Baseline analysis of Mycoplasma mycoides subsp. mycoides antigens as targets for a DIVA assay for use with a subunit vaccine for contagious bovine pleuropneumonia.

BACKGROUND: Mycoplasma mycoides subsp. mycoides (Mmm) is the causative agent of contagious bovine pleuropneumonia in cattle. A prototype subunit vaccine is being developed, however, there is currently no diagnostic test that can differentiate between infected cattle and those vaccinated with the prototype subunit vaccine. This study characterized Mmm proteins to identify potential antigens for use in differentiating infected from vaccinated animals. RESULTS: Ten Mmm antigens expressed as recombinant proteins were tested in an indirect ELISA using experimental sera from control groups, infected, and vaccinated animals. Data were imported into R software for analysis and drawing of the box and scatter plots while Cohen's Kappa assessed the level of agreement between the Mmm antigens. Two vaccine antigens (MSC_0499 and MSC_0776) were superior in detecting antibodies in sera of animals vaccinated with the subunit vaccines while two non-vaccine antigens (MSC_0636 and LppB) detected antibodies in sera of infected animals showing all clinical stages of the disease. Sensitivity and specificity of above 87.5% were achieved when the MSC_0499 and MSC_0636 antigens were tested on sera from vaccinated and infected animals. CONCLUSIONS: The MSC_0499 and MSC_0776 antigens were the most promising for detecting vaccinated animals, while MSC_0636 and LppB were the best targets to identify infected animals. Further testing of sera from vaccinated and infected animals collected at different time intervals in the field should help establish how useful a diagnostic test based on a cocktail of these proteins would be.

Mycoplasma bovis-Induced Inhibition of Bovine Peripheral Blood Mononuclear Cell Proliferation Is Ameliorated after Blocking the Immune-Inhibitory Programmed Death 1 Receptor.

Mycoplasma bovis-induced immune suppression is a major obstacle faced by the host for controlling infections. M. bovis impairment of antigen-specific T-cell responses is achieved through inhibiting the proliferation of peripheral blood mononuclear cells (PBMCs). This impairment may contribute to the persistence of M. bovis infection in various sites, including lungs, and its systemic spread to various organs such as joints, with the underlying mechanisms remaining elusive. Here, we elucidated the role of the immune-inhibitory receptor programmed death 1 (PD-1) and its ligand (PD-L1) in M. bovis infection. Flow cytometry (FCM) analyses revealed an upregulation of PD-L1 expression on tracheal and lung epithelial cell lines after M. bovis infection. In addition, we found increased PD-L1 expression on purified lung lavage macrophages following M. bovis infection by FCM and determined its localization by immunofluorescence analysis comparing infected and control lung tissue sections. Moreover, M. bovis infection increased the expression of the PD-1 receptor on total PBMCs and in gated CD4+ and CD8+ T-cell subpopulations. We demonstrated that M. bovis infection induced a significant decrease in CD4+ PD-1INT and CD8+ PD-1INT subsets with intermediate PD-1 expression, which functioned as progenitor pools giving rise to CD4+ PD-1HIGH and CD8+ PD-1HIGH subsets with high PD-1 expression levels. We blocked PD-1 receptors on PBMCs using anti-PD-1 antibody at the beginning of infection, leading to a significant restoration of the proliferation of PBMCs. Taken together, our data indicate a significant involvement of the PD-1/PD-L1 inhibitory pathway during M. bovis infection and its associated immune exhaustion, culminating in impaired host immune responses.

Immune responses to Mycoplasma bovis proteins formulated with different adjuvants.

Most vaccines for protection against Mycoplasma bovis disease are made of bacterins, and they offer varying degrees of protection. Our focus is on the development of a subunit-based protective vaccine, and to that end, we have identified 10 novel vaccine candidates. After formulation of these candidates with TriAdj, an experimental tri-component novel vaccine adjuvant developed at VIDO-InterVac, we measured humoral and cell-mediated immune responses in vaccinated animals. In addition, we compared the immune responses after formulation with TriAdj with the responses measured in animals vaccinated with a mix of a commercial adjuvant (Emulsigen™) and 2 of the components of the TriAdj, namely polyinosinic:polycytidylic acid (poly I:C) and the cationic innate defense regulator (IDR) peptide 1002 (VQRWLIVWRIRK). In this latter trial, we detected significant IgG1 humoral immune responses to 8 out of 10 M. bovis proteins, and IgG2 responses to 7 out of 10 proteins. Thus, we concluded that the commercial adjuvant formulated with poly I:C and the IDR peptide 1002 is the best formulation for the experimental vaccine.

