Non-Specific (Innate) Immune System Specific (Adaptive) Immune System
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Ch. 43 the Immune System
Ch. 43 The Immune System 1 Essential Questions: How does our immunity arise? How does our immune system work? 2 Overview of immunity: Two kinds of defense: A. innate immunity present at time of birth before exposed to pathogens nonspecific responses, broad in range skin and mucous membranes internal cellular and chemical defenses that get through skin macrophages, phagocytic cells B. acquired immunity (adaptive immunity)develops after exposure to specific microbes, abnormal body cells, foreign substances or toxins highly specific lymphocytes produce antibodies or directly destroy cells 3 Overview of Immune System nonspecific Specific 4 I. Innate immunity Nonspecific defenses A. First line of defense: skin, mucous membranes skin protects against chemical, mechanical, pathogenic, UV light damage mucous membranes line digestive, respiratory, and genitourinary tracts prevent pathogens by trapping in mucus *breaks in skin or mucous membranes = entryway for pathogen 5 secretions of skin also protect against microbes sebaceous and sweat glands keep pH at 35 stomach also secretes HCl (Hepatitis A virus can get past this) produce antimicrobial proteins (lysozyme) ex. in tears http://vrc.belfastinstitute.ac.uk/resources/skin/skin.htm 6 B. Second line of defense internal cellular and chemical defenses (still nonspecific) phagocytes produce antimicrobial proteins and initiate inflammation (helps limit spread of microbes) bind to receptor sites on microbe, then engulfs microbe, which fused with lysosome nitric oxide and poisons in lysosome can poison microbe lysozyme and other enzymes degrade the microbe *some bacteria have capsule that prevents attachment *some bacteria are resistant to lysozyme macrophages 7 Cellular Innate defenses Tolllike receptor (TLR) recognize fragments of molecules characteristic of a set of pathogens [Ex. -
WHITE BLOOD CELLS Formation Function ~ TEST YOURSELF
Chapter 9 Blood, Lymph, and Immunity 231 WHITE BLOOD CELLS All white blood cells develop in the bone marrow except Any nucleated cell normally found in blood is a white blood for some lymphocytes (they start out in bone marrow but cell. White blood cells are also known as WBCs or leukocytes. develop elsewhere). At the beginning of leukopoiesis all the When white blood cells accumulate in one place, they grossly immature white blood cells look alike even though they're appear white or cream-colored. For example, pus is an accu- already committed to a specific cell line. It's not until the mulation of white blood cells. Mature white blood cells are cells start developing some of their unique characteristics larger than mature red blood cells. that we can tell them apart. There are five types of white blood cells. They are neu- Function trophils, eosinophils, basophils, monocytes and lymphocytes (Table 9-2). The function of all white blood cells is to provide a defense White blood cells can be classified in three different ways: for the body against foreign invaders. Each type of white 1. Type of defense function blood cell has its own unique role in this defense. If all the • Phagocytosis: neutrophils, eosinophils, basophils, mono- white blood cells are functioning properly, an animal has a cytes good chance of remaining healthy. Individual white blood • Antibody production and cellular immunity: lympho- cell functions will be discussed with each cell type (see cytes Table 9-2). 2. Shape of nucleus In providing defense against foreign invaders, the white • Polymorphonuclear (multilobed, segmented nucleus): blood cells do their jobs primarily out in the tissues. -
Antibody-Dependent Cellular Cytotoxicity Riiia and Mediate Γ
