Involvement of β-Carotene in the Antioxidant Defense of the Bacterial Cell

Effects of recombinant -carotene on the resistance of E. coli culture to menadione and paraquat were studied. The presence of -carotene in E. coli cells prevented, to a considerable extent, an increase in superoxide dismutase activity (induced by redox mediators) without affecting the culture growth. These findings suggest that -carotene is involved in the defense of cells against oxidative stress.     

The β1 Integrin Subunit is Not a Specific Component of the Costamere Domain in Human Myocardial Cells

Studies on altered integrin receptor expression during cardiac hypertrophy and heart failure requires accurate knowledge of the distributional pattern of integrins in myocardial cells. At present the general consensus is that in cardiac muscle the β₁ integrin receptor is mainly localized to the same sarcolemmal domain as vinculin at Z-band levels (‘costamere’). Since most previous studies have been focusing on myocardial integrin distribution in lower mammals, the myocardial localization of the β₁ integrin subunit was investigated in biopsies collected from the auricle of patients undergoing a coronary bypass operation. Non-invasive serial optical sectioning was carried out by immuno-laser scanning confocal microscopy. Double-labelling for vinculin/α-actinin, and the cytoplasmic domain for the β₁ integrin subunit, showed that β₁ integrin is deposited throughout both the vinculin/α-actinin domains and the non-vinculin/α-actinin domains. These results were supported by a semi-quantitative analysis in extended focus images of the latter preparations. Higher magnification views at the electron microscopical levels of the large, extracellular domain of the β₁ integrin subunit disclosed a pronounced labelling in the form of a dense, irregular punctuate pattern that was distributed at Z-disc domains as well as along the entire sarcolemmal area between Z-discs. Our findings show that in human, myocardial cells, the β₁ integrin receptor does not only localize to the surface membrane at the Z-disc level (‘costamere’ in cardiac muscle), but has a widespread distribution along the sarcolemma.     

Production of the Carotenoids Lycopene, β-Carotene,and Astaxanthin in the Food Yeast Candida utilis

The food-grade yeast Candida utilis has been engineered to confer a novel biosynthetic pathway for the production of carotenoids such as lycopene, β-carotene, and astaxanthin. The exogenous carotenoid biosynthesis genes were derived from the epiphytic bacterium Erwinia uredovora and the marine bacterium Agrobacterium aurantiacum. The carotenoid biosynthesis genes were individually modified based on the codon usage of the C. utilis glyceraldehyde 3-phosphate dehydrogenase gene and expressed in C. utilis under the control of the constitutive promoters and terminators derived from C. utilis. The resultant yeast strains accumulated lycopene, β-carotene, and astaxanthin in the cells at 1.1, 0.4, and 0.4 mg per g (dry weight) of cells, respectively. This was considered to be a result of the carbon flow into ergosterol biosynthesis being partially redirected to the nonendogenous pathway for carotenoid production.Carotenoids are yellow, orange, and red pigments which are widely distributed in nature (3). Industrially, carotenoid pigments such as β-carotene are utilized as food or feed supplements. β-Carotene is also a precursor of vitamin A in mammals (11). Recently, carotenoids have attracted greater attention, due to their beneficial effect on human health: e.g., the functions of lycopene and astaxanthin include strong quenching of singlet oxygen (12), involvement in cancer prevention (2), and enhancement of immune responses (6). Astaxanthin has also been exploited for industrial use, principally as an agent for pigmenting cultured fish and shellfish.The genes responsible for the synthesis of carotenoids such as lycopene, β-carotene, and astaxanthin have been isolated from the epiphytic Erwinia species or the marine bacteria Agrobacterium aurantiacum and Alcaligenes sp. strain PC-1, and their functions have been elucidated (13, 14). The first substrate of the encoded enzymes for carotenoid synthesis is farnesyl pyrophosphate (diphosphate) (FPP), which is the common precursor for the biosynthesis of numerous isoprenoid compounds such as sterols, hopanols, dolicols, and quinones. The ubiquitous nature of FPP among yeasts has been utilized in the microbial production of lycopene and β-carotene by the yeast Saccharomyces cerevisiae carrying the Erwinia uredovora carotenogenic genes (19). However, the amount of carotenoids produced in these hosts was only 0.1 mg of lycopene and 0.1 mg of β-carotene per g (dry weight) of cells, respectively.The edible yeast Candida utilis is generally recognized as a safe substance by the Food and Drug Administration. Large-scale production of the yeast cells has been developed with cheap biomass-derived sugars as the carbon source for the production of single-cell protein and several chemicals such as glutathione and RNA (1, 4). This yeast was also found to accumulate a large amount of ergosterol in the cell during stationary phase (6 to 13 mg/g [dry weight] of cells) (17). Thus, C. utilis has the potential to produce a large amount of carotenoids by redirecting the carbon flux for the ergosterol biosynthesis into the nonendogenous pathway for carotenoid synthesis via FPP. Previously, a C. utilis strain was made to produce lycopene (0.8 mg/g [dry weight]) by expressing the three nonmodified genes crtE, crtB, and crtI derived from E. uredovora (15).In this paper, the de novo biosynthesis of lycopene, β-carotene, and astaxanthin has been performed in C. utilis by using six carotenogenic genes, which were synthesized according to the codon usage of the C. utilis glyceraldehyde-3-phosphate dehydrogenase (GAP) gene, which is expressed at high levels. By this approach, increased carotenoid production in C. utilis was achieved.     

