Until a few years ago, only two human polyomaviruses (JC and BK) were known to infect humans and cause severe illness in immunocompromised hosts. Since 2007, at least eleven new polyomaviruses... Show moreUntil a few years ago, only two human polyomaviruses (JC and BK) were known to infect humans and cause severe illness in immunocompromised hosts. Since 2007, at least eleven new polyomaviruses became known that infect humans. Among them is the polyomavirus associated with trichodysplasia spinulosa (TSPyV). In Chapter 1 of this dissertation, the main focus is on the recent developments in studying the newly identified human polyomaviruses until mid-2014. This introductory chapter sets the stage for further investigation into TSPyV infection, pathogenesis, evolution and host adaptation, which is detailed in Chapter 2. To study causality between TSPyV infection and TS disease, in Chapter 3, the prevalence, load and localization of this virus is described. In Chapter 4, the cellular mechanisms behind disruption of cellular proliferation and TS spicule formation by TSPyV Large T-antigen is investigated. By In-silico analysis, in Chapter 5, the identification of a polyomavirus evolution and adaptation mechanism called COCO-VA is highlighted. Subsequently, in Chapter 6, TSPyV genome sequences are tested to gain more insight into this COCO-VA mechanism. Finally, in Chapter 7, the findings described in this dissertation are discussed with regard to several TSPyV aspects, and compared to existing knowledge about polyomaviruses in a broader context. Show less
Trichodysplasia spinulosa (TS) is a proliferative skin disease observed in severely immunocompromized patients. It is characterized by papule and trichohyalin-rich spicule formation, epidermal... Show moreTrichodysplasia spinulosa (TS) is a proliferative skin disease observed in severely immunocompromized patients. It is characterized by papule and trichohyalin-rich spicule formation, epidermal acanthosis and distention of dysmorphic hair follicles overpopulated by inner root sheath cells (IRS). TS probably results from active infection with the TS-associated polyomavirus (TSPyV), as indicated by high viral-load, virus protein expression and particle formation. The underlying pathogenic mechanism imposed by TSPyV infection has not been solved yet. By analogy with other polyomaviruses, such as the Merkel cell polyomavirus associated with Merkel cell carcinoma, we hypothesized that TSPyV T-antigen promotes proliferation of infected IRS cells. Therefore, we analyzed TS biopsy sections for markers of cell proliferation (Ki-67) and cell cycle regulation (p16ink4a, p21waf, pRB, phosphorylated pRB), and the putatively transforming TSPyV early large tumor (LT) antigen. Intense Ki-67 staining was detected especially in the margins of TS hair follicles, which colocalized with TSPyV LT-antigen detection. In this area, staining was also noted for pRB and particularly phosphorylated pRB, as well as p16ink4a and p21waf. Healthy control hair follicles did not or hardly stained for these markers. Trichohyalin was particularly detected in the center of TS follicles that stained negative for Ki-67 and TSPyV LT-antigen. In summary, we provide evidence for clustering of TSPyV LT-antigen-expressing and proliferating cells in the follicle margins that overproduce negative cell cycle regulatory proteins. These data are compatible with a scenario of TSPyV T-antigen-mediated cell cycle progression, potentially creating a pool of proliferating cells that enable viral DNA replication and drive papule and spicule formation. Show less
Kazem, S.; Meijden, E. van der; Feltkamp, M.C.W. 2013