Role of Tim-1 in immune responses

Curtiss, Miranda Lynn

01 May 2012

Tim-1 (T cell immunoglobulin mucin domain 1) is a transmembrane protein expressed by many cell types, including activated T cells and B cells. Antibodies to Tim-1 have been shown to decrease severity of airway hyperreactivity and Th2 cytokine production in mice. Current literature suggests Tim-1 functions as a co-stimulatory molecule. We hypothesize that Tim-1 signals in lymphocytes, and that Tim-1 signaling modulates allergic airway disease. Chapter one provides a brief overview of current literature exploring identification of the Tim family of receptors, genetic associations between TIM-1 polymorphisms and human diseases, Tim-1 expression, Tim-1 ligands, studies of antibodies to Tim-1 in various mouse models of human disease, and signaling events downstream of Tim-1 engagement. Chapter two provides detailed experimental methodology. Chapter three details the characterization of Tim-1 deficient mice. Tim-1 deficient mice do not exhibit defects in lymphocyte or myeloid cell development, as determined by numbers of cells present in bone marrow, thymus, spleen, and lymph nodes. C57BL/6 Tim-1 deficient female mice appear to develop an increased number of lymph node cells and also develop anti-double stranded DNA antibodies. Chapter four explores the impact of Tim-1 deficiency in a murine allergic airway disease model, which demonstrated that Tim-1 deficient mice developed increased lung inflammation and increased antigen-specific Th2 cytokine production that was evident in mice backcrossed to both BALB/c and C57BL/6 backgrounds. These phenotypes were not evident using purified naïve CD4+ T cells polarized in vitro. As Tim-1 expression is not restricted to CD4+ T cells, adoptive transfer experiments were performed to determine whether the phenotype observed was due to the deficiency of Tim-1 on CD4+ T cells, non-CD4+ T cells, or Tim-1 deficiency on both CD4+ T cells and non-CD4+ T cells. Chapter five explores the impact of Tim-1 deficiency in a chronic Leishmania major intradermal infection model. Tim-1 deficient mice crossed to both BALB/c and C57BL/6 backrounds demonstrated similar parasite burden over the course of time, but in vitro restimulation of lymph node cells revealed a striking increase in cytokine production that extended to Th1, Th2, and Th17 lineages. Tim-1 signaling in murine B cell lines is explored in Chapter six. A Tim-1 monoclonal antibody conjugated to beads induces phosphorylation of Tim-1 and recruitment of the Src family kinase Fyn. This phosphorylation of Tim-1 is reduced in Fyn-deficient B cell lines. Chapter seven discusses the significance of these findings, relates current literature to these results, and provides some avenues for further exploration of Tim-1 function and signaling.

asthma

B cell

CD4+ T cell

signaling

Th2 cell

Tim-1

Immunology of Infectious Disease

Cost-Effectiveness Analysis of Targeted Herpes Zoster Vaccination in Adults 50-59 at Increased Cardiovascular Risk

Glassner, Kathleen M.

