The Effect of Sodium Chloride on Beta-Hemolytic Streptococci

Fashola, Bola

01 December 1987

The drug of choice for the treatment of Stieptococcal pharyngitis is penicillin G. However, a common home remedy prescribes the use of salt-water solutions for gargling. Members of Beta -hemolytic streptococcal groups A, B, and C were isolated from the upper -respiratory tracts of patients diagnosed as having streptococcal pharyngitis. These cultures we:e obtained from HCA Greenview Hospital (Bowling Green, Kentucky) and used to study the effects of sodium chloride on the isolates. The minimum inhibitory concentration of sodium chloride was determined for each of eight hospital isolates. Croup A streptococci were inhibited at a concentration of 7.2% sodium chloride while Group C streptococci were inhibited at a 7.0% concentration. Group P streptococci were more resistant, and inhibition of growth occurred at 12.0% sodium chloride concentrations. Scanning electron microscopic studies showed no significant differences in the external structure of cells treated with sodium chloride when compared to non-treated cells. Despite the lack of changes in the external structure of treated cells, fine structural alterations were observed with transmission electron microscopic studies. Treatment of the cells with sodium chloride resulted in a condensation of nucleoid deoxyribonucleic acid (DNA) and some loss of ribosomes. These changes were followed by a dissolution of the cytoplasmic cell contents resulting in an intact cell wall with capsule. Other parameters such as the rate of growth, minimum bactericidal concentrations, DNA content and protein content of cells treated with sodium chloride were examined and compared to control cells.

Biology

Immunology and Infectious Disease

Immunology of Infectious Disease

Life Sciences

The specific immune response in rainbow trout: Somatic hypermutation and VH gene utilization

Lewis, Teresa D.

01 January 2000

The study of antibody responses in prominent aquaculture species such as the rainbow trout, Oncorhynchus mykiss, can facilitate vaccine development and contribute to producing useful paradigms of adaptive immunity in lower vertebrates. Thus, it is essential to identify genes responsible for antibody responses. In the mouse model, hybridoma technology allows for the association of monoclonal antibodies possessing various affinities for antigen with specific VH sequences, gene family utilization, and other molecular events (i.e. somatic hypermutation) that occur during the specific immune response. The absence of a comparable hybridoma technology in piscine systems has limited similar studies of fish immunogenetics to date. Molecular and serological experiments were performed in an attempt to obtain information regarding somatic mutation and VH gene utilization for trout antibodies without reliance on hybridoma technology. PCR primers recognizing consensus sequences of FR1 and FR3 were used to amplify antibody VH sequences from panned, antigen-specific B cells. to follow the development of the expressed VH repertoire, lymphocytes were obtained at weeks 0, 5, 10, and 20 post primary immunization with trinitrophenylated-keyhole limpet hemocyanin (TNP-KLH) or infectious hematopoietic necrosis virus (IHNV). Lymphocytes were also collected 10 weeks post secondary immunization (week 35). These studies were conducted in parallel with serological analyses of plasma antibodies obtained from the same sample in order to correlate molecular data with serological data from individual trout. Antigen-specific lymphocytes were processed to isolate RNA templates to produce cDNA which was cloned and sequenced. This sequence analysis allowed us to report, for the first time, the temporal accumulation of potential somatic variants that correlate to the development of new, high affinity antibody subpopulations during the immune response, some with the emergence of new antibody heavy chain isoelectropherotypes as identified by 2D-IEF/SDS-PAGE. Southern analysis and gene titration using various antigen-specific cDNA probes allowed us to correlate trout antibodies possessing various affinities for antigen with specific VH sequence and gene family utilization. Thus, trout Ig VH gene family utilization appears to follow the mouse model of differential use for specific immune response. These results reveal a capability for fine-tuning the piscine immune response previously not recognized.

