Karina Juhl Rasmussen

Systematic identification of protein complexes in Saccharomyces cerevisiae by mass spectrometry

The recent abundance of genome sequence data has brought an urgent need for systematic proteomics to decipher the encoded protein networks that dictate cellular function. To date, generation of large-scale protein–protein interaction maps has relied on the yeast two-hybrid system, which detects binary interactions through activation of reporter gene expression. With the advent of ultrasensitive mass spectrometric protein identification methods, it is feasible to identify directly protein complexes on a proteome-wide scale. Here we report, using the budding yeast Saccharomyces cerevisiae as a test case, an example of this approach, which we term high-throughput mass spectrometric protein complex identification (HMS-PCI). Beginning with 10% of predicted yeast proteins as baits, we detected 3,617 associated proteins covering 25% of the yeast proteome. Numerous protein complexes were identified, including many new interactions in various signalling pathways and in the DNA damage response. Comparison of the HMS-PCI data set with interactions reported in the literature revealed an average threefold higher success rate in detection of known complexes compared with large-scale two-hybrid studies. Given the high degree of connectivity observed in this study, even partial HMS-PCI coverage of complex proteomes, including that of humans, should allow comprehensive identification of cellular networks.

Cellular and humoral factors involved in the response of rainbow trout gills to Ichthyophthirius multifiliis infections: molecular and immunohistochemical studies.

The parasitic ciliate Ichthyophthirius multifiliis infecting skin, fins and gills of fish induces a protective immune response in rainbow trout (Oncorhynchus mykiss) surviving the infection and a similar protection can be conferred by i.p. injection of live theronts. A combined molecular and immunohistochemical approach has been used in this work for pinpointing cellular and humoral immune factors in gill tissue involved in the response and indicating interactions between the systemic and local responses. Fish were immunized by intra-peritoneal injection of live I. multifiliis theronts, control fish were injected with PBS and subgroups were treated with the immuno-suppressant hydrocortisone before fish were challenged with live theronts. Significant up-regulations of genes encoding IgM, IgT, C3, SAA, IL-8, IL-22 and IFN-γ were induced by immunization and challenge. Hydrocortisone treatment had a significant down-regulating effect on genes incoding IgT, IgM, CD4, CD8, IFN-γ, IL-8 and IL-22 in all groups. Immunohistochemistry, using monoclonal antibodies to detect cellular markers, demonstrated active involvement of CD8, MHC II, IgT and IgM positive cells in gill tissue. Putative T-cells (CD8 positive cells) were detected in the intraepithelial lymphoid tissue located at the base of gill filaments and in hyperplastic gill tissue but following infection a clear efflux of these cells was detected. MHC II positive cells were distributed across the gill filaments and accumulated in hyperplastic tissue but hydrocortisone treatment affected their density negatively in both immunized and non-immunized fish. IgT positive cells were present in the epithelial lining of the gill lamellae (suggesting a primary role of this protein in the mucosal defence against the ciliate) whereas IgM positive cells were found only in gill arterioles and the lamellar capillaries. The present work indicates an intensive activity and specialized function of immune cells (B-cells, T-cells and macrophages) and humoral elements such as immunoglobulins IgT and IgM which are orchestrated by cytokines in gill tissue reacting against I. multifiliis.

Experimental evidence for direct in situ binding of IgM and IgT to early trophonts of Ichthyophthirius multifiliis (Fouquet) in the gills of rainbow trout, Oncorhynchus mykiss (Walbaum)

Freshwater fish are able to mount a protective immune response against the parasite Ichthyophthirius multifiliis (Ich) following a non-lethal exposure. Factors involved in immunity comprise cellular and humoral factors, but antibodies have been suggested to play a prominent role in protection. However, host antibodies have not yet been demonstrated to bind to the parasite in situ. By the use of immunohistochemical techniques, this study demonstrated that IgT and IgM bind to surface structures, including cilia, on the early feeding stage of the parasite in the gills of immune rainbow trout, Oncorhynchus mykiss, shortly (2 h) after invasion. No binding of IgT and no or only a weak binding of IgM was observed on the parasites in the gills of similarly exposed but naïve rainbow trout. This study indicates that antibodies play an important part in the protection of immune fish against Ich although additional humoral and cellular factors may contribute to this reaction.