17 November 2017

Background: Over the last twenty years the incidence of herpes zoster (HZ) infection, also known as shingles, has been increasing among adults for unknown reasons. The economic burden of HZ is currently estimated at over $1 billion per year in the United States (U.S.) and is expected to increase as the susceptible adult population ages. HZ is caused by a re-activation of the varicella zoster virus (VZV), chicken pox, and more than 95% of adults living today carry the virus with a lifetime risk of 1 in 3 for developing HZ. In 2006 the FDA approved a vaccine for the prevention of HZ in adults 60 years and older and in 2011 approval was expanded to include adults age 50-59 years. Since 2006 rates of adult immunization for HZ have been modest, as of 2015 approximately two-thirds of the US population ≥ 60 are still unvaccinated and more than 94% of those ages 50-59 have not been vaccinated. There is now accumulating evidence of a significantly elevated risk of ischemic stroke (IS) within the first 12 months following infection with HZ. Every 40 seconds someone in the U.S. suffers a stroke with an estimated 795,000 strokes per year. In the U.S. stroke is a significant cause of disability with costs estimated at $33 billion per year including cost of healthcare, medication, and lost productivity. As the population in the U.S ages, the risk of both HZ infection and stroke will increase significantly thus impacting mortality, morbidity, and healthcare costs. The CDC Advisory Committee for Immunization Practices (ACIP) currently recommends routine vaccination against HZ for adults ≥ 60 but does not recommend vaccination for adults age 50-59 years and does not provided any guidance or recommendations for adults who may be at increased risk of stroke associated with HZ infection. The current ACIP vaccination recommendations for HZ are predominately based on clinical trial efficacy data and cost-effectiveness analyses (CEAs) in adults ≥ 60. These prior analyses did not included costs associated with the recent evidence demonstrating increased risk of stroke up to one year following HZ infection. Aims: The objectives of this study were as follows; 1) To assess the cost-effectiveness of a targeted HZ vaccination strategy for adults age 50-59 years at increased cardiovascular (CV) risk in whom vaccination is approved but not recommended; 2) To develop a white paper directed at payers, providers, and policy makers translating the findings from the analysis into appropriate population health dissemination, implementation, and adoption priority recommendations. Methods: A decision analytic Markov Model (MM) was used to compare costs and outcomes between two vaccination strategies; usual-care (no current vaccine recommendation) and targeted vaccination in adults age 50-59 years with cardiovascular disease (CVD) in a hypothetical cohort of 100,000 adults age 50-59 years. The private payer perspective was used as it best represents this population of adults age 50-59 years who are predominately employed and covered under employer sponsored commercial insurance. The simulated cohort was assessed for incidence of IS within 12 months following HZ infection occurring within the fifth decade of life. Risk was assessed from the age at entry to the analysis, median age 55, up to age 60 using TreeAge Pro 2017 software. The cohort was then aged out to 100 years or death, whichever came first. Costs were calculated using 2016 U.S. dollars. Findings: As it relates to aim one, compared to usual-care targeting HZ vaccination in adults age 50-59 years with prevalent CVD was cost-effective with an incremental cost-effectiveness ratio (ICER) of $55,517 per quality of life-year (QALY) gained which falls well below the standard willingness-to-pay (WTP) threshold of $100,000 utilized in previous HZ CEAs (Le & Rothberg, 2015, 2016; Pellissier, Brisson, & Levin, 2007). The incremental cost of vaccinating the target population using a benchmark vaccination rate of 60% was $30.59 per person compared to $12.98 in the usual-care group with ICERs of $55,517 and $55,470 respectively. Moreover, when comparing the cost of universal vaccination in the entire 50-59 year old cohort cost-effectiveness was maintained with an incremental cost of $176.51 per person and an ICER of $55,523. Adopting the targeted strategy resulted in 162 fewer cases of HZ and 14 fewer strokes per 100,000 persons. Regarding aim two, following safety and efficacy, cost-effectiveness analysis are considered an essential metric in vaccine policy making and a substantial driver of vaccine adoption by policymakers, payers, and providers. Translating these favorable cost-effectiveness findings to policymakers, payers, and providers is necessary to help close the adoption curve gap in order to facilitate and inform effective and timely implementation strategies for HZ vaccination in this targeted population. Conclusions: This study demonstrated that targeted HZ vaccination in patients age 50-59 years at increased CV risk is cost-effective and thus updating ACIP policy recommendations regarding vaccination in this population for whom the vaccine is currently FDA approved but not recommended should be considered. Furthermore, this study showed that universal vaccination in the general 50-59 year old population is cost-effective. Given the very limited data on cost-effectiveness of HZ vaccination in adults age 50-59 years, which has resulted in a lack of recommendation for this population, and recent evidence of IS risk the results of this study demonstrating cost-effectiveness of a targeted HZ vaccination strategy directly support the National Adult Immunization Plan (NAIP) to improve adult immunization uptake by providing economic evaluations which can be used to inform policymakers, payers, and providers.

Herpes Zoster

Stroke

Cost-effectiveness

Vaccine

Cardiovascular Disease

Immunology and Infectious Disease

Public Health

Role of viruses within metaorganisms: Ciona intestinalis as a model system

Leigh, Brittany A.

