Contribution à l’étude du rôle de COMMD1 dans la physiopathologie de la mucoviscidose / COMMD1 promotes CFTR trafficking through inhibition of ubiquitination

Drévillon, Loïc

27 May 2009

La mucoviscidose (CF, Cystic Fibrosis) est la maladie génétique la plus fréquente dans les populations d’origine caucasienne. Les malades présentent une symptomatologie variée, dominée par une bronchopneumopathie chronique obstructive due à des sécrétions de mucus abondantes et anormalement épaisses et une réponse inflammatoire chronique excessive. La mucoviscidose résulte de mutations dans le gène codant la protéine CFTR (Cystic Fibrosis Transmembrane conductance Regulator), dont la plus fréquente est la délétion d’une phénylalanine en position 508 (F508del) qui est à l’origine d’un adressage défectueux et d’une fonction altérée de la protéine. Afin d’identifier différents partenaires moléculaires de CFTR qui participent à son processus de maturation, à son trafic à la membrane plasmique ou à sa fonction, un criblage double hybride de levure a été effectué en utilisant la troisième boucle intra-cytoplasmique de CFTR (ICL3) comme appât. A l’issue de ce criblage, 14 clones indépendants ont pu être identifiés dont la protéine COMMD1 qui a initialement été décrite comme un régulateur de l’homéostasie du cuivre, de l’absorption sodique et de la voie de signalisation NF-?B. L’objectif principal de ce travail a été de déterminer quel pouvait être l’impact de la protéine COMMD1 sur la maturation et le trafic intracellulaire de CFTR afin de déterminer le rôle de cette protéine dans la physiopathologie de la mucoviscidose. Nous avons montré que la protéine COMMD1 est un nouveau partenaire cytoplasmique du canal CFTR, qui régule le trafic intracellulaire de ce canal par inhibition de l’ubiquitinylation probablement au niveau des endosomes d’endocytose et de recyclage. Notre étude permet de proposer une nouvelle voie de trafic de CFTR via un modèle d’ubiquitinylation régulé par COMMD1. Au cours de cette étude, nous avons également identifié le récepteur 1 de la transferrine (TFR1) comme un nouveau partenaire de COMMD1 dont le mécanisme de régulation semble similaire à celui proposé pour CFTR. Dans un second temps, nous nous sommes intéressés aux propriétés inhibitrices de COMMD1 dans la réaction inflammatoire. COMMD1 a été décrit comme le prototype d’une nouvelle famille de protéines jouant un rôle dans l’inhibition de la voie de signalisation NF-kB. Nous avons observé que la distribution subcellulaire de COMMD1 est différente dans les cellules CF et non-CF. Nous avons mis en évidence que la surexpression de COMMD1 dans les cellules épithéliales bronchiques CF, qui présentent une inflammation excessive, pouvait restaurer un niveau d’inflammation comparable aux cellules non-CF. COMMD1 est impliquée dans plusieurs processus cellulaires altérés dans la physiopathologie de la mucoviscidose, affectant le trafic du canal CFTR, l’absorption de sodium et la réponse inflammatoire. Comprendre comment moduler d’une part le processus d’absorption/sécrétion des ions par le trafic de canaux ioniques et d’autre part, l’inflammation des cellules CF par rapport aux non-CF, devrait permettre d’identifier de nouvelles pistes thérapeutiques. Ces traitements permettraient à la fois de réduire la réaction inflammatoire exacerbée, sans nuire à l’activité essentielle de défense contre les pathogènes, et d’améliorer la sécrétion de fluide chez les patients atteints de mucoviscidose / Cystic fibrosis is mainly caused by mutations interfering with the biosynthetic folding of the CFTR protein. The aim of this study was to find proteins able to interact with CFTR and modify its processing. We have identified COMMD1 as a new CFTR partner. COMMD1 is a regulator of copper homeostasis and sodium uptake through interaction with ENaC, as well as the prototype of a new protein family that plays a role in inhibiting NF-?B signalling Co-immunoprecipitation experiments showed that COMMD1 associates with endogenous CFTR in HT29 cells and with F508del-CFTR in heterologously expressing epithelial cells. COMMD1 sub-cellular distribution is both nuclear and cytoplasmic, and more precisely in vesicular cytoplasmic compartments, as assessed by immunocytochemical microscopy. Further studies showed COMMD1 partial codistribution with an early endosomal compartments (TfR). COMMD1 is not involved in CFTR processing (C band) but wt-CFTR cell surface expression was halfreduced when COMMD1 expression was silenced. Unlike F508del-CFTR in temperature rescue, COMMD1 over-expression increased 15% wt-CFTR cell surface expression. Assessment of CFTR ubiquitination showed that COMMD1 over-expression strongly decreased CFTR ubiquitination therefore increasing CFTR cell surface expression. Finally, these data indicate that COMMD1 vesicular compartment is involved in CFTR trafficking through inhibition of CFTR ubiquitination. Understanding how COMMD1 modulation modifies transepithelial transport and inflammation in CF versus non CF cells should give new therapeutic clues to reduce exacerbated inflammation and improve fluid secretion in CF patients

