Regulation of B cell response to respiratory viruses

Sundararajan, Aarthi

01 August 2011

Viruses replicating in the respiratory tract (RT) triggers a wide- range of cytokines and chemokines that have antiviral and pro-inflammatory features, instigating an efficient virus- specific B and T cell response that aids in virus- clearance. The majority of antibody secreting cells (ASCs) localizing in the upper RT secrete IgA that can effectively neutralize viruses. In addition, elements of B cell memory are generated that can provide protection from re-infection. Studies examining these aspects, following murine gammaherpesvirus 68 (MHV-68) infection comprise chapter 2 of the dissertation work. Our studies demonstrate that following MHV-68 infection, unlike influenza infection, resulted in a generalized deficiency of virus-specific IgA induction and deficient B cell memory establishment in the respiratory tract. The studies indicate that these aspects of B cell response are regulated by features of virus- replication in the RT. These studies lead to the speculation that these features of B cell response may represent an evolutionary adaptation of viruses that establish long-term latency and are transmitted periodically after reactivation and shedding in secretions. Following cognate interactions with CD4+ T cells, the B cells undergo proliferation, isotype-switching and differentiate towards extrafollicular (low affinity, rapid) or germinal center pathway (high affinity). It is not clear what factors regulate these pathways of B cell differentiation, especially in the context of virus infection in the RT. Studies examining these aspects following influenza infection comprise chapter 3 of the dissertation work. Our studies establish a model for the investigation of host and viral factors that modulate the quality and effectiveness of the B cell response to influenza infection. The findings indicate that the strength of the extrafollicular B cell response depends on the nature of the infecting virus. We present evidence that this pathway of rapid antiviral antibody production relates to the production of non-specifically acting factors in the lung and also dependent of the cytokine profile of virus-specific CD4+T cells. In summary, the current dissertation findings point out to an influence of virus and host associated factors in regulating features of B cell response in the RT.

B cell

Respiratory tract

MHV-68

Influenza

IgA

Immunology

Immunology of Infectious Disease

Influenza-specific B cell responses in HLA-DR1 transgenic mice

Huan, Lifang

01 August 2010

HLA-DR1 transgenic (DR1 Tg) mice provide a model for evaluating the breadth and specificity of CD4 T cell responses that may develop in humans following influenza infection or vaccination. Recent studies identified a tremendously broad HLA-DR1-restricted CD4 T cell responses in DR1 Tg mice infected intranasally with influenza A/New Caledonia/20/99 (NC). In this study, our goals were to characterize B cell responses after NC infection in DR1 Tg mice and establish the correlation between B cell responses and CD4 T cell responses in this system. Influenza-specific B cell responses following virus administration were analyzed in DR1 Tg mice and in the genetically matched H-2b strain C57BL/10J (B10). Following intranasal (i.n.) NC infection, B cell responses in B10 mice featured strong IgG2b and IgG2c production and were typical of previously described B cell responses to a variety of mouse-adapted influenza strains. In contrast, B cell responses in DR1 Tg mice followed delayed kinetics and were strongly skewed to IgG1 production, suggesting the Th2 polarization of CD4 T cell responses. The different antibody isotype profile in DR1 Tg mice compared to B10 mice was evident in antibody secreting cells (ASCs) frequencies and in circulating Abs levels. Surprisingly, although DR1 Tg mice had lower influenza-specific Abs levels, they exhibited higher neutralizing Abs titers early in the response. B cell responses following intranasal infection of influenza A/Puerto Rico/8/1934 (PR8) or intramuscular vaccination of inactivated NC in DR1 Tg mice were different from the observed IgG1 bias after i.n. NC infection. After i.n. PR8 infection, B cell responses were similar in DR1 Tg mice and B10 mice, characterized by predominant IgM/IgG3 production. Additionally, following intramuscular administration of inactivated NC, B cell responses were skewed towards IgG2c production in both DR1 Tg mice and B10 mice, suggesting the Th1 polarization of CD4 T cell responses. A mechanistic understanding of IgG1/Th2 biased B cell responses and better neutralizing Abs production in DR1 Tg mice following i.n. NC infection may have implications for the optimal control of influenza infection.

