Brucella melitensis Vaccines: A Systematic Review

Brucella melitensis Vaccines: A Systematic Review

Background: Brucella melitensis is recognized as one of the predominant zoonotic pathogens globally. Live-attenuated vaccine Rev 1 is currently the most effective vaccine for controlling B. melitensis in small ruminants. While Brucella inactivated, nanoparticle, and subunit vaccines are less effecti...

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Veröffentlicht in:Agriculture (Basel) 2023-11, Vol.13 (11), p.2137
Hauptverfasser: Naseer, Alnakhli, Mo, Salman, Olsen, Steven C., McCluskey, Brian
Format: Artikel
Sprache:eng
Schlagworte:
Abortion
Animal models
Animals
Antibodies
Antigens
Attenuation
B. melitensis
Brucella
Brucella melitensis
Brucellosis
Case reports
Cattle
Chitosan
Combined vaccines
Cytokines
Diagnostic systems
DNA vaccines
Effectiveness
Epitopes
FliC protein
Food contamination & poisoning
Goats
Immunogenicity
Immunology
Infections
Interference
Livestock
Macrophages
Medical research
Membrane proteins
Membrane vesicles
Membranes
Nanoparticles
Outer membrane proteins
Proteins
Rev 1
Reviews
Serology
Sheep
small ruminants
Systematic review
Vaccines
Virulence
Zoonoses
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Zusammenfassung:Background: Brucella melitensis is recognized as one of the predominant zoonotic pathogens globally. Live-attenuated vaccine Rev 1 is currently the most effective vaccine for controlling B. melitensis in small ruminants. While Brucella inactivated, nanoparticle, and subunit vaccines are less effective and require multiple doses, live-attenuated vaccines are less expensive and more efficacious. Several drawbacks are associated with the administration of current attenuated B. melitensis vaccines, including interference with serological diagnostic tests, inducing abortion in pregnant animals, shedding in milk, and zoonotic infections in humans. In this systematic review, we summarize the current literature (1970–2022) on B. melitensis vaccines and review their advantages and disadvantages in order to support the rationale for a need for new or improved small ruminant brucellosis vaccines. Methods: A systematic search was carried out in Web of Science, CAB Abstracts, and PubMed. The original articles describing the B. melitensis vaccines were included. Review articles, articles not published in English, articles that did not offer full text, editorials, correspondences, case reports, case series, diagnostic tests, duplicate publications, and other Brucella vaccines (e.g., B. abortus and B. suis) were excluded. Results: Out of 3700 studies, we identified 18 articles that evaluated B. meltensis vaccines, including recombinant B. melitensis strains (16MΔhfq, 16MΔTcfSR, M5-90ΔmanB, LVM31, M5-90ΔvjbR, 16MΔmucR, ΔznuA, M5-90Δpgm, M5-90ΔwboA), live B. melitensis strain (Rev 1), nanoparticle vaccines (B. melitensis 16M, B. melitensis OMP 31, FliC protein—Mannosylated Chitosan Nanoparticles (FliC and FliC-MCN), B. melitensis and B. abortus combined, and B. melitensis 16M nanoparticles combined with oligopolysaccharide), subunit vaccines (outer membrane vesicles or outer membrane proteins), and a DNA vaccine based on B. melitensis outer membrane proteins (Omp25 and Omp31). The results from these studies revealed that these vaccines can induce humoral and cellular responses and reduce macrophage survival. However, most of these vaccines were evaluated only in murine models, which may not accurately reflect how they work in natural hosts. Conclusions: The high prevalence of B. melitensis in humans and animals remains an issue in many parts of the world. Human brucellosis can be prevented by controlling brucellosis in livestock using vaccination and test-and-removal strate
ISSN:2077-0472
2077-0472
DOI:10.3390/agriculture13112137