A Synthetic Biology Workflow Reveals Variation in Processing and Solubility of Nitrogenase Proteins Targeted to Plant Mitochondria, and Differing Tolerance of Targeting Sequences in a Bacterial Nitrogenase Assay.

Shoko Okada,Amratha Menon,Michelle Lisa Colgrave,Craig C Wood,Robert Silas Allen,Christina M Gregg,Vanessa Gillespie,Dawar Hussain,Keren Byrne,Ema Johnston

doi:10.3389/fpls.2020.552160

Abstract

While industrial nitrogen fertilizer is intrinsic to modern agriculture, it is expensive and environmentally harmful. One approach to reduce fertilizer usage is to engineer the bacterial nitrogenase enzyme complex within plant mitochondria, a location that may support enzyme function. Our current strategy involves fusing a mitochondrial targeting peptide (MTP) to nitrogenase (Nif) proteins, enabling their import to the mitochondrial matrix. However, the process of import modifies the N-terminus of each Nif protein and may impact nitrogenase assembly and function. Here we present our workflow assessing the mitochondrial processing, solubility and relative abundance of 16 Klebsiella oxytoca Nif proteins targeted to the mitochondrial matrix in Nicotiana benthamiana leaf. We found that processing and abundance of MTP::Nif proteins varied considerably, despite using the same constitutive promoter and MTP across all Nif proteins tested. Assessment of the solubility for all MTP::Nif proteins when targeted to plant mitochondria found NifF, M, N, S, U, W, X, Y, and Z were soluble, while NifB, E, H, J, K, Q, and V were mostly insoluble. The functional consequence of the N-terminal modifications required for mitochondrial targeting of Nif proteins was tested using a bacterial nitrogenase assay. With the exception of NifM, the Nif proteins generally tolerated the N-terminal extension. Proteomic analysis of Nif proteins expressed in bacteria found that the relative abundance of NifM with an N-terminal extension was increased ~50-fold, while that of the other Nif proteins was not influenced by the N-terminal extension. Based on the solubility, processing and functional assessments, our workflow identified that K. oxytoca NifF, N, S, U, W, Y, and Z successfully met these criteria. For the remaining Nif proteins, their limitations will need to be addressed before proceeding towards assembly of a complete set of plant-ready Nif proteins for reconstituting nitrogenase in plant mitochondria.

Highlights

Industrial nitrogen fixation has had a major contribution towards the Green Revolution, and subsequent unprecedented population growth (Smil, 1999)
Processing of pFAg77 by the mitochondrial processing peptidase (MPP) resulted in a 35 amino acids (AA) residual ‘scar’ on the N-terminus of the NifH protein, the cleavage
This result confirmed that the shortened mitochondrial targeting peptides (MTPs), pFAg51, was functional and processed as predicted to leave a nine AA scar at the N-terminus of NifU

Summary

Introduction

Industrial nitrogen fixation has had a major contribution towards the Green Revolution, and subsequent unprecedented population growth (Smil, 1999). There have been several efforts in the past 50 years to look for alternative, more sustainable means to deliver reduced nitrogen to crops, including the use of artificial symbiosis and commensal free-living bacteria (Santi et al, 2013; Curatti and Rubio, 2014; Oldroyd and Dixon, 2014). The Fe protein is the obligate electron donor to the MoFe protein and contains a [Fe4S4]-cluster. In addition to the structural proteins, numerous other nitrogenase (Nif) proteins are involved in the maturation of the enzyme and assembly of the metalloclusters. These include NifB, E, M, N, Q, S, U, V, W, X, Y, Z, and a ferredoxin (FdxN) (reviewed by Burén et al, 2020). Some diazotrophs contain Nif-specific electron transport proteins, NifF, a flavodoxin, and NifJ, an associated oxidoreductase (Mus et al, 2019)

Methods

Results

Conclusion