A role for NF-kappa B subunits p50 and p65 in the inhibition of lipopolysaccharide-induced shock

To evaluate the possibility that NF-kappaB subunits p50 and p65 have a role in limiting the systemic inflammatory response induced by endotoxin, we compared the susceptibility of wild-type (WT), p65+/-, p50-/-, and p50-/-p65+/- (3X) mice to LPS-induced shock. Interestingly, whereas p65+/- mice were no more sensitive than WT mice to LPS-induced shock, 3X mice were exquisitely sensitive to the toxic effects of LPS. Mice lacking p50 alone displayed an intermediate phenotype. Sensitivity to LPS was a property of the innate immune system and was characterized by elevated circulating levels of TNF in both p50-/- and 3X mice. The ability of LPS to induce shock depended upon TNF, and 3X mice were significantly more sensitive to the toxic effects of TNF than were p50-deficient mice. The expression of several LPS-inducible proinflammatory genes, including IFN-gamma, was significantly higher within the spleens of p50-/- mice than in the spleens of WT mice, and interestingly, the expression of IFN-gamma was augmented still further within the spleens of 3X mice. These results demonstrate that NF-kappaB subunits p50 and p65 have critical inhibitory functions during the systemic response to LPS and raise the possibility that these functions could be essential in preventing mortality associated with systemic inflammatory response syndromes.     

Ethanol-induced dysfunction of hepatocytes and leukocytes in patients without liver failure

The repeated intake of a great amount of ethanol is followed by functional and organic changes in the body. The intestinal absorption of alcohol is accompanied by an increased absorption of Gram negative bacteria endotoxins in the portal blood. In the liver, endotoxins stimulate CD14 receptors on the membrane of Kupffer cells, with a secondary inflammatory liver response, consisting in the secretion of proinflammatory cytokines and acute phase proteins. Simultaneously, alcohol metabolism in the hepatocytes by alcohol dehydrogenase, microsomal enzymes and catalase pathways determines a large production of ROS (reactive oxygen species), with secondary oxidative aggression on all liver cells: hepatocytes, Kupffer cells, endothelial sinusoidal cells, hepatic stellate cells and liver s lymphocytes. The oxidative aggression, as well as the intermediary products of the alcohol metabolism, cause a structural change of the antigenic structures of the liver and of the released proteins, that induces an immune response on the both pathways (humoral and cellular). The pathophysiological mechanisms and the paraclinical characteristics of the ethanol-induced liver failure are well known, so we were interested to study the patients with chronic alcoholism, but no clinical or paraclinical sign of liver failure, in order to describe the liver's protective mechanisms. For this reason, 153 patients with chronic alcoholism were divided into four test lots, in order to determine: the activity and the serum level of ceruloplasmin, plasma level of MDA (malondialdehyde), lactic and pyruvic acids, serum level of transferrin, alpha1-antitrypsin, CRP (C reactive protein), C3 fraction of the complement, IgA, IgG, IgM, IL-1beta, IL-6 and IL-8, cytosolic level of the cytochrome c in the circulating leukocytes. An immunophenotype study (as normal markers) on the peripheral blood lymphocytes was performed, too. The results demonstrate an important oxidative aggression induced by three sources: the alcohol metabolism in the hepatocytes, activated Kupffer cells and activated neutrophils that have infiltrated the liver, due to the chemoattractant effect of IL-8. This aggression induces apoptosis and necrosis of the liver cells. The major liver protective factor is, in our opinion, IL-6, due to its important antioxidant, antiapoptotic and proregenerative demonstrated actions. This protective effect of IL-6 is accompanied by antioxidant and antiprotease actions of ceruloplasmin, alpha1-antitrypsin and transferrin. We consider that an increased serum level of IL-6 accompanied by a decreased level of IL-1beta signify that antiapoptotic, antioxidant and proregenerative liver mechanisms prevail against proapoptotic and necrotic mechanisms. On the other hand, the ethanol-induced apoptosis of leukocytes (especially of the B cells) is very important, probably due to the absence of IL-6 protective action on these cells. The apoptosis of the circulating leukocytes is proved by their significant increase of the cytochrome c cytosolic level. The ethanol-induced liver immune response is predominantly cellular, as proved by the decreased ratio T helper (CD4+)/T cytotoxic (CD8+) in the peripheral blood. It is very important to observe that these significant immunologic changes appear before clinical or paraclinical signs of hepatic failure start. All these parameters were investigated in three groups of patients: chronic alcoholics, chronic alcoholics in the first 24 hours of the withdrawal and chronic alcoholics with acute alcohol intoxication, so the aggression types and the protective mechanisms were measured and differentiated in each "ethanolic status".     