Effector Memory αβ T Lymphocytes Can Express Fc γRIIIa and Mediate Antibody-Dependent Cellular Cytotoxicity This information is current as Béatrice Clémenceau, Régine Vivien, Mathilde Berthomé, of September 27, 2021. Nelly Robillard, Richard Garand, Géraldine Gallot, Solène Vollant and Henri Vié J Immunol 2008; 180:5327-5334; ; doi: 10.4049/jimmunol.180.8.5327 http://www.jimmunol.org/content/180/8/5327 Downloaded from References This article cites 43 articles, 21 of which you can access for free at: http://www.jimmunol.org/content/180/8/5327.full#ref-list-1 http://www.jimmunol.org/ Why The JI? Submit online. • Rapid Reviews! 30 days* from submission to initial decision • No Triage! Every submission reviewed by practicing scientists • Fast Publication! 4 weeks from acceptance to publication by guest on September 27, 2021 *average Subscription Information about subscribing to The Journal of Immunology is online at: http://jimmunol.org/subscription Permissions Submit copyright permission requests at: http://www.aai.org/About/Publications/JI/copyright.html Email Alerts Receive free email-alerts when new articles cite this article. Sign up at: http://jimmunol.org/alerts The Journal of Immunology is published twice each month by The American Association of Immunologists, Inc., 1451 Rockville Pike, Suite 650, Rockville, MD 20852 Copyright © 2008 by The American Association of Immunologists All rights reserved. Print ISSN: 0022-1767 Online ISSN: 1550-6606. The Journal of Immunology Effector Memory ␣ T Lymphocytes Can Express Fc␥RIIIa and Mediate Antibody-Dependent Cellular Cytotoxicity1 Be´atrice Cle´menceau,*† Re´gine Vivien,*† Mathilde Berthome´,*† Nelly Robillard,‡ Richard Garand,‡ Ge´raldine Gallot,*† Sole`ne Vollant,*† and Henri Vie´2*† Human memory T cells are comprised of distinct populations with different homing potential and effector functions: central memory T cells that mount recall responses to Ags in secondary lymphoid organs, and effector memory T cells that confer immediate protection in peripheral tissues. -
Automatic System for Differential Blood Counting
ISSN (Print) : 2320 – 3765 ISSN (Online): 2278 – 8875 International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering (An ISO 3297: 2007 Certified Organization) Vol. 5, Issue 4, April 2016 Automatic System for Differential Blood Counting 1 2 Manisha Shirvoikar , Dr.H.G.Virani PG Student [ECI], Dept. of ETC, Goa College of Engineering, Ponda, Goa, India1 Professor & Head of Department, Dept. of ETC, Goa College of Engineering, Ponda, Goa, India2 ABSTRACT: For detecting various diseases, Doctor first suggests the patient to undergo blood test which is used as a health indicator. Differential Blood Count (DBC) provides haematologist with valuable information about health of the patient. DBC determines the percentage of types of WBC this is important because it give exact count of five types of WBC such as neutrophil, lymphocyte, monocyte, eosinophil and basophile. Increase or decrease of DBC than the ideal count indicated that our body is not healthy. Precise counting of type of WBC is very important. Manual counting of White blood cells is time consuming and can lead to human error with increase in number of samples. Automatic cell counter sometimes misclassifies the cells having different morphology. Even they are very expensive and unaffordable by remote area health centres and hospitals. These problems are overcome by developing a system which is image based, cost effective, fast and accurate which has the capability to identify, classify the different type of white blood cell and perform DBC. Implementation is done using MATLABR2014b. KEYWORDS: MATLAB, peripheral blood smear, RBC, Thresholding, WBC, DBC. I.INTRODUCTION Total volume of blood in human is 5-6 litres i.e 8% of body weight or 80 mL/kg body weight. -
The RAG Recombinase Dictates Functional Heterogeneity and Cellular Fitness in Natural Killer Cells
The RAG Recombinase Dictates Functional Heterogeneity and Cellular Fitness in Natural Killer Cells Jenny M. Karo,1 David G. Schatz,2 and Joseph C. Sun1,* 1Immunology Program and Gerstner Sloan Kettering Graduate School of Biomedical Sciences, Memorial Sloan Kettering Cancer Center, New York, NY 10065, USA 2Department of Immunobiology and the Howard Hughes Medical Institute, Yale University School of Medicine, New Haven, CT 06510, USA *Correspondence: [email protected] http://dx.doi.org/10.1016/j.cell.2014.08.026 SUMMARY completely absent (Mombaerts et al., 1992; Shinkai et al., 1992). There is as yet no evidence that RAG plays a physiological The emergence of recombination-activating genes role in any cell type other than B and T lymphocytes or in any pro- (RAGs) in jawed vertebrates endowed adaptive cess other than V(D)J recombination. immune cells with the ability to assemble a diverse Although NK cells have long been classified as a component set of antigen receptor genes. In contrast, innate of the innate immune system, recent evidence suggests that lymphocytes, such as natural killer (NK) cells, are this cell type possesses traits attributable to adaptive immunity not believed to require RAGs. Here, we report that (Sun and Lanier, 2011). These characteristics include ‘‘educa- tion’’ mechanisms to ensure self-tolerance during NK cell devel- NK cells unable to express RAGs or RAG endonu- opment and clonal-like expansion of antigen-specific NK clease activity during ontogeny exhibit a cell-intrinsic cells during viral infection, followed by the ability to generate hyperresponsiveness but a diminished capacity long-lived ‘‘memory’’ NK cells. -