HLA-DR1 transgenic mice

influenza virus

B cell responses

IgG1

Microbiology

The Effects of Chronic Restraint Stress on Innate and Adaptive Immune Responses to Acute Theiler?s Murine Encephalomyelitis Virus Infection ? An Animal Model of Human Multiple Sclerosis

Steelman, Andrew Jonathan

15 May 2009

Multiple sclerosis (MS) is an immune-mediated prevalent chronic demyelinating and neurodegenerative disease of the central nervous system that begins with an abrupt onset during early adulthood. MS is idiopathic, but many factors are thought to influence the pathogenesis of the disease, which include genetic, gender and environmental factors. To date, there is much evidence that suggest that both the onset and progression of MS is facilitated by both viral infections and stress. Theiler’s murine encephalomyelitis virus (TMEV) is a picornavirus that upon inoculation into susceptible strains of mice (i.e. SJL and CBA) causes a persistent infection which, in turn, results in an early acute encephalomyelitis followed by a late chronic immune-mediated demyelinating and neurodegenerative disease that pathologically resembles MS. In contrast, resistant mice (i.e C57BL/6 and BALB/c) are able to clear the virus from the CNS, and consequently do not develop chronic demyelination. Previous studies indicated that stress during early infection of susceptible mice can increase CNS viral titers and alter dissemination of TMEV, decrease early cytokine and chemokine expression in the spleen and CNS, and result in an exacerbated late demyelinating disease. The studies herein, focused on the hypothesis that chronic stress during early infection with TMEV infection would lead to drastic immunosuppression of both innate and adaptive arms of immunity, and that this immunosuppression may overcome the genetically controlled resistance of C57BL/6 mice to Theiler’s virus-induced demyelination. In these series of studies, we were able to show that stress, regardless of mouse strain susceptibility, decreases NK cell activity, and increased viral titers at day 1 p.i. Furthermore, after seven days of stress, susceptible mice demonstrated decreased virus specific T-cell effector function in both the CNS and spleens as indicated by a globalized reduction in type 1 and type 2 cytokines, as well as transcription factors. Importantly, these decreased responses were, in part, attributable to the actions of glucocorticoids. However, stress during early infection of C57BL/6 mice did not alter resistance to demyelination. These results begin to shed light on how stress, infection, and genetics can influence the onset of human MS.

Theiler's virus

Multiple Sclerosis

Restraint stress

T-cell

B-cell

Immune response

Stereotyped B Cell Receptors in Chronic Lymphocytic Leukaemia : Implications for Antigen Selection in Leukemogenesis

Murray, Fiona

January 2008

Biased immunoglobulin heavy variable (IGHV) gene usage and distinctive B-cell receptor (BCR) features have been reported in chronic lymphocytic leukaemia (CLL), which may reflect clonal selection by antigens during disease development. Furthermore, the IGHV gene mutation status distinguishes two clinical entities of CLL, where patients with unmutated IGHV genes have an inferior prognosis compared to those with mutated IGHV genes. Recently, one subgroup of CLL patients expressing the IGHV3-21 gene was found to display highly similar immunoglobulin (IG) gene features, even within the heavy chain complementarity-determining region 3 (HCDR3). Patients in this subgroup typically had a poor prognosis. In paper I, we aimed to identify further subgroups with restricted BCR features among 346 CLL cases. Six subsets were defined which carried virtually identical BCRs in terms of rearranged heavy and light chain (LC) IG genes and CDR3 length and composition. In paper II, we investigated 90 IGHV3-21 cases from diverse geographical locations. We confirmed the highly restricted HCDR3 characteristics in 56% of patients and a biased usage of the IGLV3-21 gene in 72% of cases. Survival analysis also confirmed the poor outcome of this group, irrespective of IGHV gene mutation status and geographical origin. Papers III and IV involved a large-scale analysis of IGH and IG kappa and lambda (IGK/L) gene rearrangements, to define subsets with ‘stereotyped’ BCRs and also to systematically examine the somatic hypermutation (SHM) features of the IG genes in CLL. We studied a cohort of 1967 IGH and 891 IGK/L gene sequences from 1939 patients from 6 European institutions. Over 5300 IGH and ~4700 IGK/L sequences from non-CLL B cells were used as a control data set. In total, 110 CLL stereotyped subsets were defined according to HCDR3 homology. Striking IGK/L gene biases were also evident within subsets, along with distinctive K/LCDR3 features, such as length and amino acid composition. At cohort level, the patterns of mutation appeared to be consistent with that of a canonical SHM mechanism. However, at a subgroup level, certain stereotyped subsets, e.g. IGHV3-21/IGLV3-21 and IGHV4-34/IGKV2-30 CLL, deviated from this pattern. Furthermore, recurrent ‘stereotyped’ mutations occurred in cases belonging to subsets with restricted HCDR3s, in both IGHV and IGK/LV genes, which were subset- and CLL-biased when compared to non-CLL B cells. In conclusion, our findings implicate antigen selection as a significant factor in the pathogenesis of CLL, particularly in cases carrying stereotyped BCRs. The presence of stereotyped mutations throughout the VH and VL domain also indicates involvement of IG regions other than the CDR3 in antigen recognition. Finally, biased IGK/L gene usage and specific K/LCDR3 features are strong indications that LCs are crucial in shaping the specificity of leukemic BCRs, in association with defined heavy chains.