28 September 2017

Marine animals live and thrive in a literal sea of microorganisms, yet are often able to maintain specific associations that are largely dictated by the environment, host immunity and microbial interactions. Animal-associated microbiomes include bacteria and viruses that vastly outnumber host cells, especially in the gut environment, and are considered to be integral parts of healthy, functioning animals that act as a metaorganism. However, the processes underlying the initial establishment of these microbial communities are not very well understood. This dissertation focuses on the establishment of a well-known developmental animal model, Ciona intestinalis (sea squirt), to study the establishment and maintenance of a stable gut microbiome. Generation of a new model for studying microbial colonization of the gut requires the ability to rear Ciona in the absence of microbes (i.e., germ-free). This dissertation describes the establishment of a germ-free technique for rearing Ciona and the methods utilized for bacterial exposure and colonization. Additionally, to determine the spatial structure of the gut microbiome, viral and bacterial communities within the three main gut compartments (stomach, midgut, hindgut) of Ciona from San Diego, CA, were assessed. The viral community was dominated by phages (viruses infecting bacteria), and numerous prophages (phages integrated into bacterial genomes) matching sequences found in bacteria belonging to the Ciona microbiome were detected within the active viral fraction. To determine the prevalence of prophages within the Ciona microbiome, a total of 70 bacteria cultured from the gut were tested, and 22 isolates were found to possess inducible prophages. When co-cultured with other bacteria, these induced prophages were capable of lytic infection of other members of the microbiome, often exhibiting broad host ranges. The dynamic interactions of gut bacteria and phages were explored further with the isolation and characterization of a novel Shewanella phage-host system from the adult Ciona gut. Lytic phage infection resulted in an increase in biofilm formation correlating with the release of extracellular DNA, a process that was also observed to a lesser degree in control cultures as a result of spontaneous prophage induction. Furthermore, addition of the Ciona immune protein VCBP-C to static cultures of this Shewanella sp. 3313 also enhanced biofilm formation; a similar phenomenon was noted in another bacteria, a Pseudoalteromonas sp. 6751. Interestingly, both of these isolates contained inducible prophages and binding of the VCBP-C protein to these lysogenic strains was found to influence prophage induction in vitro. Colonization of the gut in vivo also correlated with differential up-regulation of VCBP-C expression in germ-free animals and a subsequent induction of prophages. This dissertation makes an important contribution to the symbiosis field by developing a new model system in which novel aspects of host-microbe interactions can be investigated. The discovery that an innate immune effector can influence bacterial biofilms and result in the induction of prophages capable of lytic infection of other co-occurring bacteria reveals a previously unrecognized intersection between secretory immune molecules and phages in shaping the microbiome. These findings establish Ciona as a relevant and tractable model for studying trans-kingdom interactions during colonization of the gut epithelium.

Ciona

bacteriophage

innate immunity

microbiome

prophage

biofilm

Immunology and Infectious Disease

Microbiology

Novel Role of Histone Deacetylase 11 (HDAC11) in Regulating Normal and Malignant Hematopoiesis

