Protein in Profile: Virus-Like Particles (VLPs)

Streamlining Production Through Cell-Free Expression

The development of VLP-based vaccines is a complex process, fraught with technical challenges. These challenges can lead to issues with yield and assembly, hindering their wider adoption as a commercially viable vaccine platform.

• VLP expression: Optimal cell concentration, multiplicity of infection, and time of harvest are crucial for protein expression and VLP assembly.⁵
• VLP assembly: In vivo assembly of VLPs involves complex interactions between capsid proteins, requiring optimal conditions for successful assembly.⁵
• Upstream processing: Non-optimal process parameters like dissolved oxygen concentration, pH, temperature, etc., can hinder cell growth or interfere with post-translational modification mechanisms.⁵
• Downstream processing: Separating VLPs from a complex mixture of proteins can be challenging due to similar sizes and molecular weights, and protein aggregation can lead to loss of target protein or reduced immunogenicity.⁵

Given the numerous challenges in VLP-based vaccine development, selecting a suitable production platform that ensures stable expression and assembly and scale-up to larger production volumes is crucial. Flexible and scalable cell-free systems could offer a solution by significantly reducing the time-to-clinic, thereby enhancing the prospects of successful VLP-based vaccine production.

Materials and Methods

Optimizing VLP Expression with the ALiCE® Cell-Free Platform

Three variations of HBc VLP sequences were tested:

VLP-1: Untagged full-length HBc VLP sequence

VLP-2: Full-length HBc sequence with N-terminal Strep-II tag

VLP-3: Full-length HBc with Strep-II tag on spike sequence

The pALiCE constructs were prepared and expression reaction set up with the following parameters:

• As the HBc VLP monomers contain neither membrane spanning domains or ER-/Golgi-mediated post-translational modifications (PTMs), the sequences were cloned into the pALiCE01 vector ⁶
• DNA was added to the ALiCE® reaction mix to a final concentration of 5 nM.
• Initial 50 µL ALiCE® reactions were set up according to user manual guidelines, and the expression reaction run for 48 hours. The best-expressing construct was then selected for scaled protein expression in ALiCE lysate volumes ranging from 0.1 mL to 1000 mL.
• VLPs were isolated via affinity chromatography using Ni-NTA.

Key Benefits of ALiCE^® 

VLPs are a promising alternative to traditional vaccine platforms as they trigger a strong and lasting immune response, with fewer safety concerns and higher stability than existing vaccine technologies. The ALiCE® cell-free expression platform, with its synthesis speed, antigen-conjugation capability, immunogenicity, and scalability, has immense potential as a versatile pandemic-preparedness vaccination platform.

Removing cell-line development as a bottleneck in pandemic response

The ALiCE® eukaryotic cell-free protein expression system is capable of producing even the most complex proteins in under 48 hours. This shaves off months of cell line development in VLP-based vaccine production, making it a promising platform to rapidly screen and validate VLPs of clinical relevance, thereby accelerating time to approval.

Versatility to produce antigen-conjugated, immunogenic vaccine candidates

Unlike traditional cell-based expression systems, which necessitate extensive screening of multiple constructs to identify those that correctly assemble into immunogenic VLPs, ALiCE® offers a more efficient solution. This system can be readily adapted to express and screen antigen-conjugated VLPs, significantly reducing the time required for these processes.

Moreover, the quality of the VLPs produced using ALiCE®, as shown by TEM analysis and immune response assays, demonstrates its effectiveness as a VLP factory. This makes ALiCE® a versatile and reliable platform for vaccine production in response to evolving threats.

Scalable development of vaccine candidates

The challenge of scaling eukaryotic cell-free systems has hindered their widespread adoption until now. ALiCE® operates efficiently from microliter reactions in microtiter plates to liter-scale reactions in bioreactors, demonstrating optimal performance at all scales. This scalability has been validated here with a VLP candidate. Currently, ALiCE® is being evaluated for the manufacturing of vaccine clinical trial material with support from CEPI.

References:

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6. LenioBio Application Note: Expressing Virus-Like Particles using the ALiCE Cell-Free Protein Expression System
7. LenioBio Poster: Rapid screening and scaled manufacture of immunogenic virus-like particles in the ALiCE cell-free protein synthesis system
8. LenioBio Press Release: https://www.leniobio.com/press-release/plant-based-alice-technology-could-shave-weeks-off-vaccine-production/