Concomitant  NH+4 secretion during astaxanthin synthesis in Haematococcus pluvialis under  high irradiance and nitrogen deficient conditions

Abstract

Abstract: The present study is focused on protein degradation during astaxanthin synthesis in Haematococcus pluvialis under high irradiance and nitrogen deficient conditions. It was found that with the onset of astaxanthin synthesis in the cultures of high light and nitrogen-free (HF), high light and nitrogen-repletion (HR), and low light and nitrogen-free (LF), (1) endopeptidase (EP) activities increased along with decrease in protein content, (2) asparagine in HF and HR rose significantly before the first 4 and 5 day, but fell after that time. While, it increased slowly and continuously in LF, (3) ammonium increased continuously in HF and HR, whereas in LF, it was detected on the sixth day, and increased slowly on the following days. By contrast, in low light and nitrogen-repletion culture, (LR), the contents of protein and asparagine as well as EP activity were maintained relatively constant, no astaxanthin and ammonium were detected. Furthermore, when HF was sealed and bubbled with CO2-free gas (O2 and N2), astaxanthin content increased as the protein level decreased. These results strongly suggest that (1) the degraded protein served as a substitutive carbon source, to some extent, for the biosynthesis of astaxanthin, (2) endopeptidase was involved in the degradative process, (3) for detoxification, part of the ammonium generated by protein degradation was transiently stored in asparagine, whereas the rest of it was expelled into the culture broth.

Key words: ammonium, asparagine, astaxanthin, endopeptidase, Haematococcus pluvialis, protein degradation

摘要： The present study is focused on protein degradation during astaxanthin synthesis in Haematococcus pluvialis under high irradiance and nitrogen deficient conditions. It was found that with the onset of astaxanthin synthesis in the cultures of high light and nitrogen-free (HF), high light and nitrogen-repletion (HR), and low light and nitrogen-free (LF), (1) endopeptidase (EP) activities increased along with decrease in protein content, (2) asparagine in HF and HR rose significantly before the first 4 and 5 day, but fell after that time. While, it increased slowly and continuously in LF, (3) ammonium increased continuously in HF and HR, whereas in LF, it was detected on the sixth day, and increased slowly on the following days. By contrast, in low light and nitrogen-repletion culture, (LR), the contents of protein and asparagine as well as EP activity were maintained relatively constant, no astaxanthin and ammonium were detected. Furthermore, when HF was sealed and bubbled with CO2-free gas (O2 and N2), astaxanthin content increased as the protein level decreased. These results strongly suggest that (1) the degraded protein served as a substitutive carbon source, to some extent, for the biosynthesis of astaxanthin, (2) endopeptidase was involved in the degradative process, (3) for detoxification, part of the ammonium generated by protein degradation was transiently stored in asparagine, whereas the rest of it was expelled into the culture broth.

关键词: ammonium;asparagine;astaxanthin;endopeptidase;Haematococcus pluvialis;protein degradation

DONGQinglin a,b ,ZHAOXueming a ,XINGXiangying b ,HUJianzhong a , GONGJixian a . Concomitant NH⁺₄secretion during astaxanthin synthesis in Haematococcus pluvialis under high irradiance and nitrogen deficient conditions[J]. .

董庆霖, 赵学明, 邢向英, 胡建中, 巩继贤. 雨生红球藻合成虾青素过程中分泌铵离子[J]. CIESC Journal.

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Concomitant NH⁺₄secretion during astaxanthin synthesis in Haematococcus pluvialis under high irradiance and nitrogen deficient conditions

雨生红球藻合成虾青素过程中分泌铵离子

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