Chen, Jie

12 January 2018

During hematopoiesis, multilineage progenitor cells and the precursors are committed to individual hematopoietic lineages. In normal myelopoiesis, the immature myeloid cells (IMCs) differentiate into macrophages, neutrophils or dendritic cells. However, under tumor burden, these IMCs differentiate into myeloid derived suppressor cells (MDSCs) result in an up-regulation of immune suppressive factors and pro-tumor effect. The development of normal or malignant is tightly controlled by endogenous signals such as transcription factors and epigenetic regulations. HDAC11 is the newest identified members of the histone deacetylase (HDAC) family. Previous study in our group had identified HDAC11 as a negative regulator of interleukin 10 (IL-10) production in antigen-presenting cells (APCs). However, the mechanisms of HDAC11 in regulating myeloid cells differentiation and function remained unclear. We have uncovered for the first time that in the absence of HDAC11, upon LPS stimulation, neutrophils isolated form mice displays an over-production of pro-inflammatory cytokines such as TNF-alpha and IL-6. Strikingly, these HDAC11KO neutrophils showed a significantly higher migratory and phagocytosis activity, resulting from an overexpression of the migratory receptor and cytokine CXCR/L2. We have performed Chromatin Immunoprecipitation (ChIP) analysis on the neutrophils and discovered that HDAC11 was recruited to the promoter regulatory region of these genes we have identified. This part of data will be discussed mainly in chapter 2. Not only does HDAC11 plays a crucial role in the neutrophil function, our group have also found out that lacking of HDAC11 result in an increased suppressive activity of the Myeloid-derived Suppressor Cells (MDSCs). The previous publication of our group had shown that the tumor bearing mice experienced a much more aggressive growth pattern in the HDAC11 KO mice compare with C57BL/6 wild type control. MDSCs isolated from mice lacking HDAC11 appeared to gain increased capability to suppress the function of antigen-specific CD8+ T cells in vitro. Followed by this initial study, in chapter 3, we observed an up-regulation of both expression and enzymatic activity of arginase 1 and Nos2, two enzymes that are crucial in regulating MDSCs suppressive function. The aberrant enzymatic activity of Arg1 and Nos2 in HDAC11KO MDSCs is possibly result from an over-expression of the lineage-specific transcription factor C/EBPβ, which is previously proved to be essential for the differentiation of functional MDSCs. Furthermore, our ChIP data confirmed that HDAC11 may play as an negative regulator of C/EBPβ. Recently, our lab had demonstrated that T cells lacking HDAC11 gained a hyperactive phenotype and anti-tumor effect, indicating that HDAC11 may play a dual role in the host immune system. We further performed an adoptive transfer therapy to C57BL/6 tumor bearing mice. Our data showed that the additional administration of HDAC11KO MDSCs could eliminate, at least partially, the anti-tumor effect by adoptive transfer of HDAC11KO T cells. Taken together, we have uncovered a previously unknown role for HDAC11 as a transcriptional regulator in the myeloid cells differentiation and function. Based on our data and previous work from our lab, we propose a dual role of HDAC11 played in the host immune system. In the absence of HDAC11, host defenders such as neutrophils and T cells are functionally more aggressive against intruders such as pathogen and cancer. However, the immune suppressors such as MDSCs became more suppressive. The contradictory role HDAC11 played in the immune system may provide some insights for the assessment of the pharmacological value of HDAC11 and contribute to the development of novel immunotherapeutic strategies.

CD8+ T cells

C/EBPbeta

Myeloid-derived suppressor cells

Neutrophils

Biology

Cell Biology

Immunology and Infectious Disease

Achievement of Transplantation Tolerance: Novel Approaches and Mechanistic Insights

Pidala, Joseph

17 March 2014

Current immune suppressive strategies fail to induce donor-recipient immune tolerance after allogeneic hematopoietic cell transplantation. Accordingly, patients suffer morbidity and mortality from graft vs. host disease (GVHD) and prolonged immune suppressive therapy. Biologic insight into transplantation tolerance is needed, and translation of such insight to novel clinical strategies may improve clinical outcomes. We report original investigation at seminal phases of this process including initial prophylactic immune suppression, onset of acute graft vs. host disease, and ultimate immune suppression discontinuation: In a controlled randomized clinical trial, we demonstrate that sirolimus-based immune suppression reduces risk for acute GVHD, ameliorates the severity of subsequent chronic GVHD, and supports reconstitution of functional regulatory T cells. Study of tissue-infiltrating CD4+ T cell subsets in acute GVHD target organs supports a pathogenic role for Th17 cells. Finally, we demonstrate that peripheral blood transcriptional biomarkers provide mechanistic insight into human transplantation tolerance. These data signal progress, and suggest rational translational efforts to achieve transplantation tolerance.