Immunology and Infectious Disease

Molecular Biology

Leishmania infantum chagasi induces a dynamic cellular inflammatory response

Thalhofer, Colin Joseph

01 May 2011

Leishmania infantum chagasi (Lic) is a pathogenic protozoan parasite and one of the etiological agents of human visceral leishmaniasis (VL). VL is a potentially deadly disease characterized by variable fevers, cachexia, hepatosplenomegaly, and global immune suppression. Many questions regarding the pathogenesis of VL and the mechanisms of host defense during Lic infection remain to be elucidated. The primary focus of this thesis is the relationship between Lic and the mammalian immune system. We studied parasite-host interactions during Lic infection at the molecular, cellular, and organismal level. We generated transgenic parasites that expressed firefly luciferase and/or fluorescent proteins to expand our capacity to detect, observe, and quantify the parasites in a variety of experimental settings with modern analytical methodologies. Using luciferase-expressing Leishmania, we developed an experimental infection model in which parasites were detected and the relative parasite burden in specific anatomical locations could be quantified in a live animal host using bioluminescence imaging. This method allowed the parasite burden to be assessed in the same host throughout the course of infection. Utilizing this model we have made some intriguing observations relating to the kinetics and distribution of the parasite burden over time. The parasite burden was observed primarily in the liver and bone marrow over the first few weeks and then shifts to the spleen and bone marrow. To gain a better understanding of the initial parasite-host immune interactions in vivo, we studied the early inflammatory response after intradermal (i.d.) inoculation. We observed a rapid and abundant influx of neutrophils into the inoculated ears. The neutrophil influx was transient, dose dependent and specific for the local inoculation site. While there was not a significant neutrophil influx into the draining lymph nodes (dLN), there was an increase in the total cellularity and a striking increase in the relative proportion of B cells to T cells over the first week after intradermal parasite challenge. By inoculating transgenic mCherry-Lic we found that neutrophils were the primary parasite-laden host cell in the dermal tissue during the first day, but macrophages harbored most of the parasites by 2 days. Neutrophil depletion using low-dose antibody treatment resulted in a reduced rate of parasite uptake initially at the site of inoculation, but no significant change in the dLN dynamics. We further examined the parasite-host relationship by studying molecular signaling and cellular interactions between Leishmania and human neutrophils. We investigated the nature of the chemotactic activity of Leishmania-conditioned growth medium for human neutrophils by testing physical properties of the activity and ruled out some of the major Leishmania surface molecules as potential candidates. We aim to identify the agent(s) responsible for the activity in on-going studies. To this end, we are collaborating with a group at the NIH and testing biochemical purification/separation samples. We conclude that intradermal Lic challenge induces a rapid innate immune response at the local site of infection, that neutrophils sense Leishmania-derived factors leading to directed migration, and that neutrophils function as a primary site for Leishmania entry into the mammalian host.

Leishmania

Neutrophil

Immunology of Infectious Disease

Optimization of Cryopreserved Memory CD4 T Cell Mediated Protection against Lethal Influenza A Virus Infection in Mice

Alam, Fahmida

01 January 2020

Interventions for influenza virus infections are essential to minimize the worldwide annual morbidity, mortality, and economic loss caused by this highly contagious respiratory pathogen. Establishment of universal, long-lasting protection against epidemic and pandemic strains of the virus can potentially eradicate the necessity of annual reformulation and readministration of low-efficacious seasonal vaccines, increasing pandemic preparedness. The protective potential of Type 1 T helper (TH1)-polarized memory CD4+ T cells against Influenza A virus (IAV) infection and generation of secondary memory populations following viral clearance are well-characterized. To assess the potential of CD4+ T memory cells as a candidate for adoptive immunotherapy, here we validated and optimized cryopreserved IAV-specific memory CD4+ T cell-mediated protection against infection and evaluated their potential for subsequent memory formation. Donor-derived in vitro-generated memory CD4+ T cells were transferred into IAV-infected naïve mice following cryopreservation of these cells for 6-12 months and overnight activation with gamma-chain cytokines, interleukin (IL)-7 and IL-7+IL-2. Results showed that cytokine-cultured cryopreserved memory CD4+ T cells, compared to their non-cultured counterparts, controlled viral titer in the lung at the peak infection phase, decreased morbidity, expedited recovery, and formed increased secondary memory cells in the lung, the primary site of infection, including lung tissue-resident memory (TRM) CD4+ T cells. Phenotypic and functional analysis confirmed that donor-derived secondary memory CD4+ T cells retain a TH1-phenotype and produce cytokines associated with protection against IAV. These observations support that the protectiveness and memory-forming potential of host- and/or donor-derived memory CD4? T cells can be preserved and harnessed for future use. This T-cell based adoptive immunotherapy addresses some of the current challenges of available preventative and therapeutic options, such as low vaccine efficacy, availability of only early treatment drugs, lack of immunity against pandemic strains and effective memory cell generation.

