The role of the spleen in Malaria : Cellular changes that affect the development of immunity

Beattie, Lynette

January 2006

Malaria, caused by the apicomplexan parasite Plasmodium, is a major cause of morbidity and mortality throughout the world. This study has focused on the role of the spleen in the control of the blood stage of infection. Three aspects have been examined specifically: the effect of infection on the architecture of the spleen, the role of the spleen in parasite clearance and the formation of B cell memory. Firstly, the effect of infection on the splenic microarchitecture was examined. An essential component of the splenic architecture is the marginal zone (MZ), an area of the spleen that separates the reticuloendothelial red pulp of the spleen from the lymphoid white pulp compartment. Two unique populations of macrophages are found in the marginal zone: marginal zone macrophages (MZM) and marginal metallophilic macrophages (MMM). In the current study, parasitised red blood cells (pRBC) as well as normal RBC located to the MZ thirty minutes after intravenous injection and formed close associations with both MMM and MZM. Eight days after infection, at the time of peak parasitemia, a complete loss of both MMM and MZM was observed. Assays to detect cell death revealed that the loss of both MMM and MZM appeared to occur as a result of apoptosis. The apoptosis was not induced by up regulation of the inflammatory cytokines tumour necrosis factor or interferon-γ and could not be blocked by over expression of the apoptosis inhibitor Bcl2. Significantly, MMM were retained in the absence of CD8+ T cells implicating CD8+ T cells in the loss of MMM. Finally, infection of CD95-/- mice demonstrated that CD95/CD95-ligand (Fas/Fas-ligand) interactions were responsible for some of the CD8+ T cell-mediated loss of MMM. These data provide evidence for a novel interaction between MMM and CD8+ T cellsfollowing infection with Plasmodium. Secondly, the role of the spleen in the control of parasitemia and disease was monitored with an emphasis on determining the role of splenic macrophage populations (MMM, MZM and red pulp macrophages [RPM]) in parasite clearance. A clodronate liposome-mediated macrophage depletion technique was used, and caused a complete loss of all three macrophage sub-populations, as well as 50% of splenic dendritic cells, within 24 hours of administration. Each of the macrophage populations, as well as splenic DC, demonstrated different repopulation kinetics following their depletion from the spleen and these kinetics were utilised to examine each cell population in isolation. RPM depleted mice had significantly higher peak parasitemias than the controls. This peak returned to the level observed in undepleted control animals only after the repopulation of RPM was complete, suggesting that RPM play a role in the control of peak parasitemia following infection. Neither MMM nor MZM played a role in the control of parasitemia. The role of non-splenic macrophages and splenic dendritic cells also was investigated and shown to be insignificant in the absence of splenic macrophages. Finally, the role of RPM in mice immune to infection was investigated and their role shown to be dispensable, with immune mice clearing parasitemia efficiently in the absence of RPM. RPM therefore are important for the innate control of infection with P. chabaudi but are dispensible once adaptive immunity is established. Finally, the role of the spleen in the development of parasite-specific B cell memory was examined. Initial studies demonstrated that germinal centre (GC) development was compromised following infection with P. chabaudi, with an involution of B cell follicles noted early in infection. Adoptive transfer of memory B cells from immunised to naïve mice demonstrated that some protection was conferred on recipient mice by parasite-specific memory B cells. But, the memory B cells could not protect the host from developing parasitemia and did not produce significant amounts of parasite-specific immunoglobulin within seven days of challenge infection. Memory B cells could not be detected ten weeks after infection, indicating that the development, or survival, of parasite-specific memory B cells was compromised. The development of bystander memory B cells was not affected by infection. Finally, long-lived plasma cells were shown to develop in response to infection, although re-exposure of the cells to parasites in the form of recrudescent parasitemia resulted in their loss. This study therefore has identified a defect in the development of long-term, B cell-mediated, protection against infection with P. chabaudi. Each of these factors has significant implications for the understanding of how the spleen contributes to the control of infection with Plasmodium and potential applications for the further development of malaria vaccines and treatment regimens.