In vitro antimicrobial susceptibility of Mycoplasma bovis clinical isolates recovered from bison (Bison bison).

Mycoplasma bovis is a pathogen globally affecting cattle and bison herds, causing pneumonia, arthritis, mastitis, abortions, and other symptoms, leading to huge economic losses. Many studies have been done regarding the antimicrobial susceptibility of M. bovis isolated from cattle, but no such study is available for isolates recovered from bison. For the first time, in vitro susceptibilities of 40 M. bovis clinical isolates collected from bison herds in Canada are reported here. Minimal inhibitory concentration (MIC) values were determined using Sensititre® plates. The most effective MIC50 and MIC90 were for spectinomycin (1 and >64 µg/mL), tiamulin (1 and >32 µg/mL), and tulathromycin (16 and 64 µg/mL), whereas tetracyclines, fluoroquinolones, and florfenicol failed to inhibit growth of M. bovis bison isolates. Isolates were nonsusceptible to tetracyclines (100%), fluoroquinolones (97.5%), and tilmicosin (100%), whereas the highest susceptibility of bison clinical isolates was seen with spectinomycin (95%) and tulathromycin (67.5%). Two lung isolates (Mb283 and 348) were found resistant to both spectinomycin and tulathromycin. These results show a marked difference in antimicrobial susceptibility of bison isolates as compared with previously reported and laboratory reference cattle isolates, emphasizing the necessity of testing antimicrobial susceptibility of M. bovis bison isolates and to generate better therapeutic regime for improved recovery chances for infected bison herds across North America.

In vitro infection of bovine monocytes with Mycoplasma bovis delays apoptosis and suppresses production of gamma interferon and tumor necrosis factor alpha but not interleukin-10.

Mycoplasma bovis is one of the major causative pathogens of bovine respiratory complex disease (BRD), which is characterized by enzootic pneumonia, mastitis, pleuritis, and polyarthritis. M. bovis enters and colonizes bovine respiratory epithelial cells through inhalation of aerosol from contaminated air. The nature of the interaction between M. bovis and the bovine innate immune system is not well understood. We hypothesized that M. bovis invades blood monocytes and regulates cellular function to support its persistence and systemic dissemination. We used bovine-specific peptide kinome arrays to identify cellular signaling pathways that could be relevant to M. bovis-monocyte interactions in vitro. We validated these pathways using functional, protein, and gene expression assays. Here, we show that infection of bovine blood monocytes with M. bovis delays spontaneous or tumor necrosis factor alpha (TNF-α)/staurosporine-driven apoptosis, activates the NF-κB p65 subunit, and inhibits caspase-9 activity. We also report that M. bovis-infected bovine monocytes do not produce gamma interferon (IFN-γ) and TNF-α, although the level of production of interleukin-10 (IL-10) is elevated. Our findings suggest that M. bovis takes over the cellular machinery of bovine monocytes to prolong bacterial survival and to possibly facilitate subsequent systemic distribution.

Vaccination with recombinant Mycoplasma bovis GAPDH results in a strong humoral immune response but does not protect feedlot cattle from an experimental challenge with M. bovis.

Mycoplasma bovis continues to cause significant disease in feedlots and dairy farms. The ability of the micro-organism to evade the immune system of the host combined with the lack of effective vaccines makes this disease difficult to control. Bacterin-based vaccines have not been successful in field trials and in some cases enhance the disease. In an attempt to develop a sub-unit vaccine, we used the conserved M. bovis glyceraldehyde-3-phosphate (GAPDH) protein in combination with a protein extract prepared from three M. bovis isolates to immunize feedlot animals. After challenge with a combination of three M. bovis isolates, there were differences in the proportion of weight loss between the control and vaccinated groups but no differences in rectal temperature and survival rate in all the groups. In addition, there were no significant differences between the proportions of lungs lesions in all the groups despite the percentages of lesions being higher in the vaccinated groups. These findings indicate that the M. bovis GAPDH protein is not a suitable antigen for a vaccine against this pathogen.

Complement-mediated killing of Mycoplasma bovis does not play a role in the protection of animals against an experimental challenge.