CFTR

Ubiquitinylation

COMMD1

NF-?B

CFTR

Ubiquitination

COMMD1

NF-?B

Chemical biology approaches for the identification of novel p53 regulatory signalling pathways

Rusilowicz, Emma Victoria

January 2013

p53 is a critical tumour suppressor which acts to repair or remove abnormal cells and thus prevent cancer. Aberrant function of p53 is therefore a critical step in tumourigenesis and p53 is mutated in half of all cancers. Mutation of p53 leads to both a loss of normal wildtype function as well as the gain of oncogenic function. p53 is considered to be a promising therapeutic target and therapeutic strategies for targeting of the p53 pathway include: 1. Activation of wild-type p53 (wtp53) protein function, 2. Refolding of mutant p53 (mtp53) into the wtp53 conformation, 3. Reduction of mtp53 protein levels. In this work a number of small molecule screening assays were used to identify potentially novel regulators of both wtp53 and mtp53. Screening of a protein kinase inhibitor library for small molecules which can stimulate wtp53 activity identified the GSK3 pathway and a CDK pathway as dominant suppressors of wtp53 function. Screening of the library for inhibitors which reduce mtp53 protein levels led to the identification of two IKKβ inhibitors. The work then focused on investigating the effects of one of these compounds, IMD0354, on the mutant p53 pathway; with a specific focus on MDM2 as the most rapidly responding biomarker. IMD0354 is a well characterised inhibitor which has been shown to specifically inhibit IKKβ leading to the repression of the Nf-κB pathway. This study shows that IKKβ inhibition leads to the loss of a number of oncogenic proteins including mtp53, MDM2 and cyclin D. Mass-spectrometry based (ITRAQ) proteomic analysis was then employed to identify potential mediators and/or co-regulated factors in response to IKKβ-inhibition via IMD0354 treatment. This led to the identification of RPS3 as a potential negative regulator of MDM2 protein expression; the reduction in MDM2 protein in response to IMD0354 treatment is shown to be partially dependent on RPS3. Together this data has identified, using small molecule kinase inhibitor libraries: (i) dominant kinase signalling pathways that suppress wt-p53 and (ii) a dominant kinase signalling pathway that sustains expression of mutant p53 and MDM2 in cancer cell lines. This latter data supports further investigation to aid understanding of how the IKK signalling pathway cross-talks to the p53-MDM2 axis.

616.99

p53 ; MDM2 ; Nf-?B ; IKK ; ITRAQ

Efeito da suplementação com L-glutamina livre e na forma de dipeptídeo sobre eixo glutamina-glutationa, sistema imune, sistema inflamatório e vias de sinalização proteica em camundongos submetidos à endotoxemia / Effects of dietary supplementation with L-glutamine in the free and dipeptide forms on glutamine-glutathione axis, immune system, inflammatory system and protein signaling pathwaysin mice submitted to endotoxemia