Malaria

Plasmodium

spleen

splenic architecture

marginal zone

marginal metallophilic macrophages

marginal zone macrophages

immunopathology

cytotoxic T cells

red pulp macrophages

adaptive immunity

innate immunity

humoral memory

memory B cells

long-lived plasma cells

Immunophänotypisierung des entzündlichen Infiltrates der Arthrose assoziierten Synovialitis

Ristow, Gerhard

07 April 2003

Die Entzündungsreaktion der Arthrose wird als eine sekundäre Reaktion auf einen degenerativen Prozeß des Gelenkknorpels angesehen. Die Ursache für die Degeneration kann im Mißverhältnis zwischen Belastbarkeit und Beanspruchung liegen, es können metabolische Störungen (Urämie, Diabetes mellitus) verantwortlich gemacht werden, weswegen von sekundärer Arthrose gesprochen wird. Die Ursache der primären Arthrose bleibt unbekannt. Es kann als bewiesen angesehen werden der Zusammenhang mit Alter und Geschlecht der Patienten, denn Arthrose ist in der Regel eine Erkrankung jenseits des fünfzigsten Lebensjahres und betrifft vornehmlich Frauen. In der vorliegenden Arbeit wurde die Synovialis von 20 Patienten aufgearbeitet und hinsichtlich des enthaltenen entzündlichen Infiltrates untersucht. Unter Anwendung der indirekten Immunperoxidase Technik und der indirekten Immunfluoreszenz Technik wurde die Expression der Antigene CD 20, CD 23, CD 40, CD 27, IgG, IgA, IgM, Kappa, Lambda, CD 3, CD 4, CD 8, Ki M4, CD 68, Ki 67 sowie die Expression der Cytokine IL 2 und IL 10 analysiert. Die Synovialmembran zeigte histologisch eine Verbreiterung der Deckzellschicht, Knorpelfragmente innerhalb der Synovialmembran und ein insgesamt schwach ausgeprägtes entzündliches Infiltrat. In lediglich drei von 20 Fällen fand sich eine stärkere entzündliche Infiltration. Diese entzündlichen Infiltrate wiesen eine perivaskuläre Verteilung auf. Am häufigsten wurden in gefäßnahen Regionen B Lymphozyten identifiziert, Plasmazellen wiesen in der Regel einen deutlich größeren Abstand zum Gefäß auf. Unter den nachgewiesenen Plasmazellen fand sich eine prädominante Expression an IgG bei ausgewogener Anwesenheit sowohl der Kappa- als auch der Lambda- Leichtketten. T Lymphozyten waren ebenfalls zirkulär um die Gefäße anzutreffen und zeigten eine prädominante Interleukin 10 Expression. Lymphozytäre Aggregate, mit follikelähnlicher Struktur ließen sich in lediglich in 4 von 20 Fällen nachweisen. Makrophagen waren sowohl perivaskulär als auch in der Deckzellschicht nachweisbar. Ki M4 positive Retikulumzellen (FDC) waren dagegen nur in einem von 20 Fällen nachweisbar. Alle Zellpopulationen der Membrana synovialis wiesen nur eine schwache Proliferationsaktivität auf. Das Fehlen von dem Keimzentrum des Lymphfollikels vergleichbaren Strukturen, die deutliche Abwesenheit von Ki M4 positiver FDC's sowie die schwache Expression von Ki 67, sprechen trotz Anwesenheit der ebenfalls zur Antigenpräsentation befähigten Makrophagen gegen eine Einwanderung und Maturation nativer B Lymphozyten in die Membrana Synovialis. Wandern dagegen Gedächtniszellen in die Membrana synovialis ein, so ist eine Maturation mit Follikelbildung nicht mehr notwendig. Unter der Mithilfe von T Lymphozyten und Makrophagen können die B Lymphozyten zu Plasmazellen differenzieren. T Lymphozyten zeichnen sich ebenfalls durch eine starke perivaskuläre Verteilung aus. Dabei ist die Expression von IL 10 prädominant, was sich