agar and Plague

Topics: Agar; Cefsulodin; Culture Media; Humans; Novobiocin; Nystatin; Plague; Yersinia pestis

According to the WHO, 75% of the world's plague cases are found in Madagascar, with an average of 200 to 700 cases suspected annually (mainly bubonic plague). In 2017, a pneumonic plague epidemic of unusual proportions occurred, which raised several challenges for laboratory confirmation of cases, pointing to the need for the development of Yersinia pestis isolation procedures, especially those that can be performed in remote areas. As the WHO gold standard for plague diagnosis is bacterial culture, we sought to develop a simple method to prepare a highly selective medium, fit for use in remote areas where plague is endemic. The performance of the new medium, named improved BIN, was examined in terms of growth support and selectivity with spiked samples as well in isolating Y. pestis from clinical specimens, and it was compared to the results obtained with commercially available selective media. The preparation of the new medium is less complex and its performance was found to be superior to that of first-generation BIN medium. The growth support of the medium is higher, there is no batch diversity, and it maintains high selectivity properties. In 55 clinical specimens obtained from patients suspected to be infected with Y. pestis, approximately 20% more Y. pestis-positive isolates were identified by the improved BIN medium than were identified by commercially available selective media. The improved BIN medium is notably advantageous for the isolation of Y. pestis from clinical specimens obtained from plague patients, thus offering better surveillance tools and proper promotion of medical treatment to more patients suspected of being infected with Y. pestis.

Topics: Agar; Culture Media; Humans; Madagascar; Plague; Yersinia pestis

Since its identification as the causative agent of plague in 1894, thousands of Yersinia pestis strains have been isolated and stored. Here, we report the ability of Y. pestis to survive up to 47 years in agar stabs, in rubber-stoppered tubes, under refrigeration (+4 to +10°C), although overall subculture recovery rates were poor and inversely related to the length of time stored. Genetic characterization of virulence gene presence among these subcultures was suggestive of significant variation in the genomic stability of Y. pestis subcultures stored under these conditions. Specifically, we found variation in the presence of plasmid and chromosomal virulence markers (genes pla, lcrV, caf1 and irp2) among multiple subcultures of Y. pestis strains in the 'Collection of Yersinia pestis' (Fiocruz-CYP) maintained by the SRP of FIOCRUZ-PE in Brazil. This variation, together with all of the inherent temporal, geographic and other genetic variation represented by all of the recoverable strains in this historical collection was preserved in new frozen culture stocks stored at -70°C as a result of this study. These frozen culture stocks represent a valuable resource for future comparative studies of Y. pestis.. We report the ability of Yersinia pestis to survive up to 47 years in agar stabs, in rubber-stoppered tubes, under refrigeration (+4 to +10°C), although overall subculture recovery rates were poor and inversely related to the length of time stored. Genetic characterization of virulence gene presence among these subcultures was suggestive of significant variation in the genomic stability of Y. pestis subcultures stored under these conditions. This variation, together with all of the inherent temporal, geographic and other genetic variation represented by all of the recoverable strains in the historical 'Collection of Yersinia pestis' (Fiocruz-CYP) maintained by the SRP of FIOCRUZ-PE in Brazil was preserved in new frozen culture stocks stored at -70°C as a result of this study. These frozen culture stocks represent a valuable resource for future comparative studies of Y. pestis.

Topics: Agar; Brazil; Cryopreservation; Genetic Variation; Humans; Plague; Plasmids; Virulence; Yersinia pestis

Yersinia pestis, the causative agent of plague, can occasionally be contracted as a naso-pharyngeal or gastrointestinal illness through consumption of contaminated meat. In this study, the use of 254 nm ultraviolet light (UV-C) to inactivate a multi-isolate cocktail of avirulent Y. pestis on food and food contact surfaces was investigated. When a commercial UV-C conveyor was used (5 mW/cm(2)/s) 0.5 J/cm(2) inactivated >7 log of the Y. pestis cocktail on agar plates. At 0.5 J/cm(2), UV-C inactivated ca. 4 log of Y. pestis in beef, chicken, and catfish, exudates inoculated onto high density polypropylene or polyethylene, and stainless steel coupons, and >6 log was eliminated at 1 J/cm(2). Approximately 1 log was inactivated on chicken breast, beef steak, and catfish fillet surfaces at a UV-C dose of 1 J/cm(2). UV-C treatment prior to freezing of the foods did not increase the inactivation of Y. pestis over freezing alone. These results indicate that routine use of UV-C during food processing would provide workers and consumers some protection against Y. pestis.

