Clostridium botulinum Group II Isolate Phylogenomic Profiling Using Whole-Genome Sequence Data.

Clostridium botulinum group II isolates (n = 163) from different geographic regions, outbreaks, and neurotoxin types and subtypes were characterized in silico using whole-genome sequence data. Two clusters representing a variety of botulinum neurotoxin (BoNT) types and subtypes were identified by multilocus sequence typing (MLST) and core single nucleotide polymorphism (SNP) analysis. While one cluster included BoNT/B4/F6/E9 and nontoxigenic members, the other comprised a wide variety of different BoNT/E subtype isolates and a nontoxigenic strain. In silico MLST and core SNP methods were consistent in terms of clade-level isolate classification; however, core SNP analysis showed higher resolution capability. Furthermore, core SNP analysis correctly distinguished isolates by outbreak and location. This study illustrated the utility of next-generation sequence-based typing approaches for isolate characterization and source attribution and identified discrete SNP loci and MLST alleles for isolate comparison.

Two novel toxin variants revealed by whole-genome sequencing of 175 Clostridium botulinum type E strains.

We sequenced 175 Clostridium botulinum type E strains isolated from food, clinical, and environmental sources from northern Canada and analyzed their botulinum neurotoxin (bont) coding sequences (CDSs). In addition to bont/E1 and bont/E3 variant types, neurotoxin sequence analysis identified two novel BoNT type E variants termed E10 and E11. Strains producing type E10 were found along the eastern coastlines of Hudson Bay and the shores of Ungava Bay, while strains producing type E11 were only found in the Koksoak River region of Nunavik. Strains producing BoNT/E3 were widespread throughout northern Canada, with the exception of the coast of eastern Hudson Bay.

Assessment of the coloring strength of brevibacterium linens strains: spectrocolorimetry versus total carotenoid extraction/quantification.

Brevibacterium linens is a major component of red-smear cheese microflora and imparts color to the cheese rind. The present study was done to evaluate carotenoid contents in 29 strains of this bacterium and to relate the color of the strains to the carotenoids present. A spectrocolorimeter was used to determine the color, and the carotenoid contents were determined by spectrophotorimetric measurement at 450 nm. Regression analysis was carried out on the color values a*, b*, and C* to determine which color value could be used to express the contents of carotenoids in B. linens biomass. The C* color value appeared to be the best estimate for correlation.

Inhibition of monocyte/macrophage migration to a spinal cord injury site by an antibody to the integrin alphaD: a potential new anti-inflammatory treatment.

The inflammatory response that ensues during the initial 48 to 72 h after spinal cord injury causes considerable secondary damage to neurons and glia. Infiltration of proinflammatory-activated neutrophils and monocytes/macrophages into the cord contributes to spinal cord injury-associated secondary damage. beta2 integrins play an essential role in leukocyte trafficking and activation and arbitrate cell-cell interactions during inflammation. The beta2 integrin, alphaDbeta2, is expressed on monocytes/macrophages and neutrophils and binds to vascular adhesion molecule-1 (VCAM-1). The increased expression of VCAM-1 during central nervous system (CNS) inflammation likely contributes to leukocyte extravasation into the CNS. Accordingly, blocking the interaction between alphaDbeta2 and VCAM-1 may attenuate the inflammatory response at the SCI site. We investigated whether the administration of monoclonal antibodies (mAbs) specific for the rat alphaD subunit would reduce the inflammatory response after a spinal cord transection injury in rats. At a 1 mg/kg dose two of three anti-alphaD mAbs caused a significant ( approximately 65%) reduction in the number of macrophages at the injury site and one anti-alphaD mAb led to a approximately 43% reduction in the number of neutrophils at the SCI site. Thus, our results support the concept that the alphaDbeta2 integrins play an important role in the trafficking of leukocytes to a site of central nervous system inflammation. This study also offers preliminary evidence that anti-alphaD mAbs can reduce the extravasation of macrophages and, to a lesser extent, neutrophils, to the SCI site.

Cyclosporin A reduces the inflammatory response to a multi-mutant herpes simplex virus type-1 leading to improved transgene expression in sympathetic preganglionic neurons in hamsters.

Herpes simplex virus type 1 (HSV-1) based vectors hold great promise for gene transfer to CNS neurons. Problems such as loss of transgene expression, vector-associated cytotoxicity and the immune response to the vector or encoded transgene still remain obstacles to success. We used a replication-defective, HSV-1 vector (14Hdelta3vhsZ) that was engineered to have reduced cytotoxicity and express recombinant beta-galactosidase. A previous study in our laboratory showed no evidence for cytotoxicity in infected neurons although an inflammatory infiltrate occurred around infected cells and transgene expression was lost between 5 and 8 days. The immune response consisted of a primary response at the site of inoculation (adrenal gland), and a secondary immune response in the spinal cord around infected adrenal sympathetic preganglionic neurons due to retrograde transport of the vector. We tested whether conventional immunosuppressants could reduce the secondary immune response, leading to improved transgene expression at the secondary CNS site. 14Hdelta3vhsZ was injected into the adrenal gland in hamsters 1 day after immunosuppressant treatment began. Non-drug treated, 14Hdelta3vhzZ-infected hamsters were used as controls. Cyclosporin A administration led to the most persistent beta-galactosidase activity in neurons at 5 and 8 days. Methylprednisolone treatment resulted in the greatest reduction in the inflammatory cell infiltrate but the numbers of infected neurons did not increase concomitantly. This suggested no direct relationship between extent of the inflammatory cell infiltrate and level of transgene expression. These data demonstrate the potential of cyclosporin A as an immunosuppressant adjunct treatment for HSV-1 vector-mediated gene transfer from a peripheral site to neurons in the spinal cord.

