatment the acute incorporation of labeled glycerol into serum triglycerides remained elevated. These data indicate that hyperlipidemia persists during multiple daily injections of TNF and that TNF induced hypertriglyceridemia is not inevitably linked to the syndrome of cachexia.
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PMID:Persistence of the hypertriglyceridemic effect of tumor necrosis factor despite development of tachyphylaxis to its anorectic/cachectic effects in rats. 271 42

Mammals infected with parasitic, bacterial or viral organisms or bearing tumours characteristically display a catabolic state and weight loss which can advance to cachexia (or wasting), shock and death. Although the phenomenon is commonly observed in many parasitic diseases its mechanism is not understood. We have identified and isolated a macrophage protein, cachectin, as the molecule that may be responsible for cachexia and shock. Cachectin is produced by macrophages in response to endotoxin or a number of other bacterial or protozoal products. The released cachectin acts as a hormone, binding to specific high affinity receptors and eliciting biological responses. In the adipocyte anabolic enzymes such as lipoprotein lipase are suppressed through the selective inhibition of mRNA production. An intriguing aspect of cachectin is its pivotal role in the pathogenesis of endotoxin-induced shock. Cachectin causes fever and anorexia and can induce lethal shock and tissue injury in experimental animals. During its chemical characterization cachectin was shown to be identical to tumour necrosis factor (TNF), a macrophage protein that kills tumour cells. This finding emphasizes the extensive range of effects associated with this protein. Cachectin has many properties in common with interleukin 1 but binds to a different receptor and lacks structural homology. Presumably, low levels of cachectin help the host in its battle to remove invasive pathogens, but extensive production of cachectin can lead to shock and catabolic stress hormone responses. These findings have added a new dimension to the biological properties of cachectin, its production, and its role in cachexia and shock.
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PMID:Physiological responses to cachectin. 283 40

Progressive weight loss and anorexia are frequent phenomena in cancer patients. Although cachexia is an expected occurrence in the terminal stages of nearly all malignancies, it may be a presenting sign when the tumor burden is quite small. Lipid depletion occurs out of proportion to the protein loss and accounts for most of the weight loss in cancer. Lipids, more specifically fatty acids, are the major source of fuel in mammals and may also be used in the synthesis of new cell products. Lipolysis and lipogenesis are under the influence of several important enzymes and peptide hormones that may be modulated by a variety of exogenous factors. There is evidence that cancer patients have lost the normal homeostatic responses to decreased energy intake or starvation that allow a decrease in oxygen consumption and protein sparing. An increase in Cori cycle activity or futile recycling of metabolic products occurs with a net energy expenditure rather than energy production. Clinical studies have shown that the body lipid depletion accompanying tumor progression is not solely secondary to decreased food intake and may be reproduced by the transplantation of certain noninvasive tumors to normal hosts. Elevated basal lipolysis has occasionally been seen early in tumor growth. Such findings suggest the presence of a tumor-associated factor responsible for this increase in lipid mobilization. Some of the potential mechanisms for the altered lipid metabolism seen in cancer have been discussed. Metabolic substrates may be remodeled and directed away from fuel-efficient into energy-requiring pathways. An increased energy expenditure may occur as a result of the energy costs of tumor synthesis, an uncoupling of oxidative phosphorylation, or energy-requiring futile cycling. An overall depletion of lipid may be the final outcome of the inhibition of lipid deposition. TNF/cachectin has recently been found to suppress the activity and synthesis of several key lipogenic enzymes, including lipoprotein lipase. Abnormalities in insulin secretion or sensitivity may be involved in the decrease of fat storage in malignancy. Insulin also exerts a significant antilipolytic effect by its antagonism of hormone-sensitive lipase. Mediators of lipolysis and abnormal lipid metabolism may occur in a number of clinical conditions and include ectopic hormone production, growth factors, and tumor-associated lipolytic factors (lipid mobilizing factor, toxohormone).
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PMID:Fat metabolism and cancer. 353 75

