Vaccenic acid-mediated reduction in cytokine production is independent of c9,t11-CLA in human peripheral blood mononuclear cells

The ruminant trans fatty acid vaccenic acid (tVA) favorably alters markers of inflammation. However, it is not yet clear whether these effects are attributed to its endogenous partial conversion to c9,t11-CLA, which is known to possess anti-inflammatory properties. We compared the cytokine reducing potential of tVA to c9,t11-CLA in human T-helper (Th) cells as a main source of cytokine production during inflammation. Secondly, we assessed whether a bioconversion of tVA to c9,t11-CLA via stearoyl-CoA desaturase (SCD) encoded activity takes place in peripheral blood mononuclear cells (PBMC) in order to relate the outcomes of intracellular cytokine measurement to the degree of conversion. TVA reduced the percentage of both IL-2 and TNF-α expressing Th cells significantly, but to a lesser extent compared to c9,t11-CLA, as determined by flow cytometry after alloreactive stimulation of PBMC. Pre-treatment with the selective PPARγ antagonist T0070907 largely re-established the IL-2 and TNF-α positive Th cell population in both tVA and c9,t11-CLA treated cultures. Interestingly, while the portion of tVA dose-dependently increased within the cellular lipid fraction, the initially marginal amount of c9,t11-CLA remained unaltered. However, SCD mRNA although abundantly expressed in PBMC was not regulated by tVA. Conclusively, these results suggest that the cytokine reducing effect of tVA in human T cells is independent of c9,t11-CLA, since no bioconversion occurred. Moreover, the data provide evidence that tVA mechanistically acts in a manner similar to c9,t11-CLA.     

Enhancement of Carotenoid Biosynthesis in Transplastomic Tomatoes by Induced Lycopene-to-Provitamin A Conversion