chronic lymphocytic leukaemia

immunoglobulin genes

somatic hypermutation

stereotyped B cell receptors

antigen selection

Molecular biology

Molekylärbiologi

T Regulatory Cells – Friends or Foes?

Lindqvist, Camilla

January 2010

T regulatory cells (Tregs) have been extensively studied in patients with cancer or autoimmunity. These cells hamper the immune system’s ability to clear tumor cells in cancer patients. In autoimmune diseases, on the other hand, they are not able to restrain autoreactive immune responses. If we manage to understand Tregs and their role in health and diseases we may be able to develop better immunomodulatory therapies. Early studies demonstrated that tolerance was maintained by a subset of CD25+ T-cells. CD25 was the earliest marker for Tregs and is still often used to define these cells. Several Treg-associated markers have been suggested throughout the years. However, these markers can be upregulated by activated T-cells as well. The most specific marker for Tregs is currently the transcription factor forkhead box P3 (FoxP3). In this thesis, we investigated the presence of CD25- Tregs in patients with B-cell malignancies and in patients with autoimmunity. These cells were identified in both patient groups. Further, patients with B-cell malignancies often have high levels of soluble CD25 (sCD25) in the periphery. In our patient cohorts, the level of peripheral Tregs correlated with the level of sCD25 in patients with lymphoma. Tregs were shown to release sCD25 in vitro and sCD25 had a suppressive effect on T-cell proliferation. These data show that Tregs may release CD25 to hamper T-cell proliferation and that this may be an immune escape mechanism in cancer patients. Previous studies have demonstrated that an increased infiltration of FoxP3+ cells into lymphoma-affected lymph nodes is associated with a better patient outcome. This is in contrast to studies from non-hematological cancers where an increased presence of Tregs is associated with a poor prognosis. Since previous studies have shown that Tregs are able to kill B-cells, we wanted to investigate if Tregs are cytotoxic in patients with B-cell tumors. In the subsequent studies, Tregs from patients with B-cell lymphoma and B-cell chronic lymphocytic leukemia (CLL) were phenotyped to investigate the presence of cytotoxic markers on these cells. FoxP3-expressing T-cells from both patients with CLL and B-cell lymphoma displayed signs of cytotoxicity by upregulation of FasL and the degranulation marker CD107a. Tregs from CLL patients could further kill their autologous B-cells in in vitro cultures. Taken together the studies in this thesis have demonstrated two possible new functions of Tregs in patients with B-cell malignancies and the presence of CD25- Tregs in both cancer and autoimmunity.

