SlideShare a Scribd company logo

Bacterial toxins

Bruno Mmassy
Bruno Mmassy
EducationTechnologyHealth & Medicine
1 of 30
Download to read offline
BACTERIAL TOXINS HOZA, A.S BLS 2009
TOXIGENESIS Two types of bacterial toxins 1. Lipopolysaccharides: are associated with the cell walls of Gram-ve bacteria.  The lipopolysaccharide (LPS) component of the Gram-ve bacterial outer membrane bears the name endotoxin because of its association with the cell wall of bacteria. 2. Proteins: may be released into the extracellular environment of pathogenic bacteria. Most of the protein toxins are thought of as exotoxins, since they are "released" from the bacteria and act on host cells at a distance. A.S. HOZA
1. BACTERIAL PROTEIN TOXINS The protein toxins are soluble proteins secreted by living bacteria during exponential growth. The production of protein toxins is specific to a particular bacterial species - (e.g. only Clostridium tetani produces tetanus toxin. - only Corynebacterium diphtheriae produces the diphtheria toxin. Usually, virulent strains of the bacterium produce the toxin (or range of toxins) while non-virulent strains do not.  Toxin is the major determinant of virulence. Both Gram-positive and Gram-negative bacteria produce soluble protein toxins. Bacterial protein toxins are the most potent poisons known and may show activity at very high dilutions. A.S. HOZA
1. BACTERIAL PROTEIN TOXINS The protein toxins resemble enzymes. Like enzymes, bacterial exotoxins are: proteins denatured by heat, acid, proteolytic enzymes have a high biological activity (most act catalytically) exhibit specificity of action Bacterial protein toxins are highly specific in the substrate utilized and in their mode of action. Usually the site of damage caused by the toxin indicates the location of the substrate for that toxin. Terms such as "enterotoxin", "neurotoxin", "leukocidin" or "hemolysin" are used to indicate the target site of some well-defined protein toxins. A.S. HOZA
BACTERIAL PROTEIN TOXINS Certain protein toxins have very specific cytotoxic activity (i.e., they attack specific cells, for example, tetanus or botulinum toxins) Some (as produced by staphylococci, streptococci, clostridia, etc.) have fairly broad cytotoxic activity and cause nonspecific death of tissues (necrosis). Toxins that are phospholipases may be relatively nonspecific in their cytotoxicity. This is also true of pore-forming "hemolysins" and "leukocidins". A few protein toxins cause death of the host and are known as "lethal toxins", (e.g. anthrax toxin). A.S. HOZA
BACTERIAL PROTEIN TOXINS Protein toxins are strongly antigenic. In vivo, specific antibody (antitoxin) neutralizes the toxicity of these bacterial proteins. In vitro, specific antitoxin may not fully inhibit their enzymatic activity. Protein toxins are inherently unstable: In time they lose their toxic properties but retain their antigenic ones. Toxoids: are detoxified toxins which retain their antigenicity and their immunizing capacity (first discovered by Ehrlich) A.S. HOZA
BACTERIAL PROTEIN TOXINS The formation of toxoids can be accelerated by:  treating toxins with a variety of reagents including formalin, iodine, pepsin, ascorbic acid, ketones, etc. The mixture is maintained at 37o at pH range 6 to 9 for several weeks. Toxoids can be use for artificial immunization against diseases caused by pathogens where the primary determinant of bacterial virulence is toxin production. E.g immunizing against diphtheria and tetanus that are part of the DPT vaccine. A.S. HOZA
1. BACTERIAL PROTEIN TOXINS A + B Subunit Arrangement of Protein Toxins Many protein toxins, consist of two components: 1. Subunit A: responsible for the enzymatic activity of the toxin. 2. Subunit B: concerned with binding to a specific receptor on the host cell membrane and transferring the enzyme across the membrane.  The enzymatic component is not active until it is released from the native toxin.  Isolated A subunits are enzymatically Tertiary structure of the active and but lack binding and cell entry pertussis toxin produced by capability. Bordetella pertussis. Pertussis  Isolated B subunits may bind to target toxin is a member of the A-B bacterial toxin superfamily. It is cells (and even block the binding of the a hexameric protein comprising native A+B toxin), but they are nontoxic. five distinct subunits, A.S. HOZA
2. ENDOTOXINS Endotoxins are: Part of the outer cell wall of bacteria. Invariably associated with Gram-ve bacteria as constituents of the outer membrane of the cell wall. NB: Endotoxin: Occasionally used to refer to any "cell-associated" bacterial toxin. But should be reserved for the lipopolysaccharide complex associated with the outer envelope of Gram-ve bacteria such as E. coli, Salmonella, Shigella, Pseudomonas, Neisseria, Haemophilus, and other leading pathogens. Lipopolysaccharide (LPS) participates:  in a number of outer membrane functions essential for bacterial growth and survival, especially within the context of a host-parasite interaction. A.S. HOZA