Immunology and Infectious Disease

Medical Biotechnology

Dynamics of the host-parasite interaction: in vitro correlates of Crassostrea-induced modulation of Perkinsus marinus function

Earnhart, Christopher G.

01 January 2004

Perkinsus marinus is an alveolate protozoan parasite of the eastern oyster (Crassostrea virginica) which is responsible for much of the decline in United States oyster populations. Perkinsus marinus can be cultured in vitro, but is rapidly attenuated in the process. Supplementation of a protein-free medium with oyster products altered proliferation, changed protease expression in the parasite extracellular products (ECP), induced morphological forms typically seen in vivo, and partially reversed parasite attenuation. Supplements derived from dissected oyster tissues were used to determine if these changes could be differentially elicited. These supplements, with the exception of adductor muscle, reduced proliferation. Whole oyster and digestive gland/gonad supplements favored palintomic, rather than binary, fission. The total ECP protease activity was generally decreased in supplemented cultures, though gill/mantle supplements may have induced proteases. A low molecular weight subset of proteases was upregulated most effectively by heart- and adductor muscle-derived supplements. Serine proteases and other ECP proteins may be virulence factors. Attempts to create antibodies to study P. marinus cells and ECP have been largely unsuccessful due to poor immune responses and crossreactivity. Ultrafiltration-concentrated P. marinus ECP were poorly immunogenic and toxic to experimental animals. Immunogenicity was not substantially affected by heat denaturation or proteolytic inhibition. Co-administration of ECP with oyster plasma caused a suppression in the anti-plasma antibody response with restriction of epitope recognition. Analysis of medium constituents revealed that a surfactant, Pluronic F-68 (PF68), was immunosuppressive. Although isolated protein antigens from the ECP remained immunosuppressive, separation of the antigens from PF68 enabled antibody production. Five monoclonal antibodies were created against ECP from unsupplemented medium and were used to study ECP function, regulation, and mechanism of storage and release. ECP are secreted by release from the cell wall and from two morphologically distinct intracellular compartments. A sandwich ELISA allowed quantification of an ECP protein with significantly reduced expression in supplemented cultures. Another antibody, which specifically bound to trophozoite and tomont walls, was used to investigate morphological and antigenic changes during thioglycollate-induced formation of prezoosporangia, and confirm supplement-induced formation of prezoosporangia. This antibody labeled P. marinus cells in fixed oyster tissue in a species-specific manner.

Animal Diseases

Immunology and Infectious Disease

Microbiology

Tonsil Cell Products which Modify in Vitro Proliferation of Blood Lymphocytes

Hodge, Thomas W.

01 May 1982

Human palatine tonsil lymphocytes, when compared to peripheral blood lymphocytes (PBL), were in an activated state even though there was no in vitro stimulation. When these tonsil lymphocytes were cultured in the absence of serum and polyclonal mitogens or antigens, the supernatant fluid often inhibited the proliferative response of target PBL to con A. The extent of this suppression ranged from 22% to 84%, and target cell viability was 90% or greater. There was no evidence for the presence of immunoglobulins or (alpha)2-macroglobulin in whole supernatant fluids. The suppressor was partially denatured at 80(DEGREES)C and was rendered completely inactive upon exposure to 100(DEGREES)C for 5 min. It was trypsin sensitive, and had an apparent molecular weight of 100,000 or greater. The protein adhered strongly to DE-52 cellulose, and the most active material eluted with 0.4-0.6 M NaCl. The suppressor was active in the pH range 5.0 (+OR-) 0.6 as demonstrated by isoelectric focusing. Occasionally, supernatant fluids comprised material which augmented the expected response of con A stimulated PBL. The augmentor was 30,000 in molecular weight and was eluted from DE-52 cellulose in the 0.15-0.25 M NaCl range. Nearly all supernatant preparations tested contained a mitogenic substance which stimulated naive allogeneic human PBL without the necessity of co-stimulation by a mitogen. The mitogenic factor (MF) behaved in a dose dependent fashion and was evidently different from the augmentor since the MF stimulated PBL independently of lectin co-stimulation.

