Plant-based diet, serum fatty acid profile, and free radicals in postmenopausal women: the diet and androgens (DIANA) randomized trial

High calorie and fat consumption and the production of free radicals are two major mechanistic pathways between diet and disease. In this study we evaluated the effect of a plant-based diet poor in animal fat and rich in (n-3) fatty acids on fatty acids of serum phospholipids and on the production of reactive oxygen metabolites (ROMs). One hundred and four healthy female postmenopausal volunteers were recruited and randomized to a dietary intervention or a control group. Dietary intervention included a program of food education and biweekly common meals for 18 weeks. When the intervention and control groups were compared, it was seen that dietary intervention resulted in a significant reduction of saturated fatty acids (-1.5%) and a significant increase in (n-3) fatty acids (+20.6%), in particular docosahexaenoic acid (+24.8%). We observed that arachidonic acid decreased (-7.7%), while (n-6) fatty acids did not, and the (n-3)/(n-6) polyunsaturated ratio increased significantly (+24.1%). As expected, ROMs decreased significantly in the intervention group (-6%). The results indicated that a plant-based diet can improve the serum fatty acid profile and decrease ROMs production. These results suggest that a plant-based diet may reduce the body's exposure to oxidative stress.     

Single units in the pigeon brain integrate reward amount and time-to-reward in an impulsive choice task

BACKGROUND: Animals prefer small over large rewards when the delays preceding large rewards exceed an individual tolerance limit. Such impulsive choice behavior occurs even in situations in which alternative strategies would yield more optimal outcomes. Behavioral research has shown that an animal's choice is guided by the alternative rewards' subjective values, which are a function of reward amount and time-to-reward. Despite increasing knowledge about the pharmacology and anatomy underlying impulsivity, it is still unknown how the brain combines reward amount and time-to-reward information to represent subjective reward value. RESULTS: We trained pigeons to choose between small, immediate rewards and large rewards delivered after gradually increasing delays. Single-cell recordings in the avian Nidopallium caudolaterale, the presumed functional analog of the mammalian prefrontal cortex, revealed that neural delay activation decreased with increasing delay length but also covaried with the expected reward amount. This integrated neural response was modulated by reward amount and delay, as predicted by a hyperbolical equation, of subjective reward value derived from behavioral studies. Furthermore, the neural activation pattern reflected the current reward preference and the time point of the shift from large to small rewards. CONCLUSIONS: The reported activity was modulated by the temporal devaluation of the anticipated reward in addition to reward amount. Our findings contribute to the understanding of neuropathologies such as drug addiction, pathological gambling, frontal lobe syndrome, and attention-deficit disorders, which are characterized by inappropriate temporal discounting and increased impulsiveness.     

Astrocyte-derived ATP induces vesicle shedding and IL-1 beta release from microglia

ATP has been indicated as a primary factor in microglial response to brain injury and inflammation. By acting on different purinergic receptors 2, ATP is known to induce chemotaxis and stimulate the release of several cytokines from these cells. The activation of purinergic receptors 2 in microglia can be triggered either by ATP deriving from dying cells, at sites of brain injury or by ATP released from astrocytes, in the absence of cell damage. By the use of a biochemical approach integrated with video microscopy experiments, we investigated the functional consequences triggered in microglia by ATP released from mechanically stimulated astrocytes, in mixed glial cocultures. Astrocyte-derived ATP induced in nearby microglia the formation and the shedding of membrane vesicles. Vesicle formation was inhibited by the ATP-degrading enzyme apyrase or by P2X(7)R antagonists. Isolation of shed vesicles, followed by IL-1beta evaluation by a specific ELISA revealed the presence of the cytokine inside the vesicular organelles and its subsequent efflux into the extracellular medium. IL-1beta efflux from shed vesicles was enhanced by ATP stimulation and inhibited by pretreatment with the P2X(7) antagonist oxidized ATP, thus indicating a crucial involvement of the pore-forming P2X(7)R in the release of the cytokine. Our data identify astrocyte-derived ATP as the endogenous factor responsible for microvesicle shedding in microglia and reveal the mechanisms by which astrocyte-derived ATP triggers IL-1beta release from these cells.     