als eine Immunantwort von TH2-Typus interpretieren läßt. Diese ermöglicht eine Differenzierung der B Lymphozyten zu Plasmazellen. Reife B Lymphozyten, die unter dem Einfluß einer TH2 Subpopulation von CD 4 positiven T Lymphozyten ohne Keimzentrum zu Plasmazellen differenzieren, könnten ein Grund dafür sein, daß follikuläre Strukturen fehlen. Vorgereifte B Lymphozyten benötigen auch keine inflammatorisch hochpotenten Zytokine um eine schnelle Reifung und eine Immunantwort zu ermöglichen. Dies könnte ein Grund sein, warum die entzündliche Reaktion bei Arthrose so schwach ausgeprägt ist. / Inflammation in osteoarthritis is a secondary reaction to a degenerating process of the articular cartilage. Cause of Degeneration can be a disproportion of mechanical stress and resistance or metabolic diseases like diabetes mellitus. This kind of osteoarthritis is called "secondary osteoarthritis". Primary osteoarthritis has an unknown cause. Age and sex of the patient are a predictor for osteoarthritis, hense it is a disease of people above the age of 50 and more often it is found in women than in men. This paper investigated the synovial membranes of twenty patients to characterize the inflammatory Infiltrate. It characterized the cell surface antigen CD 20, CD 23, CD 40, CD 27, CD 3, CD 4, CD 8, Ki M4, CD 68, the antibodies IgG, IgA, IgM, Kappa, Lambda, the proliferating antigen Ki 67 and the expression profile of the cytokines IL 2 and IL 10 by using immunohistochemical staining (indirect immunoperoxidase technique and indirect immunofluorescence technique) with monoclonal antibodies. The synovial membrane shows in histology a dissemination of cover cells, fragments of cartilage and a slight expression of inflammatory infiltrate with a perivascular allocation. In only three of twenty cases we detected stronger inflammatory infiltrates. Most of the perivascular cells express CD 20. They are B lymphocytes. Plasma cells have more distance to the blood vessels and showed a predominant expression of IgG. T-lymphocytes were also detected perivascular. The expression of IL 10 was predominant. Lymphocytes aggregates like lymph follicle were detected in four of twenty cases. Macrophages were proved perivascular as well as in the cover cells. Ki M4 positive reticulum cells were found in only one of twenty cases. All kind of cells in the synovial membrane showed a low proliferation activity. The absence of germinal centers or comparable structures, the low expression of Ki M4 and Ki 67 speak against the immigration and maturation of native B lymphocytes in the synovial membrane. Memory B-lymphocytes don't need germinal centers or compatible structures for maturation, they can mature to plasma cells by help of T-lymphocytes, macrophages or other B-lymphocytes. It is more probably that the detected B lymphocytes are memory cells. The perivascular T lymphocytes in combination with the predominant expression of IL 10 may be interpreted as a TH2 immune reaction. This supports the maturation of B-lymphocytes to plasma cells. The maturation of memory B-lymphocytes under influence of TH2 immune reaction can be the reason for the missing of germinal centers or comparable structures. Matured B-lymphocytes don't need high-grade inflammatory cytokines for quick immune response. This is the possible reason for the low-grade inflammatory reaction of osteoarthritis.

