The role of Interleukin-12 in liver inflammation

Chronic liver inflammation during viral hepatitis is a major health problem worldwide. The role of proinflammatory cytokines, like IL-12, in breaking hepatic immune tolerance, and inducing acute liver inflammation and virus clearance is not clear. Nor is clear its role in uncontrolled severe inflammatory response, leading to fulminant hepatitis and hepatic failure. This work, focused in the study of the role of endogenous produced IL-12 in inducing hepatic inflammatory responses, demonstrates: In vitro, using adenovirus coding for IL-12, that hepatocytes stimulate CD4+ T cells in a tolerogenic manner, and that endogenous IL-12 is able to switch the immune response into Th1; and in vivo, that endogenous IL-12 induces hepatocyte damage and virus elimination in mice infected with adenovirus. In addition, and in order to study in vivo the relevance of IL-12 in acute inflammation, conditional IL-12 transgenic mice expressing IL-12 in the liver after cre-recombinase mediated induction were generated. For this purpose, an IL-12 fusion protein was created, which demonstrated high levels of bioactivity. Induction of IL-12 expression during embryonic development was achieved by crossbreeding with Act-Cre transgenic mice; induction of IL-12 expression in adult mice was achieved by a plasmid coding for the cre-recombinase. This study demonstrates that after induction, IL-12 is expressed in the liver of the transgenic mice. It also demonstrates that hepatic expression of IL-12 induces splenomegaly and liver inflammation, characterized by large infiltrations in portal tracts and veins, associated with hepatic damage, necrosis areas and lethality. Furthermore, constitutive hepatic IL-12 expression does not lead to abortion, but to total lethality, short after delivery. In conclusion, in this study, a transgenic mouse model has been generated, in which the expression of active IL-12 in the liver can be induced at any time; this model will be very helpful for studying hepatic pathologies. This study has also demonstrated that hepatic produced IL-12 is able of breaking liver tolerance inducing inflammation, virus elimination, severe hepatocyte damage, and lethality. These findings suggest IL-12 as a key cytokine in acute liver inflammation and fulminant hepatic failure. 5.1 Future studies Once the importance of IL-12 in inducing hepatic inflammation and virus elimination was demonstrated in this study, understanding the mechanisms of the IL-12 induced liver damage, and more important, how to avoid it will be the main focus in the future. It is very important to achieve hepatic inflammation for a more effective and faster viral elimination, but avoiding the toxicity of IL-12, which leads to massive liver injury and lethality is obviously necessary to allow IL-12 as therapy. For that purpose, future studies will be mainly base on three different points: 1. The determination of different cell populations present in the hepatic infiltration, which of them are responsible for liver injury, and as well their state of activation. 2. The measure of other pro- and anti-inflammatory cytokines and chemokines, which can play a role in IL-12-induced liver inflammation and hepatocyte damage. For these purposes, specific blocking antibodies (anti TNF-alpha, anti IL-12, anti IFN-g) will be used. The study with different transgenic mice: TNF-alpha Receptor knockout, TGF-b, will also help in determining the role of those cytokines during IL-12-induced liver damage and lethality. 3. The establishing of liver pathology models (viral infection, tumours, auto-antigens) in mice. Induction of IL-12 at any time of the pathology development will help in clarifying the role of IL-12 in those models. Finally, the transgenic mice expressing IL-23 in the liver will be generated.

Untersuchung der Pharmakokinetik von Ciprofloxacin und Piperacillin bei Intensivpatienten mit kontinuierlichen Hämodialyseverfahren