LECTURE 05 Acquired Immunity and Clonal Selection
LECTURE: 05 Title: ACQUIRED "ADAPTIVE" IMMUNITY & CLONAL SELECTION THEROY LEARNING OBJECTIVES: The student should be able to: • Recognize that, acquired or adaptive immunity is a specific immunity. • Explain the mechanism of development of the specific immunity. • Enumerate the components of the specific immunity such as A. Primary immune response. B. Secondary immune response • Explain the different phases that are included in the primary and secondary immune responses such as: A. The induction phase. B. Exponential phase. C. Steady phase. D. Decline phase. • Compare between the phases of the primary and secondary immune responses. • Determine the type of the immunoglobulins involved in each phase. • Determine which immunoglobulin is induced first and, that last longer. • Enumerate the characteristics of the specific immunity such as: A. The ability to distinguish self from non-self. B. Specificity. C. Immunological memory. • Explain naturally and artificially acquired immunity (passive, and active). • Explain the two interrelated and independent mechanisms of the specific immune response such as : A. Humoral immunity. B. Cell-mediated (cellular) immunity. • Recognize that, the specific immunity is not always protective, for example; sometimes it causes allergies (hay fever), or it may be directed against one of the body’s own constituents, resulting in autoimmunity (thyroditis). LECTURE REFRENCE: 1. TEXTBOOK: ROITT, BROSTOFF, MALE IMMUNOLOGY. 6th edition. Chapter 2. pp. 15-31 2. TEXTBOOK: ABUL K. ABBAS. ANDREW H. LICHTMAN. CELLULAR AND MOLECULAR IMMUNOLOGY. 5TH EDITION. Chapter 1. pg 3-12. 1 ACQUIRED (SPECIFIC) IMMUNITY INTRODUCTION Adaptive immunity is created after an interaction of lymphocytes with particular foreign substances which are recognized specifically by those lymphocytes. -
Med-Pathway Zoom Workshop
MCAT Immunology Dr. Phillip Carpenter medpathwaymcat Med-pathway AAMC MCAT Content Outline: Immunology Category 1A: Structure/Function of Proteins/AA Immune System Category 3B: Organ Systems Innate vs. Adaptive Immunity T and B Lymphocytes Macrophages & Phagocytes Tissue-Bone marrow, Spleen, Thymus, Lymph nodes Antigen and Antibody Antigen Presentation Clonal Selection Antigen-Antibody recognition Structure of antibody molecule Self vs. Non-self, Autoimmune Diseases Major Histocompatibility Complex Lab Techniques: ELISA & Western Blotting Hematopoiesis Creates Immune Cells Self vs. Non-self Innate vs Adaptive Innate Immunity Physical Barriers: Skin, mucous membranes, pH Inflammatory mediators: Complement, Cytokines, Prostaglandins Cellular Components: Phagocytes-Neutrophils, Eosinophils, Basophils, Mast Cells Antigen Presenting Cells-Monocytes, Macrophages, Dendritic Cells Adaptive (Acquired) Immunity Composed of B and T lymphocytes: Activated by Innate Immunity B cells: Express B cell receptor and secrete antibodies as plasma cells T cells: Mature in thymus, express TCR surface receptor; Activated by Antigen Presenting Cells (APCs) Direct Immune response (The Ringleaders of immune system) Major Lymphoid Organs TYPE SITE FUNCTION Fetal production of Liver 1° lymphoid cells Hematopoietic production of 1° Bone marrow myeloid and lymphoid cells Receives bone marrow T 1° Thymus cells; site where self is selected from non-self Lymph nodes 2° Sites of antigen activation Spleen of lymphocytes; clearance Macrophages (Sentinel Cells) Pattern Recognition -
Digitalcommons@UNMC Granulocytopenia