Despite numerous efforts, developing recombinant vaccines for the control of M. bovis infections has not been successful. Many factors are contributing to the lack of success including the identification of protective antigens, use of effective adjuvants, and relatively limited information on the quality of immune responses needed for protection. Experimental trials using vaccination with many M. bovis proteins resulted in significant humoral immune responses before and after the challenges, however these responses were not enough to confer protection. We explored the role of complement-fixing antibodies in the killing of M. bovis in-vitro and whether animals vaccinated with proteins that elicit antibodies capable of complement-fixing would be protected against an experimental challenge. We found that antibodies against some of these proteins fixed complement and killed M. bovis in-vitro. Vaccination and challenge experiments with proteins whose cognate antibodies either fixed complement or not resulted in lack of protection against a M. bovis experimental challenge suggesting that complement fixation does not play a role in protection.

Mannheimia haemolytica increases Mycoplasma bovis disease in a bovine experimental model of BRD.

Amongst the bacterial pathogens associated with the bovine respiratory disease syndrome (BRD) in cattle are Mannheimia haemolytica and Mycoplasma bovis. The interaction between these two pathogens has not been investigated before; thus, there are gaps in the knowledge of why and how a previous infection with M. haemolytica allows the development of M. bovis-related lesions. We hypothesized that upon M. haemolytica infection, inflammatory products are produced in the lung and that these inflammatory products stimulate M. bovis to produce proteases and lipases that degrade lipids and proteins important for lung function. In this work, we identified several M. bovis proteases and lipases whose expression was modulated by M. haemolytica products in vitro. We performed co-infection animal challenges to develop a model to test vaccine protection. A prior exposure to BHV-1 followed by infection with M. bovis and M. haemolytica resulted in severe pathology and the BHV-1 infection was abandoned. When M. bovis and M. haemolytica were introduced into the lungs by bronchoscopy, we found that M. haemolytica resulted in worsening of the respiratory disease caused by M. bovis. We performed a proof-of-concept trial where animals were immunized with the M. bovis proteins identified in this study and challenged with both pathogens. Despite detecting significant humoral immune responses to the antigens, the experimental vaccine failed to protect against M. bovis disease.

Comparative genomic analysis of Canadian Mycoplasma bovis strains isolated from Bison and Cattle.

Mycoplasma bovis (M. bovis) in cattle causes pneumonia, arthritis, otitis media, and mastitis. In addition, multiple outbreaks have been recorded in North American bison. The genomic data on Canadian M. bovis in bison and cattle to date is limited. Whole-genome sequencing (WGS) was used to assess the degree of genome conservation across four Canadian M. bovis strains recovered from bison and cattle. Whole-genome sequences of four M. bovis isolates (Mb1, Mb160, Mb300, Mb304) and the PG45 reference genome were utilized to identify the M. bovis genomic similarity, whole-genome single nucleotide polymorphism (WGS-SNP), virulence determinants, and genomic islands. The pan-genome analysis showed that M. bovis encodes a minimum of 971 genes, while the core genome contained 637 genes. Comparative genomics revealed limited diversity in gene content between bison and cattle isolates. Whole-genome SNP analysis showed that the four M. bovis isolates differed from each other and to PG45. A total of 40 putative virulence genes associated with adhesion, colonization, and destruction of tissues were found in the bison and cattle isolates using the virulence factors database (VFDB). These putative virulence factors were equally distributed among isolates. Genomic Islands (GIs) ranging from 4 to 9 and associated with transposases, restriction-modification, ribosomal hypothetical proteins, variable surface lipoproteins, and unknowns were also identified. Overall, the genomic characterization of these isolates may provide new insights into the mechanisms of pathogenicity in M. bovis.

A core genome multilocus sequence typing (cgMLST) analysis of Mycoplasma bovis isolates.

