Recombinant Lactococcus lactis -based multivalent vaccine targeting Campylobacter jejuni colonisation and modulating cecal microbiota in poultry
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Background
Diarrhoeal diseases remain the second leading cause of preventable death globally, particularly among children under the age of five in developing countries, accounting for an estimated 2-3 million deaths annually. Among the bacterial pathogens causing diarrheal illness, Campylobacter jejuni ( C. jejuni ) remains one of the major contributors, particularly in LMICs. As a common gut pathogen, C. jejuni expresses several secretory or surface-expressed colonisation proteins, namely Hcp, VgrG, CadF, FlpA, and JlpA. Most of these proteins play pivotal roles in bacterial self-survival, host-cell adhesion, and invasion in avian and non-avian hosts.
Methods
To minimise the C. jejuni adhesion and subsequent colonisation in the avian gut, we explored the potential of a multivalent mucosal vaccine composition using these putative subunits of C. jejuni . For this purpose, we bioengineered a food-grade Lactic Acid-producing Bacterium, Lactococcus lactis ( L . lactis ), to express three key immunogenic subunits, Hcp, CadF and JlpA. Utilising this live vector-based multi-component mucosal vaccine platform, we investigated the immunoprotective potential of these antigens in chickens. Since the particular strain of L. lactis is non-colonising, we used chitosan as a natural mucoadhesive, biodegradable polymer to microencapsulate the engineered bacteria to increase their gut retention time for optimal interaction with local immune cells.
Results
Our in vivo immunisation study demonstrated that oral administration of this multivalent vaccine formulation elicited a strong local antibody response (sIgA) and upregulated key pro-inflammatory cytokines, leading to robust mucosal immune protection against the cecal colonisation of C. jejuni . Moreover, gut metagenomic analysis of vaccinated birds revealed a marked reduction in the phylum Campylobacterota, accompanied by an increased abundance of the phyla Bacillota and Bacteroidota, as part of a beneficial microbial community.
Conclusions
Together, this study underscores the potential of a live vector-based, multivalent mucosal vaccine as a promising, cost-effective strategy to reduce the risk of foodborne transmission of C. jejuni , particularly in poultry production systems.
