High-yield, plant-based production of an antimicrobial peptide with potent activity in a mouse model.
Shahid ChaudharyZahir AliAarón Pantoja-AnglesSherin AbdelrahmanCynthia Olivia Baldelamar JuárezGundra Sivakrishna RaoPei-Ying HongCharlotte HauserMagdy M MahfouzPublished in: Plant biotechnology journal (2024)
Plants offer a promising chassis for the large-scale, cost-effective production of diverse therapeutics, including antimicrobial peptides (AMPs). However, key advances will reduce production costs, including simplifying the downstream processing and purification steps. Here, using Nicotiana benthamiana plants, we present an improved modular design that enables AMPs to be secreted via the endomembrane system and sequestered in an extracellular compartment, the apoplast. Additionally, we translationally fused an AMP to a mutated small ubiquitin-like modifier sequence, thereby enhancing peptide yield and solubilizing the peptide with minimal aggregation and reduced occurrence of necrotic lesions in the plant. This strategy resulted in substantial peptide accumulation, reaching around 2.9 mg AMP per 20 g fresh weight of leaf tissue. Furthermore, the purified AMP demonstrated low collateral toxicity in primary human skin cells, killed pathogenic bacteria by permeabilizing the membrane and exhibited anti-infective efficacy in a preclinical mouse (Mus musculus) model system, reducing bacterial loads by up to three orders of magnitude. A base-case techno-economic analysis demonstrated the economic advantages and scalability of our plant-based platform. We envision that our work can establish plants as efficient bioreactors for producing preclinical-grade AMPs at a commercial scale, with the potential for clinical applications.
Keyphrases
- protein kinase
- mouse model
- induced apoptosis
- small molecule
- risk assessment
- cell therapy
- physical activity
- oxidative stress
- wastewater treatment
- body mass index
- high throughput
- cell wall
- weight loss
- stem cells
- weight gain
- cell proliferation
- mesenchymal stem cells
- signaling pathway
- cell death
- endoplasmic reticulum stress
- anti inflammatory
- single cell
- bone marrow
- life cycle
- wild type