What exactly is a VLP?
The origin story: from hepatitis B particles to recombinant vaccines
The next major public milestone came with HPV vaccines. Human papillomavirus vaccines use the HPV L1 major capsid protein, which self-assembles into VLPs. In June 2006, the US FDA approved Gardasil, a quadrivalent HPV vaccine targeting HPV types 6, 11, 16 and 18, for prevention of diseases including cervical cancer associated with those types. This was not just a technical success; it changed the cancer-prevention landscape by using a VLP-based vaccine to prevent infections that can lead to cancer.
VLPs then entered another global health story: malaria. RTS,S/AS01 (“MosquirixTM”) and R21/Matrix-M are malaria vaccines based on hepatitis B surface antigen particle concepts that display malaria circumsporozoite protein antigen components. The World Health Organization’s 2024 malaria vaccine position paper includes recommendations for RTS,S/AS01 and R21/Matrix-M for reducing malaria morbidity and mortality in children in areas of moderate and high malaria transmission.
The broad lesson from this history is simple: VLPs are not speculative. They have already delivered licensed vaccines and public-health impact. What is changing now is the ambition: from individual VLP vaccine products toward flexible VLP platforms.
Why VLPs are so attractive as platforms
If VLPs are so promising, why isn’t everything already VLP-based?
Mammalian cells can provide human-like post-translational processing and are useful for complex particles or proteins requiring specific folding and modifications. But they are generally associated with higher media and process costs, slower growth and more complex scale-up than microbial systems. E. coli is the contrasting option: fast growth, well-understood genetics, comparatively low-cost cultivation and highly established fermentation infrastructure. The central industrial question, however, is: can we combine the biological promise of VLPs with the speed and cost advantages of E. coli?
Why E. coli is so attractive - and why it is technically difficult
For many recombinant proteins, E. coli is the default workhorse. It grows fast, reaches high cell densities, is genetically tractable, and can be run in inexpensive media compared with many eukaryotic systems. In early-stage development, it also supports rapid design-build-test cycles.
But VLP production in E. coli has a common obstacle: capsid or particle-forming proteins can aggregate into inclusion bodies. Inclusion bodies are dense intracellular protein aggregates. They can be useful because they sometimes contain large amounts of target protein and can simplify initial capture. But they also create a downstream problem: the protein must be solubilized, purified and refolded into a functional, assembly-competent form.
This is not a minor detail, since retrieving active, correctly folded protein from E. coli inclusion-bodies is a major manufacturing challenge requiring optimization of both upstream and downstream processing. Also, protein refolding often suffers from precipitation and low recovery yields, and refolding still commonly requires trial-and-error experimentation.
For VLPs, the challenge is even more demanding than “recover a folded protein.” The protein must refold and assemble into particles with structural integrity. That means the process has to manage several linked steps: expression, inclusion-body processing, denaturing purification, contaminant removal, refolding and assembly.
Why manufacturing know-how matters
That makes process development unusually demanding. In cell-culture-based production of therapeutic viruses or VLP, host cells may also release other bionanoparticles such as exosomes, apoptotic bodies, unknown vesicles or adventitious viral particles. Some of these impurities can be physically very similar to the target product, especially for enveloped bionanoparticles, while having completely different biological effects. Separating, identifying and controlling such particles is therefore one of the central challenges in the field.
For E. coli-based VLP production, the challenge looks different but follows the same logic: the process must be understood as an integrated chain. Capsid proteins may be produced at high levels but aggregate into inclusion bodies. These must be solubilized, purified under denaturing conditions, freed from E. coli-derived contaminants, refolded into assembly-competent form and finally assembled into structurally intact particles. Every step influences the next. Losing control at one point can mean losing yield, purity, particle integrity or functionality.
That is why a successful VLP platform has to answer several questions at once: Can we express enough material? Can we remove host-derived impurities efficiently? Can we refold the protein with minimal loss? Can we assemble intact particles in a simplified and scalable way? Can we prove particle quality with suitable analytics? And, if the particle is meant for delivery, can we also control functionalization and cargo incorporation?
acib’s wider bionanoparticle toolbox: complementary expertise beyond E. coli
The E. coli platform presented in this blog focuses on microbial VLP production: expression, inclusion-body handling, denaturing purification, refolding and assembly. Separately, acib has established a broader bionanoparticle process-development environment for cell-culture and virus-related applications, including mammalian and insect-cell processes.
This complementary toolbox is relevant for partners working with more complex bionanoparticles such as viruses, enveloped VLPs, extracellular vesicles or other cell-culture-derived particles. It includes scalable benchtop and lab-scale bioreactor systems for cell culture and virus applications, single-use options, ATF-based cell-retention/process-intensification, preparative chromatography with online light-scattering detection, pilot-scale continuous ultracentrifugation, A4F/HPLC coupled to UV-MALS-DLS-RI detection, nanoparticle tracking analysis and microflow cytometry.
In other words, acib combines two complementary strengths: a dedicated E. coli workflow for suitable customizable VLP scaffolds, and a wider mammalian/insect-cell bionanoparticle toolbox for complex particle products and advanced purification/analytics. This distinction matters because the right production platform depends on the particle’s biology, required modifications, quality attributes and scale-up needs.
acib’s approach: a modular E. coli workflow for customizable VLPs
In regard to the modular E. coli-based production platform for virus-like particles, the goal is to address the main microbial manufacturing bottlenecks – expression, purification and assembly – so that targeted, customizable VLPs become more accessible for biotechnology and nanomedicine applications. The workflow is designed around the reality that many capsid proteins will not be conveniently soluble. Instead of treating inclusion-body formation only as a failure, the platform focuses on recovering value from inclusion-body-derived material: efficient removal of E. coli contaminants under denaturing conditions, followed by refolding into particles with high structural integrity through a simplified assembly step.
A key point is that acib’s approach circumvents the need for multi-stage dialysis in the assembly workflow. That matters because multi-stage dialysis can be slow, labor-intensive and difficult to scale. The acib concept aims to simplify the transition from solubilized protein to structurally intact particles.
The platform is also not limited to making “empty shells.” acib has demonstrated insertion of specific epitopes on the VLP surface to enable targeted transport, with strong potential for extension to additional targeting modalities.
In plain language: acib is building a practical and scalable route from E. coli expression to customized, structurally intact VLPs – with the downstream bottlenecks treated as the core engineering problem.
Why surface customization matters
Why this matters now
This is where E. coli has strategic appeal. It might not be the right host for every VLP, especially when complex eukaryotic modifications are essential. But when the particle design is compatible with bacterial production, E. coli can offer speed, cost efficiency and process familiarity that are highly attractive for industrial development.
Who should be interested?
Current status: acib is looking for industrial partners
The E. coli workflow is complemented by acib’s separate bionanoparticle process-development environment for mammalian and insect-cell-based systems. This broader toolbox includes cell-culture bioreactors, process-intensification tools, preparative chromatography with online light-scattering detection, pilot-scale continuous ultracentrifugation, A4F/HPLC coupled to UV-MALS-DLS-RI detection, nanoparticle tracking analysis and microflow cytometry. It is especially relevant for partner projects involving more complex cell-culture-derived bionanoparticles, while the E. coli platform remains the best route for suitable microbial VLP scaffolds.