Makrophagen

CD20

Arthrose

B Lymphozyten

T Lymphozyten

Plasmazellen

follikulär-dendritischen Zellen

Cytokin

Interleukin

CD4

FDC

Ki M4

Ki 67

IL 2

IL 10

macrophages

CD20

osteoarthritis

B-lymphocyte

T- lymphocyte

plasma cells

reticular cells

cytokine

interleukins

CD4

FDC

Ki M4

Ki 67

IL 2

IL 10

610 Medizin

33 Medizin

YK 2000

ddc:610

Impact de la production des immunoglobulines tronquées sur le développement lymphocytaire B normal et tumoral / Impact of producing truncated immunoglobulins on normal and tumoral B lymphocyte development

Srour, Nivine

05 April 2016

Le processus de recombinaison V(D)J des gènes d’immunoglobulines (Ig) est caractérisé par une grande imprécision des jonctions entre les segments variables (V), de diversité (D) et de jonction (J). Deux fois sur trois, un décalage du cadre de lecture apparaît, aboutissant à une jonction non productive dite « hors phase ». Plusieurs études ont démontré que les deux allèles productifs et non-productifs sont activement transcrits. Les transcrits matures issus des allèles non-productifs sont pris en charge par un mécanisme de surveillance des ARNm appelé NMD « Nonsense-Mediated mRNA Decay ». En dégradant efficacement les ARNm d’Ig contenant des codons non-sens, ce mécanisme prévient l’apparition des Ig tronquées au cours de l’ontogénie B. Néanmoins, aucune étude n’a jusqu’ici analysé l’impact de l’épissage alternatif des transcrits d’Ig non-productifs. Ce phénomène appelé NAS « Nonsense-associated Altered Splicing » peut conduire à une production d’Ig tronquées présentant des délétions internes du domaine variable (V).Les projets développés lors de cette thèse ont montré que la présence d’un codon non-sens, au niveau de l’exon variable (VJ) des transcrits Igκ, favorise le saut d’exon et la production de chaînes légères dépourvues de domaine variable (ΔV-κLCs). De façon intéressante, ces Ig tronquées provoquent un stress cellulaire et conduisent à l’apoptose des plasmocytes (Article 1). Ces observations ont permis d’identifier un nouveau point de contrôle agissant tardivement lors de la différenciation plasmocytaire : le TIE « Truncated-Ig Exclusion » checkpoint. Ce processus de contrôle provoque l’élimination des plasmocytes qui produisent des chaînes d’Ig tronquées. Nous avons également étudié l’épissage alternatif des transcrits d’Ig non-productifs en l’absence de TIE-checkpoint (Article 2). Cette étude a révélé que l’hypertranscription des gènes d’Ig dans les plasmocytes favorise l’épissage alternatif des transcrits d’Ig non-productifs. En utilisant un modèle d’expression forcée d’Ig tronquées, nous avons mis en évidence une coopération entre les mécanismes assurant la surveillance des ARNm (NMD) et la surveillance au niveau protéique (UPR : « Unfolded Protein Response », autophagie) (Article 3). Sur la base de ces résultats, nous avons mis au point une nouvelle approche thérapeutique qui consiste à forcer la production d’Ig tronquées en utilisant des oligonucléotides anti-sens (AON) capables de provoquer l’élimination de l’exon variable lors de l’épissage. Cette invention pourrait ouvrir des perspectives thérapeutiques pertinentes dans le traitement du Myélome Multiple et d’autres pathologies touchant les plasmocytes. / The recombination process V(D)J of immunoglobulin (Ig) genes is characterized by random junctions between the variable (V), diversity (D) and joining (J) segments. A frameshift mutation appears in two-third of cases, generating a non-productive or « out of frame » junction. Several studies have shown that both productive and non-productive alleles are actively transcribed. The mature transcripts from nonproductive alleles are usually considered sterile and innocuous as a result of an mRNA surveillance mechanism called NMD « Nonsense-Mediated mRNA Decay ». By degrading aberrant mRNA, this mechanism prevents the appearance of truncated Ig during B cell ontogeny. However, less is known about the impact of alternative splicing on non-productive Ig transcripts. This mechanism, called NAS « Nonsense-associated Altered Splicing » can lead to the production of truncated Ig with internal deletions of variable domain (V). During my thesis, we have shown that the presence of a stop codon, within the variable exon (VJ) of Igκ transcripts, promotes exon skipping and synthesis of V domain-less κ light chains (ΔV-κLCs). Interestingly, such truncated Ig causes cellular stress and leads to plasma cells apoptosis (Article 1). These findings have identified a new checkpoint acting late during plasma cell differentiation: TIE « Truncated-Ig Exclusion » checkpoint. This process ensures counter-selection of plasma cells producing truncated-Ig. We also studied the alternative splicing of non-productive Ig transcripts in the absence of TIE-checkpoint (Article 2). We found that hypertranscription of Ig genes in plasma cells promote alternative splicing of non-productive Ig transcripts. Using a model forcing the expression of truncated Ig, we identified a cooperative action between mRNA surveillance mechanisms (NMD) and those of protein surveillance (UPR « Unfolded Protein Response », autophagy) (Article 3). Based on these results, we have developed a new therapeutic approach by increasing the production of truncated Ig using antisense oligonucleotides (AON) that leads to the elimination of the variable exon during splicing. This invention could open new avenues for the treatment of Multiple Myeloma patients and other pathologies affecting plasma cells.

Plasmocytes

Immunoglobulines (Ig)

Ig tronquées

Surveillance des ARN

NMD (Nonsense-Mediated mRNA Decay)

UPR (Unfolded Protein Response)

Plasma cells

Immunoglobulins (Ig)

Truncated-Ig

RNA surveillance

NMD (Nonsense-Mediated mRNA Decay)

UPR (Unfolded Protein Response)

615.37