Detection and genotypic characterization of Toxoplasma gondii DNA within the milk of Mongolian livestock.

Toxoplasma gondii is a global, zoonotic parasite capable of infecting any warm-blooded host. Toxoplasmosis can cause a variety of illnesses including abortions and congenital defects in humans, sheep, and goats. Congenital toxoplasmosis is considered to have the highest global disease burden of any foodborne illness in humans. This study examined the potential role of milk as a route of T. gondii transmission between livestock and humans within Mongolian herders, a little-studied population which relies heavily on animals. Milk of Mongolian sheep, goats and Bactrian camels was tested for the presence of T. gondii DNA, and a survey was conducted to ascertain what behavioral and environmental factors were present that might potentiate T. gondii infection within these Mongolian communities. T. gondii DNA was detected in samples from one sheep and five camels. Sequence analysis of DNA from camel milk revealed that two were from potentially virulent T. gondii genotypes. This has implications for public health in the region, as milk is an extremely important source of nutrition and our survey results imply that some people believe consumption of raw camel milk carries health benefits. This is the first report of T. gondii DNA in Bactrian camel milk as well as the first genotypic characterization of T. gondii within Mongolia.

Intra-nasal inoculation of American bison (Bison bison) with ovine herpesvirus-2 (OvHV-2) reliably reproduces malignant catarrhal fever.

Sheep-associated malignant catarrhal fever (MCF) due to infection with ovine herpesvirus 2 (OvHV-2) is common in commercial herds of American bison ( Bison bison). Inability to propagate OvHV-2 in vitro has been a constraint on experimental studies of the disease. We sought to establish whether nasal secretions from sheep that shed OvHV-2 might induce the disease in bison and to define a minimum challenge dose. Fourteen bison were nebulized with sheep nasal sections containing 10(3)-10(7) OvHV-2 deoxyribonucleic acid (DNA) copies. Most challenged bison (11/14, 78.6%) developed clinical signs at 29-52 days postnebulization (DPN). The mean incubation time was 42.18 (+/-7.33 SD) DPN. Using real-time polymerase chain reaction, we detected OvHV-2 DNA in peripheral blood leukocytes at 21-31 DPN. All bison that developed MCF had antibodies against the MCF group viruses. Gross and histologic lesions were typical of the acute disease. There was no morphologic evidence of a dose-related difference in the severity or distribution of lesions. This is the first successful reproduction of MCF in bison using a nasal route of exposure. Experimentally challenged bison are more susceptible to MCF, compared with experimentally challenged domestic cattle in a previous experiment. Bison are a pertinent ruminant species in which the pathogenesis of the disease can be investigated.

The herpes simplex virus type 1 ICP0 promoter is activated by viral reactivation stimuli in trigeminal ganglia neurons of transgenic mice.

Herpes simplex virus type 1 (HSV-1) causes a latent infection in sensory ganglia neurons in humans and in the mouse model. The ability of the virus to latently infect neurons and reactivate is central to the ability of HSV-1 to remain in the human population and spread to new hosts. It is possible that neuronal transcriptional proteins control latency and reactivation by modulating activation of the HSV-1 immediate-early (IE) gene ICP0. We have previously shown that factors in trigeminal ganglia neurons can differentially activate the IE ICP0 promoter and the IE ICP4 promoter in developing trigeminal ganglia neurons of transgenic mice. Ultraviolet (UV) irradiation and hyperthermic stress have been shown to result in HSV-1 reactivation from sensory neurons in the mouse model. Reporter transgenic mice were exposed to UV irradiation or hyperthermia to test whether stimuli that are known to reactivate HSV-1 could activate viral IE promoters in the absence of viral proteins. Measurement of beta-galactosidase activity in trigeminal ganglia from these transgenic mice indicated that the ICP0 promoter activity was significantly increased by both UV irradiation and hyperthermia. The IE genes ICP4 and ICP27 and the late gene gC reporter transgenes failed to be activated in parallel experiments. These results suggest that the ICP0 promoter is a target for activation by host transcription factors in sensory neurons that have undergone damage. It further suggests the possibility that activation of ICP0 gene expression by neuronal transcription factors may be important in reactivation of HSV-1 in neurons.

The transgenic ICP4 promoter is activated in Schwann cells in trigeminal ganglia of mice latently infected with herpes simplex virus type 1.