Health and environmental sciences

Immunology

Immunology and Infectious Disease

Generation, Isolation and Assay Methods for Human Lymphocyte Mitogenic Factor

Seay, Thomas E.

01 December 1982

Activated lymphocytes secrete many products including the lymphokine human lymphocyte mitogenic factor (HLMF). In preliminary experiments lymphocytes from peripheral blood and palatine tonsils were evaluated as possible sources of HLMF by evaluating their level of activation through screening their spontaneous and concanavalin A (con A)-induced blastogenic responses. Tonsil lymphocytes (TL) were found to have high spontaneous proliferation as compared to peripheral blood lymphocytes (PBL). Cells from both sources responded to con A by undergoing a typical blastogenic response. Because TL must be obtained septically, they are frequently cultured in the presence of the antimycotic agent, Amphotericin B (Am B). Since the primary and induced blastogenesis of TL were greatly inhibited by even low concentrations of Am B, those lymphocytes were considered unacceptable sources of HLMF. In contrast to TL the induced blastogenic responses of PBL were found to be augmented by concentrations of Am B less than 5 (mu)g/ml, but the drug appeared to provide no beneficial effect on the quantity of HLMF produced by the cells. HLMF appeared to be produced optimally in the first 48 hr of culture by 10('7) PBL/ml, cultured in Neuman-Tytell serumless medium which had been adjusted to 5 x 10('-5) M 2-mercaptoethanol, and 5-35 (mu)g con A/ml. Stability of the HLMF activity could best be maintained by immediate dialysis against 0.05 M NH(,4)HCO(,3) solution, followed by lyophilization and storage of the dried material at -80(DEGREES)C until use. Activity was retained at -80(DEGREES)C for greater than 3 months. The activity was diminished after exposure to 56(DEGREES)C for 30 min, and completely lost after treatment at 80(DEGREES)C for 10 min or 100(DEGREES)C for 5 min. HLMF was insensitive to trypsin and exposure to pH ranges 2-7. Separation of HLMF and con A blastogenic activities was accomplished by addition of ovalbumin followed by Bio-Gel P-100 column Chromatography. HLMF activity eluted in the 12,000-20,000 d and 30,000-50,000 d ranges. The lower molecular weight material was active in the pH range 3.4-4.6 as demonstrated by isoelectric focusing. The larger molecular weight fractions had a pI of 4.14 (+OR-) 0.97. HLMF activated T cells, B cells and unfractionated PBL in assay, with the T cell response being generally, but not always greater. The factor behaved in a dose dependent fashion when assayed against unfractionated PBL.

Health and environmental sciences

Immunology

Immunology and Infectious Disease

Mechanisms of T Cell-mediated Macrophage Activation: Role of Antigen Specific and Antigen Nonspecific Cognate Interactions

