I have developed "tennis elbow" from lugging this book around the past four weeks, but it is worth the pain, the effort, and the aspirin. It is also worth the (relatively speaking) bargain price. Including appendixes, this book contains 894 pages of text. The entire panorama of the neural sciences is surveyed and examined, and it is comprehensive in its scope, from genomes to social behaviors. The editors explicitly state that the book is designed as "an introductory text for students of biology, behavior, and medicine," but it is hard to imagine any audience, interested in any fragment of neuroscience at any level of sophistication, that would not enjoy this book. The editors have done a masterful job of weaving together the biologic, the behavioral, and the clinical sciences into a single tapestry in which everyone from the molecular biologist to the practicing psychiatrist can find and appreciate his or

Principles of Neural Science

Insulin resistance is a cardinal feature of type 2 diabetes and is characteristic of a wide range of other clinical and experimental settings. Little is known about why insulin resistance occurs in so many contexts. Do the various insults that trigger insulin resistance act through a common mechanism? Or, as has been suggested, do they use distinct cellular pathways? Here we report a genomic analysis of two cellular models of insulin resistance, one induced by treatment with the cytokine tumour-necrosis factor-alpha and the other with the glucocorticoid dexamethasone. Gene expression analysis suggests that reactive oxygen species (ROS) levels are increased in both models, and we confirmed this through measures of cellular redox state. ROS have previously been proposed to be involved in insulin resistance, although evidence for a causal role has been scant. We tested this hypothesis in cell culture using six treatments designed to alter ROS levels, including two small molecules and four transgenes; all ameliorated insulin resistance to varying degrees. One of these treatments was tested in obese, insulin-resistant mice and was shown to improve insulin sensitivity and glucose homeostasis. Together, our findings suggest that increased ROS levels are an important trigger for insulin resistance in numerous settings.

Reactive oxygen species have a causal role in multiple forms of insulin resistance.

Inflammation may underlie the metabolic disorders of insulin resistance and type 2 diabetes. IkappaB kinase beta (IKK-beta, encoded by Ikbkb) is a central coordinator of inflammatory responses through activation of NF-kappaB. To understand the role of IKK-beta in insulin resistance, we used mice lacking this enzyme in hepatocytes (Ikbkb(Deltahep)) or myeloid cells (Ikbkb(Deltamye)). Ikbkb(Deltahep) mice retain liver insulin responsiveness, but develop insulin resistance in muscle and fat in response to high fat diet, obesity or aging. In contrast, Ikbkb(Deltamye) mice retain global insulin sensitivity and are protected from insulin resistance. Thus, IKK-beta acts locally in liver and systemically in myeloid cells, where NF-kappaB activation induces inflammatory mediators that cause insulin resistance. These findings demonstrate the importance of liver cell IKK-beta in hepatic insulin resistance and the central role of myeloid cells in development of systemic insulin resistance. We suggest that inhibition of IKK-beta, especially in myeloid cells, may be used to treat insulin resistance.

IKK-beta links inflammation to obesity-induced insulin resistance.

Reactive oxygen species (ROS) and reactive nitrogen species (RNS) play important roles in regulation of cell survival. In general, moderate levels of ROS/RNS may function as signals to promote cell proliferation and survival, whereas severe increase of ROS/RNS can induce cell death. Under physiologic conditions, the balance between generation and elimination of ROS/RNS maintains the proper function of redox-sensitive signaling proteins. Normally, the redox homeostasis ensures that the cells respond properly to endogenous and exogenous stimuli. However, when the redox homeostasis is disturbed, oxidative stress may lead to aberrant cell death and contribute to disease development. This review focuses on the roles of key transcription factors, signal-transduction pathways, and cell-death regulators in affecting cell survival, and how the redox systems regulate the functions of these molecules. The current understanding of how disturbance in redox homeostasis may affect cell death and contribute to the development of diseases such as cancer and degenerative disorders is reviewed. We also discuss how the basic knowledge on redox regulation of cell survival can be used to develop strategies for the treatment or prevention of those diseases. Antioxid. Redox Signal. 10, 1343–1374.

/pdf/redox-regulation-of-cell-survival-4xc79e1yo5.pdf

Redox Regulation of Cell Survival

http://www.whitelabs.org/publications/pdf/2000/MFW166.pdf

The c-Jun NH(2)-terminal kinase promotes insulin resistance during association with insulin receptor substrate-1 and phosphorylation of Ser(307).

Lethal hyperkalemic response to succinylcholine continues to be reported, but the molecular mechanisms for the hyperkalemia have not been completely elucidated. In the normal innervated mature muscle, the acetylcholine receptors (AChRs) are located only in the junctional area. In certain pathologic states, including upper or lower motor denervation, chemical denervation by muscle relaxants, drugs, or toxins, immobilization, infection, direct muscle trauma, muscle tumor, or muscle inflammation, and/or burn injury, there is up-regulation (increase) of AChRs spreading throughout the muscle membrane, with the additional expression of two new isoforms of AChRs. The depolarization of these AChRs that are spread throughout the muscle membrane by succinylcholine and its metabolites leads to potassium efflux from the muscle, leading to hyperkalemia. The nicotinic (neuronal) 7 acetylcholine receptors, recently described to be expressed in muscle also, can be depolarized not only by acetylcholine and succinylcholine but also by choline, persistently, and possibly play a critical role in the hyperkalemic response to succinylcholine in patients with upregulated AChRs.