Cruzat, Vinicius Fernandes

14 March 2013

A sepse é a principal causa de morte em unidades de terapia intensiva (UTIs) no mundo. A reduzida disponibilidade do aminoácido mais abundante do organismo, a glutamina contribui para o complicado estado catabólico da sepse. No presente estudo investigamos os efeitos da suplementação oral com L-glutamina e L-alanina (GLN+ALA), ambos na norma livre e como dipeptídeo, L-alanil-L-glutamina (DIP), sobre o eixo glutamina-glutationa (GSH), sistema imune, inflamação, proteínas de choque térmico (HSPs) e expressão de genes envolvidos com vias de sinalização proteica em animais endotoxêmicos. Camundongos C57/B6 foram submetidos à endotoxemia (Escherichia coli LPS, 5 mg.kg-1, grupo LPS) e suplementados por 48 horas com L-glutamina (1 g.kg-1) e L-alanina (0,61 g.kg-1, grupo GLN+ALA-LPS) ou 1,49 g.kg-1 de DIP (grupo DIP-LPS). A endotoxemia promoveu depleção da concentração de glutamina no plasma (71%), músculo esquelético (50%) e fígado (49%), quando comparado ao grupo CTRL, sendo restauradas nos grupos DIP-LPS e GLN+ALA-LPS (P<0,05), fato que atenuou a redução da GSH e o estado redox (taxa GSSG/GSH) em eritrócitos circulantes, musculo e fígado (P<0,05). A suplementação em animais endotoxêmicos resultou em uma upregulation dos genes GSR, GPX1 e GCLC no músculo e fígado. A concentração das citocinas plasmáticasTNF-&#945;, IL-6, IL-1&#946; e IL-10 foi atenuada pelas suplementações, bem como a expressão de mRNAs envolvidos com a resposta inflamatória, ativadas pela via do NF-&#954;B(P<0,05). Concomitantemente, verificou-se aumento da capacidade proliferativa de linfócitos T e B circulantes nos grupos GLN+ALA-LPS e DIP-LPS. A expressão de mRNAs e a concentração de HSPs no tecido muscular foi restabelecida pelas suplementações, contudo, a expressão mRNAs relacionados às vias de síntese e degradação proteica foi somente estimulada no tecido hepático(P<0,05). Os resultados do presente estudo demonstram que a suplementação por via oral com GLN+ALA ou DIP podem ser utilizados clinicamente como métodos nutricionais em reverter o quadro de depressão da disponibilidade de glutamina corporal da sepse induzida por LPS, tendo impacto no eixo glutamina-glutationa, sistema imune e inflamatório. / Sepsis is the leading cause of death inintensive care units (ICUs) in the world.The availability ofthe most abundant amino acid in the body, glutamine, is reduced in this situation, fact that contribute to the complicated catabolic state of sepsis. In the present study, we investigated the effects of oral supplementation with L-glutamine and L-alanine (GLN+ALA), both in their free form and as a dipeptide, L-alanyl-L-glutamine (DIP) on glutamine-glutathione axis (GSH), immune and inflammatory system, heat shock proteins (HSPs) expression and gene expressions involved in protein signaling pathways during endotoxemia. C57/B6 mice were subjected to endotoxemia (Escherichia coli LPS, 5 mg.kg-1, LPS group) and supplemented for 48 hours with L-glutamine (1 g.kg-1) plus L-alanine(0.61 g.kg-1, GLN+ALA-LPS group) or 1.49 g.kg-1of DIP (DIP-LPS group). Endotoxemia promoted depletion glutamine concentration in plasma (71%), skeletal muscle (50%) and liver (49%), when compared to the CTRL group, and was restored in the DIP-LPS e GLN+ALA-LPS (P<0.05), fact that attenuate the reduction of GSH and the redox state (GSSG/GSH rate) in circulating erythrocytes, liver and muscle (P<0.05). Supplementations in endotoxemic mice resulted in upregulation of GSR, GCLC and GPX1 genes in muscle and liver. Plasma concentration of TNF-&#945;, IL-6, IL-1&#946; and IL-10 were attenuated by supplementation as well as the expression of mRNAs involved in the inflammatory response, activated by NF&#954;-B pathway (P <0.05). At the same time, high proliferative capacity of circulating T and B lymphocytes GLN+ALA-LPS e DIP-LPS were observed. HSPs (protein and mRNAs) and in muscle were restored by the supplements, however, the mRNAs expression related to the synthesis and degradation of protein pathways was only stimulated in the liver (P <0.05). Our results demonstrate that oral supplementation with GLN+ALA or DIP can be used as clinically nutritional methods to reverse the depression of body glutamine availability during sepsis induced by LPS, impacting on the glutamine-glutathione axis, immune and inflammatory system.

