Anaerobic Fungal Mevalonate Pathway Genomic Biases Lead to Heterologous Toxicity Underpredicted by Codon Adaptation Indices.

Ethan T Hillman,Kevin V Solomon,Jacob A Englaender,Elizabeth M Frazier,Evan K Shank,Adrian N Ortiz-Velez

doi:10.3390/microorganisms9091986

Ethan T Hillman, Kevin V Solomon + Show 4 more

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https://doi.org/10.3390/microorganisms9091986

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Journal: Microorganisms	Publication Date: Sep 18, 2021
Citations: 5	License type: CC BY 4.0

Affiliation: Purdue University West Lafayette

Abstract

Anaerobic fungi are emerging biotechnology platforms with genomes rich in biosynthetic potential. Yet, the heterologous expression of their biosynthetic pathways has had limited success in model hosts like E. coli. We find one reason for this is that the genome composition of anaerobic fungi like P. indianae are extremely AT-biased with a particular preference for rare and semi-rare AT-rich tRNAs in E coli, which are not explicitly predicted by standard codon adaptation indices (CAI). Native P. indianae genes with these extreme biases create drastic growth defects in E. coli (up to 69% reduction in growth), which is not seen in genes from other organisms with similar CAIs. However, codon optimization rescues growth, allowing for gene evaluation. In this manner, we demonstrate that anaerobic fungal homologs such as PI.atoB are more active than S. cerevisiae homologs in a hybrid pathway, increasing the production of mevalonate up to 2.5 g/L (more than two-fold) and reducing waste carbon to acetate by ~90% under the conditions tested. This work demonstrates the bioproduction potential of anaerobic fungal enzyme homologs and how the analysis of codon utilization enables the study of otherwise difficult to express genes that have applications in biocatalysis and natural product discovery.

Highlights

Over the last century, fungi have been a source of valuable products in biotechnology, from medicines and insecticides to food additives and enzymes [1]
We focused on expressing individual genes and the complete mevalonate biosynthesis pathway from recently isolated Piromyces indianae, a pathway composed of three genes that convert acetyl-CoA
Without codon optimization, some genes from anaerobic fungi cause moderate to severe growth defects in E. coli that are not predicted by the standard codon adaptation index

Summary

Introduction

Fungi have been a source of valuable products in biotechnology, from medicines and insecticides to food additives and enzymes [1]. Anaerobic fungi in particular are increasingly recognized as a vast, untapped source of enzymes for biotechnology [2,3,4]. Genomic studies of anaerobic fungi show they have the largest array of biomass-degrading enzymes among fungi, which can be used for platforms that convert lignocellulosic waste to biofuels and chemicals [3,5]. In addition to plant biomassdegrading enzymes, anaerobic fungi have specialized membrane transporters [6] and unique biosynthetic pathways [7,8] that may be a valuable source of natural products, like polyketides synthases (PKS), non-ribosomal peptide synthetases (NRPS), terpenes, and bacteriocins [1,9]. The full potential of anaerobic fungi remains unrealized because there are few existing tools for their engineering.

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