Infektionen zählen bei hämodialysepflichtigen Intensivpatienten zu den häufigsten Todesursachen. Um die Wirksamkeit und Sicherheit der Antibiotikatherapie zu verbessern, müssen verschiedene Faktoren, zum Beispiel die Pharmakodynamik und Pharmakokinetik des Antibiotikums, die Art des Hämodialyseverfahrens, die Art des Dialysefilters und der Zustand des Patienten berücksichtigt werden. Im Rahmen einer klinischen Studie wurde die antibiotische Wirkung von Piperacillin und Ciprofloxacin bei kontinuierlichen Hämodialyseverfahren mittels pharmakokinetischer Methoden bestimmt.Für die klinische Studie wurde eine HPLC-Methode mit kombinierter Festphasenextraktion (SPE) entwickelt und nach den Grenzwerten der EMA Guideline on Bioanalytical Method Validation validiert. Die Methode erwies sich für die gleichzeitige Bestimmung von Piperacillin und Ciprofloxacin in Plasma- und Dialysatproben als valide und zuverlässig. Die ermittelten Konzentrationen der beiden Antibiotika wurden für die Berechnung der pharmakokinetischen Parameter verwendet.In der klinischen Studie wurden bei 24 Intensivpatienten mit kontinuierlicher venovenöser Hämodialyse (CVVHD) bzw. kontinuierlicher venovenöser Hämodiafiltration (CVVHDF), bei denen Piperacillin/Tazobactam, Ciprofloxacin oder eine Kombination dieser Antibiotika indiziert war, die Antibiotikakonzentrationen im Plasma und Dialysat im Steady State gemessen. Unmittelbar vor einer Antibiotikainfusion (0 min) wurde ein Volumen von sechs Milliliter Blut entnommen. Weitere Blutentnahmen erfolgten 30 Minuten nach der Infusion sowie nach 1, 2, 3, 4, 8, 12 und 24 Stunden. Sobald ein Filtratbeutel ausgetauscht wurde, wurden parallel zu den Blutproben Dialysatproben entnommen. Die Konzentrationen von Piperacillin und Ciprofloxacin wurden nach der Festphasenextraktion aus den Plasmaproben mit der validierten HPLC-Methode innerhalb von 15 Minuten zuverlässig bestimmt. Neben den gemessenen Plasmakonzentrationen (Cmax, Cmin) wurden pharmakokinetische Parameter wie t0,5, VdSS, AUC, Cltot, ClCRRT und Clextrarenal berechnet. Für Piperacillin wurde untersucht, ob die Plasmaspiegel der Patienten für das gesamte Dosierungsintervall oberhalb der geforderten vierfachen MHK von 64 mg/l liegen. Für Ciprofloxacin wurde untersucht, ob die aus gemessenen Plasmaspiegeln berechnete AUC den Quotienten aus AUC und MHK (=AUIC) ≥ 125 h erfüllt.Bei zehn der 21 mit Piperacillin behandelten Patienten lagen die Plasmaspiegel unterhalb der angestrebten Konzentration von 64 mg/l für das gesamte Dosierungsintervall. Das Patientenkollektiv wies eine große interindividuelle Variabilität auf. Mit einer Wahrscheinlichkeit von 95 % waren 26 - 70 % der Patienten unterdosiert. In der Gruppe der mit Ciprofloxacin behandelten Patienten wurde die angestrebte AUIC von 125 h nur bei neun der 20 Patienten erreicht. Mit einer Wahrscheinlichkeit von 95 % waren 29 - 76 % der Patienten unterdosiert. Die kontinuierlichen Nierenersatzverfahren hatten nur einen geringen Anteil an der totalen Clearance der untersuchten Antibiotika. Während die Clearance des kontinuierlichen Nierenersatzverfahren bei Piperacillin für ein Drittel der Arzneistoffelimination verantwortlich war, trug diese im Fall von Ciprofloxacin lediglich zu 16 % zur Arzneistoffelimination bei.Die Dosierung von Piperacillin/Tazobactam bzw. Ciprofloxacin sollte bei kritisch kranken Intensivpatienten mit kontinuierlicher Hämodialyse mindestens 4 mal 4/0,5 g pro Tag bzw. 2 mal 400 mg pro Tag betragen. Diese Empfehlungen sind insbesondere für die verwendeten Dialyseverfahren und -bedingungen zutreffend. Zur weiteren Optimierung der Antibiotikatherapie ist ein Therapeutisches Drug Monitoring empfehlenswert.