Treg

T regulatory cell

FoxP3

CD25

CLL

B-cell lymphoma

Clinical immunology

Klinisk immunologi

Mechanism of Mismatch Repair Induced Mutagenesis in Somatic Hypermutation

Frieder, Darina

15 April 2010

B cells produce a diverse array of antibody specificities that are of low affinity during the initial phase of a humoral immune response. However, somatic hypermutation of the rearranged V region in the immunoglobulin locus generates new antibody affinities, accompanied by the selection of B cells that produce superior antibody affinities. Somatic hypermutation is initiated by the conversion of G:C base pairs to G:U lesions by the enzyme activation induced cytosine deaminase. Left unrepaired, G:U lesions will give rise to transition mutations at G:C base pairs, but are converted to transition and transversion mutations at G:C and A:T base pairs by the paradoxical participation of the base excision repair and mismatch repair pathways. The mismatch repair pathway, which evolved to correct errors produced during DNA replication, is co-opted by hypermutating B cells to produce A:T mutations via the processing of G:U lesions. This process requires the mismatch repair components Msh2, Msh6, and Exo1, but is additionally dependent upon the translesional DNA polymerase eta, a known A:T mutator, and on ubiquitinated PCNA, an initiator of translesion synthesis. The presence of certain types of lesions in the template strand during DNA replication leads to the activation of translesion synthesis. I propose that a similar mechanism operates during somatic hypermutation to activate translesion synthesis and recruit DNA polymerase eta. Our model suggests that mismatch repair-generated single-stranded DNA tracts contain abasic sites produced as a result of uracil excision by uracil-N-glycosylase. Synthesis opposite abasic sites activates translesion synthesis and results in the recruitment of polymerase eta and the subsequent production of A:T mutations. In this thesis, I present data from hypermutating murine B cells and the B cell line Ramos to support this model, demonstrating that the base excision repair and mismatch repair pathways cooperate during somatic hypermutation to generate A:T mutations. In addition, I explore the role of the Mre11-Rad50-Nbs1 complex in its contribution to A:T mutations in Ramos cells. Taken together, these studies demonstrate that conversion of classical DNA repair pathways into mutation-generating processes is driven by the unique environment of the V region in hypermutating B cells.

Immunology

DNA Repair

Mutagenesis

B Cell

Mismatch Repair

Somatic Hypermutation

0982

Mechanism of Mismatch Repair Induced Mutagenesis in Somatic Hypermutation

Frieder, Darina

15 April 2010

B cells produce a diverse array of antibody specificities that are of low affinity during the initial phase of a humoral immune response. However, somatic hypermutation of the rearranged V region in the immunoglobulin locus generates new antibody affinities, accompanied by the selection of B cells that produce superior antibody affinities. Somatic hypermutation is initiated by the conversion of G:C base pairs to G:U lesions by the enzyme activation induced cytosine deaminase. Left unrepaired, G:U lesions will give rise to transition mutations at G:C base pairs, but are converted to transition and transversion mutations at G:C and A:T base pairs by the paradoxical participation of the base excision repair and mismatch repair pathways. The mismatch repair pathway, which evolved to correct errors produced during DNA replication, is co-opted by hypermutating B cells to produce A:T mutations via the processing of G:U lesions. This process requires the mismatch repair components Msh2, Msh6, and Exo1, but is additionally dependent upon the translesional DNA polymerase eta, a known A:T mutator, and on ubiquitinated PCNA, an initiator of translesion synthesis. The presence of certain types of lesions in the template strand during DNA replication leads to the activation of translesion synthesis. I propose that a similar mechanism operates during somatic hypermutation to activate translesion synthesis and recruit DNA polymerase eta. Our model suggests that mismatch repair-generated single-stranded DNA tracts contain abasic sites produced as a result of uracil excision by uracil-N-glycosylase. Synthesis opposite abasic sites activates translesion synthesis and results in the recruitment of polymerase eta and the subsequent production of A:T mutations. In this thesis, I present data from hypermutating murine B cells and the B cell line Ramos to support this model, demonstrating that the base excision repair and mismatch repair pathways cooperate during somatic hypermutation to generate A:T mutations. In addition, I explore the role of the Mre11-Rad50-Nbs1 complex in its contribution to A:T mutations in Ramos cells. Taken together, these studies demonstrate that conversion of classical DNA repair pathways into mutation-generating processes is driven by the unique environment of the V region in hypermutating B cells.

Immunology

DNA Repair

Mutagenesis

B Cell

Mismatch Repair

Somatic Hypermutation

0982

The Effects of Chronic Restraint Stress on Innate and Adaptive Immune Responses to Acute Theiler?s Murine Encephalomyelitis Virus Infection ? An Animal Model of Human Multiple Sclerosis