graft vs. host disease

immune tolerance

regulatory T cells

sirolimus

Immunology and Infectious Disease

Combined Metal-Enhanced Fluorescence-Surface Acoustic Wave (MEF-SAW) Biosensor

Morrill, Samuel

17 March 2014

Immunofluorescence assays are capable of both detecting the amount of a protein and the location of the protein within a cell or tissue section. Unfortunately, the traditional technique is not capable of detecting concentrations on the nanoscale. Also, the technique suffers from non-specific attachment, which can cause false-positives, as well as photobleaching when detecting lower concentrations is attempted. There is also a time constraint problem since the technique can take from many hours to a few days in some cases. In this work, metal-enhanced fluorescence (MEF) is used to lower the detection limit and reduce photobleaching. Unfortunately, MEF also increases the intensity of non-specifically bound proteins (NSBPs). Therefore, a surface acoustic wave (SAW) device is used to remove the more weakly bound NSBPs. Previously, this has been shown on lithium niobate, but it is used with a quartz substrate in this work. The SAW device is also used to cause micro-mixing which speeds the process up significantly. In this research, it was found that silver nanocubes can lower the detection limit down to below 1 ng/mL. Quartz SAW devices are shown to remove NSBPs at a power of 10 mW applied for five minutes. Micro-mixing is shown to be improved by a factor of six at 10 mW for 10 minutes by saturating the antibody used in this research, which takes 1 hour without micro-mixing. Finally, all three components are combined. In this work, the whole device is used to detect 50 ng/mL. After micro-mixing, the intensity is the same as with MEF, and, after removal, it has been lowered by 7 a.u.

bioassay

immunofluorescence

Micro-mixing

nanoparticles

removal

Biochemistry

Immunology and Infectious Disease

Immature Myeloid Cells Promote Tumor Formation Via Non-Suppressive Mechanism

Ortiz, Myrna Lillian

17 February 2014

ABSTRACT Although there is ample evidence linking chronic inflammation with cancer, the cellular mechanisms involved in early events leading to tumor development remain unclear. Myeloid cells are an intricate part of inflammation. They consist of mature cells represented by macrophages, dendritic cells and granulocytes and a population of Immature Myeloid Cells (IMC), which in healthy individuals are cells in transition to mature cells. There is a substantial expansion of IMC in cancer and many other pathological conditions which is associated with pathologic activation of these cells. As a result, these cells acquire the ability to suppress immune responses and are termed Myeloid-derived Suppressor Cells (MDSCs). Although the role of MDSC in immune suppression in cancer and tumor progression is well established, their contribution to tumor development is still uncertain. The fact that cells with MDSC phenotype and function are observed in chronic inflammation raised the possibility that these cells can contribute to initial stages of tumor development. To address this question, we used an experimental system where the number of IMC was regulated by the expression of S100A9 protein. In this project, we used two different models of chronic inflammation in S100A9 transgenic (S100A9tg) and S100A9 knock-out (S100A9KO) mice. In the first model, we created the conditions for topical accumulation of these cells in the skin in the absence of infection or tissue damage using S100A9tg mice. Accumulation of IMC in the skin resulted in a dramatic increase in the formation of skin tumors during epidermal carcinogenesis. Conversely, lack of myeloid cell accumulation in S100A9KO mice substantially reduced the formation of skin papillomas. The effect of IMC was not associated with immune suppression but with the recruitment of CD4+ T cells mediated by CCL4 chemokine released by activated IMC. Elimination of CD4+ T cells or blockade of CCL4 abrogated the increase in tumor formation caused by myeloid cells. Thus, this study implicates the accumulation of IMC as an initial step in facilitating of tumor formation, which can mediate the recruitment of CD4+ T cells via the release of CCL4 chemokine. In the second model, we used inflammation-associated lung cancer caused by the chemical lung carcinogen urethane in combination with exposure to cigarette smoke referred to throughout as CS. Exposure of mice to CS alone resulted in a significant accumulation of cells with typical MDSC phenotype in different organs; however, these cells lacked immune suppressive activity and could not be defined as bona fide MDSC. When CS was combined with the single dose of urethane, it led to the accumulation of immune suppressive cells. The expansion of MDSC followed the onset of lung tumors development. This suggests that MDSC in this model is not the preceding factor but rather a consequence of tumor formation. Further studies are necessary to determine the relevance of targeting these cells for cancer treatment and prevention.

CCL4

inflammation

MDSC

S100A9

T helper Cells

Cell Biology

Immunology and Infectious Disease

Molecular Biology

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

Identifying Mechanisms Associated with Innate Immunity in Cows Genetically Susceptible to Mastitis