Nitration of β-Lactoglobulin but Not of Ovomucoid Enhances Anaphylactic Responses in Food Allergic Mice

BackgroundWe revealed in previous studies that nitration of food proteins reduces the risk of de novo sensitization in a murine food allergy model. In contrast, in situations with preformed specific IgE antibodies, in vitro experiments suggested an increased capacity of effector cell activation by nitrated food proteins.ObjectiveThe aim of this study was to investigate the influence of protein nitration on the effector phase of food allergy.DesignBALB/c mice were immunized intraperitoneally (i.p.) with the milk allergen β-lactoglobulin (BLG) or the egg allergen ovomucoid (OVM), followed by intragastric (i.g.) gavages to induce a strong local inflammatory response and allergen-specific antibodies. Subsequently, naïve and allergic mice were intravenously (i.v.) challenged with untreated, sham-nitrated or nitrated BLG or OVM. Anaphylaxis was monitored by measuring core body temperature and determination of mouse mast cell protease-1 (mMCP-1) levels in blood.ResultsA significant drop of body temperature accompanied with significantly elevated concentrations of the anaphylaxis marker mMCP-1 were only observed in BLG allergic animals challenged with nitrated BLG and not in OVM allergic mice challenged with nitrated OVM. SDS-PAGE and circular dichroism analysis of the differentially modified allergens revealed an effect of nitration on the secondary protein structure exclusively for BLG together with enhanced protein aggregation.ConclusionOur data suggest that nitration affects differently the food allergens BLG and OVM. In the case of BLG, structural changes favored dimerization possibly explaining the increased anaphylactic reactivity in BLG allergic animals.     

Cardiac Dysfunction Induced by Obesity Is Not Related to β-Adrenergic System Impairment at the Receptor-Signalling Pathway

Obesity has been shown to impair myocardial performance. Some factors have been suggested as responsible for possible cardiac abnormalities in models of obesity, among them beta-adrenergic (βA) system, an important mechanism of regulation of myocardial contraction and relaxation. The objective of present study was to evaluate the involvement of βA system components in myocardial dysfunction induced by obesity. Thirty-day-old male Wistar rats were distributed in control (C, n = 25) and obese (Ob, n = 25) groups. The C group was fed a standard diet and Ob group was fed four unsaturated high-fat diets for 15 weeks. Cardiac function was evaluated by isolated papillary muscle preparation and βA system evaluated by using cumulative concentrations of isoproterenol and Western blot. After 15 weeks, the Ob rats developed higher adiposity index than C rats and several comorbidities; however, were not associated with changes in systolic blood pressure. Obesity caused structural changes and the myocardial responsiveness to post-rest contraction stimulus and increased extracellular calcium (Ca²⁺) was compromised. There were no changes in cardiac function between groups after βA stimulation. The obesity was not accompanied by changes in protein expression of G protein subunit alpha (Gsα) and βA receptors (β₁AR and β₂AR). In conclusion, the myocardial dysfunction caused by unsaturated high-fat diet-induced obesity, after 15 weeks, is not related to βAR system impairment at the receptor-signalling pathway.     

