References

vavilov

Вавиловский журнал генетики и селекции

Vavilov Journal of Genetics and Breeding

2500-3259

Institute of Cytology and Genetics of Siberian Branch of the RAS

10.18699/VJ20.602

vavilov-2544

Research Article

ГЕНЕТИКА МИКРООРГАНИЗМОВ

MICROBIAL GENETICS

Разнообразие и распространение метилотрофных дрожжей, используемых в генной инженерии

Diversity and occurrence of methylotrophic yeasts used in genetic engineering

Розанов

А. С.

Rozanov

A. S.

sibiryak.n@gmail.com

https://orcid.org/0000-0003-2658-7906

Першина

Е. Г.

Pershina

E. G.

Богачева

Н. В.

Bogacheva

N. V.

Шляхтун

В.

Shlyakhtun

Сычев

А. А.

Sychev

A. A.

Белгородская область

https://orcid.org/0000-0002-3524-0456

Пельтек

С. Е.

Peltek

S. E.

Федеральный исследовательский центр Институт цитологии и генетики Сибирского отделения Российской академии наукРоссияInstitute of Cytology and Genetics of Siberian Branch of the Russian Academy of SciencesRussian Federation

ООО «Инновационный центр «Бирюч-НТ»РоссияInnovation Centre Biruch-NTRussian Federation

2020

23042020

242149157

2020

Розанов А.С., Першина Е.Г., Богачева Н.В., Шляхтун В., Сычев А.А., Пельтек С.Е.

Rozanov A.S., Pershina E.G., Bogacheva N.V., Shlyakhtun V., Sychev A.A., Peltek S.E.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://vavilov.elpub.ru/jour/article/view/2544

Метилотрофные дрожжи используются в качестве платформы для экспрессии гетерологичных белков с 1980-х гг. Они имеют высокий уровень продукции и позволяют получить белки эукариот с приемлемым уровнем гликозилирования. Первая система для экспрессии рекомбинантного белка на основе Pichia pastoris была разработана на основе штамма, выделенного из сокотечения деревьев на юго-западе США. Система распространялась бесплатно в научных целях и применяется во всем мире. В ходе классификации метилотрофных дрожжей по молекулярно-биологическим маркерам штаммы, используемые для получения рекомбинантного белка, были реклассифицированы как Komagataella phaffii. Они находятся в свободном доступе согласно патентному законодательству, однако распространялись на договорной основе. Это делает неопределенным их статус для коммерческого использования и, соответственно, стимулирует поиск альтернативных штаммов для экспрессии рекомбинантного белка. Были адаптированы штаммы других видов метилотрофных дрожжей, среди которых преобладают представители рода Ogataea. Несмотря на филогенетическую удаленность представите-лей рода Ogataeaи Komagataella, во всех случаях оказалось возможным использовать классические векторы и промоторы для экспрессии рекомбинантного белка. Существуют системы экспрессии на основе других штаммов рода Komagataella, а также рода Candida. Потенциал этих микроорганизмов для генной инженерии далеко не исчерпан. Перспективно как усовершенствование имеющихся систем экспрессии, так и создание новых на основе штаммов, выделенных из природных источников. Исторически до 2009 г. в качестве систем экспрессии использовались штаммы, выделенные на юго-западе США. В настоящее время начали развиваться системы экспрессии на основе штаммов, полученных в Таиланде. Поскольку эта группа микроорганизмов широко представлена по всему миру как в природной, так и в городской среде, можно ожидать появления систем экспрессии рекомбинантных белков, созданных на основе штаммов, выделенных и в других регионах планеты.

Methylotrophic yeasts have been used as the platform for expression of heterologous proteins since the 1980’s. They are highly productive and allow producing eukaryotic proteins with an acceptable glycosylation level. The first Pichia pastoris-based system for expression of recombinant protein was developed on the basis of the treeexudate-derived strain obtained in the US southwest. Being distributed free of charge for scientific purposes, this system has become popular around the world. As methylotrophic yeasts were classified in accordance with biomolecular markers, strains used for production of recombinant protein were reclassified as Komagataella phaffii. Although patent legislation suggests free access to these yeasts, they have been distributed on a contract basis. Whereas their status for commercial use is undetermined, the search for alternative stains for expression of recombinant protein continues. Strains of other species of methylotrophic yeasts have been adapted, among which the genus Ogataearepresentatives prevail. Despite the phylogenetic gap between the genus Ogataeaand the genus Komagataellarepresentatives, it turned out possible to use classic vectors and promoters for expression of recombinant protein in all cases. There exist expression systems based on other strains of the genus Komagataellaas well as the genus Candida. The potential of these microorganisms for genetic engineering is far from exhausted. Both improvement of existing expression systems and development of new ones on the basis of strains obtained from nature are advantageous. Historically, strains obtained on the southwest of the USA were used as expression systems up to 2009. Currently, expression systems based on strains obtained in Thailand are gaining popularity. Since this group of microorganisms is widely represented around the world both in nature and in urban environments, it may reasonably be expected that new expression systems for recombinant proteins based on strains obtained in other regions of the globe will appear.

метилотрофные дрожжиPichia pastorisOgataeaKomagataellaрекомбинантные ферменты

methylotrophic yeastsPichia pastorisOgataeaKomagataellarecombinant enzymes

This research is supported by the publically funded project No. 0259-2019-0005 of the Institute of Cytology and Genetics of the Siberian Branch of the Russian Academy of Sciences

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The authors declare that there are no conflicts of interest present.