2. ENDOTOXINS The biological activity of endotoxin is associated with the lipopolysaccharide (LPS). Toxicity is associated with the lipid component (Lipid A) and Immunogenicity (antigenicity) is associated with the polysaccharide components. The cell wall antigens (O antigens) of Gram-negative bacteria are components of LPS. LPS activates complement by the alternative (properdin) pathway and may be a part of the pathology of most Gram-negative bacterial infections. A.S. HOZA
2. ENDOTOXINS NB 2: Most part of endotoxins remain associated with the cell wall until disintegration of the bacteria. In vivo, this results from autolysis, external lysis, and phagocytic digestion of bacterial cells. Small amounts of endotoxin may be released in a soluble form, especially by young cultures. Compared to the classic exotoxins of bacteria, endotoxins are less potent and less specific in their action, since they do not act enzymatically. Endotoxins are heat stable (boiling for 30 min does not destabilize endotoxin). but certain powerful oxidizing agents such as , superoxide, peroxide and hypochlorite degrade them. Endotoxins, although strongly antigenic, cannot be converted to toxoids. A.S. HOZA
CHARACTERISTICS OF BACTERIAL ENDOTOXINS AND EXOTOXINS PROPERTY ENDOTOXIN EXOTOXIN Lipopolysaccharide (mw = Chemical nature Protein (mw = 50-1000kDa) 10kDa) Relationship to cell Part of outer membrane Extracellular, diffusible Denatured by boiling No Usually Antigenic Yes Yes Form toxoid No Yes Potency Relatively low (>100ug) Relatively high (1 ug) Specificity Low degree High degree Enzymatic activity No Usually Pyrogenicity Yes Occasionally A.S. HOZA
2. ENDOTOXINS Lipopolysaccharides:  Are complex amphiphilic molecules with a mw of about 10kDa, that vary widely in chemical composition both between and among bacterial species.  In a basic ground plan common to all endotoxins, LPS consists of three components: (1) Lipid A (2) Core polysaccharide (3) O polysaccharide A.S. HOZA
2. Endotoxins: heat stable A.S. HOZA
2. ENDOTOXINS 1. Lipid A :  Lipid component of LPS.  Contains the hydrophobic, membrane-anchoring region of LPS.  Lipid A consists of a phosphorylated N-acetylglucosamine (NAG) dimer with 6 or 7 fatty acids (FA) attached.  6 FA are found. All FA in Lipid A are saturated.  Some FA are attached directly to the NAG dimer and others are esterified to the 3-hydroxy fatty acids that are characteristically present.  The structure of Lipid A is highly conserved among Gram-ve bacteria.  Among Enterobacteriaceae Lipid A is virtually constant A.S. HOZA
2. ENDOTOXINS 2. Core (R) polysaccharide: Is attached to the 6 position of one NAG. The R antigen consists of a short chain of sugars. For example: KDO - Hep - Hep - Glu - Gal - Glu - GluNAc. Two unusual sugars - present Heptose and 2-keto-3-deoxyoctonoic acid (KDO), in the core polysaccharide. KDO is unique and invariably present in LPS and so has been an indicator in assays for LPS (endotoxin). A.S. HOZA
2. ENDOTOXINS Core polysaccharide is common to all members of a bacterial genus with minor variations (e.g. Salmonella). but it is structurally distinct in other genera of Gram-negative bacteria. Salmonella, Shigella and Escherichia have similar but not identical cores. A.S. HOZA
2. ENDOTOXINS 3. O polysaccharide (also referred to as the O antigen or O side chain): Is attached to the core polysaccharide. Consists of repeating oligosaccharide subunits made up of 3-5 sugars. The individual chains vary in length ranging up to 40 repeat units. O polysaccharide is much longer than the core polysaccharide and it maintains the hydrophilic domain of the LPS molecule. A.S. HOZA
2. ENDOTOXINS A unique group of sugars, called dideoxyhexoses, occurs in the O polysaccharide. A major antigenic determinant (antibody-combining site) of the Gram-negative cell wall resides in the O polysaccharide. Great variation occurs in the composition of the sugars in the O side chain between species and even strains of Gram-negative bacteria. A.S. HOZA
2. ENDOTOXINS LPS and virulence of Gram-negative bacteria Endotoxins are toxic to most mammals. They are strong antigens but they seldom elicit immune responses which give full protection to the animal against secondary challenge with the endotoxin. Cannot be toxoided. Endotoxins released from multiplying or disintegrating bacteria significantly contribute to the symptoms of Gram-ve bacteremia and septicemia important pathogenic factors in Gram-ve infections. A.S. HOZA