Carotenoids are essential pigments of the photosynthetic apparatus and an indispensable component of the human diet. In addition to being potent antioxidants, they also provide the vitamin A precursor β-carotene. In tomato (Solanum lycopersicum) fruits, carotenoids accumulate in specialized plastids, the chromoplasts. How the carotenoid biosynthetic pathway is regulated and what limits total carotenoid accumulation in fruit chromoplasts is not well understood. Here, we have introduced the lycopene β-cyclase genes from the eubacterium Erwinia herbicola and the higher plant daffodil (Narcissus pseudonarcissus) into the tomato plastid genome. While expression of the bacterial enzyme did not strongly alter carotenoid composition, expression of the plant enzyme efficiently converted lycopene, the major storage carotenoid of the tomato fruit, into provitamin A (β-carotene). In green leaves of the transplastomic tomato plants, more lycopene was channeled into the β-branch of carotenoid biosynthesis, resulting in increased accumulation of xanthophyll cycle pigments and correspondingly reduced accumulation of the α-branch xanthophyll lutein. In fruits, most of the lycopene was converted into β-carotene with provitamin A levels reaching 1 mg per g dry weight. Unexpectedly, transplastomic tomatoes also showed a >50% increase in total carotenoid accumulation, indicating that lycopene β-cyclase expression enhanced the flux through the pathway in chromoplasts. Our results provide new insights into the regulation of carotenoid biosynthesis and demonstrate the potential of plastids genome engineering for the nutritional enhancement of food crops.Carotenoids are isoprenoid molecules that are synthesized by all photosynthetic organisms and also by some fungi and nonphotosynthetic bacteria. In plants, they participate in photosynthetic light harvesting and protection against light stress. In addition, carotenoids accumulate to large levels as storage metabolites in chromoplasts of flowers, fruits, and taproots. Carotenoids are also essential to animals, which, however, are unable to synthesize them de novo, and therefore must rely on dietary sources of carotenoids. β-Carotene is the main dietary precursor of vitamin A and therefore also referred to as provitamin A. Vitamin A deficiency in humans represents a global health problem affecting approximately one-third of the countries of the world (Mayer et al., 2008). Presumably due to their antioxidant activity, β-carotene and other carotenoid species also exert protective effects against cardiovascular diseases, certain cancers, and aging-related diseases (Collins, 1999).While the enzymology of the carotenoid biosynthetic pathways in plants and eubacteria is now reasonably well understood (Armstrong, 1997; Cunningham and Gantt, 1998; Hirschberg, 2001), understanding of the regulation of carotenoid biosynthesis is still rather poor (Bramley, 2002). Mainly using the tomato (Solanum lycopersicum) fruit as model system, the study of pigmentation mutants (Ronen et al., 2000; Isaacson et al., 2002; Galpaz et al., 2006) and transgenic approaches (Giuliano et al., 2000, 2008; Römer and Fraser, 2005; Fraser et al., 2007) have provided first insights into regulatory mechanisms operating in carotenogenesis. For example, constitutive expression of the phytoene desaturase (crtI) gene from the bacterium Erwinia uredovora resulted in elevated β-carotene accumulation in tomatoes, but also led to an unexpected reduction in total carotenoid levels (Römer et al., 2000). The reduction in total carotenoids is believed to be an effect of feedback regulation from β-carotene or one of its downstream metabolites (Bramley, 2002). However, fruit-specific overexpression of the native lycopene β-cyclase resulted in increased β-carotene accumulation, without a concomitant decrease in total carotenoids (Rosati et al., 2000). Why some genetic disturbances of carotenoid biosynthesis negatively affect total carotenoid accumulation and others do not (or even result in an increase; Dharmapuri et al., 2002; Fraser et al., 2002), remains to be established.Here we have used tomato plastid transformation to address the regulation of carotenoid biosynthesis exerted at the level of lycopene to β-carotene conversion by the enzyme lycopene β-cyclase (Fig. 1A). We show that plastid expression of a plant lycopene β-cyclase does not only trigger efficient conversion of lycopene to β-carotene, but unexpectedly also results in a >50% increase in total carotenoid accumulation. This contrasts moderately increased β-carotene levels and reduced total carotenoid accumulation upon expression of a bacterial lycopene β-cyclase (Wurbs et al., 2007) and suggests lycopene β-cyclase activity as an important regulatory point in plant and microbial carotenoid biosynthesis.Open in a separate windowFigure 1.Engineering of the carotenoid biosynthetic pathway by plastid transformation. A, Carotenoid biosynthetic pathway in higher plants. The pathway splits into an α-branch and a β-branch immediately downstream of lycopene, the major storage carotenoid of tomato fruits. The enzyme expressed from the tomato plastid genome in this study, lycopene β-cyclase, leads into the β-branch. B, Physical maps of the targeting region in the plastid genome (ptDNA) and the plastid transformation vectors pEcrtY and pNLyc constructed in this study. Genes above the line are transcribed from the left to the right, genes below the line are transcribed in the opposite direction. The transgenes are targeted to the intergenic region between the trnfM and trnfG genes (Ruf et al., 2001). The selectable marker gene aadA is driven by a chimeric rRNA operon promoter (Prrn; Svab and Maliga, 1993), fused to the 3′-UTR from the psbA gene (TpsbA), and flanked by two loxP sites to allow marker removal by Cre-mediated site-specific recombination (Zhou et al., 2008). The transgene expression cassette consists of the ribosomal RNA operon promoter fused to the 5′ leader from the gene 10 of phage T7 (Prrn-G10L; Kuroda and Maliga, 2001) and the 3′-UTR of the rps16 gene (Trps16). Restriction sites used for cloning or RFLP analysis are indicated, and the psaB-derived hybridization probe is denoted by a horizontal bar. Sites lost due to ligation to heterologous ends are in parentheses. C, Southern-blot analysis of tomato transplastomic lines carrying the lycopene β-cyclase gene from daffodil (S.l.-pNLyc) or from E. herbicola (S.l.-pEcrtY). Total cellular DNA was digested with BglII and hybridized to a radioactively labeled probe detecting the psaB region of the plastid genome, which flanks the transgene insertion site (section B). Fragment sizes are given in kb. wt, Wild type. D, Alignment (produced with ClustalW2) of the amino acid sequences of the lycopin β-cyclases from daffodil (Np) and E. herbicola (Eh). Asterisk (*) denotes residues identical in both sequences (marked in bold), colon (:) indicates conserved substitutions, and a dot indicates semiconserved substitutions. The N-terminal extension of the Np sequence is likely to harbor the transit peptide for protein import into plastids. The amino acids that changed due to correction of the Lyc sequence from daffodil (published sequence: GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"X98796.1","term_id":"1419692"}}X98796.1; corrected sequence: accession no. {"type":"entrez-nucleotide","attrs":{"text":"GQ327929","term_id":"254681605"}}GQ327929) are underlined. The corrections improve the sequence similarity in the N-terminal domains of the Np and Eh sequences.     

Dynamics of the actin-binding protein drebrin in motile cells and definition of a juxtanuclear drebrin-enriched zone

The actin-binding protein (ABP) drebrin, isoform E2, is involved in remodelling of the actin cytoskeleton and in formation of cell processes, but its role in cell migration has not yet been investigated. Therefore, we have studied the organization of drebrin in motile cultured cells such as murine B16F1 melanoma and human SV80 fibroblast cells, using live cell confocal microscopy. In cells overexpressing DNA constructs encoding drebrin linked to EGFP, numerous long, branched cell processes were formed which slowly retracted and extended, whereas forward movement was halted. In contrast, stably transfected B16F1 cells containing drebrin-EGFP at physiological levels displayed lamellipodia and were able to migrate on laminin. Surprisingly, in such cells, drebrin was absent from anterior lamellipodia but was enriched in a specific juxtanuclear zone, the "drebrin-enriched zone" (DZ), and in the tail. In leading edges of SV80 cells, characterized by pronounced actin microspikes, drebrin was specifically enriched along posterior portions of the microspikes, together with tropomyosin. Drebrin knock-down by small interfering RNAs did not impair movements of SV80 cells. Our results confirm the role of drebrin E2 in the formation of branching processes and further indicate that during cell migration, the protein contributes to retraction of the cell body and the tail but not to lamellipodia formation. In particular, the novel, sizable juxtanuclear DZ structure will have to be characterized in future experiments with respect to its molecular assembly and cell biological functions.     

