Gitta Maria Seleznik

TAK1 Suppresses a NEMO-Dependent but NF-κB-Independent Pathway to Liver Cancer

The MAP3-kinase TGF-beta-activated kinase 1 (TAK1) critically modulates innate and adaptive immune responses and connects cytokine stimulation with activation of inflammatory signaling pathways. Here, we report that conditional ablation of TAK1 in liver parenchymal cells (hepatocytes and cholangiocytes) causes hepatocyte dysplasia and early-onset hepatocarcinogenesis, coinciding with biliary ductopenia and cholestasis. TAK1-mediated cancer suppression is exerted through activating NF-kappaB in response to tumor necrosis factor (TNF) and through preventing Caspase-3-dependent hepatocyte and cholangiocyte apoptosis. Moreover, TAK1 suppresses a procarcinogenic and pronecrotic pathway, which depends on NF-kappaB-independent functions of the I kappaB-kinase (IKK)-subunit NF-kappaB essential modulator (NEMO). Therefore, TAK1 serves as a gatekeeper for a protumorigenic, NF-kappaB-independent function of NEMO in parenchymal liver cells.

Nonredundant Function of Soluble LTα3 Produced by Innate Lymphoid Cells in Intestinal Homeostasis

Command and Control Innate lymphoid cells are vital for the development of gut-associated lymphoid tissues, maintenance of the epithelial barrier, and protection against intestinal microbes; their dysfunction can promote immune pathology. Immunoglobulin A (IgA) production is important for maintenance of the gut epithelial barrier and the composition of the gut microbiota. Through the generation of knockout mouse models, Kruglov et al. (p. 1243) were able to distinguish how soluble and membrane-bound lymphotoxins expressed by innate lymphoid cells in the gut specifically regulate IgA production and thereby control gut microbiota composition. Soluble lymphotoxin plays a paracrine role in controlling immunoglobulin A responses and regulating gut microbiota. Immunoglobulin A (IgA) production at mucosal surfaces contributes to protection against pathogens and controls intestinal microbiota composition. However, mechanisms regulating IgA induction are not completely defined. We show that soluble lymphotoxin α (sLTα3) produced by RORγt+ innate lymphoid cells (ILCs) controls T cell–dependent IgA induction in the lamina propria via regulation of T cell homing to the gut. By contrast, membrane-bound lymphotoxin β (LTα1β2) produced by RORγt+ ILCs is critical for T cell–independent IgA induction in the lamina propria via control of dendritic cell functions. Ablation of LTα in RORγt+ cells abrogated IgA production in the gut and altered microbiota composition. Thus, soluble and membrane-bound lymphotoxins produced by ILCs distinctly organize adaptive immune responses in the gut and control commensal microbiota composition.

The unexpected role of lymphotoxin |[beta]| receptor signaling in carcinogenesis: from lymphoid tissue formation to liver and prostate cancer development

The cytokines lymphotoxin (LT) α, β and their receptor (LTβR) belong to the tumor necrosis factor (TNF) superfamily, whose founder—TNFα—was initially discovered due to its tumor necrotizing activity. LTβR signaling serves pleiotropic functions including the control of lymphoid organ development, support of efficient immune responses against pathogens due to maintenance of intact lymphoid structures, induction of tertiary lymphoid organs, liver regeneration or control of lipid homeostasis. Signaling through LTβR comprises the noncanonical/canonical nuclear factor-κB (NF-κB) pathways thus inducing chemokine, cytokine or adhesion molecule expression, cell proliferation and cell survival. Blocking LTβR signaling or Fcγ-receptor mediated immunoablation of LT-expressing cells was demonstrated to be beneficial in various infectious or noninfectious inflammatory or autoimmune disorders. Only recently, LTβR signaling was shown to initiate inflammation-induced carcinogenesis, to influence primary tumorigenesis and to control reemergence of carcinoma in various cancer models through distinct mechanisms. Indeed, LTβR signaling inhibition has already been used as efficient anti-inflammatory, anti-cancer therapy in some experimental models. Here, we review the pleiotropic functions attributed to LT, the effects of its deregulation and extensively discuss the recent literature on LTs link to carcinogenesis.