Glutamina

Glutamine

GSH

GSH

HSP

HSP

NF-B

NF-B

Sepse

Sepsis

Efeito da suplementação com L-glutamina livre e na forma de dipeptídeo sobre eixo glutamina-glutationa, sistema imune, sistema inflamatório e vias de sinalização proteica em camundongos submetidos à endotoxemia / Effects of dietary supplementation with L-glutamine in the free and dipeptide forms on glutamine-glutathione axis, immune system, inflammatory system and protein signaling pathwaysin mice submitted to endotoxemia

Vinicius Fernandes Cruzat

14 March 2013

A sepse é a principal causa de morte em unidades de terapia intensiva (UTIs) no mundo. A reduzida disponibilidade do aminoácido mais abundante do organismo, a glutamina contribui para o complicado estado catabólico da sepse. No presente estudo investigamos os efeitos da suplementação oral com L-glutamina e L-alanina (GLN+ALA), ambos na norma livre e como dipeptídeo, L-alanil-L-glutamina (DIP), sobre o eixo glutamina-glutationa (GSH), sistema imune, inflamação, proteínas de choque térmico (HSPs) e expressão de genes envolvidos com vias de sinalização proteica em animais endotoxêmicos. Camundongos C57/B6 foram submetidos à endotoxemia (Escherichia coli LPS, 5 mg.kg-1, grupo LPS) e suplementados por 48 horas com L-glutamina (1 g.kg-1) e L-alanina (0,61 g.kg-1, grupo GLN+ALA-LPS) ou 1,49 g.kg-1 de DIP (grupo DIP-LPS). A endotoxemia promoveu depleção da concentração de glutamina no plasma (71%), músculo esquelético (50%) e fígado (49%), quando comparado ao grupo CTRL, sendo restauradas nos grupos DIP-LPS e GLN+ALA-LPS (P<0,05), fato que atenuou a redução da GSH e o estado redox (taxa GSSG/GSH) em eritrócitos circulantes, musculo e fígado (P<0,05). A suplementação em animais endotoxêmicos resultou em uma upregulation dos genes GSR, GPX1 e GCLC no músculo e fígado. A concentração das citocinas plasmáticasTNF-&#945;, IL-6, IL-1&#946; e IL-10 foi atenuada pelas suplementações, bem como a expressão de mRNAs envolvidos com a resposta inflamatória, ativadas pela via do NF-&#954;B(P<0,05). Concomitantemente, verificou-se aumento da capacidade proliferativa de linfócitos T e B circulantes nos grupos GLN+ALA-LPS e DIP-LPS. A expressão de mRNAs e a concentração de HSPs no tecido muscular foi restabelecida pelas suplementações, contudo, a expressão mRNAs relacionados às vias de síntese e degradação proteica foi somente estimulada no tecido hepático(P<0,05). Os resultados do presente estudo demonstram que a suplementação por via oral com GLN+ALA ou DIP podem ser utilizados clinicamente como métodos nutricionais em reverter o quadro de depressão da disponibilidade de glutamina corporal da sepse induzida por LPS, tendo impacto no eixo glutamina-glutationa, sistema imune e inflamatório. / Sepsis is the leading cause of death inintensive care units (ICUs) in the world.The availability ofthe most abundant amino acid in the body, glutamine, is reduced in this situation, fact that contribute to the complicated catabolic state of sepsis. In the present study, we investigated the effects of oral supplementation with L-glutamine and L-alanine (GLN+ALA), both in their free form and as a dipeptide, L-alanyl-L-glutamine (DIP) on glutamine-glutathione axis (GSH), immune and inflammatory system, heat shock proteins (HSPs) expression and gene expressions involved in protein signaling pathways during endotoxemia. C57/B6 mice were subjected to endotoxemia (Escherichia coli LPS, 5 mg.kg-1, LPS group) and supplemented for 48 hours with L-glutamine (1 g.kg-1) plus L-alanine(0.61 g.kg-1, GLN+ALA-LPS group) or 1.49 g.kg-1of DIP (DIP-LPS group). Endotoxemia promoted depletion glutamine concentration in plasma (71%), skeletal muscle (50%) and liver (49%), when compared to the CTRL group, and was restored in the DIP-LPS e GLN+ALA-LPS (P<0.05), fact that attenuate the reduction of GSH and the redox state (GSSG/GSH rate) in circulating erythrocytes, liver and muscle (P<0.05). Supplementations in endotoxemic mice resulted in upregulation of GSR, GCLC and GPX1 genes in muscle and liver. Plasma concentration of TNF-&#945;, IL-6, IL-1&#946; and IL-10 were attenuated by supplementation as well as the expression of mRNAs involved in the inflammatory response, activated by NF&#954;-B pathway (P <0.05). At the same time, high proliferative capacity of circulating T and B lymphocytes GLN+ALA-LPS e DIP-LPS were observed. HSPs (protein and mRNAs) and in muscle were restored by the supplements, however, the mRNAs expression related to the synthesis and degradation of protein pathways was only stimulated in the liver (P <0.05). Our results demonstrate that oral supplementation with GLN+ALA or DIP can be used as clinically nutritional methods to reverse the depression of body glutamine availability during sepsis induced by LPS, impacting on the glutamine-glutathione axis, immune and inflammatory system.