University of Nebraska Medical Center DigitalCommons@UNMC MD Theses Special Collections 5-1-1936 Granulocytopenia Howard E. Mitchell University of Nebraska Medical Center This manuscript is historical in nature and may not reflect current medical research and practice. Search PubMed for current research. Follow this and additional works at: https://digitalcommons.unmc.edu/mdtheses Part of the Medical Education Commons Recommended Citation Mitchell, Howard E., "Granulocytopenia" (1936). MD Theses. 457. https://digitalcommons.unmc.edu/mdtheses/457 This Thesis is brought to you for free and open access by the Special Collections at DigitalCommons@UNMC. It has been accepted for inclusion in MD Theses by an authorized administrator of DigitalCommons@UNMC. For more information, please contact [email protected]. G PA~lULOCYTOPENI A SENIOR THESIS By Howard E. Mitchell April 17, 1936 TABLE OF CONT'ENTS Introduction Definition • · 1 History . • • • 1 Nomenclature • • • • • 4 ClassificBtion • • • • 6 Physiology • • • • .10 Etiology • • 22 Geographic Distribution • 23 Age, Sex, and R9ce • • ·• 23 Occupation • .. • • • • .. • 23 Ba.cteria • • • • .. 24 Glandu18.r Dysfunction • • • 27 Radiation • • • • 28 Allergy • • • 28 Chemotactic and Maturation Factors • • 28 Chemicals • • • • • 30 Pathology • • • • • 36 Symptoms • • • • • • • 43 DiEtgnosis • • • • • .. • • • • • .. • 4'7 Prognosis 48 '" • • • • • • • • • • • • Treatment • • • • • • • • 49 Non"'specific Therapy • • • • .. 50 Transfusion • • • • .. 51 X-Ray • • • • • • • • • 52 Liver ·Extract • • • • • • • 53 Nucleotides • • • • • • • • • • • 53 General Ca.re • • • • • • • • 57 Conclusion • • • • • • • • • 58 480805 INTHODUCTION Although t~ere is reference in literature of the Nineteenth Century to syndromes similating the disease (granulocytopenia) 9.8 W(~ know it todes, it "vas not un til the year 1922 that Schultz 8ctually described his C8se as a disease entity and by so doing, stimulated the interest of tne medical profession to further in vestigation. -
A Novel CD4+ CTL Subtype Characterized by Chemotaxis and Inflammation Is Involved in the Pathogenesis of Graves’ Orbitopa
Cellular & Molecular Immunology www.nature.com/cmi ARTICLE OPEN A novel CD4+ CTL subtype characterized by chemotaxis and inflammation is involved in the pathogenesis of Graves’ orbitopathy Yue Wang1,2,3,4, Ziyi Chen 1, Tingjie Wang1,2, Hui Guo1, Yufeng Liu2,3,5, Ningxin Dang3, Shiqian Hu1, Liping Wu1, Chengsheng Zhang4,6,KaiYe2,3,7 and Bingyin Shi1 Graves’ orbitopathy (GO), the most severe manifestation of Graves’ hyperthyroidism (GH), is an autoimmune-mediated inflammatory disorder, and treatments often exhibit a low efficacy. CD4+ T cells have been reported to play vital roles in GO progression. To explore the pathogenic CD4+ T cell types that drive GO progression, we applied single-cell RNA sequencing (scRNA-Seq), T cell receptor sequencing (TCR-Seq), flow cytometry, immunofluorescence and mixed lymphocyte reaction (MLR) assays to evaluate CD4+ T cells from GO and GH patients. scRNA-Seq revealed the novel GO-specific cell type CD4+ cytotoxic T lymphocytes (CTLs), which are characterized by chemotactic and inflammatory features. The clonal expansion of this CD4+ CTL population, as demonstrated by TCR-Seq, along with their strong cytotoxic response to autoantigens, localization in orbital sites, and potential relationship with disease relapse provide strong evidence for the pathogenic roles of GZMB and IFN-γ-secreting CD4+ CTLs in GO. Therefore, cytotoxic pathways may become potential therapeutic targets for GO. 1234567890();,: Keywords: Graves’ orbitopathy; single-cell RNA sequencing; CD4+ cytotoxic T lymphocytes Cellular & Molecular Immunology -
Understanding the Immune System: How It Works
Understanding the Immune System How It Works U.S. DEPARTMENT OF HEALTH AND HUMAN SERVICES NATIONAL INSTITUTES OF HEALTH National Institute of Allergy and Infectious Diseases National Cancer Institute Understanding the Immune System How It Works U.S. DEPARTMENT OF HEALTH AND HUMAN SERVICES NATIONAL INSTITUTES OF HEALTH National Institute of Allergy and Infectious Diseases National Cancer Institute NIH Publication No. 03-5423 September 2003 www.niaid.nih.gov www.nci.nih.gov Contents 1 Introduction 2 Self and Nonself 3 The Structure of the Immune System 7 Immune Cells and Their Products 19 Mounting an Immune Response 24 Immunity: Natural and Acquired 28 Disorders of the Immune System 34 Immunology and Transplants 36 Immunity and Cancer 39 The Immune System and the Nervous System 40 Frontiers in Immunology 45 Summary 47 Glossary Introduction he immune system is a network of Tcells, tissues*, and organs that work together to defend the body against attacks by “foreign” invaders. These are primarily microbes (germs)—tiny, infection-causing Bacteria: organisms such as bacteria, viruses, streptococci parasites, and fungi. Because the human body provides an ideal environment for many microbes, they try to break in. It is the immune system’s job to keep them out or, failing that, to seek out and destroy them. Virus: When the immune system hits the wrong herpes virus target or is crippled, however, it can unleash a torrent of diseases, including allergy, arthritis, or AIDS. The immune system is amazingly complex. It can recognize and remember millions of Parasite: different enemies, and it can produce schistosome secretions and cells to match up with and wipe out each one of them. -
