Abstract
BackgroundA major obstacle to industrial-scale astaxanthin production by the yeast Phaffia rhodozyma is the strong inhibitory effect of high glucose concentration on astaxanthin synthesis. We investigated, for the first time, the mechanism of the regulatory effect of high glucose (> 100 g/L) at the metabolite and transcription levels.ResultsTotal carotenoid, β-carotene, and astaxanthin contents were greatly reduced in wild-type JCM9042 at high (110 g/L) glucose; in particular, β-carotene content at 24–72 h was only 14–17% of that at low (40 g/L) glucose. The inhibitory effect of high glucose on astaxanthin synthesis appeared to be due mainly to repression of lycopene-to-β-carotene and β-carotene-to-astaxanthin steps in the pathway. Expression of carotenogenic genes crtE, pbs, and ast was also strongly inhibited by high glucose; such inhibition was mediated by creA, a global negative regulator of carotenogenic genes which is strongly induced by glucose. In contrast, astaxanthin-overproducing, glucose metabolic derepression mutant strain MK19 displayed de-inhibition of astaxanthin synthesis at 110 g/L glucose; this de-inhibition was due mainly to deregulation of pbs and ast expression, which in turn resulted from low creA expression. Failure of glucose to induce the genes reg1 and hxk2, which maintain CreA activity, also accounts for the fact that astaxanthin synthesis in MK19 was not repressed at high glucose.ConclusionWe conclude that astaxanthin synthesis in MK19 at high glucose is enhanced primarily through derepression of carotenogenic genes (particularly pbs), and that this process is mediated by CreA, Reg1, and Hxk2 in the glucose signaling pathway.
Highlights
A major obstacle to industrial-scale astaxanthin production by the yeast Phaffia rhodozyma is the strong inhibitory effect of high glucose concentration on astaxanthin synthesis
At 6% liquid volume, astaxanthin production (YP/S) increased to 0.32 mg/g (Table 3) without change of astaxanthin content. These findings indicate that MK19 is a glucose metabolic derepression strain in regard to both astaxanthin production and cell growth, when dissolved oxygen level (DO) is sufficient
Accumulation of β-carotene was strikingly higher for 110 g/L vs. 40 g/L glucose. These findings suggest that (i) additional astaxanthin synthase (AST) is required to synthesize more astaxanthin in spite of high ast gene expression; (ii) β-carotene synthesis is completely deregulated by high glucose level; (iii) inhibition of astaxanthin synthesis is relieved when glucose is exhausted
Summary
A major obstacle to industrial-scale astaxanthin production by the yeast Phaffia rhodozyma is the strong inhibitory effect of high glucose concentration on astaxanthin synthesis. Astaxanthin is an orange-red carotenoid pigment that has great commercial value because of its antioxidant and coloration properties. It is utilized increasingly as a protective agent against in vivo oxidative damage [1,2,3,4,5], and as a colorant for aquatic food products such as salmon, lobster, and crab. It can eliminate free radicals with antioxidant activity ~ 500-fold higher than that of. Biosynthesis of carotenoids (tetraterpenoids; a class of terpenoids) is a complicated process, and regulatory mechanisms in P. rhodozyma and other producers remain poorly known, some research progress has been made during the past five years [16,17,18,19,20]
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