Glutamina

GSH

HSP

NF-B

Sepse

Glutamine

GSH

HSP

NF-B

Sepsis

NF-κB-regulated differential gene transcription : a systems biology analysis

Daniels, Damon

January 2015

The NF-κB transcription factor is expressed in the majority of mammalian cells and regulates a large number of genes with important functions in a variety of cellular processes including cell growth, division, apoptosis and inflammatory responses. Perturbation of NF-κB response has been implicated in a variety of diseases such as asthma and inflammatory bowel disease, in addition to various forms of cancer. Through experiments at the single cell level it has been shown that NF-κB displays complex temporal activation, notably including nucleo-cytoplasmic oscillations. It has been observed that these oscillations occur in a heterogeneous manner; as such they are masked when measured at the population level. In contrast, pulsed TNFα treatment at 100 min intervals produces regular and synchronous nuclear peaks of NF-κB. Such pulsatile stimulation may reflect more accurately physiological conditions. The work in this project uses a Systems Biology approach consisting of bioinformatic, mathematical, and experimental methodologies to investigate how NF-κB can regulate such a diverse set of gene responses. Previously published studies have proposed that target gene expression levels following NF-κB activation (continuous TNFα) can be explained by a combination of key parameters, including transcript degradation rate, transcript structure, and transcription initiation rate. Initial work in this project highlighted that these explanatory factors are not sufficient to describe the observed temporal order of gene transcription. The roles of miRNAs and NF-κB subunit phosphorylation in regulation were additionally explored. A large set of genes was identified that are activated more strongly by pulsed TNFα than by continuous TNFα treatment. This suggests a new unreported mechanism of gene regulation, the possible causes of which are examined in this thesis. The gene list was refined by altering pulse frequency, which revealed an enrichment of NF-κB targets correlated with the regularity of these pulses. Temperature shift and anti-inflammatory drug treatment (Diclofenac) were shown to have a profound effect on NF-κB oscillation frequency. These perturbations provide an alternative method to study the effects of NF-κB oscillation frequency on specific target genes, independent of a pulse regime. Integration and analysis of these datasets suggested that a core, frequency-encoded set of genes regulated by NF-κB might exist. It is proposed that such genes may respond optimally to specific frequencies of NF-κB activation, implying a potential frequency threshold. The presence of such genes may explain the need for the complex systems that control NF-κB timing. It was noted that there was an enrichment of genes encoding transcription factors within the frequency encoding set, in addition to proteins which are known to be involved in the control of inflammation.

570

Autophagy- and TBK1-mediated regulation of TRAF2/3 in alternative NF-κB signalling

Newman, Alice Clare

January 2016

Autophagy is a core cytoplasmic degradation process. It is established that KRas-mutant lung cancer cells require basal autophagy for survival. However, the mechanisms that govern this are poorly understood. It has recently been suggested that selective autophagic degradation of signalling complexes may regulate downstream cell signalling pathways. Primarily, this thesis aims to uncover molecular mechanisms through which selective autophagy can regulate signalling pathways that may impact upon cancer cell proliferation. Previous work in the lab identified a putative interaction between the signalling protein TRAF3 and the autophagy protein Ndp52 via mass spectrometric screening. In this thesis I have identified TRAF3 as a target of selective autophagy in both KRas-mutant lung cancer cells and in in vitro transformed MEFs. TRAF3 is a negative regulator of a gene expression regulation pathway called alternative NF-κB. As such, autophagy of TRAF3 promotes basal activation of the alternative NF-κB signalling pathway. This basal activity supports the proliferation of cancer cells. Investigation of TRAF2, a protein closely related to TRAF3, revealed that it too associates with the autophagy pathway, but is not degraded. This is promoted by the activity of TBK1, which itself can phosphorylate TRAF2. Both TBK1 and TRAF2 promote alternative NF-κB signalling, and I investigate possible mechanisms underlying this, including changes in TRAF3 mRNA and protein levels and binding to other alternative NF-κB regulators. This thesis therefore identifies mechanisms through which basal alternative NF-κB signalling is regulated in KRas-mutant lung cancer cells, with implications for cell proliferation. Ultimately, this work provides valuable mechanistic insight to inform the use of autophagy and/or TBK1 inhibition in future cancer therapies.