Lymphotoxin β Receptor Signaling Promotes Development of Autoimmune Pancreatitis

BACKGROUND & AIMS Little is known about the pathogenic mechanisms of autoimmune pancreatitis (AIP), an increasingly recognized, immune-mediated form of chronic pancreatitis. Current treatment options are limited and disease relapse is frequent. We investigated factors that contribute to the development of AIP and new therapeutic strategies. METHODS We used quantitative polymerase chain reaction, immunohistochemical, and enzyme-linked immunosorbent analyses to measure the expression of cytokines and chemokines in tissue and serum samples from patients with and without AIP. We created a mouse model of human AIP by overexpressing lymphotoxin (LT)α and β specifically in acinar cells (Ela1-LTab mice). RESULTS Messenger RNA levels of LTα and β were increased in pancreatic tissues from patients with AIP, compared with controls, and expression of chemokines (CXCL13, CCL19, CCL21, CCL1, and B-cell-activating factor) was increased in pancreatic and serum samples from patients. Up-regulation of these factors was not affected by corticosteroid treatment. Acinar-specific overexpression of LTαβ (Ela1-LTαβ) in mice led to an autoimmune disorder with various features of AIP. Chronic inflammation developed only in the pancreas but was sufficient to cause systemic autoimmunity. Acinar-specific overexpression of LTαβ did not cause autoimmunity in mice without lymphocytes (Ela1-LTab/Rag1(-/-)); moreover, lack of proinflammatory monocytes (Ela1-LTab/Ccr2(-/-)) failed to prevent AIP but prevented early pancreatic tissue damage. Administration of corticosteroids reduced pancreatitis but did not affect production of autoantibodies, such as antipancreatic secretory trypsin inhibitor in Ela1-LTab mice. In contrast, inhibition of LTβR signaling reduced chemokine expression, renal immune-complex deposition, and features of AIP in Ela1-LTab mice. CONCLUSIONS Overexpression of LTαβ specifically in acinar cells of mice causes features of AIP. Reagents that neutralize LTβR ligands might be used to treat patients with AIP.

p21WAF1/Cip1 limits senescence and acinar-to-ductal metaplasia formation during pancreatitis

Trans‐differentiation of pancreatic acinar cells into ductal‐like lesions, a process defined as acinar‐to‐ductal metaplasia (ADM), is observed in the course of organ regeneration following pancreatitis. In addition, ADM is found in association with pre‐malignant PanIN lesions and correlates with an increased risk of pancreatic adenocarcinoma (PDAC). Human PDAC samples show down‐regulation of p21WAF1/Cip1, a key regulator of cell cycle and cell differentiation. Here we investigated whether p21 down‐regulation is implicated in controlling the early events of acinar cell trans‐differentiation and ADM formation. p21‐mediated regulation of ADM formation and regression was analysed in vivo during the course of cerulein‐induced pancreatitis, using wild‐type (WT) and p21‐deficient (p21−/−) mice. Biochemical and immunohistochemical methods were used to evaluate disease progression over 2 weeks of the disease and during a recovery phase. We found that p21 was strongly up‐regulated in WT acinar cells during pancreatitis, while it was absent in ADM areas, suggesting that p21 down‐regulation is associated with ADM formation. In support of this hypothesis, p21−/− mice showed a significant increase in number and size of metaplasia. In addition, p21 over‐expression in acinar cells reduced ADM formation in vitro, suggesting that the protein regulates the metaplastic transition in a cell‐autonomous manner. p21−/− mice displayed increased expression and relocalization of β‐catenin both during pancreatitis and in the subsequent recovery phase. Finally, loss of p21 was accompanied by increased DNA damage and development of senescence. Our findings are consistent with a gate‐keeper role of p21 in acinar cells to limit senescence activation and ADM formation during pancreatic regeneration. Copyright

NIK promotes tissue destruction independently of the alternative NF-κB pathway through TNFR1/RIP1-induced apoptosis.

NF-κB-inducing kinase (NIK) is well-known for its role in promoting p100/NF-κB2 processing into p52, a process defined as the alternative, or non-canonical, NF-κB pathway. Here we reveal an unexpected new role of NIK in TNFR1-mediated RIP1-dependent apoptosis, a consequence of TNFR1 activation observed in c-IAP1/2-depleted conditions. We show that NIK stabilization, obtained by activation of the non-death TNFRs Fn14 or LTβR, is required for TNFα-mediated apoptosis. These apoptotic stimuli trigger the depletion of c-IAP1/2, the phosphorylation of RIP1 and the RIP1 kinase-dependent assembly of the RIP1/FADD/caspase-8 complex. In the absence of NIK, the phosphorylation of RIP1 and the formation of RIP1/FADD/caspase-8 complex are compromised while c-IAP1/2 depletion is unaffected. In vitro kinase assays revealed that recombinant RIP1 is a bona fide substrate of NIK. In vivo, we demonstrated the requirement of NIK pro-death function, but not the processing of its substrate p100 into p52, in a mouse model of TNFR1/LTβR-induced thymus involution. In addition, we also highlight a role for NIK in hepatocyte apoptosis in a mouse model of virus-induced TNFR1/RIP1-dependent liver damage. We conclude that NIK not only contributes to lymphoid organogenesis, inflammation and cell survival but also to TNFR1/RIP1-dependent cell death independently of the alternative NF-κB pathway.

