Variable Lipoprotein Hemagglutinin A Gene (vlhA) Expression in Variant Mycoplasma gallisepticum Strains In Vivo.

Mycoplasma gallisepticum, the primary etiologic agent of chronic respiratory disease, is a significant poultry pathogen, causing severe inflammation and leading to economic losses worldwide. Immunodominant proteins encoded by the variable lipoprotein and hemagglutinin (vlhA) gene family are thought to be important for M. gallisepticum-host interaction, pathogenesis, and immune evasion, but their exact role remains unknown. Previous work has demonstrated that vlhA phase variation is dynamic throughout the earliest stages of infection, with vlhA 3.03 being the predominant vlhA expressed during the initial infection, and that the pattern of dominant vlhA expression may be nonrandom and regulated by previously unrecognized mechanisms. To further investigate this gene family, we assessed the vlhA profile of two well-characterized vaccine strains, GT5 and Mg7, a vlhA 3.03 mutant strain, and an M. gallisepticum population expressing an alternative immunodominant vlhA Here, we report that two M. gallisepticum vaccine strains show different vlhA profiles over the first 2 days of infection compared to that of wild-type Rlow, while the population expressing an alternative immunodominant vlhA gene reverted to a profile indistinguishable from that of wild-type Rlow Additionally, we observed a slight shift in the vlhA gene expression profile but no reduction in virulence in a vlhA 3.03 mutant. Taken together, these data further support the hypothesis that M. gallisepticum vlhA genes change in a nonstochastic temporal progression of expression and that vlhA 3.03, while preferred, is not required for virulence. Collectively, these data may be important in elucidating mechanisms of colonization and overall pathogenesis of M. gallisepticum.

Transcriptional Profiling of the Chicken Tracheal Response to Virulent Mycoplasma gallisepticum Strain Rlow.

Mycoplasma gallisepticum, the primary etiologic agent of chronic respiratory disease (CRD) in poultry, leads to prolonged recruitment and activation of inflammatory cells in the respiratory mucosa. This is consistent with the current model of immune dysregulation that ostensibly allows the organism to evade clearance mechanisms and establish chronic infection. To date, studies using quantitative reverse transcription-PCR (qRT-PCR) and microarrays have shown a significant transient upregulation of cytokines and chemokines from tracheal epithelial cells (TECs) in vitro and tracheal tissue ex vivo in response to virulent strain Rlow that contributes to the infiltration of inflammatory cells into the tracheal mucosa. To expand upon these experiments, RNA was isolated from tracheas of 20 chickens infected with M. gallisepticum Rlow and 20 mock-infected animals at days 1, 3, 5, and 7 postinoculation, and samples were analyzed for differential gene expression using Illumina RNA sequencing. A rapid host response was observed 24 h postinfection, with over 2,500 significantly differentially expressed genes on day 3, the peak of infection. Many of these genes have immune-related functions involved in signaling pathways, including Toll-like receptor (TLR), mitogen-activated protein kinase, Jak-STAT, and the nucleotide oligomerization domain-like receptor pathways. Of interest was the increased expression of numerous cell surface receptors, including TLR4 and TLR15, which may contribute to the production of cytokines. Metabolic pathways were also activated on days 1 and 3 postinfection, ostensibly due to epithelial cell distress that occurs upon infection. Early perturbations in tissue-wide gene expression, as observed here, may underpin a profound immune dysregulation, setting the stage for disease manifestations characteristic of M. gallisepticum infection.

Attenuated Phenotype of a Recent House Finch-Associated Mycoplasma gallisepticum Isolate in Domestic Poultry.

Mycoplasma gallisepticum, known primarily as a respiratory pathogen of domestic poultry, has emerged since 1994 as a significant pathogen of the house finch (Haemorhousmexicanus) causing severe conjunctivitis and mortality. House finch-associated M. gallisepticum (HFMG) spread rapidly and increased in virulence for the finch host in the eastern United States. In the current study, we assessed virulence in domestic poultry with two temporally distant, and yet geographically consistent, HFMG isolates which differ in virulence for house finches-Virginia 1994 (VA1994), the index isolate of the epidemic, and Virginia 2013 (VA2013), a recent isolate of increased house finch virulence. Here we report a significant difference between VA1994 and VA2013 in their levels of virulence for chickens; notably, this difference correlated inversely to the difference in their levels of virulence for house finches. VA1994, while moderately virulent in house finches, displayed significant virulence in the chicken respiratory tract. VA2013, while highly virulent in the house finch, was significantly attenuated in chickens relative to VA1994, displaying less-severe pathological lesions in, and reduced bacterial recovery from, the respiratory tract. Overall, these data indicate that a recent isolate of HFMG is greatly attenuated in the chicken host relative to the index isolate, notably demonstrating a virulence phenotype in chickens inversely related to that in the finch host.

Global Changes in Mycoplasma gallisepticum Phase-Variable Lipoprotein Gene vlhA Expression during In Vivo Infection of the Natural Chicken Host.

Mycoplasma gallisepticum is the primary etiologic agent of chronic respiratory disease in poultry, a disease largely affecting the respiratory tract and causing significant economic losses worldwide. Immunodominant proteins encoded by members of the variable lipoprotein and hemagglutinin (vlhA) gene family are thought to be important for mechanisms of M. gallisepticum-host interaction, pathogenesis, and immune evasion, but their exact role and the overall nature of their phase variation are unknown. To better understand these mechanisms, we assessed global transcriptomic vlhA gene expression directly from M. gallisepticum populations present on tracheal mucosae during a 7-day experimental infection in the natural chicken host. Here we report differences in both dominant and minor vlhA gene expression levels throughout the first week of infection and starting as early as day 1 postinfection, consistent with a functional role not dependent on adaptive immunity for driving phase variation. Notably, data indicated that, at given time points, specific vlhA genes were similarly dominant in multiple independent hosts, suggesting a nonstochastic temporal progression of dominant vlhA gene expression in the colonizing bacterial population. The dominant expression of a given vlhA gene was not dependent on the presence of 12-copy GAA trinucleotide repeats in the promoter region and did not revert to the predominate vlhA gene when no longer faced with host pressures. Overall, these data indicate that vlhA phase variation is dynamic throughout the earliest stages of infection and that the pattern of dominant vlhA expression may be nonrandom and regulated by previously unrecognized mechanisms.