New roles for B-cell lymphoma 10 in the nucleus

Dronyk, Ashley D

06 1900

Radiation therapy targets cancer cell death by overwhelming cells with harmful DNA damage. Understanding how cells repair radiation damage and in particular how they become resistant to radiation therapy is important for effective cancer treatment. Our lab made the novel discovery that Bcl10, a cytoplasmic protein important for NF-B activation, localizes to endogenous H2AX foci in the nucleus of breast cancer cells. We determined that following radiation treatment Bcl10 is recruited to ionizing radiation-induced foci in a dose-dependent matter and that it is important for the repair of radiation-induced DNA damage. We also observed that breast cancer cells are extremely sensitive to Bcl10 knockdown, causing cellular senescence, while normal breast epithelial cells are insensitive. Our findings identify Bcl10 as potent anti-cancer target. / Experimental Oncology

Bcl10

DNA double strand break

NF-B

DNA repair

H2AX

Biochemical Mechanism of Protein Kinase Activation by the Ubiquitnation System

Xia, Zong-Ping

January 2008

Dissertation (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2008. / Vita. Bibliography: p.126-146

Attenuation of the Host Innate Cytokine Response by the Human Cytomegalovirus Immediate-Early 2 Protein le86

Taylor, Roger Travis

January 2006

Dissertation (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2006. / Vita. Bibliography: p.148-174

Investigating the development and function of M cells

Sehgal, Anuj

January 2017

Gut-associated lymphoid tissues such as Peyer’s patches (PP) are inductive sites for immune response in the intestine. Unlike other peripheral lymphoid tissues, gut-associated lymphoid tissues lack afferent lymphatics and can directly sample mucosal antigens by specialized epithelial cells in the follicular associated epithelia (FAE), known as M cells. M cells derive from Lgr5+ intestinal stem cells in intestinal crypts, where the daughter cells of Lgr5+ cells differentiate into M cells after stimulation from the cytokine receptor activator of nuclear factor-κB ligand (RANKL). RANKL is produced by stromal cells within the sub-epithelial dome (SED) residing below the FAE. The transcytosis of antigens across the FAE by M cells is an important initial step in the induction of efficient mucosal immune responses against certain pathogenic bacteria as well as the commensal bacterial flora. However some pathogens, for example orally-acquired prions, may also exploit M cells to infect the host. M cells have been implicated in the uptake of orally acquired prions from the gut lumen. After oral exposure, the accumulation of prions in PP is important for their efficient spread to the nervous system. Previous studies have also shown that pathogen-induced inflammation increases M cell density and this effect can be mimicked by exogenous administration of RANKL. This has led to the hypothesis tested in this thesis that inflammation-related enhancement of M cell differentiation aids the delivery of prions into the lamina propria of villi. The administration of RANKL resulted in increased M cell density in the gut epithelium of mice. Consequently, RANKL treatment enhanced the accumulation of orally-administered prions in PP, decreased disease incubation time and increased prion disease susceptibility. These data indicate the importance of M cells in prion disease pathogenesis and highlight the potential of M cells as vaccine targets against prion disease. The fate and terminal differentiation of distinct intestinal epithelial cell lineages from their uncommitted precursors is dependent on their intrinsic expression of one or more specific transcription factors during their development. Alongside inducing M cell differentiation, RANKL stimulation can also induce the nuclear translocation of the NF-κB transcription factor subunit c-Rel. A comparison of the genes encoding the individual NF-κB subunits c-Rel, Rel-A and Rel-B revealed that they were expressed at the mRNA level in the FAE and by M cells. A c-Rel-deficiency in mice did not influence the expression of RANKL or RANK in PP. The subsequent induction of M cell maturation in the FAE was also unaffected in, indicating that c-Rel is dispensable for the RANKL-mediated differentiation and functional maturation of M cells. The factors implicated in Lgr5+ intestinal stem cell proliferation and their differentiation into M cells are poorly understood. Some reports have indicated that crypt-associated macrophages may provide extrinsic factors that assist Lgr5+ intestinal stem cell proliferation. In this thesis, the ablation of macrophages in the gut resulted in dysregulation of crypt microarchitecture, depleting Paneth cells and the Lgr5+ stem cells. This adversely affected the subsequent differentiation of intestinal epithelial cell lineages and impeded the functional development of M cells. These data reveal a previously unknown role for macrophages in the maintenance of intestinal crypts and intestinal stem cell proliferation and differentiation.