2. ENDOTOXINS Regardless of the bacterial source all endotoxins produce the same range of biological effects in the animal host. Injection of living or killed Gram-ve cells, or purified LPS, into experimental animals wide spectrum of nonspecific pathophysiological reactions related to inflammation such as: fever changes in white blood cell counts disseminated intravascular coagulation tumor necrosis hypotension shock A.S. HOZA
2. ENDOTOXINS The role of Lipid A Physiological activities of endotoxins- mediated mainly by the Lipid A component of LPS. Lipid A is the toxic component of LPS. Its biological activity depends on a peculiar conformation determined by the glucosamine disaccharide, PO4 groups, Acyl chains, and KDO-containing inner core. Lipid A is known to react at the surfaces of macrophages release cytokines that mediate the pathophysiological response to endotoxin. A.S. HOZA
2. ENDOTOXINS The role of the O polysaccharide Although nontoxic, the polysaccharide side chain (O antigen) of LPS may act as a determinant of virulence in Gram-ve bacteria. O polysaccharide is responsible for the property of "smoothness" of bacterial cells, which may contribute to their resistance to phagocytic engulfment. O polysaccharide is hydrophilic and may allow diffusion or delivery of the toxic lipid in the hydrophilic (in vivo) environment. A.S. HOZA
2. ENDOTOXINS Long side chains of LPS afforded by the O polysaccharide may prevent host complement from depositing on the bacterial cell surface which would bring about bacterial cell lysis. O polysaccharide may supply a bacterium with its specific ligands (adhesins) for colonization which is essential for expression of virulence. O-polysaccharide is antigenic, and the usual basis for antigenic variation in Gram-ve bacteria rests in differences in their O polysaccharides. A.S. HOZA
Pathogenicity Islands Pathogenicity Islands (PAI): Are a distinct class of genomic islands which are acquired by horizontal gene transfer. Incorporated in the genome of pathogenic bacteria usually absent from non-pathogenic organisms of the same or closely related species. They occupy relatively large genomic regions ranging from 10-200 kb encode genes which contribute to virulence of the pathogen. Typical examples: adhesins, toxins, iron uptake systems, invasins, etc. A.S. HOZA
Pathogenicity Islands One species of bacteria may have more than one pathogenicity island. For example, in Salmonella, five pathogenicity islands have been identified. Found mainly in Gram-ve bacteria, but have been shown in a few Gram-positives. Found in pathogens that undergo gene transfer by plasmid, phage, or a conjugative transposon and are typically transferred through mechanisms of horizontal gene transfer (HGT). A.S. HOZA
Pathogenicity Islands May be located on the bacterial chromosome or may be a part of a plasmid. Are rich in Guanine + Cytosine content. They are flanked by direct repeats i.e., the sequence of bases at two ends are the same. Are associated with tRNA genes, which target sites for the integration of DNA. Have characteristics of transposons in that they carry functional genes  e.g. integrase, transposase, or part of insertion sequences may move from one tRNA locus to another on the chromosome or plasmid. A.S. HOZA
Pathogenicity Islands Play a vital role in the virulence of bacterial pathogens of humans , animals and plants. The availability of a large number of genome sequences of pathogenic bacteria and their nonpathogenic relatives identification of novel pathogen-specific genomic islands. PAI apparently -acquired during the speciation of pathogens from their nonpathogenic or environmental ancestors. The acquisition of PAI is an ancient evolutionary event that led to the appearance of bacterial pathogens on a timescale of millions of years May also represent a mechanism that contributes to the appearance of new pathogens. A.S. HOZA
Pathogenicity Islands Knowledge about PAI, their structure, their mobility, and the pathogenicity factors they encode is helpful: a) In gaining a better understanding of bacterial evolution and interactions of pathogens with eucaryotic host cells b) Also may have important practical implications such as providing delivery systems for vaccination and tools for the development of new strategies for therapy of bacterial infections. A.S. HOZA
Pathogenicity Islands PAIs represent distinct genetic elements encoding virulence factors of pathogenic bacteria Belong to a more general class of genomic islands Common genetic elements sharing a set of unifying features. Genomic islands have been acquired by horizontal gene transfer. In recent years many different genomic islands have been discovered in a variety of pathogenic as well as non-pathogenic bacteria. Because they promote genetic variability, genomic islands play an important role in microbial evolution A.S. HOZA