Hydrogen peroxide production from glycerol metabolism is dispensable for virulence of Mycoplasma gallisepticum in the tracheas of chickens.

Hydrogen peroxide (H2O2) is a by-product of glycerol metabolism in mycoplasmas and has been shown to cause cytotoxicity for cocultured eukaryotic cells. There appears to be selective pressure for mycoplasmas to retain the genes needed for glycerol metabolism. This has generated interest and speculation as to their function during infection. However, the actual effects of glycerol metabolism and H2O2 production on virulence in vivo have never been assessed in any Mycoplasma species. To this end, we determined that the wild-type (WT) R(low) strain of the avian pathogen Mycoplasma gallisepticum is capable of producing H2O2 when grown in glycerol and is cytotoxic to eukaryotic cells in culture. Transposon mutants with mutations in the genes present in the glycerol transport and utilization pathway, namely, glpO, glpK, and glpF, were identified. All mutants assessed were incapable of producing H2O2 and were not cytotoxic when grown in glycerol. We also determined that vaccine strains ts-11 and 6/85 produce little to no H2O2 when grown in glycerol, while the naturally attenuated F strain does produce H2O2. Chickens were infected with one of two glpO mutants, a glpK mutant, R(low), or growth medium, and tracheal mucosal thickness and lesion scores were assessed. Interestingly, all glp mutants were reproducibly virulent in the respiratory tracts of the chickens. Thus, there appears to be no link between glycerol metabolism/H2O2 production/cytotoxicity and virulence for this Mycoplasma species in its natural host. However, it is possible that glycerol metabolism is required by M. gallisepticum in a niche that we have yet to study.

The high-resolution diffraction beamline P08 at PETRA III.

The new third-generation synchrotron radiation source PETRA III located at the Deutsches Elektronen-Synchrotron DESY in Hamburg, Germany, has been operational since the second half of 2009. PETRA III is designed to deliver hard X-ray beams with very high brilliance. As one of the first beamlines of PETRA III the high-resolution diffraction beamline P08 is fully operational. P08 is specialized in X-ray scattering and diffraction experiments on solids and liquids where extreme high resolution in reciprocal space is required. The resolving power results in the high-quality PETRA III beam and unique optical elements such as a large-offset monochromator and beryllium lens changers. A high-precision six-circle diffractometer for solid samples and a specially designed liquid diffractometer are installed in the experimental hutch. Regular users have been accepted since summer 2010.

The influence of host tissue on M. gallisepticum vlhA gene expression.

Mycoplasma gallisepticum, a significant poultry pathogen, has evolved rapidly in its new passerine host since its first reported isolation from house finches in the US in 1994. In poultry, M. gallisepticum infects the upper respiratory tract, causing tracheal mucosal thickening and inflammation, in addition to inflammation of the reproductive tract. However, in house finches M. gallisepticum primarily causes inflammation of the conjunctiva. Given that different tissues are primarily affected by the same pathogen in different hosts, we have compared the early changes in gene expression of the phase-variable lipoproteins (vlhA) gene family of M. gallisepticum collected directly from target tissues in both hosts. Previous data have demonstrated that vlhA genes may be related to virulence, exhibiting changes in expression in a non-stochastic, temporal progression and we hypothesize that this may be influenced by differences in the target host tissue. If this is true, we would expect M. gallisepticum to display a different vlhA gene expression pattern in the chicken trachea compared to its expression pattern in house finch conjunctiva. Here we report significant differences in vlhA gene expression patterns between M. gallisepticum collected from chicken tracheas compared to those collected from house finch conjunctiva. While many of the predominant vlhA genes expressed in the input population showed an increase in expression in the chicken trachea at day one postinfection, those same vlhA genes decreased in expression in the house finch. These data suggest that discrete suites of vlhA genes may be involved in M. gallisepticum pathogenesis and tropism for unique tissues in two disparate avian hosts.

A compact and low-weight sputtering unit for in situ investigations of thin film growth at synchrotron radiation beamlines.

In this work, we report on a highly variable, compact, and light high-vacuum sputter deposition unit designed for in situ experiments using synchrotron radiation facilities. The chamber can be mounted at various synchrotron beamlines for scattering experiments in grazing incidence geometry. The sample position and the large exit window allow to perform x-ray experiments up to large q values. The sputtering unit is easy to mount on existing experimental setups and can be remote-controlled. In this paper, we describe in detail the design and the performance of the new sputtering chamber and present the installation of the apparatus at different 3rd generation light sources. Furthermore, we describe the different measurement options and present some selected results. The unit has been successfully commissioned and is now available for users at PETRA III at DESY.

A compact high vacuum heating chamber for in-situ x-ray scattering studies.

A very compact multi purpose high vacuum heating chamber for x-ray scattering techniques was developed. The compact design allows the chamber to be installed on high precision diffractometers which usually cannot support heavy and/or large equipment. The chamber is covered by a Be dome allowing full access to the hemisphere above the sample which is required for in-plane grazing incident x-ray diffraction and out-off plane wide angle x-ray diffraction.