Investigating the cardiac pathology of SCO2‐mediated hypertrophic cardiomyopathy using patients induced pluripotent stem cell–derived cardiomyocytes

Mutations in SCO2 are among the most common causes of COX deficiency, resulting in reduced mitochondrial oxidative ATP production capacity, often leading to hypertrophic cardiomyopathy (HCM). To date, none of the recent pertaining reports provide deep understanding of the SCO2 disease pathophysiology. To investigate the cardiac pathology of the disease, we were the first to generate induced pluripotent stem cell (iPSC)‐derived cardiomyocytes (iPSC‐CMs) from SCO2‐mutated patients. For iPSC generation, we reprogrammed skin fibroblasts from two SCO2 patients and healthy controls. The first patient was a compound heterozygote to the common E140K mutation, and the second was homozygote for the less common G193S mutation. iPSC were differentiated into cardiomyocytes through embryoid body (EB) formation. To test the hypothesis that the SCO2 mutation is associated with mitochondrial abnormalities, and intracellular Ca²⁺‐overload resulting in functional derangements and arrhythmias, we investigated in SCO2‐mutated iPSC‐CMs (compared to control cardiomyocytes): (i) the ultrastructural changes; (ii) the inotropic responsiveness to β‐adrenergic stimulation, increased [Ca²⁺]_o and angiotensin‐II (AT‐II); and (iii) the Beat Rate Variability (BRV) characteristics. In support of the hypothesis, we found in the mutated iPSC‐CMs major ultrastructural abnormalities and markedly attenuated response to the inotropic interventions and caffeine, as well as delayed afterdepolarizations (DADs) and increased BRV, suggesting impaired SR Ca²⁺ handling due to attenuated SERCA activity caused by ATP shortage. Our novel results show that iPSC‐CMs are useful for investigating the pathophysiological mechanisms underlying the SCO2 mutation syndrome.     

Reaching out: junctions between cardiac telocytes and cardiac stem cells in culture

Telocytes (TCs) were previously shown by our group to form a tandem with stem/progenitor cells in cardiac stem cell (CSC) niches, fulfilling various roles in cardiac renewal. Among these, the ability to ‘nurse’ CSCs in situ, both through direct physical contact (junctions) as well as at a distance, by paracrine signalling or through extracellular vesicles containing mRNA. We employed electron microscopy to identify junctions (such as gap or adherens junctions) in a co‐culture of cardiac TCs and CSCs. Gap junctions were observed between TCs, which formed networks, however, not between TCs and CSCs. Instead, we show that TCs and CSCs interact in culture forming heterocellular adherens junctions, as well as non‐classical junctions such as puncta adherentia and stromal synapses. The stromal synapse formed between TCs and CSCs (both stromal cells) was frequently associated with the presence of electron‐dense nanostructures (on average about 15 nm in length) connecting the two opposing membranes. The average width of the synaptic cleft was 30 nm, whereas the average length of the intercellular contact was 5 μm. Recent studies have shown that stem cells fail to adequately engraft and survive in the hostile environment of the injured myocardium, possibly as a result of the absence of the pro‐regenerative components of the secretome (paracrine factors) and/or of neighbouring support cells. Herein, we emphasize the similarities between the junctions described in co‐culture and the junctions identified between TCs and CSCs in situ. Reproducing a CSC niche in culture may represent a viable alternative to mono‐cellular therapies.     

Emlen funnel experiments revisited: methods update for studying compass orientation in songbirds

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Hydration of POPC bilayers studied by 1H-PFG-MAS-NOESY and neutron diffraction

The stability of lipid bilayers is ultimately linked to the hydrophobic effect and the properties of water of hydration. Magic angle spinning (MAS) nuclear Overhauser enhancement spectroscopy (NOESY) with application of pulsed magnetic field gradients (PFG) was used to study the interaction of water with 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine bilayers in the fluid phase. NOESY cross-relaxation between water and polar groups of lipids, but also with methylene resonances of hydrophobic hydrocarbon chains, has been observed previously. This observation led to speculations that substantial amounts of water may reside in the hydrophobic core of bilayers. Here, the results of a quantitative analysis of cross-relaxation in a lipid 1-palmitoyl-2-oleoyl-sn-glycero-3 phosphocholine (POPC)/water mixture are reported. Coherences were selected via application of pulsed magnetic field gradients. This technique shortens acquisition times of NOESY spectra to 20 min and reduces t ₁-spectral noise, enabling detection of weak crosspeaks, like those between water and lipids, with higher precision than with non-gradient NOESY methods. The analysis showed that water molecules interact almost exclusively with sites of the lipid–water interface, including choline, phosphate, glycerol, and carbonyl groups. The lifetime of lipid–water associations is rather short, on the order of 100 ps, at least one order of magnitude shorter than the lifetime of lipid–lipid associations. The distribution of water molecules over the lipid bilayer was measured at identical water content by neutron diffraction. Water molecules penetrate deep into the interfacial region of bilayers but water concentration in the hydrophobic core is below the detection limit of one water molecule per lipid, in excellent agreement with the cross-relaxation data. Dedicated to Prof. K. Arnold on the occasion of his 65th birthday.