The role of lymphotoxin signaling in the development of autoimmune pancreatitis and associated secondary extra-pancreatic pathologies

The pathogenic mechanisms of autoimmune pancreatitis (AIP), an increasingly recognized, immune-mediated form of chronic pancreatitis, have so far remained elusive. Treatment options for AIP are currently limited and disease relapse is frequent. Still, AIP can be characterized by specific clinical and histologic features. It has turned out that as described in other autoimmune diseases the generation of tertiary lymphoid organs is also a hallmark of patients with AIP. We have recently demonstrated that pancreata derived from human AIP patients display overexpression of lymphotoxin (LT) α and β and LTβR-target genes expressed by immune cells but also by irradiation resistant cells of the pancreas (e.g. acinar cells). Expression of LT α and β on acinar cells in murine pancreata Tg(Ela1-Lta,b) mice led to chronic pancreatitis and sufficed to reproduce key features of human AIP including the development of autoimmunity and AIP associated secondary extra pancreatic pathologies. Here, we review how aberrant and ectopic expression of LT α and β can induce inflammation and autoimmune diseases in general and how this knowledge might specifically lead to an alternative treatment for patients suffering from autoimmune pancreatitis.

Lymphotoxin’s Link to Carcinogenesis: Friend or Foe? From Lymphoid Neogenesis to Hepatocellular Carcinoma and Prostate Cancer

Tumor necrosis factor alpha (TNFα) was initially discovered due to its tumor necrotizing activity in mice, leading to the death of vascular endothelial cells. Today, pro- and anti-tumorigenic effects of TNF are discussed and TNF as well as other members of the TNF superfamily (TNFSF) were described to play an important role in the development and maintenance of lymphoid tissue and inflammatory reactions. Notably, recent reports indicate a pivotal role of lymphotoxin (LT), a closely related cytokine, in controlling the development of liver and prostate cancer or nasopharyngeal carcinoma – however by distinct mechanisms. Here, we review the pleiotropic functions attributed to LT, the effects of its deregulation and discuss recent literature on LT’s link to cancer.

Class I histone deacetylase inhibition improves pancreatitis outcome by limiting leukocyte recruitment and acinar‐to‐ductal metaplasia

Pancreatitis is a common inflammation of the pancreas with rising incidence in many countries. Despite improvements in diagnostic techniques, the disease is associated with high risk of severe morbidity and mortality and there is an urgent need for new therapeutic interventions. In this study, we evaluated whether histone deacetylases (HDACs), key epigenetic regulators of gene transcription, are involved in the development of the disease.

Inactivation of TGFβ receptor II signalling in pancreatic epithelial cells promotes acinar cell proliferation, acinar-to-ductal metaplasia and fibrosis during pancreatitis

Determining signalling pathways that regulate pancreatic regeneration following pancreatitis is critical for implementing therapeutic interventions. In this study we elucidated the molecular mechanisms underlying the effects of transforming growth factor‐β (TGFβ) in pancreatic epithelial cells during tissue regeneration. To this end, we conditionally inactivated TGFβ receptor II (TGFβ‐RII) using a Cre–LoxP system under the control of pancreas transcription factor 1a (PTF1a) promoter, specific for the pancreatic epithelium, and evaluated the molecular and cellular changes in a mouse model of cerulein‐induced pancreatitis. We show that TGFβ‐RII signalling does not mediate the initial acinar cell damage observed at the onset of pancreatitis. However, TGFβ‐RII signalling not only restricts acinar cell replication during the regenerative phase of the disease but also limits ADM formation in vivo and in vitro in a cell‐autonomous manner. Analyses of molecular mechanisms underlying the observed phenotype revealed that TGFβ‐RII signalling stimulates the expression of cyclin‐dependent kinase inhibitors and intersects with the EGFR signalling axis. Finally, TGFβ‐RII ablation in epithelial cells resulted in increased infiltration of inflammatory cells in the early phases of pancreatitis and increased activation of pancreatic stellate cells in the later stages of pancreatitis, thus highlighting a TGFβ‐based crosstalk between epithelial and stromal cells regulating the development of pancreatic inflammation and fibrosis. Collectively, our data not only contribute to clarifying the cellular processes governing pancreatic tissue regeneration, but also emphasize the conserved role of TGFβ as a tumour suppressor, both in the regenerative process following pancreatitis and in the initial phases of pancreatic cancer. Copyright