Elliott, Alexandra Alida

01 December 2010

Mastitis, or mammary gland inflammation, causes the greatest loss in profit for dairy producers. Mastitis susceptibility differs among cows due to environmental, physiological, and genetic factors. Prior research identified a genetic marker in a chemokine receptor, CXCR1, associated with mastitis susceptibility and decreased neutrophil migration. Current research seeks to identify reasons behind mastitis susceptibility by validating this model through in vivo challenge with Streptococcus uberis and studying specific mechanisms causing impaired neutrophil migration. Holstein cows with GG (n=19), GC (n=28), and CC (n=20) genotypes at CXCR1+777 were challenged intramammarily with S. uberis strain UT888. After challenge 68% of quarters from GG genotype, 74% from CC genotype and only 47% from GC genotype cows had ≥10 colony forming units/ml S. uberis for at least two sampling time points (P<0.05). However, among infected cows, number of S. uberis, somatic cell count, rectal temperature, milk scores and mammary scores were comparable among genotypes throughout infection. These findings suggest that cows with GC genotypes may be more resistant to S. uberis mastitis, but have similar responses if infected. To better understand the mechanisms associated with disease resistance, migration patterns in neutrophils from cows with different CXCR1+777 genotypes were evaluated. Neutrophils from cows with GG (n=11) and CC (n=11) genotypes were isolated and stimulated with zymosan activated sera (ZAS). Cells were fixed and stained for F-actin and evaluated for F-actin content, distribution, and cell morphology. Neutrophils from CC cows had significantly lower average F-actin polymerization than GG cows v (P=0.05). Directed migration of neutrophils from GG (n=10) and CC (n=10) genotypes was imaged and tracking data was analyzed for individual cells. Cells from GG genotype traveled further on an X axis and had higher X/Y movement towards IL8 compared to CC genotype, meaning they moved more directly towards IL8. Our findings suggest lower F-actin polymerization in combination with lower ability to directly move towards IL8 could impair neutrophil response to infection in cows with a CC genotype and may contribute to increased mastitis susceptibility. Finding what makes certain cows more susceptible to mastitis could lead to strategies aimed at improved prevention and treatment of mastitis.

Mastitis

innate immunity

neutrophil

chemotaxis

CXCR1

F-actin

Cell Biology

Dairy Science

Immunology and Infectious Disease

Immunopathology

Naive and memory T cell trafficking in selectin ligand-deficient mice: the role of fucosyltransferase –IV and –VII in the differential migration of T cell populations

Harp, John Robert

01 August 2010

The correct and timely delivery of immune cells is critical for protection against foreign antigen. In order for cells to access most organs, there are requirements that must be met to facilitate exit from the blood into extravasculature. The initial requirement is selectin-selectin ligand interactions that mediate tethering and rolling to allow shear resistance. For proper selectin-selectin ligand interaction, glycoproteins must be modified by fucosyltransferases –IV and –VII, which adds fucose to an acceptor substrate to form the sialyl-LewisX moiety. Using fucosyltransferase –IV and –VII double knockout (FtDKO) mice, we made several novel observations. Our first observation showed increased numbers of naïve T cells in non-lymphoid organs. To support this observation, we blocked chemokine-mediated entry into lymph nodes (LNs) with pertussis toxin and L-selectin mediated entry with anti-CD62L antibody in WT mice. We also treated WT mice with the S1P1 agonist, FTY720, to retain lymphocytes in LNs. Our results suggested that when access to LN is perturbed, lymphocytes accumulate in non-lymphoid organs. Our second observation showed an enrichment of effector/memory T cells in FtDKO LNs. To determine if effector/memory CD8 T cells were retained in LNs, we transferred naïve and memory CD8 T cells into WT mice then treated the recipient mice with anti-CD62L. We found that LN exit rates of naïve and memory CD8 T cells were similar, but slowed as T cell density decreased. To understand if memory CD8 T cells were using selectin ligand independent mechanisms, we transferred naïve and memory CD8 T cells into WT or FtDKO mice. We found reduced numbers of memory CD8 T cells in LNs, however, their frequency was increased. We explored this result by transferring CFSE labeled memory CD8 T cells. We found that memory CD8 T cells divide more in FtDKO mice compared to WT. These experiments suggested that selectin ligand deficiencies cause increased frequency of effector/memory T cells in LNs due to low density and increased emptiness induced proliferation. Taken together, these findings reveal how selectin ligand deficiencies contribute to T cell accumulation in non-lymphoid organs and elucidate mechanisms of retention in LNs.

T cell

T cell trafficking

immune system

selectin ligand

fucosyltransferase

Immunology and Infectious Disease