Two mannose-binding lectin homologues and an MBL-associated serine protease are expressed in the gut epithelia of the urochordate species Ciona intestinalis.

The lectin complement pathway has important functions in vertebrate host defence and accumulating evidence of primordial complement components trace its emergence to invertebrate phyla. We introduce two putative mannose-binding lectin homologues (CioMBLs) from the urochordate species Ciona intestinalis. The CioMBLs display similarities with vertebrate MBLs and comprise a collagen-like region, alpha-helical coiled-coils and a carbohydrate recognition domain (CRD) with conserved residues involved in calcium and carbohydrate binding. Structural analysis revealed an oligomerization through interchain disulphide bridges between N-terminal cysteine residues and cysteines located between the neck region and the CRD. RT-PCR showed a tissue specific expression of CioMBL in the gut and by immunohistochemistry analysis we also demonstrated that CioMBL co-localize with an MBL-associated serine protease in the epithelia cells lining the stomach and intestine. In conclusion we present two urochordate MBLs and identify an associated serine protease, which support the concept of an evolutionary ancient origin of the lectin complement pathway.

Differential occurrence of immune cells in the primary and secondary vascular systems in rainbow trout, Oncorhynchus mykiss (Walbaum)

The vascular system in fish is divided into two components, the blood circulation and a secondary circulatory system, which is a vessel system referred to by earlier authors as ‘lymphatics’. Also, Wardle (1971) used the latter term for his description of the secondary system. However, true lymphatics are defined solely anatomically (and not functionally) as a system of vessels without direct vascular connection to the arterial part of the blood circulation. Based on newer studies pointing to deviations from this picture in fish, the term secondary vascular system (SVS) was proposed for these special vessels, and accordingly, the normal blood circulation system was termed the primary vascular system (PVS) (Vogel 1985a, b). The SVS was described in some detail in rayfinned fishes (Actinopterygii) by Vogel & Claeviez (1981), Vogel (1985a,b), Steffensen & Vogel (1986) and Steffensen & Lomholt (1992) confirming that this system described thus far lacked the characteristic anatomy of lymphatics normally seen in other vertebrates, especially mammals. The latter authors showed that the SVS was in communication with the systemic arteries via a large number of anastomoses of capillary dimensions. The SVS forms capillary beds situated in the outer surfaces of the fish, such as the skin, gills, mouth and pharynx (Vogel 1985a,b), but appears to be absent in regions of the mesenteric and renal tissues, where the lymphatic system is normally found in mammals. In addition, red blood cells may, under certain circumstances, be present in the SVS, which was also shown by Wardle (1971) when describing lymphatic-like vessel systems in the plaice. Although this author interpreted this as an artefact (due to puncturing of vessels or abnormal blood pressure), the latter study does comply with the notion of the existence of a communication between PVS and SVS. These clear deviations from the structure in higher vertebrates advocate for a reassessment of whether the SVS has functions related to lymphatic functions in higher vertebrates – including immune-related elements – or not (Vogel 1985a,b; Steffensen & Lomholt 1992; Skov & Bennett 2004). As a first elucidation of this question, we have investigated whether the composition of immunologically central elements (various leucocytes) in SVS of rainbow trout, Oncorhynchus mykiss (Walbaum), differs from that of PVS. Rainbow trout (total body weight 300–400 g), were collected from the fish farm ‘Hvilested Dambrug’, Kolding, Denmark, and brought to the laboratory where they were kept in 1500-L tanks and provided with continuously aerated recirculated fresh water (10 C). Fish were acclimatized to laboratory conditions for 3 weeks, and remained unfed for at least 1 week before sampling to minimize physiological changes induced by differences in feed uptake. A total of five fish Correspondence K Buchmann, Section of Biomedicine, Faculty of Health and Medical Sciences, University of Copenhagen, Stigbojlen 7, DK-1870 Frederiksberg C, Denmark (e-mail: kub@sund.ku.dk)