Recommended

Bacterial toxins
Bacterial toxins Bacterial toxins
Bacterial toxins Nagaraj Salapakshi
 
Bacterial pathogenesis
Bacterial pathogenesisBacterial pathogenesis
Bacterial pathogenesisBruno Mmassy
 
BACTERIAL TOXINS
BACTERIAL TOXINSBACTERIAL TOXINS
BACTERIAL TOXINSDebiprasad1997
 
Immunity to Microbes
Immunity to MicrobesImmunity to Microbes
Immunity to MicrobesMd Murad Khan
 
The complement system
The complement systemThe complement system
The complement systemsushma93
 
BACTERIAL TOXINS
BACTERIAL TOXINSBACTERIAL TOXINS
BACTERIAL TOXINSShirsak Mondal
 
antigen antibody interaction
antigen antibody interactionantigen antibody interaction
antigen antibody interactionArunima Sur
 
Epsilometer Test
Epsilometer TestEpsilometer Test
Epsilometer TestDr. Samira Fattah
 

Recommended

Bacterial toxins
Bacterial toxins Bacterial toxins
Bacterial toxins Nagaraj Salapakshi
 
Bacterial pathogenesis
Bacterial pathogenesisBacterial pathogenesis
Bacterial pathogenesisBruno Mmassy
 
BACTERIAL TOXINS
BACTERIAL TOXINSBACTERIAL TOXINS
BACTERIAL TOXINSDebiprasad1997
 
Immunity to Microbes
Immunity to MicrobesImmunity to Microbes
Immunity to MicrobesMd Murad Khan
 
The complement system
The complement systemThe complement system
The complement systemsushma93
 
BACTERIAL TOXINS
BACTERIAL TOXINSBACTERIAL TOXINS
BACTERIAL TOXINSShirsak Mondal
 
antigen antibody interaction
antigen antibody interactionantigen antibody interaction
antigen antibody interactionArunima Sur
 
Epsilometer Test
Epsilometer TestEpsilometer Test
Epsilometer TestDr. Samira Fattah
 
Bacterial toxin and its harmful effect
Bacterial toxin and its harmful effectBacterial toxin and its harmful effect
Bacterial toxin and its harmful effectRaNa MB
 
Theories of Antibody production
Theories of Antibody productionTheories of Antibody production
Theories of Antibody productionSaranraj P
 
Mechanism of pathogenicity-Exotoxin and endotoxin
Mechanism of pathogenicity-Exotoxin and endotoxinMechanism of pathogenicity-Exotoxin and endotoxin
Mechanism of pathogenicity-Exotoxin and endotoxinaiswarya thomas
 
Subunit and peptide vaccine
Subunit and peptide vaccineSubunit and peptide vaccine
Subunit and peptide vaccineAdnya Desai
 
Cells & organs of immune system
Cells & organs of immune systemCells & organs of immune system
Cells & organs of immune systemArchanaSoni3
 
Mechanism of bacterial pathogenesis and virulence
Mechanism of bacterial pathogenesis and virulenceMechanism of bacterial pathogenesis and virulence
Mechanism of bacterial pathogenesis and virulenceMeher Rizvi
 
interferon
interferoninterferon
interferonDr-Abdul Mannan
 
Bacterial Pathogenesis
Bacterial PathogenesisBacterial Pathogenesis
Bacterial PathogenesisAman Ullah
 
ANTIGEN ( IMMUNOLOGY-1)
ANTIGEN ( IMMUNOLOGY-1)ANTIGEN ( IMMUNOLOGY-1)
ANTIGEN ( IMMUNOLOGY-1)Suraj Dhara
 
Brief history of immunology
Brief history of immunologyBrief history of immunology
Brief history of immunologyDhanya K C
 
Viral assay
Viral assay Viral assay
Viral assay J K COLLEGE,PURULIA
 
Polyclonal and monoclonal antibody production
Polyclonal and monoclonal antibody productionPolyclonal and monoclonal antibody production
Polyclonal and monoclonal antibody productionDr. Amer Ali Khaleel /HMU
 