/pdf/succinylcholine-induced-hyperkalemia-in-acquired-pathologic-br4ggkudtc.pdf

Succinylcholine-induced hyperkalemia in acquired pathologic states: etiologic factors and molecular mechanisms.

Multiple factors alter the interaction of muscle relaxants with the NMJ. This review has focused on the aberrant responses caused principally by alterations in AChRs (table 1). Many pathologic states increase (up-regulate) AChR number. These include upper and lower motor neuron lesions, muscle trauma, burns, and immobilization. Pre- or postjunctional inhibition of neurotransmission by drugs or toxins also up-regulate AChRs. These include alpha- and beta-BT, NDMR, anticonvulsants, and clostridial toxins. We speculate that other bacterial toxins also up-regulate AChR. With proliferation of AChRs, agonist drug dose-response curves are shifted to the left. The exaggerated release of potassium when depolarization occurs with the use of agonists such as SCh and decamethonium can be attributed to the increased number of AChR. Thus, SCh should be avoided in patients who are in the susceptible phase (see section V). In the presence of increased AChR, the requirement for NDMR is markedly increased. Thus, the response to NDMR may be used as an indirect estimator of increased sensitivity to SCh (table 1). The most extensively studied pathologic state in which there is a decrease in AChRs is myasthenia gravis; there is immunologically mediated destruction and/or functional blockade of AChRs. The pathophysiologic and pharmacologic changes in LEMS are quite distinct from those of myasthenia gravis. Decreased AChRs in myasthenia gravis result in resistance to agonists and increased sensitivity to competitive antagonists. In conditioning exercise, the perturbed muscles show sensitivity to NDMR that may be due to decreased AChRs. Chronic elevations of ACh observed with organophosphorus poisoning or chronic use of reversible cholinesterase inhibitors results in down-regulation of AChRs. In this condition, SCh should be avoided because its metabolic breakdown would be impaired; the requirement for NDMR may be decreased. All of the varied responses to SCh and NDMR, which are associated with concomitant changes in AChRs, are analogous to drug-receptor interactions observed in other biologic systems.

Up-and-down regulation of skeletal muscle acetylcholine receptors. Effects on neuromuscular blockers.

S-nitrosylation-dependent inactivation of Akt/protein kinase B in insulin resistance

Obesity is a major cause of type 2 diabetes, clinically evidenced as hyperglycemia. The altered glucose homeostasis is caused by faulty signal transduction via the insulin signaling proteins, which results in decreased glucose uptake by the muscle, altered lipogenesis, and increased glucose output by the liver. The etiology of this derangement in insulin signaling is related to a chronic inflammatory state, leading to the induction of inducible nitric oxide synthase and release of high levels of nitric oxide and reactive nitrogen species, which together cause posttranslational modifications in the signaling proteins. There are substantial differences in the molecular mechanisms of insulin resistance in muscle versus liver. Hormones and cytokines from adipocytes can enhance or inhibit both glycemic sensing and insulin signaling. The role of the central nervous system in glucose homeostasis also has been established. Multipronged therapies aimed at rectifying obesity-induced anomalies in both central nervous system and peripheral tissues may prove to be beneficial.

/pdf/obesity-induced-insulin-resistance-and-hyperglycemia-3y989vv7gd.pdf

Obesity-induced insulin resistance and hyperglycemia: etiologic factors and molecular mechanisms.

Chronic inflammation has been postulated to play an important role in the pathogenesis of insulin resistance. Inducible nitric oxide synthase (iNOS) has been implicated in many human diseases associated with inflammation. iNOS deficiency was shown to prevent high-fat diet-induced insulin resistance in skeletal muscle but not in the liver. A role for iNOS in fasting hyperglycemia and hepatic insulin resistance, however, remains to be investigated in obesity-related diabetes. To address this issue, we examined the effects of a specific inhibitor for iNOS, L-NIL, in obese diabetic (ob/ob) mice. iNOS expression was increased in the liver of ob/ob mice compared with wild-type mice. Treatment with iNOS inhibitor reversed fasting hyperglycemia with concomitant amelioration of hyperinsulinemia and improved insulin sensitivity in ob/ob mice. iNOS inhibitor also increased the protein expression of insulin receptor substrate (IRS)-1 and -2 1.5- and 2-fold, respectively, and enhanced IRS-1- and IRS-2-mediated insulin signaling in the liver of ob/ob mice. Exposure to NO donor and ectopically expressed iNOS decreased the protein expression of IRS-1 and -2 in cultured hepatocytes. These results suggest that iNOS plays a role in fasting hyperglycemia and contributes to hepatic insulin resistance in ob/ob mice.

https://diabetes.diabetesjournals.org/content/diabetes/54/5/1340.full.pdf

J. A. Jeevendra Martyn

Papers

Succinylcholine-induced hyperkalemia in acquired pathologic states: etiologic factors and molecular mechanisms.

Up-and-down regulation of skeletal muscle acetylcholine receptors. Effects on neuromuscular blockers.

S-nitrosylation-dependent inactivation of Akt/protein kinase B in insulin resistance

Obesity-induced insulin resistance and hyperglycemia: etiologic factors and molecular mechanisms.

A Role for iNOS in Fasting Hyperglycemia and Impaired Insulin Signaling in the Liver of Obese Diabetic Mice