The biosynthesis of astaxanthin

from the isoprenoid precu

The biosynthesis of astaxanthin

from the isoprenoid precursor geranylgeranyl pyrophosphate (GGPP) in X. dendrorhous requires at least four enzymatic activities, which are catalyzed by enzymes encoded by the genes crtI, crtYB and crtS. During the first phase H 89 manufacturer of biosynthesis, the phytoene synthase activity of the bifunctional enzyme phytoene-β-carotene synthase (PBS, product of crtYB) catalyzes the condensation of two GGPP molecules to produce one molecule of phytoene, the first carotenoid of the pathway [5]. After four desaturation reactions catalyzed by the enzyme phytoene desaturase (product of crtI), phytoene is transformed into a lycopene [6]. Subsequently, the lycopene is cyclized to BV-6 datasheet form β-carotene via the

β-carotene synthase activity of PBS [5]. Finally, the β-carotene is oxidized at both ends in a process that requires cytochrome p450 astaxanthin synthase (product of crtS) [7, 8]. This reaction requires the accessory activity of a cytochrome p450 reductase enzyme as an electron donor [9]. Although the structural genes needed for the synthesis of astaxanthin in this yeast have been characterized, the regulatory mechanisms that control this process are largely unknown. Importantly, alternative processing of crtYB and crtI have been reported to occur [10], although the implications of this phenomenon have not been established. In addition, alternative Histone demethylase transcripts of both genes have several premature stop codons in all three reading frames, and they likely encode non-functional proteins [10]. X. dendrorhous can develop two metabolic modes depending on the type of carbon source present in the medium. Glucose

or other fermentable Inhibitor Library clinical trial sugars are assimilated through the glycolytic pathway followed by alcoholic fermentation to produce ethanol, even in the presence of oxygen [11]. However, non-fermentable carbon sources, such as ethanol or succinate, are transformed to acetyl-CoA and are processed through the citric acid cycle. Thus, energy is produced mainly through oxidative phosphorylation. There is a strong correlation between the carbon source used and the level of pigment synthesized; high glucose concentrations as the carbon source yield minimal pigment synthesis [12, 13], ethanol as the carbon source yields greater pigment synthesis [14]. In addition, when X. dendrorhous is grown on glucose as the only carbon source, the induction of carotenogenesis coincides with sugar depletion and the beginning of ethanol consumption (produced by fermentation of the carbohydrate) [15]. Finally, previous studies have reported the presence of putative MIG1 binding sites in the promoter regions of the crtYB, crtI and crtS genes [7]. MIG1 was originally described in S. cerevisiae and is a well-known transcription factor that mediates glucose-driven transcriptional repression processes in various yeasts [16–19].

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