Herpes simplex virus type 1 (HSV-1) establishes a latent infection in neurons of sensory ganglia, including those of the trigeminal ganglia. Latent viral infection has been hypothesized to be regulated by restriction of viral immediate-early gene expression in neurons. Numerous in situ hybridization studies in mice and in humans have shown that transcription from the HSV-1 genome in latently infected neurons is limited to the latency-associated transcripts. In other studies, immediate-early gene (ICP4) transcripts have been detected by reverse transcription-PCR (RT-PCR) in homogenates of latently infected trigeminal ganglia of mice. We used reporter transgenic mice containing the HSV-1(F) ICP4 promoter fused to the coding sequence of the beta-galactosidase gene to determine whether neurons in latently infected trigeminal ganglia activated the ICP4 promoter. Mice were inoculated via the corneal route with HSV-1(F). At 5, 11, 23, and 37 days postinfection (dpi), trigeminal ganglia were examined for beta-galactosidase-positive cells. The numbers of beta-galactosidase-positive neurons and nonneuronal cells were similar at 5 dpi. The number of positive neurons decreased at 11 dpi and returned to the level of mock-inoculated transgenic controls at 23 and 37 dpi. The number of positive nonneuronal cells increased at 11 and 23 dpi and remained elevated at 37 dpi. Viral proteins were detected in neurons and nonneuronal cells in acutely infected ganglia, but were not detected in latently infected ganglia. Colabeling experiments confirmed that the transgenic ICP4 promoter was activated in Schwann cells during latent infection. These findings suggest that the cells that express the HSV-1 ICP4 gene in latently infected ganglia are not neurons.

Increased severity of herpes simplex virus type 1-induced keratitis in Hox A5 transgenic mice.

PURPOSE: Herpes simplex virus type 1 is a major cause of stromal keratitis and blindness in humans. Understanding of the role of host genes in the pathogenesis of herpes stromal keratitis is limited. We used a transgenic mouse model to examine the effect of a host gene, Hox A5 (which binds to the TAATGARAT sequence in the promoter regions of HSV-1 immediate early genes and increases HSV-1 replication), on the pathogenesis of HSV-1 induced stromal keratitis. METHODS: Corneas of wildtype and Hox A5 transgenic mice were infected with HSV-1 strain F following corneal scarification. Clinical severity of keratitis was evaluated using slit-lamp biomicroscopy. Histologic severity of keratitis was determined by light microscopic evaluation and by computerized morphometry. Ocular viral replication was measured via plaque assay. RESULTS: Clinical lesions of stromal keratitis were more severe at 17 and 23 days post infection in Hox A5 transgenic mice than in wildtype mice. Histological evaluation and morphometric analysis confirmed that keratitis lesions were more severe in the transgenic mice. HSV-1 replication was approximately100-fold greater in the corneas of transgenic mice than in wildtype mice. CONCLUSIONS: Our results demonstrate that a host gene (Hox A5) can increase ocular replication of HSV-1 and alter the pathogenesis of herpetic stromal keratitis.

Herpes simplex virus type 1 gene UL14: phenotype of a null mutant and identification of the encoded protein.

Herpes simplex virus type 1 (HSV-1) gene UL14 is located between divergently transcribed genes UL13 and UL15 and overlaps the promoters for both of these genes. UL14 also exhibits a substantial overlap of its coding region with that of UL13. It is one of the few HSV-1 genes for which a phenotype and protein product have not been described. Using mass spectrometric and immunological approaches, we demonstrated that the UL14 protein is a minor component of the virion tegument of 32 kDa which is expressed late in infection. In infected cells, the UL14 protein was detected in the nucleus at discrete sites within electron-dense nuclear bodies and in the cytoplasm initially in a diffuse distribution and then at discrete sites. Some of the UL14 protein was phosphorylated. A mutant with a 4-bp deletion in the central region of UL14 failed to produce the UL14 protein and generated small plaques. The mutant exhibited an extended growth cycle at low multiplicity of infection and appeared to be compromised in efficient transit of virus particles from the infected cell. In mice injected intracranially, the 50% lethal dose of the mutant was reduced more than 30,000-fold. Recovery of the mutant from the latently infected sacral ganglia of mice injected peripherally was significantly less than that of wild-type virus, suggesting a marked defect in the establishment of, or reactivation from, latent infection.

Herpes simplex virus 1 DNA cleavage/packaging: the UL28 gene encodes a minor component of B capsids.