DamX Controls Reversible Cell Morphology Switching in Uropathogenic Escherichia coli

ABSTRACT The ability to change cell morphology is an advantageous characteristic adopted by multiple pathogenic bacteria in order to evade host immune detection and assault during infection. Uropathogenic Escherichia coli (UPEC) exhibits such cellular dynamics and has been shown to transition through a series of distinct morphological phenotypes during a urinary tract infection. Here, we report the first systematic spatio-temporal gene expression analysis of the UPEC transition through these phenotypes by using a flow chamber-based in vitro infection model that simulates conditions in the bladder. This analysis revealed a novel association between the cell division gene damX and reversible UPEC filamentation. We demonstrate a lack of reversible bacterial filamentation in a damX deletion mutant in vitro and absence of a filamentous response by this mutant in a murine model of cystitis. While deletion of damX abrogated UPEC filamentation and secondary surface colonization in tissue culture and in mouse infections, transient overexpression of damX resulted in reversible UPEC filamentation. In this study, we identify a hitherto-unknown damX-mediated mechanism underlying UPEC morphotypical switching. Murine infection studies showed that DamX is essential for establishment of a robust urinary tract infection, thus emphasizing its role as a mediator of virulence. Our study demonstrates the value of an in vitro methodology, in which uroepithelium infection is closely simulated, when undertaking targeted investigations that are challenging to perform in animal infection models. IMPORTANCE Urinary tract infections (UTIs) are most often caused by uropathogenic Escherichia coli (UPEC) and account for a considerable health care burden. UPEC exhibits a dynamic lifestyle in the course of infection, in which the bacterium transiently adopts alternative morphologies ranging from rod shaped to coccoid and filamentous, rendering it better at immune evasion and host epithelium adhesion. This penchant for morphotype switching might in large measure account for UPEC’s success as a pathogen. In aiming to uncover genes underlying the phenomenon of UPEC morphotype switching, this study identifies damX, a cell division gene, as a mediator of reversible filamentation during UTI. DamX-mediated filamentation represents an additional pathway for bacterial cell shape control, an alternative to SulA-mediated FtsZ sequestration during E. coli uropathogenesis, and hence represents a potential target for combating UTI. Urinary tract infections (UTIs) are most often caused by uropathogenic Escherichia coli (UPEC) and account for a considerable health care burden. UPEC exhibits a dynamic lifestyle in the course of infection, in which the bacterium transiently adopts alternative morphologies ranging from rod shaped to coccoid and filamentous, rendering it better at immune evasion and host epithelium adhesion. This penchant for morphotype switching might in large measure account for UPEC’s success as a pathogen. In aiming to uncover genes underlying the phenomenon of UPEC morphotype switching, this study identifies damX, a cell division gene, as a mediator of reversible filamentation during UTI. DamX-mediated filamentation represents an additional pathway for bacterial cell shape control, an alternative to SulA-mediated FtsZ sequestration during E. coli uropathogenesis, and hence represents a potential target for combating UTI.

Immunohistochemical localization of inflammatory cells and cell cycle proteins in the gills of Loma salmonae infected rainbow trout (Oncorhynchus mykiss).

