ABSTRACT
Bovine brucellosis induces abortion in cows, produces important economic losses, and causes a widely distributed zoonosis. Its eradication was achieved in several countries after sustained vaccination with the live attenuated Brucella abortus S19 vaccine, in combination with the slaughtering of serologically positive animals. S19 induces antibodies against the smooth lipopolysaccharide (S-LPS), making difficult the differentiation of infected from vaccinated bovines. We developed an S19 strain constitutively expressing the green fluorescent protein (S19-GFP) coded in chromosome II. The S19-GFP displays similar biological characteristics and immunogenic and protective efficacies in mice to the parental S19 strain. S19-GFP can be distinguished from S19 and B. abortus field strains by fluorescence and multiplex PCR. Twenty-five heifers were vaccinated withS19-GFP (5×109 CFU) by the subcutaneous or conjunctival routes and some boosted with GFP seven weeks thereafter. Immunized animals were followed up for over three years and tested for anti-S-LPS antibodies by both the Rose Bengal test and a competitive ELISA. Anti-GFP antibodies were detected by an indirect ELISA and Western blotting. In most cases, anti-S-LPS antibodies preceded for several weeks those against GFP. The anti-GFP antibody response was higher in the GFP boosted than in the non-boosted animals. In all cases, the anti-GFP antibodies persisted longer, or at least as long, as those against S-LPS. The drawbacks and potential advantages of using the S19-GFP vaccine for identifying vaccinated animals in infected environments are discussed.
Subject(s)
Brucella Vaccine/analysis , Brucella abortus/isolation & purification , Brucellosis, Bovine/diagnosis , Brucellosis, Bovine/prevention & control , Green Fluorescent Proteins/analysis , Animals , Brucella Vaccine/therapeutic use , Cattle/microbiology , Enzyme-Linked Immunosorbent Assay , Female , Fluorescence , Green Fluorescent Proteins/therapeutic use , Mice , Multiplex Polymerase Chain Reaction , Vaccination/veterinaryABSTRACT
Brucellosis is a zoonosis caused by Brucella species. Brucellosis research in natural hosts is often precluded by practical, economical and ethical reasons and mice are widely used. However, mice are not natural Brucella hosts and the course of murine brucellosis depends on bacterial strain virulence, dose and inoculation route as well as breed, genetic background, age, sex and physiological statu of mice. Therefore, meaningful experiments require a definition of these variables. Brucella spleen replication profiles are highly reproducible and course in four phases: i), onset or spleen colonization (first 48 h); ii), acute phase, from the third day to the time when bacteria reach maximal numbers; iii), chronic steady phase, where bacterial numbers plateaus; and iv), chronic declining phase, during which brucellae are eliminated. This pattern displays clear physiopathological signs and is sensitive to small virulence variations, making possible to assess attenuation when fully virulent bacteria are used as controls. Similarly, immunity studies using mice with known defects are possible. Mutations affecting INF-γ, TLR9, Myd88, Tγδ and TNF-ß favor Brucella replication; whereas IL-1ß, IL-18, TLR4, TLR5, TLR2, NOD1, NOD2, GM-CSF, IL/17r, Rip2, TRIF, NK or Nramp1 deficiencies have no noticeable effects. Splenomegaly development is also useful: it correlates with IFN-γ and IL-12 levels and with Brucella strain virulence. The genetic background is also important: Brucella-resistant mice (C57BL) yield lower splenic bacterial replication and less splenomegaly than susceptible breeds. When inoculum is increased, a saturating dose above which bacterial numbers per organ do not augment, is reached. Unlike many gram-negative bacteria, lethal doses are large (≥ 108 bacteria/mouse) and normally higher than the saturating dose. Persistence is a useful virulence/attenuation index and is used in vaccine (Residual Virulence) quality control. Vaccine candidates are also often tested in mice by determining splenic Brucella numbers after challenging with appropriate virulent brucellae doses at precise post-vaccination times. Since most live or killed Brucella vaccines provide some protection in mice, controls immunized with reference vaccines (S19 or Rev1) are critical. Finally, mice have been successfully used to evaluate brucellosis therapies. It is concluded that, when used properly, the mouse is a valuable brucellosis model.
Subject(s)
Brucella/physiology , Brucella/pathogenicity , Brucellosis/immunology , Brucellosis/microbiology , Disease Models, Animal , Mice , Animals , Brucellosis/genetics , Brucellosis/physiopathology , Humans , VirulenceABSTRACT
Brucellosis is an important malady of productive and wildlife animals and a worldwide zoonosis. The use of effective vaccines and the corresponding diagnostic tests that allow differentiating infected from vaccinated animals are essential tools to control the disease. For this, a prototype of Brucella abortus S19 vaccine expressing green fluorescent protein (S19-GFP) was constructed. The S19-GFP was readily identified under ultraviolet light by macroscopic and microscopic examination and maintained all the biochemical characteristics of the parental S19 vaccine. S19-GFP replicated ex vivo and in vivo, and protected mice against challenge with virulent B. abortus to the same extent as the isogenic S19. An immunoenzymatic assay designed to measure anti-GFP antibodies allowed the discrimination between mice vaccinated with S19-GFP and those immunized with S19. Both vaccines raised antibodies against lipopolysaccharide molecule to similar levels. This experimental model constitutes a "proof of concept" for the use of Brucella-GFP vaccines and associated diagnostic tests to distinguish vaccinated from naturally Brucella infected animals.