In the rapidly evolving field of filovirus research, attention is increasingly turning to the less characterized members of the Orthomarburgvirus genus. Among these, the Ravn virus (RAVV) remains underexplored despite its genetic divergence from the Marburg virus (MARV). This divergence presents unique challenges and opportunities for vaccine development, especially as efforts intensify to create broadly protective countermeasures against these deadly pathogens. Current vaccine strategies predominantly target various MARV isolates, leaving a critical gap in protection against RAVV, which shares significant pathogenic potential but differs antigenically.
This gap stems largely from the high genetic variation observed between MARV and RAVV, particularly in their glycoprotein (GP) sequences, which are the primary targets of immune responses. Vaccination approaches that effectively cross-protect against both viruses are vital for comprehensive filovirus outbreak preparedness. Intriguingly, some recent experimental vaccine candidates have demonstrated promising cross-protective efficacy, reinvigorating hopes for a universal orthomarburgvirus vaccine capable of mitigating future outbreaks with single immunization regimens.
One compelling approach involves the use of adenovirus-vectored vaccines engineered to express fusion GP proteins derived from multiple MARV strains, such as the wild-type Musoke and Ci67 variants. In preclinical studies involving murine and guinea pig models, these adenovirus-based vaccines triggered robust antibody production, exhibiting protection not only against homologous MARV challenges but also heterologous RAVV infections. This cross-reactive protection underscores the potential for designing trivalent vaccine constructs that harness conserved antigenic determinants across related orthomarburgviruses, effectively broadening immune coverage.
Complementary to these findings, in vitro immunogenicity assays reinforced the ability of adenovirus vectors expressing individual GPs from MARV-Musoke, MARV-Ci67, or RAVV to elicit specific humoral and cellular responses. Although protective efficacy in live organism challenges was not assessed in this study, these immune signatures provide preliminary evidence supporting multi-pathogen vaccine strategies. Such data suggest that sequencing and structural analysis of GP variants can be leveraged to rationally construct vaccines capable of inducing cross-reactive immunity with potential translational benefits.
Beyond viral vector platforms, virus-like particle (VLP) vaccines have demonstrated significant promise in expanding protection against orthomarburgviruses. VLPs assembled from MARV-Musoke GPs administered to guinea pigs elicited potent humoral responses, including antibodies with cross-reactivity to RAVV GP epitopes. Subsequent challenge with adapted MARV strains and RAVV produced marked protection in vaccinated animals, sparing them from clinical signs such as lethargy, hemorrhagic manifestations, and hepatic pathology, which were prevalent in control groups. These findings highlight the utility of VLPs as non-replicative immunogens stimulating both neutralizing antibodies and cellular immunity.
Crucially, transition into non-human primate (NHP) models yielded parallel results, with cynomolgus macaques vaccinated with MARV-Musoke VLPs surviving lethal challenges with MARV-Ci67 and RAVV, exhibiting minimal clinical illness. These results further substantiate the translational potential of VLP-based vaccines for human application, offering a safe, scalable, and immunogenically effective platform that triggers durable protection across orthomarburgvirus variants. The observed breakthrough case of mild disease without viremia emphasizes the robustness of vaccine-induced immunity but also signals the need for continued optimization to achieve sterilizing immunity.
The emergence of messenger RNA (mRNA) lipid nanoparticle vaccines extends the landscape of orthomarburgvirus vaccine technology. Recent work utilizing mRNA constructs encoding GP proteins from MARV-Angola and RAVV delivered intramuscularly induced strong antigen-specific IgG and neutralizing antibody titers in guinea pigs. A booster immunization amplified these responses significantly. Notably, the cross-neutralization profile revealed that the MARV-based mRNA vaccine elicited robust neutralizing activities against RAVV, whereas the reciprocal was less pronounced, indicating asymmetry in cross-protective immune recognition likely due to structural and epitope accessibility differences within GPs.
Further analysis revealed distinct qualitative variations in antibody binding affinity and neutralization specificity between MARV and RAVV vaccines. MARV-specific sera exhibited lower affinity for cleaved GP forms compared to RAVV-induced antibodies, suggesting differences in epitope presentation or immunodominance that influence vaccine efficacy. Nevertheless, both vaccine formulations conferred cross-protection upon challenge with heterologous viruses in guinea pigs, providing a compelling proof-of-concept for future pan-orthomarburgvirus mRNA vaccines. This adaptability of mRNA platforms affords rapid development timelines and precision antigen design, key advantages amid potential filovirus outbreaks.
Collectively, these diverse preclinical endeavors illuminate a path toward broadly protective orthomarburgvirus vaccines capable of mitigating the substantial genetic and antigenic heterogeneity inherent among MARV and RAVV strains. The convergence of viral vectored, VLP, and mRNA vaccine platforms illustrates a multipronged approach, each with distinct mechanistic benefits and translational considerations. The integration of cross-protection data underscores the feasibility of developing multivalent formulations that could streamline immunization strategies against these high-consequence pathogens in both endemic and outbreak settings.
Moreover, the immunological insights gained through these studies reveal nuanced humoral and cellular responses elicited by different vaccine modalities. Understanding the molecular determinants driving cross-neutralization and protection is paramount for rational vaccine design. Structural characterization of GP epitopes and their conservation across orthomarburgvirus species would further aid in optimizing immunogen selection, enhancing the breadth and durability of vaccine-induced immunity.
As filovirus outbreaks pose recurrent and unpredictable threats to public health, advancements in vaccine development targeting the full spectrum of orthomarburgviruses are critical. The demonstrated cross-protective immunogenicity against RAVV, historically overshadowed by MARV-focused efforts, prominently shifts the paradigm toward universal filovirus vaccines. Such innovations promise to reduce morbidity and mortality, improving epidemic preparedness and response capabilities globally.
Ongoing challenges include ensuring vaccine safety, efficacy across genetically diverse populations, and scalable manufacturing. Additionally, elucidating correlates of protection and mechanisms of immune evasion by orthomarburgviruses will refine booster regimens and vaccine deployment strategies. The emerging consensus favors a holistic approach integrating cross-reactivity and heterogeneity considerations to preempt zoonotic spillovers and contain outbreaks efficiently.
In summary, the recent breakthroughs in experimental vaccines exhibiting potent cross-protection against MARV and RAVV signify a transformative advancement in orthomarburgvirus research. The prospect of a pan-orthomarburgvirus vaccine is no longer theoretical but increasingly attainable through convergent multidisciplinary efforts. Continual refinement of immunogens, vaccine platforms, and analytical tools will accelerate progress toward durable, broadly protective interventions essential for countering the persistent threat posed by filoviruses.
Subject of Research:
The development of cross-protective vaccines targeting genetic variants of Orthomarburgvirus, with a focus on Marburg virus (MARV) and Ravn virus (RAVV).
Article Title:
Revisiting Ravn virus as the lesser known orthomarburgvirus
Article References:
Yordanova, I.A., Prescott, J.B. Revisiting Ravn virus as the lesser known orthomarburgvirus. npj Viruses 4, 11 (2026). https://doi.org/10.1038/s44298-026-00180-x
Image Credits:
AI Generated
DOI:
https://doi.org/10.1038/s44298-026-00180-x
Tags: adenovirus-vectored vaccinescross-protective filovirus vaccinesexperimental filovirus vaccinesfilovirus vaccine developmentgenetic divergence Marburg virusguinea pig filovirus modelsMarburg virus glycoprotein variationmurine filovirus vaccine studiesOrthomarburgvirus genusRavn virus researchsingle-dose filovirus immunizationuniversal orthomarburgvirus vaccine
