Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin

Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin

<p>Abstract</p> <p>Background</p> <p>The prevalence of diabetes is predicted to rise significantly in the coming decades. A recent analysis projects that by the year 2030 there will be ~366 million diabetics around the world, leading to an increased demand for inexpensi...

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Main Authors: Chugh Dipti, Gäbel Thomas, Adnan Ahmad, Skoko Natasa, Polez Sulena, Gurramkonda Chandrasekhar, Swaminathan Sathyamangalam, Khanna Navin, Tisminetzky Sergio, Rinas Ursula
Format: Article
Language:English
Published: BMC 2010-05-01
Series:Microbial Cell Factories
Online Access:http://www.microbialcellfactories.com/content/9/1/31
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spelling doaj-1d08d46fa7ca4a20a25e9fe36e0e65a32020-11-25T00:51:32ZengBMCMicrobial Cell Factories1475-28592010-05-01913110.1186/1475-2859-9-31Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulinChugh DiptiGäbel ThomasAdnan AhmadSkoko NatasaPolez SulenaGurramkonda ChandrasekharSwaminathan SathyamangalamKhanna NavinTisminetzky SergioRinas Ursula<p>Abstract</p> <p>Background</p> <p>The prevalence of diabetes is predicted to rise significantly in the coming decades. A recent analysis projects that by the year 2030 there will be ~366 million diabetics around the world, leading to an increased demand for inexpensive insulin to make this life-saving drug also affordable for resource poor countries.</p> <p>Results</p> <p>A synthetic insulin precursor (IP)-encoding gene, codon-optimized for expression in <it>P. pastoris</it>, was cloned in frame with the <it>Saccharomyces cerevisiae </it>α-factor secretory signal and integrated into the genome of <it>P. pastoris </it>strain X-33. The strain was grown to high-cell density in a batch procedure using a defined medium with low salt and high glycerol concentrations. Following batch growth, production of IP was carried out at methanol concentrations of 2 g L<sup>-1</sup>, which were kept constant throughout the remaining production phase. This robust feeding strategy led to the secretion of ~3 gram IP per liter of culture broth (corresponding to almost 4 gram IP per liter of cell-free culture supernatant). Using immobilized metal ion affinity chromatography (IMAC) as a novel approach for IP purification, 95% of the secreted product was recovered with a purity of 96% from the clarified culture supernatant. Finally, the purified IP was trypsin digested, transpeptidated, deprotected and further purified leading to ~1.5 g of 99% pure recombinant human insulin per liter of culture broth.</p> <p>Conclusions</p> <p>A simple two-phase cultivation process composed of a glycerol batch and a constant methanol fed-batch phase recently developed for the intracellular production of the Hepatitis B surface antigen was adapted to secretory IP production. Compared to the highest previously reported value, this approach resulted in an ~2 fold enhancement of IP production using <it>Pichia </it>based expression systems, thus significantly increasing the efficiency of insulin manufacture.</p> http://www.microbialcellfactories.com/content/9/1/31
collection DOAJ
language English
format Article
sources DOAJ
author Chugh Dipti
Gäbel Thomas
Adnan Ahmad
Skoko Natasa
Polez Sulena
Gurramkonda Chandrasekhar
Swaminathan Sathyamangalam
Khanna Navin
Tisminetzky Sergio
Rinas Ursula
spellingShingle Chugh Dipti
Gäbel Thomas
Adnan Ahmad
Skoko Natasa
Polez Sulena
Gurramkonda Chandrasekhar
Swaminathan Sathyamangalam
Khanna Navin
Tisminetzky Sergio
Rinas Ursula
Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin
Microbial Cell Factories
author_facet Chugh Dipti
Gäbel Thomas
Adnan Ahmad
Skoko Natasa
Polez Sulena
Gurramkonda Chandrasekhar
Swaminathan Sathyamangalam
Khanna Navin
Tisminetzky Sergio
Rinas Ursula
author_sort Chugh Dipti
title Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin
title_short Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin
title_full Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin
title_fullStr Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin
title_full_unstemmed Application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>Pichia pastoris </it>with subsequent purification and conversion to human insulin
title_sort application of simple fed-batch technique to high-level secretory production of insulin precursor using <it>pichia pastoris </it>with subsequent purification and conversion to human insulin
publisher BMC
series Microbial Cell Factories
issn 1475-2859
publishDate 2010-05-01
description <p>Abstract</p> <p>Background</p> <p>The prevalence of diabetes is predicted to rise significantly in the coming decades. A recent analysis projects that by the year 2030 there will be ~366 million diabetics around the world, leading to an increased demand for inexpensive insulin to make this life-saving drug also affordable for resource poor countries.</p> <p>Results</p> <p>A synthetic insulin precursor (IP)-encoding gene, codon-optimized for expression in <it>P. pastoris</it>, was cloned in frame with the <it>Saccharomyces cerevisiae </it>α-factor secretory signal and integrated into the genome of <it>P. pastoris </it>strain X-33. The strain was grown to high-cell density in a batch procedure using a defined medium with low salt and high glycerol concentrations. Following batch growth, production of IP was carried out at methanol concentrations of 2 g L<sup>-1</sup>, which were kept constant throughout the remaining production phase. This robust feeding strategy led to the secretion of ~3 gram IP per liter of culture broth (corresponding to almost 4 gram IP per liter of cell-free culture supernatant). Using immobilized metal ion affinity chromatography (IMAC) as a novel approach for IP purification, 95% of the secreted product was recovered with a purity of 96% from the clarified culture supernatant. Finally, the purified IP was trypsin digested, transpeptidated, deprotected and further purified leading to ~1.5 g of 99% pure recombinant human insulin per liter of culture broth.</p> <p>Conclusions</p> <p>A simple two-phase cultivation process composed of a glycerol batch and a constant methanol fed-batch phase recently developed for the intracellular production of the Hepatitis B surface antigen was adapted to secretory IP production. Compared to the highest previously reported value, this approach resulted in an ~2 fold enhancement of IP production using <it>Pichia </it>based expression systems, thus significantly increasing the efficiency of insulin manufacture.</p>
url http://www.microbialcellfactories.com/content/9/1/31
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