Therapeutic vaccination for chronic hepatitis B in the Trimera mouse model

Therapeutic vaccination for chronic hepatitis B in the Trimera mouse modelrnRaja Vuyyuru and Wulf O. BöcherrnHepatitis B is a liver disease caused by Hepatitis B virus (HBV). It ranges in severity from a mild illness, lasting a few weeks (acute), to a serious long-term (chronic) illness that can lead either to liver disease or liver cancer. Acute infection is self limiting in most adults, resulting in clearance of virus from blood and liver and the development of lasting immunity. However 5% of acutely infected patients do not resolve primary HBV infection, leading to chronic infection with persistent viral replication in the liver. The strength of the initial antiviral immune response elicited to Hepatitis B determines the subsequent clinical outcome. A strong and broad T cell response leads to spontaneous resolution. Conversely, a weak T cell response favours viral persistence and establishment of chronic disease. While treatments using interferon-alpha or nucleos(t)ide analogues can reduce disease progression, they rarely lead to complete recovery. The lack of a suitable small animal model hampered efforts to understand the mechanisms responsible for immune failure in these chronic patients.rnIn current study we used Trimera mice to study the efficacy of potential vaccine candidates using HBV loaded dendritic cells in HBV chronic infection in vivo. The Trimera mouse model is based on Balb/c mice implanted with SCID mouse bone marrow and human peripheral blood mononuclear cells (PBMC) from HBV patients, and thus contains the immune system of the donor including their HBV associated T cell defect.rnIn our present study, strong HBV specific CD4+ and CD8+ T cell responses were enhanced by therapeutic vaccination in chronic HBV patients. These T cell responses occurred independently of either the course of the disease or the strength of their underlying HBV specific T cell failure. These findings indicate that the Trimera mouse model represents a novel experimental tool for evaluating potential anti-HBV immunotherapeutic agents. This in vivo data indicated that both the HBV specific CD4+ cell and CD8+ responses were elicited in the periphery. These HBV specific T cells proliferated and secreted cytokines upon restimulation in Trimera mice. The observation that these HBV specific T cells are not detectable directly ex vivo indicates that they must be immune tolerant or present at a very low frequency in situ. HBV specific T cell responses were suppressed in Trimera mice under viremic conditions, suggesting that viral factors might be directly involved in tolerizing or silencing antiviral T cell responses. Thus, combination of an effective vaccine with antiviral treatment to reduce viremia might be a more effective therapeutic strategy for the future. Such approaches should be tested in Trimera mice generated in HBV or HBs expressing transgenic mice before conducting clinical trials.rn

Generation and characterisation of acute myeloid leukaemia-reactive CD4 + T cells and their potential to eliminate human leukaemia blasts in NSG mice

Acute myeloid leukaemia (AML) is a cancer of the haematopoietic system, which can in many cases only be cured by haematopoietic stem cell transplantation (HSCT) and donor lymphocyte infusion (DLI) (Burnett et al., 2011). This therapy is associated with the beneficial graft-versus-leukaemia (GvL) effect mediated by transplanted donor T and NK cells that either recognise mismatch HLA molecules or polymorphic peptides, so-called minor histocompatibility antigens, leukaemia-associated or leukaemia-specific antigens in the patient and thus eliminate remaining leukaemic blasts. Nevertheless, the mature donor-derived cells often trigger graft-versus-host disease (GvHD), leading to severe damages in patients’ epithelial tissue, mainly skin, liver and intestine (Bleakley & Riddell, 2004). Therefore, approaches for the selective mediation of strong GvL effects are needed, also in order to prevent relapse after transplantation. One promising opportunity is the in vitro generation of AML-reactive CD4+ T cells for adoptive transfer. CD4+ T cells are advantageous compared to CD8+ T cells, as HLA class II molecules are under non-inflammatory conditions only expressed on haematopoietic cells; a fact that would minimise GvHD (Klein & Sato, 2000). In this study, naive CD4+ T cells were isolated from healthy donors and were successfully stimulated against primary AML blasts in mini-mixed lymphocyte/leukaemia cell cultures (mini-MLLC) in eight patient/donor pairs. After three to seven weekly restimulations, T cells were shown to produce TH1 type cytokines and to be partially of monoclonal origin according to their TCR Vβ chain usage. Furthermore, they exhibited lytic activity towards AML blasts, which was mediated by the release of granzymes A and B and perforin. The patient/donor pairs used in this study were fully HLA-class I matched, except for one pair, and also matched for HLA-DR and -DQ, whereas -DP was mismatched in one or both alleles, reflecting the actual donor selection procedure in the clinic (Begovich et al., 1992). Antibody blocking experiments suggested that the generated CD4+ T cells were directed against the HLA-DP mismatches, which could be confirmed by the recognition of donor-derived lymphoblastoid cell lines (LCLs) electroporated with the mismatched DP alleles. Under non-inflammatory conditions primary fibroblasts did not express HLA-DP and were thus not recognised, supporting the idea of a safer application of CD4+ T cells regarding induction of GvHD. For the assessment of the biological significance of these T cells, they were adoptively transferred into NSG mice engrafted with human AML blasts, where they migrated to the bone marrow and lymphoid tissue and succeeded in eliminating the leukaemic burden after only one week. Therefore, AML-reactive CD4+ T cells expanded from the naive compartment by in vitro stimulation with primary leukaemia blasts appear to be a potent tool for DLI in HSCT patients and promise to mediate specific GvL effects without causing GvHD.