The tale of tail-anchored proteins: coming from the cytosol and looking for a membrane

A group of integral membrane proteins, known as C-tail anchored, is defined by the presence of a cytosolic NH2-terminal domain that is anchored to the phospholipid bilayer by a single segment of hydrophobic amino acids close to the COOH terminus. The mode of insertion into membranes of these proteins, many of which play key roles in fundamental intracellular processes, is obligatorily posttranslational, is highly specific, and may be subject to regulatory processes that modulate the protein's function. Although recent work has elucidated structural features in the tail region that determine selection of the correct target membrane, the molecular machinery involved in interpreting this information, and in modulating tail-anchored protein localization, has not been identified yet.     

Considerations on the astroglial architecture and the columnar organization of the cerebral cortex

Present knowledge on astroglial roles in brain organization and function indicates that these cells can regulate the extracellular ionic composition and modulate neuronal activity. In this regard, the panglial synctium formed by electrically and chemically coupled stellate astrocytes (general mammalian architecture) is believed to provide an intracellular pathway for the redistribution of ions and molecules within the cerebral cortex. Long astroglial interlaminar processes (primate-specific architecture) that run parallel to apical dendrites in the cerebral cortex of primates, may provide additional properties to the glial participation in cortical physiology and function. Since these processes are exclusively present within the primate order, functional models of cortical computations for these species should incorporate the astroglial interlaminar architecture in addition to the panglial synctium. This study analyzes possible implications of interlaminar astroglial processes, for the regulation of the extracellular ionic composition and segregation of functional columns in the cerebral cortex.     

Vaccination of Stage IV patients with allogeneic IL-4- or IL-2-gene-transduced melanoma cells generates functional antibodies against vaccinating and autologous melanoma cells

The antibody (Ab) response to allogeneic Me14932 and autologous melanoma cells was analyzed in 13 Stage IV (AJCC) melanoma patients immunized with Me14932 cells transduced with the IL-4 (Me14932/IL-4) ( n=10) or IL-2 (Me14932/IL-2) ( n=3) gene. No Ab response was observed before the 4th vaccination. Among 8 patients that received four vaccinations, 3/5 patients vaccinated with Me14932/IL-4 cells developed Ab (IgG and/or IgM) to Me14932 ( n=3) and to autologous ( n=2) melanoma cells, and 2/3 patients vaccinated with Me14932/IL-2 cells developed Ab (IgG) to Me14932, but not to autologous melanoma cells. Further, among these 5 responding patients, circulating Ab against the HLA-A3 allele, expressed only on vaccinating cells, were identified in the immune sera of 4 patients immunized with Me14932/IL-4 ( n=2) or Me14932/IL-2 ( n=2) cells. These sera mediated antibody-dependent cell cytotoxicity (ADCC) of Me14932 cells, and a direct correlation ( r=0.85; P=0.03) between intensity of staining (IgG) and extent of lysis was found. Immune serum of one of these patients also induced ADCC of autologous melanoma cells, and serum from another patient mediated complement cytotoxicity of Me14932, but not of autologous melanoma cells. Thus, Abs against vaccinating and autologous melanoma cells were generated in 62% of patients after four vaccinations with cytokine-transduced melanoma cells. These findings demonstrate that the identification and titration of alloreactive Ab helps to monitor the extent of immunization against cellular vaccines, while the induction of Ab reactive to antigens shared between vaccinating and autologous melanoma cells may contribute to their therapeutic efficacy.     

Base promoted air oxidation of 13beta-ethyl-11-methylenegon-4-en-17-one.

The structure of 13-ethyl-11-methylene-18,19-dinor-17alpha-pregn-4-en-20-yn-16beta,17-diol (3, 16beta-OH desogestrel), a by-product obtained in the last step of the synthesis of desogestrel (1) by reaction of monolithium acetylide-ethylenediamine complex with 13beta-ethyl-11-methylenegon-4-en-17-one (2), is here reported. The structural assignments were supported by NMR 1H-, 13C-, 1H-1H COSY, 1H-13C HSQC, COLOC) and mass spectroscopy, and the configuration at the C-16 and C-17 stereocentres was established by X-ray crystallography. When the same 17-ketoderivative 2 was treated with a non-alkylating base, such as potassium tert-butoxide, instead of the expected 16-hydroxylated ketone, a dimeric product, 13beta-ethyl-16-[2'-(des-D-13"-carboxy-13"beta-ethyl-11"-methylenegon-4"-en-14"-yl)-ethyliden]-11-methylenegon-4-en-17-one (4), was isolated in good yield; it was characterized by NMR, mass, ultraviolet spectroscopy, and chemical transformations. Compounds 3 and 4 originate from the high reactivity of the 16-methylenic position of the 17-keto substrate (2) toward molecular oxygen under basic conditions.