The Future Direction of Inter-Professional Education in Ireland: Insights From Focus Groups With Key Stakeholders

Rationale: An inter-professional education (IPE) masterclass symposium titled, ‘The journey to team-based healthcare’, was jointly hosted by the School of Pharmacy, Royal College of Surgeons in Ireland (RCSI), the Irish Institute of Pharmacy and the Bill Gatton College of Pharmacy in East Tennessee State University in May 2017. The masterclass provided a comprehensive overview of IPE initiatives based on the extensive experience of senior academics from the host institutions, which included staff from pharmacy, nursing and medicine. The masterclass was attended by healthcare professionals, policy makers and educationalists working in Ireland. As part of the symposium, focus groups were conducted with a sample of symposium attendees to determine their opinions and perceptions, as key stakeholders, regarding the development, implementation and future direction of IPE in Ireland. Methods: Focus groups were conducted with symposium attendees using a topic guide that was developed based on previous literature. Questions explored participants’ views and experiences on a range of topics including development and implementation of IPE activities, and key priorities for developing future IPE initiatives. Thematic analysis was conducted to identify key themes. Findings: Three focus groups were conducted each involving five to six participants (total 16 participants: nine female). Preliminary themes have been identified and further analysis is ongoing. Discussion/conclusion: The research findings will help to inform the future development and direction of IPE initiatives at both undergraduate and postgraduate level within the host institutions and could help in the development of an IPE strategy for undergraduate and post-graduate teaching across Ireland

Expanding Interprofessional Education Through a Graduation Requirement

Abstract available in the American Journal of Pharmaceutical Education

Guanidinylated Neomycin Mediates Heparan Sulfate–dependent Transport of Active Enzymes to Lysosomes

Guanidinylated neomycin (GNeo) can transport bioactive, high molecular weight cargo into the interior of cells in a process that depends on cell surface heparan sulfate proteoglycans. In this report, we show that GNeo-modified quantum dots bind to cell surface heparan sulfate, undergo endocytosis and eventually reach the lysosomal compartment. An N-hydroxysuccinimide activated ester of GNeo (GNeo-NHS) was prepared and conjugated to two lysosomal enzymes, β--glucuronidase (GUS) and α--iduronidase. Conjugation did not interfere with enzyme activity and enabled binding of the enzymes to heparin-Sepharose and heparan sulfate on primary human fibroblasts. Cells lacking the corresponding lysosomal enzyme took up sufficient amounts of the conjugated enzymes to restore normal turnover of glycosaminoglycans. The high capacity of proteoglycan-mediated uptake suggests that this method of delivery might be used for enzyme replacement or introduction of foreign enzymes into cells

Syndecan-1 is the primary heparan sulfate proteoglycan mediating hepatic clearance of triglyceride-rich lipoproteins in mice

Elevated plasma triglyceride levels represent a risk factor for premature atherosclerosis. In mice, accumulation of triglyceride-rich lipoproteins can occur if sulfation of heparan sulfate in hepatocytes is diminished, as this alters hepatic lipoprotein clearance via heparan sulfate proteoglycans (HSPGs). However, the relevant HSPG has not been determined. In this study, we found by RT-PCR analysis that mouse hepatocytes expressed the membrane proteoglycans syndecan-1, -2, and -4 and glypican-1 and -4. Analysis of available proteoglycan-deficient mice showed that only syndecan-1 mutants (Sdc1–/– mice) accumulated plasma triglycerides. Sdc1–/– mice also exhibited prolonged circulation of injected human VLDL and intestinally derived chylomicrons. We found that mice lacking both syndecan-1 and hepatocyte heparan sulfate did not display accentuated triglyceride accumulation compared with single mutants, suggesting that syndecan-1 is the primary HSPG mediating hepatic triglyceride clearance. Immunoelectron microscopy showed that syndecan-1 was expressed specifically on the microvilli of hepatocyte basal membranes, facing the space of Disse, where lipoprotein uptake occurs. Abundant syndecan-1 on wild-type murine hepatocytes exhibited saturable binding of VLDL and inhibition by heparin and facilitated degradation of VLDL. Furthermore, adenovirus-encoded syndecan-1 restored binding, uptake, and degradation of VLDL in isolated Sdc1–/– hepatocytes and the lipoprotein clearance defect in Sdc1–/– mice. These findings provide the first in vivo genetic evidence that syndecan-1 is the primary hepatocyte HSPG receptor mediating the clearance of both hepatic and intestinally derived triglyceride-rich lipoproteins

6-O sulfated and N-sulfated Syndecan-1 promotes baculovirus binding and entry into mammalian cells.

Baculoviruses are insect-specific viruses commonly found in nature. They are not able to replicate in mammalian cells but can transduce them when equipped with an appropriate mammalian cell active expression cassette. Although the viruses have been studied in several types of mammalian cells from different origins, the receptor that baculovirus uses to enter or interact with mammalian cells has not yet been identified. Due to the wide tropism of the virus, the receptor has been suggested to be a generally found cell surface molecule. In this article, we investigated the interaction of baculovirus and mammalian cell surface heparan sulfate proteoglycans (HSPG) in more detail. Our data show that baculovirus requires HSPG sulfation, particularly N- and 6-O-sulfation, to bind to and transduce mammalian cells. According to our results, baculovirus binds specifically to syndecan-1 (SDC-1) but does not interact with SDC-2 to SDC-4 or with glypicans. Competition experiments performed with SDC-1 antibody or recombinant SDC-1 protein inhibited baculovirus binding, and SDC-1 overexpression enhanced baculovirus-mediated transduction. In conclusion, we show that SDC-1, a commonly found cell surface HSPG molecule, has a role in the binding and entry of baculovirus in vertebrate cells. The results presented here reveal important aspects of baculovirus entry and can serve as a basis for next-generation baculovirus vector development for gene delivery.peerReviewe