Klassifizierung von zellbasierten Arzneimitteln und rechtliche Implikationen

Bundesgesundheitsblatt - Gesundheitsforschung - Gesundheitsschutz - Zellbasierte Arzneimittel im weiteren Sinne stellen keine einheitliche Arzneimittelgruppe dar, sondern umfassen Arzneimittel mit...     

Tissue-type plasminogen activator (t-PA) is stored in Weibel-Palade bodies in human endothelial cells both in vitro and in vivo

Vascular endothelial cells are thought to be the main source of plasma tissue-type plasminogen activator (t-PA) and von Willebrand factor (VWF). Previous studies have suggested that both t-PA and VWF are acutely released in response to the same stimuli, both in cultured endothelial cells and in vivo. However, the subcellular storage compartment in endothelial cells has not been definitively established. We tested the hypothesis that t-PA is localized in Weibel-Palade (WP) bodies, the specialized endothelial storage granules for VWF. In cultured human umbilical vein endothelial cells (HUVECs), t-PA was expressed in a minority of cells and found in WP bodies by immunofluorescence. After up-regulation of t-PA synthesis either by vascular endothelial growth factor (VEGF) and retinoic acid or by sodium butyrate, there was a large increase in t-PA-positive cells. t-PA was exclusively located to WP bodies, an observation confirmed by immunoelectron microscopy. Incubation with histamine, forskolin, and epinephrine induced the rapid, coordinate release of both t-PA and VWF, consistent with a single storage compartment. In native human skeletal muscle, t-PA was expressed in endothelial cells from arterioles and venules, along with VWF. The 2 proteins were found to be colocalized in WP bodies by immunoelectron microscopy. These data indicate that t-PA and VWF are colocalized in WP bodies, both in HUVECs and in vivo. Release of both t-PA and VWF from the same storage pool likely accounts for the coordinate increase in the plasma level of the 2 proteins in response to numerous stimuli, such as physical activity, beta-adrenergic agents, and 1-deamino-8d-arginine vasopressin (DDAVP) among others.     

One-stop routing for surgical interventions: a cost-analysis of endoscopic groin repair

Surgical Endoscopy - Single-visit (SV) totally extraperitoneal (TEP) inguinal hernia repair is an efficient service without impairment of safety or complication rate. Data on the economic impact of...     