Tao, Xiang

01 June 1993

Macrophages play an important role in host antimicrobial immunity and in non-septic inflammatory reactions. Most studies on macrophage activation have focused on the roles of the T cell-produced cytokine, interferon-$\gamma$ (IFN$\gamma)$ and bacterial product, lipopolysaccharide (LPS). T cell-macrophage interaction is a critical step in initiating both specific and nonspecific immune responses to antigenic stimulation. The current study examines the role of cognate T cell-macrophage interaction in activation of macrophage effector functions and induction of macrophage early activation gene expression. Viable resting T$\sb{\rm H}$2 clone cells can activate IFN$\gamma$-primed macrophages to produce reactive nitrogen intermediates (RNI) or express cytostatic activity. The activating signal is mediated by cognate membrane contact between T cells and macrophages as evidenced by the ability of paraformaldehyde fixed anti-CD3-activated T$\sb{\rm H}$2 cells or plasma membranes isolated from the activated T cells to activate the IFN$\gamma$-primed macrophages. In contrast to the antigen-specific interaction of macrophages with viable resting T$\sb{\rm H}$2 cells, the activation of IFN$\gamma$-primed macrophages by fixed activated T$\sb{\rm H}$2 cells or by membranes from activated T$\sb{\rm H}$2 cells does not display antigen specificity. Fixed resting T$\sb{\rm H}$2 cells or plasma membranes isolated from the resting T cells can not activate the IFN$\gamma$-primed macrophages. Similar results are obtained with use of fresh splenic T cells to induce macrophage RNI production and cytostasis. Monoclonal antibody against CD4, which presumably blocks the interaction between CD4 (a co-receptor of T cell receptor) and class II MHC molecules on macrophages, inhibits significantly the activation of IFN$\gamma$-primed macrophages by viable resting T$\sb{\rm H}$2 cells but does not inhibit the ability of fixed activated T$\sb{\rm H}$2 cells to activate the macrophages. To examine the intracellular events in macrophages initiated by the cognate signaling, the expression of a panel of macrophage early activation genes, c-Myc, c-Fos, JE, IP10, D3, TNF$\alpha$ and IL-$\alpha$, are analyzed by dot blot hybridization. Plasma membranes from activated T$\sb{\rm H}$2 cells induce the expression of all these genes in macrophages stimulated for 1-4 hour. In contrast, the plasma membranes from resting T$\sb{\rm H}$2 cells are unable to induce the expression of most of the genes examined. These results suggest that the T cell-macrophage interaction involves reciprocal activation of both cells--an antigen specific activation of the T cells which results in the acquisition of T cell membrane components involved in antigen nonspecific activation of the macrophages. The nature of those T cell membrane components involved in cognate signaling of macrophage is currently being investigated.

Health and environmental sciences

Immunology

Immunology and Infectious Disease

The Development and Application of an Antibody-based Biosensor for the Detection of the Petroleum-derived Compounds

Spier, Candace Rae

01 January 2011

Petroleum is one of the most important natural resources, but can also be problematic to environmental and human health. Petroleum is comprised of thousands of compounds, including polycyclic aromatic hydrocarbons (PAHs) and heterocycles, some of which are toxic and/or carcinogenic. Traditional analytical methods for environmental monitoring of low-level PAHs are time-consuming labor-intensive, and often laboratory-bound. Efforts to achieve timely, sensitive, and accurate analysis of PAHs in the field have become a priority for environmental research and monitoring. Antibody-based biosensors are presently being developed for environmental analysis. Anti-PAH antibody molecules can be coupled with electronic transducers to provide new biosensor technology for the rapid determination and quantification of PAHs. Although PAHs are not immunogenic on their own, advances in immunology have provided the means to develop antibodies to PAHs. Thiophenes, a defined subset of aromatic heterocycles, were selected as the target molecules for antibody development. Characterization of a monoclonal antibody (mAb) to dibenzothiophene revealed specificity for 3 to 5-ring PAHs and heterocycles. Therefore, the goals of antibody development were focused on developing additional antibodies to 2-ring PAHs and to alkylated PAHs. Characterization of antibodies to these novel targets revealed unexpected insights into antibody induction and specificity: namely suitable hapten sizes for small hydrophobic molecule recognition should be larger than one benzene ring, derivatization of the hapten target in immunogen synthesis must preserve structural characteristics, the utility of heterologous assay formats can improve antibody inhibition, and high antibody titers can result in limited assay sensitivity. The anti-dibenzothiophene mAb 7B2.3 was employed, along with a fluorescence-based transducer, for the generation of a new biosensor for PAHs. The biosensor was utilized in a variety of different applications to determine dissolved PAH concentrations including: 1) sampling groundwater at a former wood-treatment (creosote) facility, 2) analyzing estuarine water during the dredging of PAH-contaminated sediments, revealing a plume of PAHs emanating from the dredge site, 3) frequent monitoring of phenanthrene (a 3-ring PAH) concentrations during a laboratory toxicological dosing study, and 4) monitoring PAH concentrations in stormwater runoff into both a retention pond and a river near a roadway. Overall, these applications demonstrated the utility of this biosensor for rapid analysis of PAHs in a variety of aqueous environments. The biosensor was operated on-site for both the estuarine and groundwater monitoring trials. The biosensor could process samples, produce quantitative measurements, and regenerate itself in approximately 10 minutes. Sample volumes of 400 mul could be used with little to no sample pretreatment. Most importantly, PAHs could be quantified down to 0.3 microg/l in the field using the sensor platform. These results were validated with conventional gas chromatography-mass spectrometry and high performance liquid chromatography analytical methods. This system shows great promise as a field instrument for the rapid monitoring of PAH pollution.