Ingenuity Pathway Analysis of Human Facet Joint Tissues: Insight Into Facet Joint Osteoarthritis
EXPERIMENTAL AND THERAPEUTIC MEDICINE 19: 2997-3008, 2020 Ingenuity pathway analysis of human facet joint tissues: Insight into facet joint osteoarthritis CHU CHEN*, SHENGYU CUI*, WEIDONG LI, HURICHA JIN, JIANBO FAN, YUYU SUN and ZHIMING CUI Department of Spine Surgery, The Second Affiliated Hospital of Nantong University, Nantong, Jiangsu 226001, P.R. China Received August 17, 2019; Accepted January 30, 2020 DOI: 10.3892/etm.2020.8555 Abstract. Facet joint osteoarthritis (FJOA) is a common the top 5 IPA networks (with a score >30). The present study degenerative joint disorder with high prevalence in the elderly. provides insight into the pathological processes of FJOA from FJOA causes lower back pain and lower extremity pain, and a genetic perspective and may thus benefit the clinical treat- thus severely impacts the quality of life of affected patients. ment of FJOA. Emerging studies have focused on the histomorphological and histomorphometric changes in FJOA. However, the dynamic Introduction genetic changes in FJOA have remained to be clearly deter- mined. In the present study, previously obtained RNA deep Facet joint osteoarthritis (FJOA) is a common degenerative sequencing data were subjected to an ingenuity pathway joint disorder that causes the degeneration and breakdown analysis (IPA) and canonical signaling pathways of differ- of cartilage and restricts the movement of joints (1). It has entially expressed genes (DEGs) in FJOA were studied. The been reported that lumbar FJOA occurs at high prevalence top 25 enriched canonical signaling pathways were identified and the presence of FJOA is highly associated with age (2,3). and canonical signaling pathways with high absolute values A community-based cross-sectional study indicated that of z-scores, specifically leukocyte extravasation signaling, in populations aged <50 years, the prevalence of FJOA was Tec kinase signaling and osteoarthritis pathway, were inves- <45%, while it was ~75% in populations aged >50 years (4). -
Late Stages of T Cell Maturation in the Thymus
ARTICLES Late stages of T cell maturation in the thymus involve NF-B and tonic type I interferon signaling Yan Xing, Xiaodan Wang, Stephen C Jameson & Kristin A Hogquist Positive selection occurs in the thymic cortex, but critical maturation events occur later in the medulla. Here we defined the precise stage at which T cells acquired competence to proliferate and emigrate. Transcriptome analysis of late gene changes suggested roles for the transcription factor NF-B and interferon signaling. Mice lacking the inhibitor of NF-B (IB) kinase (IKK) kinase TAK1 underwent normal positive selection but exhibited a specific block in functional maturation. NF-B signaling provided protection from death mediated by the cytokine TNF and was required for proliferation and emigration. The interferon signature was independent of NF-B; however, thymocytes deficient in the interferon- (IFN-) receptor IFN-R showed reduced expression of the transcription factor STAT1 and phenotypic abnormality but were able to proliferate. Thus, both NF-B and tonic interferon signals are involved in the final maturation of thymocytes into naive T cells. T cell development occurs in the thymus, which provides a unique reside predominantly in the medulla; however, not all SP thymocytes microenvironment and presents ligands consisting of self peptide and are equivalent. major histocompatibility complex (MHC) molecules to T cell anti- CD24hiQa2lo SP thymocytes have been defined as ‘semi-mature’ gen receptors (TCRs). In the cortex of the thymus, low-affinity TCR and have been shown to be susceptible to apoptosis when triggered interactions initiate positive selection signals in CD4+CD8+ double- through the TCR6.