Groups of eight chickens were challenged with 10-fold dilutions of one of two strains of Mycoplasma synoviae (MS); each challenge group contained two noninfected sentinels. Both strains were highly efficient in colonizing the respiratory tract with challenge doses as low as 76 and 24 color-changing units/bird. Infection spread rapidly (within 7 days) to sentinels, while uninfected control chickens separated from infected chickens by two empty pens remained uninfected for the 56-day experimental period. Although sentinels and birds challenged with the lowest doses had weaker or slightly slower antibody responses in some cases as measured by serum plate agglutination, enzyme-linked immunosorbent assay (ELISA), and hemagglutination inhibition (HI), they generally exhibited a typical antibody response. Agglutination reactions tended to be weak, but a high percentage of tests (generally >30% from day 14 postchallenge) were positive. ELISA results were variable, and in some cases reactor rates were low (generally <20%), even though the chickens were colonized in the upper respiratory tract. The HI test was reliable in detecting infected groups; usually >50% were positive from 14 days postchallenge. Mean HI titers were higher when using hemagglutination antigens prepared from the homologous MS strain as compared with antigen prepared from the heterologous strain or with standard antigen prepared from WVU 1853.
Mycoplasma gallisepticum (MG) contains two sets of rRNA genes (5S, 16S and 23S) in its genome, but only one of the two is organized in an operon cluster and contains a unique 660-nucleotide intergenic spacer region (IGSR) between the 16S and the 23S rRNA genes. We designed a polymerase chain reaction (PCR) for the specific amplification of the complete MG IGSR segment. The MG IGSR PCR was tested on 18 avian mollicute species and was confirmed as MG specific. The reaction sensitivity was demonstrated by comparing it to the well-established MG mgc2 PCR. The MG IGSR sequence was found to be highly variable (discrimination [D] index of 0.950) among a variety of MG laboratory strains, vaccine strains, and field isolates. The sequencing of the MG IGSR appears to be a valuable single-locus sequence typing (SLST) tool for MG isolate differentiation in diagnostic cases and epizootiological studies.
Several commercial broiler flocks in northeastern Georgia that were the progeny of the same parent flock (Flock 40) were diagnosed as Mycoplasma gallisepticum (MG) positive by serology, culture, and PCR. Flock 40 had been vaccinated with ts-11 live MG vaccine. Several isolates were obtained from the MG-positive broiler flocks, and these isolates were indistinguishable from the ts-11 vaccine strain by the molecular strain differentiation methods used. A pathogenicity study was performed to compare the virulence of one of the isolates, K6216D, to the ts-11 vaccine strain. K6216D elicited a significantly stronger antibody response and significantly increased colonization of the tracheas and air sacs. K6216D also elicited significantly greater air sac and tracheal lesions than the ts-11 vaccine strain at 10 and 21 days postinoculation (P < or = 0.05). This is the first report of a field case of the apparent reversion to virulence and vertical transmission of the ts-11 vaccine.
Molecular analysis was conducted on 36 Mycoplasma gallisepticum DNA extracts from tracheal swab samples of commercial poultry in seven South African provinces between 2009 and 2012. Twelve unique M. gallisepticum genotypes were identified by polymerase chain reaction and sequence analysis of the 16S-23S rRNA intergenic spacer region (IGSR), M. gallisepticum cytadhesin 2 (mgc2), MGA_0319 and gapA genetic regions. The DNA sequences of these genotypes were distinct from those of M. gallisepticum isolates in a database composed of sequences from other countries, vaccine and reference strains. The most prevalent genotype (SA-WT#7) was detected in samples from commercial broilers, broiler breeders and layers in five provinces. South African M. gallisepticum sequences were more similar to those of the live vaccines commercially available in South Africa, but were distinct from that of F strain vaccine, which is not registered for use in South Africa. The IGSR, mgc2 or MGA_0319 sequences of three South African genotypes were identical to those of the ts-11 vaccine strain, necessitating a combination of mgc2 and IGSR targeted sequencing to differentiate South African wild-type genotypes from ts-11 vaccine. To identify and differentiate all 12 wild-types, mgc2, IGSR and MGA_0319 sequencing was required. Sequencing of gapA was least effective at strain differentiation. This research serves as a model for the development of an M. gallisepticum sequence database, and illustrates its application to characterize M. gallisepticum genotypes, select diagnostic tests and better understand the epidemiology of M. gallisepticum.
Mycoplasma synoviae (MS) is an important pathogen of domestic poultry and is prevalent in commercial layers. During the last decade Escherichia coli peritonitis became a major cause of layer mortality. The possible role of MS in the E. coli peritonitis syndrome of laying hens was studied. Four groups of 64 mycoplasma-free commercial layers at the onset of lay (about 80% daily production) were challenged with a virulent MS strain or a virulent avian E. coli strain or both. The four experimental groups were identified as follows: negative control, E. coli, MS, and MS plus E. coli. A typical E. coli peritonitis mortality was reproduced and included one, three, zero, and five birds in the negative control, E. coli, MS, and MS plus E. coli groups, respectively. Only the increased mortality in the MS plus E. coli group had statistical significance. Four weeks postchallenge 10 clinically normal birds from each of the four experimental groups were necropsied. All of the examined birds in the two MS-challenged groups demonstrated severe tracheal lesions. Body cavity lesions were detected in two and four birds in the MS and MS plus E. coli groups, respectively. The results demonstrate a possible pathogenesis mechanism of respiratory origin with regard to the layer E. coli peritonitis syndrome, show the MS pathological effect in layers, and indicate that a virulent MS strain can act as a complicating factor in the layer E. coli peritonitis syndrome.
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