Formation of dAMP-glycerol and dAMP-Tris derivatives by Thermococcus kodakaraensis DNA primase

In the presence of dATP, glycerol, and Tris buffer, the DNA primase isolated from Thermococcus kodakaraensis catalyzed the formation of dAMP and two products that were identified as dAMP-glycerol and dAMP-Tris. These products were formed by the T. kodakaraensis p41 catalytic subunit alone and the T. kodakaraensis p41-p46 complex in the absence of a DNA template. They were not formed with preparations containing the catalytically inactive p41 subunit. Similar glycerol and Tris derivatives as well as dNMPs were also formed with dGTP, dCTP, or dTTP. The mechanism contributing to the formation of these products and its implications in the initiation reaction catalyzed by the T. kodakaraensis primase are discussed.     

The proneural gene ascl1a is required for endocrine differentiation and cell survival in the zebrafish adenohypophysis

Mammalian basic helix-loop-helix proteins of the achaete-scute family are proneural factors that, in addition to the central nervous system, are required for the differentiation of peripheral neurons and sensory cells, derivatives of the neural crest and placodal ectoderm. Here, in identifying the molecular nature of the pia mutation, we investigate the role of the zebrafish achaete-scute homologue ascl1a during development of the adenohypophysis, an endocrine derivative of the placodal ectoderm. Similar to mutants deficient in Fgf3 signaling from the adjacent ventral diencepahalon, pia mutants display failure of endocrine differentiation of all adenohypophyseal cell types. Shortly after the failed first phase of cell differentiation, the adenohypophysis of pia mutants displays a transient phase of cell death, which affects most, but not all adenohypophyseal cells. Surviving cells form a smaller pituitary rudiment, lack expression of specific adenohypophyseal marker genes (pit1, neurod), while expressing others (lim3, pitx3), and display an ultrastructure reminiscent of precursor cells. During normal development, ascl1a is expressed in the adenohypophysis and the adjacent diencephalon, the source of Fgf3 signals. However, chimera analyses show that ascl1a is required cell-autonomously in adenohypophyseal cells themselves. In fgf3 mutants, adenohypophyseal expression of ascl1a is absent, while implantation of Fgf3-soaked beads into pia mutants enhances ascl1a, but fails to rescue pit1 expression. Together, this suggests that Ascl1a might act downstream of diencephalic Fgf3 signaling to mediate some of the effects of Fgf3 on the developing adenohypophysis.     

Impairment of LTD and cerebellar learning by Purkinje cell-specific ablation of cGMP-dependent protein kinase I

The molecular basis for cerebellar plasticity and motor learning remains controversial. Cerebellar Purkinje cells (PCs) contain a high concentration of cGMP-dependent protein kinase type I (cGKI). To investigate the function of cGKI in long-term depression (LTD) and cerebellar learning, we have generated conditional knockout mice lacking cGKI selectively in PCs. These cGKI mutants had a normal cerebellar morphology and intact synaptic calcium signaling, but strongly reduced LTD. Interestingly, no defects in general behavior and motor performance could be detected in the LTD-deficient mice, but the mutants exhibited an impaired adaptation of the vestibulo-ocular reflex (VOR). These results indicate that cGKI in PCs is dispensable for general motor coordination, but that it is required for cerebellar LTD and specific forms of motor learning, namely the adaptation of the VOR.     

Do Female Zebra Finches,Taeniopygia guttata,Choose Their Mates Based on Their ‘Personality’?

A major challenge in behavioural and evolutionary ecology is to understand the evolution and maintenance of consistent behavioural differences among individuals within populations, often referred to as animal ‘personalities’. Here, we present evidence suggesting that sexual selection may act on such personality differences in zebra finches (Taeniopygia guttata), as females seem to choose males on the basis of their exploratory behaviour per se, while taking into account their own personality. After observing a pair of males, whose apparent levels of exploration were experimentally manipulated, females that exhibited low‐exploratory tendencies showed no preference during mate choice for males that had appeared to be either ‘exploratory’ or ‘unexploratory’. In contrast, intermediate and highly exploratory females preferred apparently exploratory males over apparently unexploratory ones. Our results suggest that behavioural or genetic compatibility for personality traits might be important for mate choice, at least for exploratory individuals.