Rates of lipogenesis and lipoprotein lipase (LPL) activity were measured in liver, adipose tissue, heart, and tumor at several stages during 10 days of palpable growth of a transplantable Leydig cell tumor in rats. This model showed the same characteristics as human cancer cachexia, including anorexia, weight loss, and muscle wasting. Comparison with pair-fed controls showed that the rate of loss of body fat was greater than could be explained by anorexia alone. The rate of lipogenesis tended to decrease during the later stages of tumor growth, particularly in the liver, where there was a statistically significant reduction on Days 5 and 10. This may be largely attributable to decreased availability of substrates caused by decreasing food intake and increasing glucose uptake by the tumor. There was a significant decrease in plasma glucose concentration by Day 10. In contrast, LPL activity in adipose tissue was depressed from the earliest stage of tumor growth, and this is likely to be a major cause of lipid depletion in cancer. There was no difference in adipose tissue LPL activity between the fed and postabsorptive states in the tumor-bearing rats, indicating that the normal response to nutrient intake was impaired. Thus, treatment of cancer cachexia should concentrate on normalizing the metabolic response to nutrient ingestion.
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PMID:Lipid metabolism in cachectic tumor-bearing rats at different stages of tumor growth. 844 17

Cachexia is a common problem in the clinical management of cancer patients, particularly those with solid tumors. Cachexia is most obviously manifested as weight loss with massive depletion of both adipose tissue and muscle mass, and death is probably due to loss of lean body tissue. Not only is the survival time shorter in patients with cachexia, but the frequency of response to chemotherapy is also significantly reduced. Although anorexia frequently accompanies cachexia, attempts to halt or reverse cachexia by nutritional repletion have not been successful. This suggests that cachexia is due to metabolic abnormalities produced by the tumor in addition to the underlying anorexia. In some patients weight loss is associated with an increased relative energy expenditure possibly through an elevated adrenergic state. Several factors have been postulated as mediators of cancer cachexia and can be divided into two groups. (i) Materials with hormone-like characteristics which result in direct catabolism of host tissues. (ii) Cytokines which cause alterations in host metabolism indirectly. Included in group (i) are the conventional catabolic hormones and a lipid mobilizing factor (LMF) produced by tumors, which causes direct breakdown of adipose tissue. Included in group (ii) are tumor necrosis factor-alpha, interleukin-6, interferon-gamma and leukaemia inhibitory factor. The materials appear to influence adipose tissue indirectly through an inhibition of lipoprotein lipase. Reversal of cachexia has been achieved by two groups of agents. (i) Those stimulating food intake, e.g. megestrol acetate. (ii) Those directly inhibiting the LMF, e.g. eicosapentaenoic acid. While agents in group (i) can cause tumor growth stimulation, those in group (ii) act as tumor growth inhibitors. This latter results suggests that the products of catabolism of host tissues may be important for tumor growth and provides a new avenue for chemotherapeutic intervention.
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PMID:Cancer cachexia. 849 Jan 91

Progressive weight loss is a common feature of many types of cancer and is responsible not only for a poor quality of life and poor response to chemotherapy, but also a shorter survival time than is found in patients with comparable tumors without weight loss. Although anorexia is common, a decreased food intake alone is unable to account for the changes in body composition seen in cancer patients, and increasing nutrient intake is unable to reverse the wasting syndrome. Although energy expenditure is increased in some patients, cachexia can occur even with a normal energy expenditure. Various factors have been investigated as mediators of tissue wasting in cachexia. These include cytokines such as tumor necrosis factor-alpha (TNF-alpha), interleukin-6 (IL-6), interferon-gamma (IFN-gamma) and leukemia inhibitory factor (LIF), as well as tumor-derived factors such as lipid mobilizing factor (LMF) and protein mobilizing factor (PMF), which can directly mobilize fatty acids and amino acids from adipose tissue and skeletal muscle respectively. Induction of lipolysis by the cytokines is thought to result from an inhibition of lipoprotein lipase (LPL), although clinical studies provide no evidence for an inhibition of LPL in the adipose tissue of cancer patients. Instead there is an increased expression of hormone sensitive lipase, the enzyme activated by LMF. Protein degradation in cachexia is associated with an increased activity of the ATP-ubiquitin-proteasome pathway. The biological activity of both the LMF and PMF was shown to be attenuated by eicosapentaenoic acid (EPA). Clinical studies show that this polyunsaturated fatty acid is able to stabilize the rate of weight loss and adipose tissue and muscle mass in cachectic patients with unresectable pancreatic cancer. Knowledge of the mechanism of cancer cachexia should lead to the development of new therapeutic agents.
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PMID:Wasting in cancer. 991 7