Simultaneous identification of two populations of sympathetic preganglionic neurons using recombinant herpes simplex virus type 1 expressing different reporter genes.

We generated neurotropic herpes simplex type 1 viruses expressing human placental alkaline phosphatase and studied the utility of this enzyme as a marker of infected neurons. The neurotropism of these viruses was assessed by their ability to infect sympathetic preganglionic neurons after adrenal injection in hamsters. The transneuronal transfer of these viruses was examined by their ability to cross the peripheral synapse from the kidney to renal preganglionic neurons or to cross the central synapse from the adrenal gland to the medulla oblongata. Finally, we injected an alkaline phosphatase-expressing herpes simplex virus into the adrenal gland and a beta-galactosidase-expressing herpes simplex virus (US5gal) into the muscular wall of the small intestine to label two neural circuits in one animal and to assess the feasibility of a dual-virus labelling system. The alkaline phosphatase gene was inserted into the glycoprotein J locus or the virus-induced host shut-off locus in the herpes simplex genome to create viruses which replicate (gJHAP HSV or vhsHAP HSV) or into the thymidine kinase locus to generate a virus that does not replicate in neurons in vivo (TK- HAP HSV). Each of the three viruses was retrogradely transported from the adrenal gland of hamsters to sympathetic preganglionic neurons, suggesting that the neurotropism of these viruses was maintained. gJHAP HSV travelled transneuronally from the kidney to sympathorenal preganglionic neurons and from the adrenal gland to neurons in the rostral ventrolateral medulla. Neuronal infection with alkaline phosphatase-expressing virus could be identified using histochemistry but detailed morphology of these neurons was not revealed. However, staining by anti-herpes simplex virus immunoperoxidase demonstrated that they had normal morphology. Identification of two distinct neural circuits in one animal was achieved with our dual-virus labelling system. The nonreplicating TK- HAP HSV was used in combination with US5gal to identify intestinal and adrenal sympathetic preganglionic neurons. The beta-galactosidase-expressing intestinal neurons were labelled bilaterally in the nucleus intermediolateralis, pars principalis, and alkaline phosphatase-expressing adrenal neurons were found ipsilaterally. Some clusters of sympathetic preganglionic neurons in the nucleus intermediolateralis, pars principalis contained mostly intestinal sympathetic preganglionic neurons and a few adrenal sympathetic preganglionic neurons. In other areas, the opposite pattern occurred. About 3-7% of the labelled sympathetic preganglionic neurons were double-labelled by both markers. The distinct and crisp morphology and dendritic processes of neurons stained by beta-galactosidase histochemistry contrasted with the partial staining of neurons by alkaline phosphatase, revealing beta-galactosidase as a better marker of infected neurons. In conclusion, alkaline phosphatase-expressing herpes simplex viruses are yet neurotropic after insertion of this marker enzyme into any of three different loci of the herpes simplex genome. One replicating alkaline phosphatase-expressing virus travelled transneuronally. These alkaline phosphatase-expressing herpes simplex virus can be used together with beta-galactosidase-expressing herpes simplex viruses to determine the target specificity of sympathetic preganglionic neurons controlling visceral organs or can be used to express two different recombinant genes in two targeted neuronal populations. This study suggests that sympathetic preganglionic neurons controlling the intestine and adrenal gland are almost completely distinct.

Identification of sympathetic preganglionic neurons controlling the small intestine in hamsters using a recombinant herpes simplex virus type-1.

Sympathetic preganglionic neurons (SPNs) may be organized topographically within the spinal cord for selective control of visceral organs. We used a recombinant herpes simplex virus type-1 (rHSV-1) to identify SPNs innervating the small intestine in hamsters. These SPNs were distributed bilaterally in the cord from the fifth thoracic spinal segment to the second lumbar segment, but predominantly in thoracic segments 5-10. They had morphology similar to that of renal and adrenal SPNs infected with HSV-1. The majority of intestinal SPNs were found in the intermediolateral cell column, with a few located in the lateral funiculus. The SPNs labelled following duodenal injection of rHSV-1 were in the same spinal segments as the SPNs labelled following jejunal or ileal injections, suggesting lack of a relation between target topography and the topographic organization of these neurons. In addition, intestinal SPNs were located in the same spinal segments, and autonomic nuclei as renal and adrenal SPNs suggesting that SPNs controlling the abdominal viscera are not organized viscerotopically for discrete control of different organs.