Publications

The oral mucosa is an attractive cell source for autologous transplantation in human patients who require regenerative therapies of various epithelia. However, the time-course of cellular changes in transplanted oral mucosal epithelia at ectopic sites remains poorly understood. By applying a rat model, we analyzed phenotypic changes in oral mucosal epithelial cell sheets after harvest from temperature-responsive culture dishes and subsequent autologous subcutaneous transplantation. We used monoclonal antibodies to identify epithelial-specific cytokeratins 4, 10, 13, and 14, the stem/progenitor cell marker p63, and proliferating cell nuclear antigen, within the regenerated tissues. Transplanted oral mucosal epithelial cell sheets proliferated during the first week after grafting in conjunction with host inflammation, but then began to degenerate afterward with complete disappearance after 3 weeks. Our findings suggest that host subcutaneous tissues support proliferation and differentiation of the oral mucosal epithelial cell sheets, but are unable to promote maintenance of stem and progenitor cells and therefore cannot produce long-term survivability.

Cardioviruses comprise a genus of picornaviruses that cause severe illnesses in rodents, but little is known about the prevalence, diversity, or spectrum of disease of such agents among humans. A single cardiovirus isolate, Saffold virus, was cultured in 1981 in stool from an infant with fever. Here, we describe the identification of a group of human cardioviruses that have been cloned directly from patient specimens, the first of which was detected using a pan-viral microarray in respiratory secretions from a child with influenza-like illness. Phylogenetic analysis of the nearly complete viral genome (7961 bp) revealed that this virus belongs to the Theiler's murine encephalomyelitis virus (TMEV) subgroup of cardioviruses and is most closely related to Saffold virus. Subsequent screening by RT-PCR of 719 additional respiratory specimens [637 (89%) from patients with acute respiratory illness] and 400 cerebrospinal fluid specimens from patients with neurological disease (aseptic meningitis, encephalitis, and multiple sclerosis) revealed no evidence of cardiovirus infection. However, screening of 751 stool specimens from 498 individuals in a gastroenteritis cohort resulted in the detection of 6 additional cardioviruses (1.2%). Although all 8 human cardioviruses (including Saffold virus) clustered together by phylogenetic analysis, significant sequence diversity was observed in the VP1 gene (66.9%-100% pairwise amino acid identities). These findings suggest that there exists a diverse group of novel human Theiler's murine encephalomyelitis virus-like cardioviruses that hitherto have gone largely undetected, are found primarily in the gastrointestinal tract, can be shed asymptomatically, and have potential links to enteric and extraintestinal disease.

Increasing recognition of the association of rhinovirus with severe lower respiratory tract illnesses has clarified the need to understand the relationship between specific serotypes of rhinovirus and their clinical consequences. To accomplish this, a specific and sensitive assay to detect and serotype rhinovirus directly from clinical specimens is needed. Traditional methods of serotyping using culture and serum neutralization are time-consuming, limited to certain reference laboratories, and complicated by the existence of over 100 serotypes of human rhinoviruses (HRVs). Accordingly, we have developed a sequence-based assay that targets a 390-bp fragment accounting for approximately two-thirds of the 5' noncoding region (NCR). Our goal was to develop an assay permitting amplification of target sequences directly from clinical specimens and distinction among all 101 prototype strains of rhinoviruses. We determined the sequences of all 101 prototype strains of HRV in this region to enable differentiation of virus genotypes in both viral isolates and clinical specimens. We evaluated this assay in a total of 101 clinical viral isolates and 24 clinical specimens and compared our findings to genotyping results using a different region of the HRV genome (the VP4-VP2 region). Five specimens associated with severe respiratory disease in children did not correlate with any known serotype of rhinovirus and were found to belong to a novel genogroup of rhinovirus, genogroup C. Isolates were also found that corresponded to the genogroup A2 variant identified in New York and Australia and two other novel group A clusters (GAC1 and GAC2).