The Obesity Epidemic: A Consequence of Reduced Energy Expenditure and the Uncoupling of Energy Intake?

Obesity prevalence has increased, and increased energy intake or decreased physical activity are the two most obvious contributing factors. The percentage of Americans engaging in exercise has been stable over the past few decades, but decreases in occupation‐related energy expenditure are sufficient to partially explain increased obesity prevalence. Further, the contribution of energy intake and energy expenditure to the obesity epidemic is complicated because they are not independent—they are influenced by each other. For example, Mayer found that low activity levels were marked by higher body weight and higher “unregulated” energy intake levels. Conversely, higher activity levels were marked by lower body weight and energy intake that matched energy expenditure. Consistent with Mayer, we propose that because most Americans have low levels of occupation‐related activity, they do not benefit from the regulation of energy intake achieved at higher activity levels, resulting in weight gain due to energy intake exceeding energy expenditure.     

Heat Treatment and β-Carotene Incorporation Effect in the Interaction of β-Lactoglobulin and Carboxymethylcellulose System

Encapsulation technologies using proteins or polysaccharides can be employed with the purpose of solubilizing and protecting carotenoids. However, information on the role of protein and polysaccharide interactions is still slightly limited. The aim of this work was to investigate the effect of β-carotene linked to protein β-lactoglobulin (BLG) in the interaction carboxymethylcellulose (CMC) using isothermal titration calorimetry (ITC). Firstly, BLG and CMC interaction was assessed by means of turbidity analysis. Based on the results of turbidity, the thermodynamic profile of BLG-CMC complexes at pH 4.0 was obtained using ITC analysis at 25 °C. Afterward, it was evaluated the effect of a thermal treatment applied to the BLG (68 °C for 50 min) in the interaction with CMC also using ITC and circular dichroism (CD). ITC and CD analysis showed that the heat treatment applied on BLG did not cause changes in molecular interactions. The binding isotherm of BLG-CMC complexes incorporated with β-carotene showed an increase in the molar ratio and a slight decrease in enthalpy of the system. Incorporation of β-carotene in the system did not significantly affect the BLG and CMC interaction, suggesting this system can be applied in food application as encapsulation.     

The N-Terminal Transmembrane Domain of λ S Is Required for Holin but Not Antiholin Function