An antiserum directed against a bacterial fusion protein containing UL28 protein sequences specifically recognized an 86,000 apparent Mr protein in immunoblots of wild-type capsids. This protein was not detected in immunoblots of capsids purified from cells infected with a UL28 deletion virus, indicating that the protein was a product of UL28. The 86,000 Mr protein was also detected in capsids purified from cells infected with mutant viruses lacking the UL6, UL15, and UL25 genes, indicating that the UL28 protein can associate with capsids independently of successful DNA packaging and other minor capsid components. The UL6 protein, full-length UL15 protein, and UL25-encoded proteins were also detected in capsids purified from cells infected with the UL28 deletion virus. The UL28 and UL6 proteins remained associated with capsids treated with 1.0 M guanidine-HCl, indicating that, like the UL6 protein, the UL28 protein was an integral component of capsids. Amounts of UL28 protein were reduced in DNA-containing capsids and UL28 protein was not detected in virions, suggesting that some UL28 protein is lost during the cleavage-packaging reaction.

The herpes simplex virus 1 UL 17 gene is required for localization of capsids and major and minor capsid proteins to intranuclear sites where viral DNA is cleaved and packaged.

In nuclei of cells infected with herpes simplex virus (HSV), synthesized viral DNA accumulates as concatamers that are cleaved into genomic lengths and inserted into preformed capsids. Whereas newly replicated DNA and enzymes required for DNA synthesis accumulate in sites of infected cell nuclei termed replication compartments, the intranuclear site of DNA cleavage and packaging is currently controversial. DNA packaging requires the UL6, UL15, UL17, UL25, UL28, UL32, and UL33 genes in addition to the major capsid proteins. Using confocal immunofluorescence microscopy, it was observed that in > 95% of HEp-2 cells fixed at late times after infection with wild-type HSV-1, capsids, major capsid proteins ICP5 and ICP35, and the UL6-encoded minor capsid protein localized in DNA replication compartments. These data support the hypothesis that capsid assembly and DNA cleavage/packaging normally occur in HEp-2 cell replication compartments. In contrast, cells infected with a viral mutant lacking functional UL17 contained antigenically dense nuclear aggregates that stained with ICP35, ICP5, and capsid specific antibodies. Cells infected with the UL17 mutant virus also displayed UL6-specific fluorescence in a diffuse pattern at the nuclear periphery in regions not containing ICP35 and ICP5. Displacement of ICP35 from replication compartments was not observed in cells infected with cleavage/packaging mutants lacking UL28 and UL33. We conclude that the UL17 gene is required for correct targeting of capsids and major and minor capsid proteins to the DNA replication compartment of HEp-2 cells and deduce that this targeting reflects one functional role of UL17 in viral DNA cleavage and packaging.

Perchlorate potentiation of excitation-contraction coupling in mammalian skeletal muscles.

The action of perchlorate (ClO4-), an agonist of the voltage sensor in excitation-contraction (EC) coupling, has been examined using bundles of intact muscle cells, isolated membrane vesicles [sarcoplasmic reticulum (SR) and transverse tubule (TT)], and cultured myotubes. The effect of ClO4- on mechanical parameters was investigated in isolated murine limb muscles. The presence of ClO4- (5 or 10 mM) greatly increased twitch tension ( > 250%), slightly enhanced tetanic tension, and increased K contracture tension. K contracture thresholds of extensor digitorum longus (EDL, 40 mM K+) and soleus (30 mM K+) muscles were not altered by ClO4-. However, in whole cell patch clamp studies of mouse myotubes, contractile activation was shifted by approximately -10 mV by 10 mM ClO4-. To further define the site of alteration of EC coupling by ClO4-, studies were conducted with isolated porcine SR and TT vesicles and with cultured mouse myotubes. The rate constant of Ca-induced 45Ca release from SR vesicles was significantly increased by ClO4-. However, neither the affinity nor level of [3H]PN200-110 binding to TT vesicles was significantly affected by ClO4- concentrations that increased twitch tension. Furthermore, slow plasmalemmal Ca currents of myotubes recorded in the whole cell patch-clamp mode were enhanced by 10 mM ClO4-, and the current-voltage relationship was shifted approximately -7mV. Thus, in enhancing EC coupling in mammalian muscle, ClO4- may act at multiple sites including the SR Ca release channel and the TT Ca channel-voltage sensor.