Genome-scale Reconstructions of the Mammalian Secretory Pathway Predict Metabolic Costs and Limitations of Protein Secretion

Overview

Journal Nat Commun

Specialty Biology

Date 2020 Jan 4

PMID 31896772

Citations 37

Authors

Jahir M Gutierrez

Amir Feizi

Shangzhong Li

Thomas B Kallehauge

Hooman Hefzi

Lise M Grav

Daniel Ley

Deniz Baycin Hizal

Michael J Betenbaugh

Bjorn Voldborg

Helene Faustrup Kildegaard

Gyun Min Lee

Bernhard O Palsson

Jens Nielsen

Nathan E Lewis

Affiliations

Soon will be listed here.

Abstract

In mammalian cells, >25% of synthesized proteins are exported through the secretory pathway. The pathway complexity, however, obfuscates its impact on the secretion of different proteins. Unraveling its impact on diverse proteins is particularly important for biopharmaceutical production. Here we delineate the core secretory pathway functions and integrate them with genome-scale metabolic reconstructions of human, mouse, and Chinese hamster ovary cells. The resulting reconstructions enable the computation of energetic costs and machinery demands of each secreted protein. By integrating additional omics data, we find that highly secretory cells have adapted to reduce expression and secretion of other expensive host cell proteins. Furthermore, we predict metabolic costs and maximum productivities of biotherapeutic proteins and identify protein features that most significantly impact protein secretion. Finally, the model successfully predicts the increase in secretion of a monoclonal antibody after silencing a highly expressed selection marker. This work represents a knowledgebase of the mammalian secretory pathway that serves as a novel tool for systems biotechnology.

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