Microsporidial gill diseases particularly those caused by Loma salmonae incur significant economic losses to the salmonid aquaculture industry. The gill responses to infection include the formation of xenomas and the acute hyperplastic inflammatory responses once the xenomas rupture releasing infective spores. The aim of this work was to characterize the inflammatory responses of the gill to both the presence of the xenomas as well as the hyperplasia associated with L. salmonae infection in the rainbow trout gill following an experimental infection using immunohistochemistry. Hyperplastic lesions demonstrated numerous cells expressing PCNA as well as an apparent increased expression of caspase-3 and number of apoptotic cells (TUNEL positive cells). There was an expression of TNFα in individual cells within the gill and increased expression of a myeloid cell line antigen indicating the presence of granulocyte infiltration of both the hyperplastic lesions as well as the xenomas. Similar immune-reactivity was seen in gill EGCs. Hyperplastic gill lesions showed a marked infiltration of CD8+ cells and expression of MHC class I antigens. These findings suggest that L. salmonae xenomas may be subject to infiltration by the host immune cells as well as the mounting or a marked cellular cytotoxic immunoreaction in the resultant hyperplasia following xenoma rupture and spore release.

A novel in vitro model for hematogenous spreading of S. aureus device biofilms demonstrating clumping dispersal as an advantageous dissemination mechanism

Staphylococcus aureus is able to disseminate from vascular device biofilms to the blood and organs, resulting in life‐threatening infections such as endocarditis. The mechanisms behind spreading are largely unknown, especially how the bacterium escapes immune effectors and antibiotics in the process. Using an in vitro catheter infection model, we studied S. aureus biofilm growth, late‐stage dispersal, and reattachment to downstream endothelial cell layers. The ability of the released biofilm material to resist host response and disseminate in vivo was furthermore studied in whole blood and phagocyte survival assays and in a short‐term murine infection model. We found that S. aureus biofilms formed in flow of human plasma release biofilm thromboemboli with embedded bacteria and bacteria‐secreted polysaccharides. The emboli disseminate as antibiotic and immune resistant vehicles that hold the ability to adhere to and initiate colonisation of endothelial cell layers under flow. In vivo experiments showed that the released biofilm material reached the heart similarly as ordinary broth‐grown bacteria but also that clumps to some extend were trapped in the lungs. The clumping dispersal of S. aureus from in vivo‐like vascular biofilms and their specific properties demonstrated here help explain the pathophysiology associated with S. aureus bloodstream infections.

Proteome-wide antigen discovery of novel protective vaccine candidates against Staphylococcus aureus infection.

Methicillin-resistant Staphylococcus aureus (MRSA) is a rapidly growing problem, especially in hospitals where MRSA cause increased morbidity and mortality and a significant rise in health expenditures. As many strains of MRSA are resistant to other antimicrobials in addition to methicillin, there is an urgent need to institute non-antimicrobial measures, such as vaccination, against the spread of MRSA. With the aim of finding new protective antigens for vaccine development, this study used a proteome-wide in silico antigen prediction platform to screen the proteome of S. aureus strain MRSA252. Thirty-five different S. aureus proteins were identified, recombinantly expressed, and tested for protection in a lethal sepsis mouse model using S. aureus strain MRSA252 as the challenge organism. We found that 13 of the 35 recombinant peptides yielded significant protection and that 12 of these antigens were highly conserved across 70 completely sequenced S. aureus strains. Thus, this in silico platform was capable of identifying novel candidates for inclusion in future vaccines against MRSA.

A novel antihuman C3d monoclonal antibody with specificity to the C3d complement split product

The complement component C3 and the cleavage products of C3b/iC3b, C3c and C3d are used as biomarkers in clinical diagnostics. Currently, no specific antibodies are able to differentiate C3d from other fragments, although such a distinction could be very valuable considering that they may reflect different pathophysiological mechanisms. We have developed a rat antihuman C3d monoclonal antibody with specificity to the end sequence of the N-terminal region of C3d. The antibody can therefore only bind to C3d when it manifests itself as the final end product of cleaved C3. We believe that this specificity is it first of its kind, and predicts that it can be used as a detection tool in several immunological methods with great value in diagnostics.