The λ S gene encodes a holin, S105, and an antiholin, S107, which differs by its Met-Lys N-terminal extension. The model for the lysis-defective character of S107 stipulates that the additional N-terminal basic residue keeps S107 from assuming the topology of S105, which is N-out, C-in, with three transmembrane domains (TMDs). Here we show that the N terminus of S105 retains its fMet residue but that the N terminus of S107 is fully deformylated. This supports the model that in S105, TMD1 inserts into the membrane very rapidly but that in S107, it is retained in the cytoplasm. Further, it reveals that, compared to S105, S107 has two extra positively charged moieties, Lys2 and the free N-terminal amino group, to hinder its penetration into an energized membrane. Moreover, an allele, S105_ΔTMD1, with TMD1 deleted, was found to be defective in lysis, insensitive to membrane depolarization, and dominant to the wild-type allele, indicating that the lysis-defective, antiholin character of S107 is due to the absence of TMD1 from the bilayer rather than to its ectopic localization at the inner face of the cytoplasmic membrane. Finally, the antiholin function of the deletion protein was compromised by the substitution of early-lysis missense mutations in either the deletion protein or parental S105 but restored when both S105_ΔTMD1 and holin carried the substitution.In general, holins control the length of the infection cycle of double-stranded DNA phages (37). During late gene expression, the holin protein accumulates harmlessly in the bilayer until suddenly and spontaneously triggering the formation of holes in the membrane at an allele-specific time (13, 15). Holin genes are extremely diverse, but most can be grouped into two main classes based on the number of predicted transmembrane domains (TMDs): class I, with three TMDs and a predicted N-out, C-in topology, and class II, with two TMDs and a predicted N-in, C-in topology (38). Holin genes and function are subject to several levels of regulation, among which a particularly striking feature is the common occurrence of two potential translational starts, or dual-start motifs (5, 37), separated by only a few codons. Dual-start motifs are found in many holins of both of the two major classes; in nearly every case, the two starts are separated by at least one basic residue. The first dual-start motif to be characterized was that of λ S, the prototype class I holin gene (Fig. 1A and B). Translation initiation events occur at codons 1 and 3, giving rise to two products, S107 and S105, each named because of the length of its amino acid sequence; in the wild-type (wt) allele, two RNA structures define the ratio of initiations at the two start codons, resulting in an S105/S107 ratio of ∼2:1.Open in a separate windowFIG. 1.Gene, topology, and sequence of λ S. (A, top) The λ lysis cassette, including genes S, R, Rz, and Rz1, is shown, along with its promoter p_R′, and Q, encoding the late gene activator. The 5′ end of the class I holin gene S has two start codons, Met1, the start for S107, and Met3, the start for S105, and two RNA structures that regulate initiations at these codons. The S105 and S107 alleles have Leu (CUG) codons in place of the Met3 and Met1 codons, respectively. (B) Primary structure of S proteins. Missense changes relevant to the text are shown. Starts for S107 and S105 are indicated by asterisks. The three TMDs are boxed (13), and the extent of the ΔTMD1 deletion is indicated. (C) Model for the membrane topology of S105, S107, and S105_ΔTMD1. Topology and boundary residues for TMD1, -2, and -3 are based on Graschopf and Blasi (11) and Gründling et al. (13), respectively.Although they differ only by the Met-Lys N-terminal extension of S107, the two proteins have opposing functions; S105 is the holin and S107 the antiholin. The antiholin function is reflected by four principal features: first, when the Met3 start is inactivated, the mutant allele, designated S107 (Fig. ​(Fig.1A),1A), is lysis defective (26); second, the S107 protein binds and inhibits S105 specifically (3, 16); third, when S107 is produced in stoichiometric excess over S105, lysis is blocked for several times the length of the normal infection cycle (3, 4, 7, 16); and fourth, S107 antiholin function, i.e., inhibition of S105 hole formation, can be instantly subverted by collapsing the proton motive force, most easily done by addition of energy poisons to the medium (3). The predicted N-out, C-in topology and the requirement for the energized membrane led to a model in which S107 is initially inserted in the membrane with only two TMDs, with TMD1 being blocked from insertion by the presence of the positively charged residue, Lys2, whereas S105 has three TMDs (Fig. ​(Fig.1C)1C) (39). From this perspective, S105-S107 complexes, which are approximately twice as numerous as the S105 homodimers, are defective in triggering hole formation. An appealing feature of this model is that when an S105-mediated hole formation event does occur in a cell, the resultant collapse of the membrane potential allows insertion of TMD1 of S107 into the membrane, instantly tripling the amount of active holin by making the previously inactive pool of S105-S107 complexes functional (38).Some genetic and physiological evidence for the topology of the λ S proteins has been obtained using gene fusions. First, a fusion of the S gene at codon 105 with lacZ generates a functional, membrane-inserted β-galactosidase chimera, indicating, as expected, the cytoplasmic disposition of the highly charged C terminus of the S protein (40). Second, Graschopf and Bläsi (12) demonstrated that S-mediated hole formation could be obtained with constructs where a secretory signal sequence was fused to the N termini of both S105 and S107. Lysis required the cleavage of the signal sequence by leader peptidase, and export of the signal-S107 form was slower than for the signal-S105 form. However, evidence for the topology of native forms of S has not been available. Moreover, no basis for the inhibitory character of S107 has been established. In the simplest view, the antiholin function could be due to the absence of TMD1 from the bilayer or the ectopic localization of TMD1 in the cytoplasm, or both. Here, we report studies directed at dissecting the precise role of topology in S107 function and correlating antiholin activity with its ability to heterodimerize with S105. The results are discussed in terms of a general model for the formation of the holin lesion and the role of dynamic membrane topology in its temporal regulation.     