Mycoplasma bovis (M. bovis) is an emerging major bovine pathogen, causing economic losses worldwide in the dairy and beef industry. Whole-genome sequencing (WGS) now allows high resolution for tracing clonal populations. Based on WGS, we developed the core genome multilocus sequence typing (cgMLST) scheme and applied it onto 151 genomes of clonal and non-clonal strains of M. bovis isolated from China, Australia, Israel, Denmark, Canada, and the USA. We used the complete genome of M. bovis PG45 as the reference genome. The pairwise genome comparison of these 151 genome sequences resulted in 478 cgMLST gene targets present in > 99.0 % clonal and non-clonal isolates with 100 % overlap and > 90 % sequence similarity. A total of 478 core genes were retained as cgMLST target genes of which an average of 90.4-99 % were present in 151 M. bovis genomes, while M. agalactiae (PG2) had 17.0 % and M. mycoides subsp. capri (PG3), M. ovipneumoniae (Y98), and M. arginine resulted in 0.0 % of good targets. When tested against the clonal and non-clonal strains, we found cgMLST clusters were congruent with the MLST-defined clonal groups, which had various degrees of diversity at the whole-genome level. Notably, cgMLST could distinguish between clonal and epidemiologically unrelated strains of the same clonal group, which could not be achieved using traditional MLST schemes. Our results showed that ninety-two M. bovis genomes from clonal group isolates had > 10 allele differences and unambiguously differentiated from unrelated outgroup strains. Additionally, cgMLST revealed that there might be several sub-clones of the emerging ST-52 clone. The cgMLST phylogenetic analysis results showed substantial agreement with geographical and temporal information. cgMLST enables the use of next-generation sequencing technology to bovine mycoplasma epidemiology at both the local and global levels. In conclusion, the novel cgMLST scheme not only showed discrimination resolution highly as compared with MLST and SNP cgMLST in sub-typing but also indicated the capability to reveal more population structure characteristics than MLST.

Protein chimeras containing the Mycoplasma bovis GAPDH protein and bovine host-defence peptides retain the properties of the individual components.

Besides the well characterized role in glycolysis, glyceraldehyde-3-phosphate dehydrogenase (GAPDH) has been implicated in virulence of pathogenic micro-organisms and because of its cell surface location, it has been shown to act as an adhesin for colonization of tissue surfaces both for pathogenic and non-pathogenic normal microflora. These novel properties of GAPDH make this protein a target for studies in pathogenesis and a candidate for vaccine development against several diseases. Previously, we have isolated the GAPDH protein of Mycoplasma bovis and we are currently using this protein as a test antigen to develop a vaccine to protect feedlot animals from M. bovis-related diseases. As part of our vaccine studies, we are testing several novel immune modulators, some of which are host-defence peptides (HDP). HDP are small protein molecules that are part of the innate immune system of the host possess antimicrobial activities and can act as adjuvants. These novel compounds have been used as part of chimeric proteins composed of viral antigens fused to HDP and these chimeras were found to promote immune responses. The first step in the use of the M. bovis GAPDH protein and HDP as components of a vaccine was to construct M. bovis GAPDH-HDP chimeric proteins. The three M. bovis GAPDH-HDP chimeric proteins constructed here: GAPDH-BMAP28 (sGap-M), GAPDH-indolicidin (sGap-I), and GAPDH-TAP (Gap-T) retained properties associated with the individual components, namely GAPDH enzymatic and HDP antimicrobial activities.

Respiratory disease caused by Mycoplasma bovis is enhanced by exposure to bovine herpes virus 1 (BHV-1) but not to bovine viral diarrhea virus (BVDV) type 2.

To determine if previous exposure to bovine viral diarrhea virus (BVDV) and bovine herpes virus 1 (BHV-1) type 2 affects the onset of disease caused by Mycoplasma bovis, 6- to 8-month-old beef calves were exposed to BVDV or BHV-1 4 d prior to challenge with a suspension of 3 clinical isolates of M. bovis. Animals were observed for clinical signs of disease and at necropsy, percent abnormal lung tissue and presence of M. bovis were determined. Most animals pre-exposed to BHV-1 type 2 but not BVDV developed M. bovis-related respiratory illness. In a second trial, we determined that a 100-fold reduction in the number of M. bovis bacteria administered to BHV-1 exposed animals reduced the percentage of abnormal lung tissue but not the severity of clinical signs. We conclude that previous exposure to BHV-1 but not BVDV type 2 was a necessary cause of M. bovis-related respiratory diseases in our disease model.

Phylogeny of Mycoplasma bovis isolates from cattle and bison based on multi locus sequence typing and multiple-locus variable-number tandem repeats.