Tumor necrosis factor (TNF, cachectin), a cytokine secreted by macrophages and T-cells, mediates inflammatory and immune responses, and is associated with wasting in persons with malignancies or AIDS. In inflammation, TNF attracts and activates neutrophils, stimulating phagocytic function of neutrophils and macrophages. TNF also increases hepatic cell resistance to damaging parasitic effects; enhances endothelial permeability, causing edema; aids in wound healing by stimulating tissue and vascular growth; enhances lymphocytic activity through cytokine activation; acts with interleukin (IL) to produce fever, anorexia, lethargy and sleep; and possesses antitumor activity, particularly against the presumed origin of Kaposi's sarcoma, capillary endothelial cells. The host has an acute phase response (APR) following TNF- and IL-induced immunologic activation. TNF and IL decrease production and activity of lipoprotein lipase (LPL), resulting in reduced uptake and improper storage of fat; and they stimulate anabolism of fatty acids, causing hypertriglyceridemia. This "futile cycling" causes shuttling of fatty acids between adipose tissue and the liver, and use of muscle protein as the main fuel source. This, along with further muscular breakdown due to the increased caloric demands of fever, may affect cachexia. TNF benefits the HIV-infected through selective killing of HIV-infected cells, although effects may be dose and time dependent. The negative effects of TNF may be impeded by anti-cytokine therapy. Possible therapies include dietary N-3 fatty acid (fish oil), an inhibitor of TNF and IL production in vitro; pentoxifylline (Trental), another TNF production inhibitor; anti-TNF monoclonal antibodies; and soluble TNF receptors.
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PMID:Tumor necrosis factor: its role in HIV/AIDS. 1136 96

Administration of the phosphodiesterase-IV inhibitor EMD 95832/3 (Merck KGaA, Darmstadt, Germany) to rats bearing the ascites hepatoma Yoshida AH-130, a highly cachectic tumour, could not prevent either the anorexia nor the massive weight loss (affecting both adipose and skeletal muscle tissues) present in the tumour-bearing animals. This compound did not have any effects on the fractional rates of protein turnover in skeletal muscle, and did not affect circulating triacylglycerols or lipoprotein lipase activity in adipose tissue. Although the administration of EMD 95832/3 did not influence tumour growth either, it did increase the number of tumour cells undergoing apoptosis. It is concluded that the drug is unable to reverse the cachectic state in this particular experimental tumour model.
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PMID:Effects of the phosphodiesterase-IV inhibitor EMD 95832/3 on tumour growth and cachexia in rats bearing the Yoshida AH-130 ascites hepatoma. 1240 48

Eating and appetite disorders are frequent complications of the uremic syndrome which contribute to malnutrition in dialysis patients. The data suggest that uremic anorexia may occur with or without abdominal and visceral fat accumulation despite a lower food intake. This form of obesity (i.e., with low food intake and malnutrition) is more common in dialysis patients than obesity with high food intake. This article reviews the current knowledge regarding mechanisms responsible for appetite regulation in normal conditions and in uremic patients. Anorexia in dialysis patients has been historically considered as a sign of uremic toxicity due to "inadequate" dialysis as judged by uncertain means ("middle molecule" accumulation, Kt/V, "peak-concentration hypothesis," and others). We propose the tryptophan-serotonin hypothesis, based on a uremia-induced disorder in patients' amino acid profile--low concentrations of large neutral and branched-chain amino acids with high tryptophan levels. A high rate of tryptophan transport across the blood-brain barrier increases the synthesis of serotonin, a major appetite inhibitor. Inflammation may also play a role in the genesis of anorexia and malnutrition. For example, silent infection with Helicobacter pylori may be a source of cytokines with cachectic action; its eradication improves appetite and nutrition. The evaluation of appetite should take into account cultural and social aspects. Uremic patients showed a universal trend to carbohydrate preference and red meat refusal compared to healthy people. In contrast, white meat was less problematic. Uremic patients also have a remarkable attraction for citrics and strong flavors in general. Eating preferences or refusals have been related to the predominance of some appetite peptide modulators. High levels of cholecystokinin (CCK) (a powerful anorexigen) are associated with early satiety for carbohydrates and neuropeptide Y (NPY) (an orexigen) with repeated food intake. Obesity and elevated body mass index often falsely suggest a good nutritional status. In uremic patients (a hyperinsulinemia state), disorders in the regulation of fat distribution (insulin, leptin, insulin-like growth factor [IGF]-1, fatty acids, and disorders in receptors for insulin, lipoprotein lipase, mitochondrial uncoupling protein-2, and beta 3 adrenoreceptors) may cause abdominal fat accumulation without an increase in appetite. Finally, appetite regulation in uremia is highly complex. Disorders in adipose tissue, gastrointestinal and neuropeptides, retained or hyperproduced inflammatory end products, and central nervous system changes may all play a role. Uremic anorexia may be explained by a hypothalamic hyperserotoninergic state derived from a high concentration of tryptophan and low branched-chain amino acids.
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PMID:Eating behavior disorders in uremia: a question of balance in appetite regulation. 1471 11


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