Analytical Chemistry

Environmental Sciences

Immunology and Infectious Disease

The induction and regulation of CD4 T cells following respiratory syncytial virus infection

Weiss, Kayla Ann

01 May 2014

Respiratory syncytial virus (RSV) is the leading cause of lower respiratory tract infections in young children. RSV induces variable disease severities in infected children. Severe cases of RSV-induced disease result in bronchiolitis, with a subset of children going onto develop long-term airway morbidities. The host antiviral T cell response is believed to contribute to the severity of pulmonary disease following acute RSV infection. However recent work has questioned the relative proportion of T cells that migrate into the lung tissue following a respiratory virus infection. Using in vivo intravascular antibody labeling, >80% of antigen-specific effector T cells were found to remain in the pulmonary vasculature following an intratracheal infection with the systemic viral pathogen lymphocytic choriomeningitis virus (LCMV). Therefore, I determined the proportion of RSV-specific CD4 T cells located within the lung tissue following infection. In contrast to recent reports with LCMV-specific CD8 T cells, I found approximately 85% of RSV-specific CD4 T cells were located within the lung tissue, indicating that the vast majority of virus-specific effector CD4 T cells are located within the lung tissue and not in the pulmonary vasculature following an acute RSV infection. Genetic variations can occur in the circulating RSV strains both within and between infectious seasons. Therefore, I questioned if different RSV strains could induce differential CD4 T cell responses. I demonstrate that RSV strains induce differential CD4 T helper responses, which are associated with the differential activation of the innate immune response. The RSV line 19 strain induced the early production of the pro-inflammatory cytokines IL-1Β and IL-6 resulting in an increased Th17 response as compared to the RSV strains A2 and 2-20. Blockade and/or neutralization of IL-1Β and IL-6 inhibited the ability of RSV line 19 to induce a Th17 response. These results demonstrate that RSV strains can differentially activate innate immunity that subsequently influences the type of adaptive immune response. This in part may contribute to differential RSV pathogenesis and the development of long-term airway morbidities observed in humans. IL-10 is a pleotropic cytokine able to suppress the adaptive immune response. Because the host adaptive immune response is believed to contribute to RSV-induced pulmonary disease, I evaluated the role of IL-10 in modulating the RSV-specific immune response. I found that IL-10 protein levels in the lung were increased following acute RSV infection with maximum production corresponding to the peak of the virus-specific T cell response. Multiple populations of CD4 T cells accounted for the majority of IL-10 produced in the lung including Foxp3+ Tregs, Foxp3- CD4 T cells that co-produce IFN-Γ, and Foxp3- CD4 T cells that do not co-produce IFN-Γ. Furthermore, RSV-induced disease severity was increased in both the absence of IL-10 and following IL-10 receptor blockade as compared to control mice. I also observed an increase in the magnitude of the RSV-induced CD8 and CD4 T cell response that correlated with increased disease severity following IL-10 receptor blockade. IL-10 receptor blockade during acute RSV infection altered CD4 T cell subset distribution, resulting in a significant increase in IL-17A-producing CD4 T cells and a concomitant decrease in Foxp3+ regulatory T cells. These results demonstrate that IL-10 plays a critical role in modulating the adaptive immune response to RSV by limiting T-cell-mediated pulmonary inflammation and injury. Overall, my data demonstrate that RSV-specific CD4 T cells migrate into the lung tissue with their differentiation influenced by the strain-specific activation of innate immune response. IL-10 is then produced by CD4 T cells to regulate the RSV-specific T cell responses and inhibit virus-induced immunopathology. My data indicate that there are multiple targets for immunotherapy for individuals with severe RSV-induced disease.

Cytokine

T cells

Virus

Immunology of Infectious Disease