Multiple outbreaks of Mycoplasma bovis (M. bovis) have been reported in North American bison (Bison bison) in Alberta, Manitoba, Saskatchewan, Nebraska, New Mexico, Montana, North Dakota, and Kansas. M. bovis is mainly spread through direct contact and disseminated via animal movements thus, reliable genotyping is crucial for epidemiological investigations. The present study describes the genotyping of sixty-one M. bovis strains from cattle and bison isolated from different provinces of Canada by multi locus sequence typing (MLST), and multiple-locus variable-number tandem repeat analysis (MLVA). The sixty M. bovis clinical isolates together with the reference strain PG45 were divided into ten sequence types by MLST. Three novel sequence types were identified. Two isolates, one from cattle and one from bison shared the same sequence type, whereas one strain had the same sequence type as PG45. The cattle isolates could be further subdivided in Clade A with two subclades and bison isolates were grouped in Clade B with two subclades. With the exception of one animal, isolates originating from the same animal had the same sequence type. The sixty-one isolates also formed three main clades with several subclades when analyzed by MLVA. A total of 20 VNTR (Variable number tandem repeats) types were distinguished, 8 in cattle and 12 in bison isolates. The results showed multiple sequence types and genotype populations of M. bovis in bison and cattle. The results may further help to understand the evolution of M. bovis and develop strain specific or sequence type diagnostic tools.

Complete Genome Sequences of Four Canadian Mycoplasma bovis Strains Isolated from Bison and Cattle.

Mycoplasma bovis is a major bacterial pathogen that causes respiratory diseases in cattle and bison. We report here the complete genome sequences of four Mycoplasma bovis strains isolated in three Canadian provinces. These genome sequences could provide important information on virulence factors and targets for new vaccines against M. bovis.

Effect of maternal separation and transportation stress on the bovine upper respiratory tract microbiome and the immune response to resident opportunistic pathogens.

BACKGROUND: The bovine upper respiratory tract (URT) microbiome includes opportunistic pathogens that cause respiratory disease and stress associated with maternal separation and transportation contributes to the severity of this respiratory disease. Stress is known to alter the gut microbiome but little is known regarding the effect of stress on the URT microbiota. This study used six-month old suckling beef calves to investigate whether maternal separation (weaned), by itself or combined with transportation (weaned + transport), altered the URT microbiome and host immune responses to resident opportunistic pathogens. RESULTS: Taxonomic and functional composition of the URT microbiome in suckling and weaned beef calves did not change significantly when serially sampled over a one-month period. Subtle temporal changes in the URT microbiome composition were observed in weaned + transport calves. Total bacterial density was lower (p < 0.05) on day 4 post-weaning in both the weaned and weaned + transport groups when compared to suckling calves. In addition, significant (p < 0.05) temporal changes in the density of the opportunistic pathogens, M. haemolytica and P. multocida, were observed independent of treatment but these changes did not correlate with significantly increased (p < 0.05) serum antibody responses to both of these bacteria in the weaned and weaned + transport groups. Serum antibody responses to My. bovis, another opportunistic pathogen, remained unchanged in all treatment groups. Weaning, by itself and in combination with transportation, also had significant (p < 0.05) short- (2 to 8 days post-weaning) and long-term (28 days post-weaning) effects on the expression of adrenergic receptor genes in blood leukocytes when compared to age-matched suckling beef calves. CONCLUSIONS: Maternal separation (weaning) and transportation has minor effects on the taxonomic and functional composition of the URT microbiome and temporal changes in the density of opportunistic pathogen residing in the URT did not correlate with significant changes in immune responses to these bacteria. Significant changes in adrenergic receptor expression in blood leukocytes following weaning, with or without transportation, suggests altered neuroimmune regulation should be further investigated as a mechanism by which stress can alter host-microbiome interactions for some opportunistic respiratory pathogens that reside in the URT.

Effects of inflammatory stimuli on responses of macrophages to Mycoplasma bovis infection.

Inflammation in the respiratory tract is thought to worsen the disease response to Mycoplasma bovis infection. This study investigated the cells involved in this response with a focus on proteases and cytokines as harmful effector mechanisms. By immunohistochemistry, Mac387-positive macrophages were the main cell type comprising the foci of caseous necrosis in cattle with M. bovis pneumonia. Thus, the study evaluated how priming of different types of macrophages with bacterial lysate (or pro-inflammatory cytokines induced by the bacterial lysate) affected their responses to M. bovis infection. Inducible responses were detected in monocyte-derived macrophages (M1-MDMs and M2-MDMs), whereas pulmonary alveolar macrophages (PAMs) were minimally affected by priming or infection. M. bovis-infected MDMs secreted MMP-12 and SPLA2, and priming with pro-inflammatory cytokines increased the secretion of cathepsin B in response to M. bovis infection. Of these, there were higher concentrations of cathepsin B and SPLA2 in lungs with M. bovis pneumonia compared to healthy lungs, and these are potential mechanisms for macrophage-induced lung damage in M. bovis infection. Priming of MDMs with either bacterial lysate or with pro-inflammatory cytokines caused an enhanced response to M. bovis infection with respect to IL-8 and IL-1ß secretion. The findings of this study suggest proteases, lipases and cytokines derived from monocyte-derived macrophages as possible mediators by which prior inflammation in the respiratory tract worsen disease outcomes from M. bovis infection.