Topics: Agar; Animals; Catfishes; Chickens; Colony Count, Microbial; Food Contamination; Food Handling; Food Irradiation; Food Microbiology; Freezing; Microbial Viability; Plague; Red Meat; Ultraviolet Rays; Yersinia pestis

Existing media designed for selective isolation of clinically important members of the genus Yersinia were found to be unsatisfactory for the growth and isolation of Yersinia pestis. We report the development of a new selective agar medium (termed BIN) that supports the growth of Y. pestis. The development of the formulation of this medium was based on a fluorescence screening system designed for monitoring bacterial growth on semisolid media, using a green fluorescent protein-expressing strain. High-throughput combinatorial experiments can be conducted for the quantitative evaluation of the effect of different medium components on growth. Generation of fluorescence plots in this system, using microplates, allowed the quantitative evaluation of the growth rate of Y. pestis EV76 cultures in different agar compositions. The final BIN formulation is based on brain heart infusion agar, to which the selective agents irgasan, cholate salts, crystal violet, and nystatin were introduced. It was found that BIN agar is more efficient in supporting colony formation and recovery of Y. pestis than are the conventional semisolid media MacConkey agar and Yersinia-selective agar (cefsulodin-irgasan-novobiocin agar). The advantage of BIN over other media has been also demonstrated in recovering virulent Y. pestis from the mixed bacterial populations found in decaying carcasses of infected mice. The BIN medium is suggested as a selective medium for isolation and recovery of Y. pestis from various backgrounds.

Topics: Agar; Animals; Animals, Outbred Strains; Bacteriological Techniques; Colony Count, Microbial; Culture Media; Female; Green Fluorescent Proteins; Luminescent Proteins; Mice; Plague; Yersinia pestis

Three serological procedures, the agar-gel precipitin inhibition, the complement fixation, and the indirect hemagglutination tests, were used to detect and measure antibody to Yersinia pestis in the sera from 383 individuals. Although all three tests were useful in detecting plague antibody, the most reliable and sensitive test procedure was indirect hemagglutination.

Topics: Agar; Antibodies; Antibody Formation; Complement Fixation Tests; Diagnosis, Differential; Evaluation Studies as Topic; Hemagglutination Tests; Humans; Immunization; Methods; Plague; Plague Vaccine; Precipitin Tests; Serologic Tests; Yersinia pestis

Topics: Agar; Animals; Asparaginase; Asparagine; Blood; Culture Media; Guinea Pigs; Humans; Mice; Plague; Rodent Diseases; Species Specificity; Yersinia pestis

Current methods of identifying Pasteurella pestis rely heavily on tests specific for detecting fraction I, the envelope antigen. Pesticin I, a bacteriocin inhibitory for P. pseudotuberculosis, has been demonstrated in nearly all tested strains isolated from human infections. The results of using this characteristic as an identifying trait for P. pestis were compared with results reported for detecting fraction I by fluorescent-antibody and antiserum-agar techniques. Data indicate that, although certain atypical strains of P. pestis fail to react in one system or the other, a combination of these tests provides positive identification in all cases. Detection of P. pestis in contaminated materials is greatly facilitated, and the simplicity of this test makes it a valuable tool in the study of plague infections and an important adjunct to methods currently in use. The use of the pesticin I assay is not intended to replace other accepted techniques, but rather to supplement them and increase the effectiveness of plague investigation.

Topics: Agar; Bacteriocins; Biological Assay; Calcium; Diagnosis, Differential; Edetic Acid; Fluorescent Antibody Technique; Humans; Immune Sera; Methods; Pasteurella; Plague; Yersinia pestis

Ability to detect pigmented and nonpigmented Pasteurella pestis is essential in plague research, and is currently dependent on use of the synthetic hemin-agar of Jackson and Burrows. We have devised a new differential medium for this purpose, containing Congo red dye and common, commercially available laboratory media. The ease and simplicity of preparation make the Congo red-agar a practical routine laboratory tool in plague research. These findings, possibly indicating a common binding site for hematin and Congo red, should be useful in efforts to determine the chemical nature of a bacterial component associated with high virulence in P. pestis.

Topics: Agar; Congo Red; Culture Media; Humans; Pigments, Biological; Plague; Yersinia pestis

Topics: Agar; Culture Media; Francisella tularensis; Methods; Penicillins; Plague