CAROTENOID CLEAVAGE DIOXYGENASE4 Is a Negative Regulator of β-Carotene Content in Arabidopsis Seeds

Experimental approaches targeting carotenoid biosynthetic enzymes have successfully increased the seed β-carotene content of crops. However, linkage analysis of seed carotenoids in Arabidopsis thaliana recombinant inbred populations showed that only 21% of quantitative trait loci, including those for β-carotene, encode carotenoid biosynthetic enzymes in their intervals. Thus, numerous loci remain uncharacterized and underutilized in biofortification approaches. Linkage mapping and genome-wide association studies of Arabidopsis seed carotenoids identified CAROTENOID CLEAVAGE DIOXYGENASE4 (CCD4) as a major negative regulator of seed carotenoid content, especially β-carotene. Loss of CCD4 function did not affect carotenoid homeostasis during seed development but greatly reduced carotenoid degradation during seed desiccation, increasing β-carotene content 8.4-fold relative to the wild type. Allelic complementation of a ccd4 null mutant demonstrated that single-nucleotide polymorphisms and insertions and deletions at the locus affect dry seed carotenoid content, due at least partly to differences in CCD4 expression. CCD4 also plays a major role in carotenoid turnover during dark-induced leaf senescence, with β-carotene accumulation again most strongly affected in the ccd4 mutant. These results demonstrate that CCD4 plays a major role in β-carotene degradation in drying seeds and senescing leaves and suggest that CCD4 orthologs would be promising targets for stabilizing and increasing the level of provitamin A carotenoids in seeds of major food crops.     

TNF-α, IL-6, and Leptin Increase the Expression of miR-378, an Adipogenesis-Related microRNA in Human Adipocytes

Obesity has become a global public health problem associated with complications including type 2 diabetes, cardiovascular disease, and several cancers. Adipocyte differentiation (adipogenesis) plays an important role in obesity and energy homeostasis. Adipose tissue secretes multiple cytokines and adipokines which can cause the complications of obesity, especially insulin resistance. TNF-α, IL-6, leptin, and resistin have been identified as the main regulators of obesity and insulin activity. miR-378 is highly induced during adipogenesis and has been reported to be positively regulated in adipogenesis. In the current study, matured human adipocytes were treated with TNF-α, IL-6, leptin, or resistin on the 15th day after the induction of human pre-adipocyte differentiation. We demonstrated that TNF-α, IL-6, and leptin upregulated miR-378 expression indicating that miR-378 probably is a novel mediator in the development of insulin resistance related to obesity.     

The many blades of the β-propeller proteins: conserved but versatile

The β-propeller is a highly symmetrical structure with 4-10 repeats of a four-stranded antiparallel β-sheet motif. Although β-propeller proteins with different blade numbers all adopt disc-like shapes, they are involved in a diverse set of functions, and defects in this family of proteins have been associated with human diseases. However, it has remained ambiguous how variations in blade number could alter the function of β-propellers. In addition to the regularly arranged β-propeller topology, a recently discovered β-pinwheel propeller has been found. Here, we review the structural and functional diversity of β-propeller proteins, including β-pinwheels, as well as recent advances in the typical and atypical propeller structures.     

Thermal Inactivation of Poliovirus in the Presence of Selective Organic Molecules (Cholesterol, Lecithin, Collagen, and β-Carotene)

Poliovirus type 1 strain LS-a exhibited the typical thermal inactivation pattern observed previously by other investigators for poliovirus strains sensitive to the temperatures used in these experiments. However, when the virus suspension was thermally treated at 121 C for 5 sec in the presence of 2% collagen, a stabilizing effect on the virus was observed. The stabilizing effect in the presence of other food additives, such as cholesterol, lecithin, or beta-carotene, was less dramatic or there was no effect at all. Pretreatment of the cells with the same additives before inoculation induced various changes in the susceptibility of the cells to infection by poliovirus. Lecithin and cholesterol treatment appeared to increase HeLa cell susceptibility to the invading virus, thereby enhancing infectivity. Ultraviolet examination of thermally inactivated virus (121 C) suspensions did not indicate any severe denaturation of the nucleic acid core. Subsequent phenol extraction of the infectious nucleic acid from the heat-inactivated virions revealed that infectious nucleic acid was still present in the denatured heat-treated (62 to 72 C) samples of virion. The immediate past history of treatment of the uninoculated cells appeared to be important, since pretreatment of the cells with cholesterol before inoculation resulted in a noticeable increase in infectivity. In addition, cholesterol-treated uninoculated cell sheets also exhibited an increase in longevity compared to the uninoculated, untreated controls.     