Peptidoglycan-binding protein TsaP functions in surface assembly of type IV pili

Type IV pili (T4P) are ubiquitous and versatile bacterial cell surface structures involved in adhesion to host cells, biofilm formation, motility, and DNA uptake. In Gram-negative bacteria, T4P pass the outer membrane (OM) through the large, oligomeric, ring-shaped secretin complex. In the β-proteobacterium Neisseria gonorrhoeae, the native PilQ secretin ring embedded in OM sheets is surrounded by an additional peripheral structure, consisting of a peripheral ring and seven extending spikes. To unravel proteins important for formation of this additional structure, we identified proteins that are present with PilQ in the OM. One such protein, which we name T4P secretin-associated protein (TsaP), was identified as a phylogenetically widely conserved component of the secretin complex that co-occurs with genes for T4P in Gram-negative bacteria. TsaP contains an N-terminal carbohydrate-binding lysin motif (LysM) domain and a C-terminal domain of unknown function. In N. gonorrhoeae, lack of TsaP results in the formation of membrane protrusions containing multiple T4P, concomitant with reduced formation of surface-exposed T4P. Lack of TsaP did not affect the oligomeric state of PilQ, but resulted in loss of the peripheral structure around the PilQ secretin. TsaP binds peptidoglycan and associates strongly with the OM in a PilQ-dependent manner. In the δ-proteobacterium Myxococcus xanthus, TsaP is also important for surface assembly of T4P, and it accumulates and localizes in a PilQ-dependent manner to the cell poles. Our results show that TsaP is a novel protein associated with T4P function and suggest that TsaP functions to anchor the secretin complex to the peptidoglycan.Type IV pili systems (T4PSs) are involved in the assembly of long, thin fibers, which are found on the surfaces of many bacteria and archaea (1). Type IV pili (T4P) function in host cell adhesion, twitching motility, virulence, DNA uptake, and biofilm formation and are evolutionary related to type II secretion systems (T2SSs), bacterial transformation systems, and the archaellum (2–4). T4PSs can be divided into T4aPSs and T4bPSs that are distinguished based on pilin size and assembly systems (5, 6). T4aPSs form the most abundant class, and the T4P formed by these systems can undergo cycles of extension, adhesion, and retraction, which is a feature that distinguishes them from the other bacterial surface structures (7, 8). T4aP retract at rates up to 1 μm/s and can generate forces up to 150 pN (9, 10). Generally, T4bPSs are not associated with retraction. Here, we focus on T4aPSs and refer to these as T4PSs unless specifically indicated. T4PSs have been studied extensively in many bacteria but are especially well characterized in Neisseria and Pseudomonas spp. and in Myxococcus xanthus. Different nomenclature is used for different T4PSs (Table S1). Here, the Neisseria gonorrhoeae nomenclature is used.T4P are composed of major (e.g., PilE) and minor (in N. gonorrhoeae; e.g., PilV, PilX, ComP) pilins that are synthesized as preproteins with a type III signal peptide. After cleavage of the signal peptide by the prepilin peptidase PilD (11, 12), the T4P are assembled by a multiprotein complex (13). In Gram-negative bacteria, the proteins of T4PSs can be divided into three subcomplexes: the inner membrane (IM) motor complex, the alignment complex, and the outer membrane (OM) pore complex (6). The IM motor complex drives both the assembly and the retraction of T4P. Pilin subunits are extruded from the IM by the platform protein PilG (14) and the hexameric ATPase PilF (15). Disassembly of T4P with retraction occurs when PilF is replaced by the hexameric ATPase PilT (7, 16). PilU, a PilT paralog, is involved in retraction to a lesser extent (17). The alignment complex consisting of PilM, PilN, PilO, and PilP is proposed to connect the IM motor complex and the OM pore complex, and it is also thought to be involved in the stability and/or gating of the OM complex (18–20). In the OM, PilQ forms a homooligomeric ring that serves as a conduit for T4P (21–23).PilQ is a member of the secretin protein family. Proteins belonging to this family are present in many Gram-negative bacteria and are components of T4PSs, T2SSs, type III secretion systems (T3SSs), and extrusion systems of filamentous phages (24). Secretins are multidomain proteins with a signal sequence and a conserved C-terminal OM-spanning domain. Most secretins contain multiple copies of an N-terminal α/β domain (the N domains). PilQ proteins are integral OM proteins and form large gated channels. Oligomeric secretin complexes with different symmetries have been identified. Structural characterization by EM of purified PilQ from Neisseria meningitidis showed a dodecameric structure with a chamber sealed at both ends (25, 26), whereas the T2SS secretins PulD (27) and GspD (28) of the Klebsiella oxytoca pullanase and Vibrio cholerae toxin secretion systems, respectively, showed dodecameric structures with a chamber open at the periplasmic side and closed at the OM side. The structure of the InvG secretin complex of the T3SS of the Salmonella typhimurium needle complex showed 15-fold symmetry and is open at both ends (29), and the phage pIV secretin showed 14-fold symmetry (30). The structure of the C-terminal OM-spanning domain involved in multimer formation is currently not known. Crystal structures of the periplasmic N domains of GspD of the T2SS of enterotoxigenic Escherichia coli (31), of EscC of the T3SS of S. typhimurium (32), and of N. meningitidis PilQ (25) showed that these domains consist of α-helices packed against three-stranded β-sheets. Secretins of T4P systems also contain B domains, which are not present in other secretins and are located N-terminal to the N domains. The structure of the B2 domain of N. meningitidis PilQ consists of several β-strands (25). Remarkably, when the sequence conservation of the B2 domain was mapped to the structure of the B2 domain of N. meningitidis PilQ, a highly conserved patch was identified that was proposed to form the binding site for a currently unidentified T4PS protein (25).Secretins interact with several other proteins. Pilotin proteins are small lipoproteins that interact with the extreme C terminus of secretins and are responsible for OM targeting and oligomerization of secretins (33–38). Secretins of T4PSs also interact with the alignment complex. For N. meningitidis, Pseudomonas aeruginosa, and M. xanthus PilQ, a direct interaction was demonstrated between the respective PilPs and the N0 domains of the PilQs (25, 39, 40). Recently, ExeA of the T2SS of Aeromonas hydrophila (41) and FimV of the T4PS of P. aeruginosa (42) were also implicated in secretin assembly. They contain, respectively, PF01471 and LysM peptidoglycan (PG)-binding domains that might attach them to the PG. However, neither of these two proteins is ubiquitously conserved in bacteria assembling T4P.We have previously shown that the PilQ secretin of N. gonorrhoeae embedded in OM sheets is surrounded by a peripheral structure, which is formed by an additional peripheral ring as well as spikes (43). The proteins that make up these structures are not known. Here, we identify a widely conserved protein, which we name T4P secretin-associated protein (TsaP), that is important for the formation of the peripheral structure. Phylogenomic analysis of 450 genomes of Proteobacteria showed that the presence of the tsaP gene is strongly linked to the presence of genes for T4aPSs. We characterize the TsaP protein and demonstrate the importance of TsaP for T4aP assembly in the two phylogenetically widely separated model organisms N. gonorrhoeae and M. xanthus.     

Follow-up imaging after cryoablation of clear cell renal cell carcinoma is feasible using single photon emission computed tomography with 111In-girentuximab

European Journal of Nuclear Medicine and Molecular Imaging - Detection of residual or recurrent vital renal tumor on follow-up (FU) cross-sectional imaging after ablative therapy is challenging....     

ArF-excimer laser–induced secondary radiation in photoablation of biological tissue

Secondary radiation, emitted during and after the irradiation of corneal, dermal, and dental tissue by an ArF-excimer laser (193 nm), was qualitatively and quantitatively characterized. Emission of secondary radiation was found in the range of 200–800 nm. The intensity of secondary radiation in the range of 200–315 nm (UVC and UVB) is ∼20% of the total intensity at high laser fluences (>2 J/cm²), and ∼50% at moderate laser fluences (<500 mJ/cm²); 10 μJ/cm² in the UVC and UVB were measured at the sample surface, at fluences (<1J/cm²) which are of relevance for clinical procedures on soft tissues. In dental tissue processing, very high fluences (>5 J/cm²) are required. As a consequence, laser–induced plasma formation can be observed. Secondary radiation can be used as a visible guide for selective removal of carious altered tissue. The data we have found might be of assistance in estimating potential hazards for future mutagenic studies in the field. © 1994 Wiley-Liss, Inc.