Invasion of bovine peripheral blood mononuclear cells and erythrocytes by Mycoplasma bovis.

Mycoplasma bovis is a small, cell wall-less bacterium that contributes to a number of chronic inflammatory diseases in both dairy and feedlot cattle, including mastitis and bronchopneumonia. Numerous reports have implicated M. bovis in the activation of the immune system, while at the same time inhibiting immune cell proliferation. However, it is unknown whether the specific immune-cell population M. bovis is capable of attaching to and potentially invading. Here, we demonstrate that incubation of M. bovis Mb1 with bovine peripheral blood mononuclear cells (PBMC) resulted in a significant reduction in their proliferative responses while still remaining viable and capable of gamma interferon secretion. Furthermore, we show that M. bovis Mb1 can be found intracellularly (suggesting a role for either phagocytosis or attachment/invasion) in a number of select bovine PBMC populations (T cells, B cells, monocytes, γδ T cells, dendritic cells, NK cells, cytotoxic T cells, and T-helper cells), as well as red blood cells, albeit it at a significantly lower proportion. M. bovis Mb1 appeared to display three main patterns of intracellular staining: diffuse staining, an association with the intracellular side of the cell membrane, and punctate/vacuole-like staining. The invasion of circulating immune cells and erythrocytes could play an important role in disease pathogenesis by aiding the transport of M. bovis from the lungs to other sites.

Pathogenesis and Virulence of Mycoplasma bovis.

Mycoplasma bovis is an important component of the bovine respiratory disease complex and recent reports identified that other species are also affected by M bovis. Control of the disease caused by M bovis has been unsuccessful owing to many factors, including the capacity of M bovis to evade and modulate the immune system of the host; the lack of known virulence factors; the absence of a cell wall, which renders antibiotics targeting cell-wall synthesis unusable; and the failure of vaccines to control disease on the field. The current knowledge on virulence and pathogenesis is presented in this review.

Complete Genome Sequences of 16 Mycoplasma bovis Isolates from Canadian Bison and Cattle.

Here, we report the complete genome sequences of 12 Mycoplasma bovis isolates cultured from Canadian bison and 4 cultured from Canadian cattle. The sequences are of value for understanding the phylogenetic relationship between cattle and bison isolates and will aid in elucidating the genetic basis for virulence and host specificity.

Mycoplasma bovis delay in apoptosis of macrophages is accompanied by increased expression of anti-apoptotic genes, reduced cytochrome C translocation and inhibition of DNA fragmentation.

Bacterial pathogens have evolved to manipulate host cell death and survival pathways for their intracellular persistence. Understanding the ability of a bacterium to induce or inhibit cell death is essential for elucidating the disease pathogenesis and suggesting potential therapeutic options to manage the infection. In recent years, apoptosis inhibition by different bacteria has been suggested as a mechanism of survival by allowing the pathogen to replicate and disseminate in the host. Mycoplasma bovis has evolved mechanisms to invade and modulate apoptosis of bovine peripheral blood mononuclear cells (PBMC), red blood cells (RBCs), primary macrophages and monocytes. To date, these mechanisms are poorly understood. Using apoptosis assays such as Annexin V binding, caspases activity, reactive oxygen species production, DNA fragmentation and differential gene expression we set out to determine how M. bovis modulates macrophage survival. Using the BoMac cell line, we report a significant reduction in STS-induced apoptosis through caspase dependent manner. Besides activating the NF-kß pathway and inhibiting caspases 3, 6 and 9, M. bovis strain Mb1 also inhibits production of reactive oxygen species and DNA fragmentation of the host cell. We also report a significant up-regulation of the anti-apoptotic genes Bcl-2 and Bcl-XL upon infection. Our results indicate that M. bovis strain Mb1 inhibits the intrinsic pathway of apoptosis and up-regulate survival genes in BoMac cells.