Nitration of the Striatal Na,K-ATPase α3 Isoform Occurs in Normal Brain Development but Is Not Increased During Hypoxia-Ischemia in Newborn Piglets

Neonatal hypoxia-ischemia (HI) can result in significant sensorimotor abnormalities, including movement and posture disorders. These neurological impairments are believed to result from basal ganglia (striatum) damage, but the exact cause of this injury is not known. One mechanism involved in brain injury after HI is the generation of reactive oxygen species, which damage cellular macromolecules. We tested the hypothesis that inactivation of plasma membrane enzyme Na,K-ATPase during striatal neurodegeneration after HI emerges with peroxynitrite attack on the enzyme. In vitro, reaction of peroxynitrite (100–500 M) with purified Na,K-ATPase produced nitration of the (catalytic) and (transport) subunits, as quantified by immunoblots of the reaction products for nitrotyrosine. To evaluate for peroxynitrite damage to Na,K-ATPase in vivo, striatal plasma membrane fractions from 1-week-old piglets subjected to asphyxic cardiac arrest and recovery were also studied by immunoprecipitation. During the progression of striatal neurodegeneration and loss of enzyme function 3–24 h after arrest, nitration of the ₃ (neuronal) isoform of Na,K-ATPase was not increased relative to sham control. Suprisingly, however, nitration of this isoform occurs during normal brain development and peaks at 2 weeks of age. We conclude that Na,K-ATPase is a target of peroxynitrite, but that this mechanism is not responsible for enzyme inactivation after HI. Protein nitration may serve as marker of other normal, noninjurious cell processes in the developing brain.     

RasGRP1, but Not RasGRP3, Is Required for Efficient Thymic β-Selection and ERK Activation Downstream of CXCR4

T cell development is a highly dynamic process that is driven by interactions between developing thymocytes and the thymic microenvironment. Upon entering the thymus, the earliest thymic progenitors, called CD4⁻CD8⁻ ‘double negative’ (DN) thymocytes, pass through a checkpoint termed “β-selection” before maturing into CD4⁺CD8⁺ ‘double positive’ (DP) thymocytes. β-selection is an important developmental checkpoint during thymopoiesis where developing DN thymocytes that successfully express the pre-T cell receptor (TCR) undergo extensive proliferation and differentiation towards the DP stage. Signals transduced through the pre-TCR, chemokine receptor CXCR4 and Notch are thought to drive β-selection. Additionally, it has long been known that ERK is activated during β-selection; however the pathways regulating ERK activation remain unknown. Here, we performed a detailed analysis of the β-selection events in mice lacking RasGRP1, RasGRP3 and RasGRP1 and 3. We report that RasGRP1 KO and RasGRP1/3 DKO deficient thymi show a partial developmental block at the early DN3 stage of development. Furthermore, DN3 thymocytes from RasGRP1 and RasGRP1/3 double knock-out thymi show significantly reduced proliferation, despite expression of the TCRβ chain. As a result of impaired β-selection, the pool of TCRβ⁺ DN4 is significantly diminished, resulting in inefficient DN to DP development. Also, we report that RasGRP1 is required for ERK activation downstream of CXCR4 signaling, which we hypothesize represents a potential mechanism of RasGRP1 regulation of β-selection. Our results demonstrate that RasGRP1 is an important regulator of proliferation and differentiation at the β-selection checkpoint and functions downstream of CXCR4 to activate the Ras/MAPK pathway.     

ACKR3 Regulation of Neuronal Migration Requires ACKR3 Phosphorylation,but Not β-Arrestin

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