MALDI-TOF MS and genomic analysis can make the difference in the clarification of canine brucellosis outbreaks.

Brucellosis is one of the most common bacterial zoonoses worldwide affecting not only livestock and wildlife but also pets. Canine brucellosis is characterized by reproductive failure in dogs. Human Brucella canis infections are rarely reported but probably underestimated due to insufficient diagnostic surveillance. To improve diagnostics, we investigated dogs in a breeding kennel that showed clinical manifestations of brucellosis and revealed positive blood cultures. As an alternative to the time-consuming and hazardous classical identification procedures, a newly developed species-specific intact-cell matrix-assisted laser desorption/ionization-time of flight mass spectrometry analysis was applied, which allowed for rapid identification of B. canis and differentiation from closely related B. suis biovar 1. High-throughput sequencing and comparative genomics using single nucleotide polymorphism analysis clustered our isolates together with canine and human strains from various Central and South American countries in a distinct sub-lineage. Hence, molecular epidemiology clearly defined the outbreak cluster and demonstrated the endemic situation in South America. Our study illustrates that MALDI-TOF MS analysis using a validated in-house reference database facilitates rapid B. canis identification at species level. Additional whole genome sequencing provides more detailed outbreak information and leads to a deeper understanding of the epidemiology of canine brucellosis.

Comparative application of IS711-based polymerase chain reaction (PCR) and loop-mediated isothermal amplification (LAMP) for canine brucellosis diagnosis.

Canine brucellosis is caused by Brucella canis, a gram negative and facultative intracellular bacterium that is commonly associated with reproductive failures in dogs. The accurate diagnosis of the infection relies on the use of serological tests associated with blood culturing to guarantee sensitivity. The polymerase chain reaction (PCR) can replace the culturing procedure for the direct diagnosis of the infection because of its speed, high specificity and sensitivity values; however, it depends on some laboratory infrastructure to be conducted. The loop-mediated isothermal amplification (LAMP) may be an alternative method for DNA amplification in a shorter period, using simpler equipment, and with a lower cost. This study evaluated the potential of molecular tools based on PCR and LAMP using primers targeting the insertion sequence IS711 for Brucella detection in three groups of dogs (infected, non-infected and suspected of brucellosis), which were determined according to the results of blood culturing and clinical examination. The performance of the three diagnostic tests was also determined using McNemar test and Kappa coefficient. The proportion of positive samples detected by blood culturing, PCR and LAMP was respectively 31.57% (18/57), 33.34% (19/57), and 14.03% (8/57). The agreement between blood culturing and PCR was almost perfect, while the agreement of PCR and blood culturing compared to LAMP was fair. The diagnostic sensitivity of PCR and LAMP was respectively 100% (18/18) and 44.44% (8/18), while the diagnostic specificity of both tests was 100% (21/21). LAMP performance was not satisfactory for canine brucellosis diagnosis because of the low diagnostic sensitivity of the test. The IS711 based PCR, otherwise, showed high values of sensitivity and specificity, which makes it a good alternative for use for the rapid diagnosis of canine brucellosis.