Steelman, Andrew Jonathan

15 May 2009

Multiple sclerosis (MS) is an immune-mediated prevalent chronic demyelinating and neurodegenerative disease of the central nervous system that begins with an abrupt onset during early adulthood. MS is idiopathic, but many factors are thought to influence the pathogenesis of the disease, which include genetic, gender and environmental factors. To date, there is much evidence that suggest that both the onset and progression of MS is facilitated by both viral infections and stress. Theiler’s murine encephalomyelitis virus (TMEV) is a picornavirus that upon inoculation into susceptible strains of mice (i.e. SJL and CBA) causes a persistent infection which, in turn, results in an early acute encephalomyelitis followed by a late chronic immune-mediated demyelinating and neurodegenerative disease that pathologically resembles MS. In contrast, resistant mice (i.e C57BL/6 and BALB/c) are able to clear the virus from the CNS, and consequently do not develop chronic demyelination. Previous studies indicated that stress during early infection of susceptible mice can increase CNS viral titers and alter dissemination of TMEV, decrease early cytokine and chemokine expression in the spleen and CNS, and result in an exacerbated late demyelinating disease. The studies herein, focused on the hypothesis that chronic stress during early infection with TMEV infection would lead to drastic immunosuppression of both innate and adaptive arms of immunity, and that this immunosuppression may overcome the genetically controlled resistance of C57BL/6 mice to Theiler’s virus-induced demyelination. In these series of studies, we were able to show that stress, regardless of mouse strain susceptibility, decreases NK cell activity, and increased viral titers at day 1 p.i. Furthermore, after seven days of stress, susceptible mice demonstrated decreased virus specific T-cell effector function in both the CNS and spleens as indicated by a globalized reduction in type 1 and type 2 cytokines, as well as transcription factors. Importantly, these decreased responses were, in part, attributable to the actions of glucocorticoids. However, stress during early infection of C57BL/6 mice did not alter resistance to demyelination. These results begin to shed light on how stress, infection, and genetics can influence the onset of human MS.

Theiler's virus

Multiple Sclerosis

Restraint stress

T-cell

B-cell

Immune response

Influenza-specific B cell responses in HLA-DR1 transgenic mice

Huan, Lifang

01 August 2010

HLA-DR1 transgenic (DR1 Tg) mice provide a model for evaluating the breadth and specificity of CD4 T cell responses that may develop in humans following influenza infection or vaccination. Recent studies identified a tremendously broad HLA-DR1-restricted CD4 T cell responses in DR1 Tg mice infected intranasally with influenza A/New Caledonia/20/99 (NC). In this study, our goals were to characterize B cell responses after NC infection in DR1 Tg mice and establish the correlation between B cell responses and CD4 T cell responses in this system. Influenza-specific B cell responses following virus administration were analyzed in DR1 Tg mice and in the genetically matched H-2b strain C57BL/10J (B10). Following intranasal (i.n.) NC infection, B cell responses in B10 mice featured strong IgG2b and IgG2c production and were typical of previously described B cell responses to a variety of mouse-adapted influenza strains. In contrast, B cell responses in DR1 Tg mice followed delayed kinetics and were strongly skewed to IgG1 production, suggesting the Th2 polarization of CD4 T cell responses. The different antibody isotype profile in DR1 Tg mice compared to B10 mice was evident in antibody secreting cells (ASCs) frequencies and in circulating Abs levels. Surprisingly, although DR1 Tg mice had lower influenza-specific Abs levels, they exhibited higher neutralizing Abs titers early in the response. B cell responses following intranasal infection of influenza A/Puerto Rico/8/1934 (PR8) or intramuscular vaccination of inactivated NC in DR1 Tg mice were different from the observed IgG1 bias after i.n. NC infection. After i.n. PR8 infection, B cell responses were similar in DR1 Tg mice and B10 mice, characterized by predominant IgM/IgG3 production. Additionally, following intramuscular administration of inactivated NC, B cell responses were skewed towards IgG2c production in both DR1 Tg mice and B10 mice, suggesting the Th1 polarization of CD4 T cell responses. A mechanistic understanding of IgG1/Th2 biased B cell responses and better neutralizing Abs production in DR1 Tg mice following i.n. NC infection may have implications for the optimal control of influenza infection.

HLA-DR1 transgenic mice

influenza virus

B cell responses

IgG1

Microbiology

Induction and regulation of bovine B lymphocyte responses /

Haas, Karen Marie,

January 2000

Thesis (Ph. D.)--University of Missouri--Columbia, 2000. / "December 2000." Typescript. Vita. Includes bibliographical references (leaves 177-206). Also available on the Internet.