Humoral immune response
Humoral immune responseHumoral immune response
Humoral immune responsesufihannan
 
Thermophile
ThermophileThermophile
Thermophilekeyurbhuva2
 
Recombinant vaccine
Recombinant vaccineRecombinant vaccine
Recombinant vaccineDr NEETHU ASOKAN
 
Isolation of Bacteriophage
Isolation of Bacteriophage Isolation of Bacteriophage
Isolation of Bacteriophage Amani Riyadh
 
Interferon
InterferonInterferon
InterferonSnehal Patel
 
Vibrio by Dr. Rakesh Prasad Sah
Vibrio by Dr. Rakesh Prasad SahVibrio by Dr. Rakesh Prasad Sah
Vibrio by Dr. Rakesh Prasad SahDr. Rakesh Prasad Sah
 
Human retroviruses
Human retroviruses Human retroviruses
Human retroviruses ankit
 
E coli
E coliE coli
E coliNoman-Hafeez khosa
 
Bacterial-Toxigenesis.docx
Bacterial-Toxigenesis.docxBacterial-Toxigenesis.docx
Bacterial-Toxigenesis.docxMidhatSarfraz
 
Bacterial toxins ppt (powerpoint presentation) by Suraj soni
Bacterial toxins ppt (powerpoint presentation) by Suraj soniBacterial toxins ppt (powerpoint presentation) by Suraj soni
Bacterial toxins ppt (powerpoint presentation) by Suraj sonisuraj soni
 

More Related Content

What's hot

Bacterial toxin and its harmful effect
Bacterial toxin and its harmful effectBacterial toxin and its harmful effect
Bacterial toxin and its harmful effectRaNa MB
 
Theories of Antibody production
Theories of Antibody productionTheories of Antibody production
Theories of Antibody productionSaranraj P
 
Mechanism of pathogenicity-Exotoxin and endotoxin
Mechanism of pathogenicity-Exotoxin and endotoxinMechanism of pathogenicity-Exotoxin and endotoxin
Mechanism of pathogenicity-Exotoxin and endotoxinaiswarya thomas
 
Subunit and peptide vaccine
Subunit and peptide vaccineSubunit and peptide vaccine
Subunit and peptide vaccineAdnya Desai
 
Cells & organs of immune system
Cells & organs of immune systemCells & organs of immune system
Cells & organs of immune systemArchanaSoni3
 
Mechanism of bacterial pathogenesis and virulence
Mechanism of bacterial pathogenesis and virulenceMechanism of bacterial pathogenesis and virulence
Mechanism of bacterial pathogenesis and virulenceMeher Rizvi
 
Bacterial Pathogenesis
Bacterial PathogenesisBacterial Pathogenesis
Bacterial PathogenesisAman Ullah
 
ANTIGEN ( IMMUNOLOGY-1)
ANTIGEN ( IMMUNOLOGY-1)ANTIGEN ( IMMUNOLOGY-1)
ANTIGEN ( IMMUNOLOGY-1)Suraj Dhara
 
Brief history of immunology
Brief history of immunologyBrief history of immunology
Brief history of immunologyDhanya K C
 
Polyclonal and monoclonal antibody production
Polyclonal and monoclonal antibody productionPolyclonal and monoclonal antibody production
Polyclonal and monoclonal antibody productionDr. Amer Ali Khaleel /HMU
 
Humoral immune response
Humoral immune responseHumoral immune response
Humoral immune responsesufihannan
 
Isolation of Bacteriophage
Isolation of Bacteriophage Isolation of Bacteriophage
Isolation of Bacteriophage Amani Riyadh
 
Human retroviruses
Human retroviruses Human retroviruses
Human retroviruses ankit
 

What's hot (20)

Bacterial toxin and its harmful effect
Bacterial toxin and its harmful effectBacterial toxin and its harmful effect
Bacterial toxin and its harmful effect
 
Theories of Antibody production
Theories of Antibody productionTheories of Antibody production
Theories of Antibody production
 
Mechanism of pathogenicity-Exotoxin and endotoxin
Mechanism of pathogenicity-Exotoxin and endotoxinMechanism of pathogenicity-Exotoxin and endotoxin
Mechanism of pathogenicity-Exotoxin and endotoxin
 
Subunit and peptide vaccine
Subunit and peptide vaccineSubunit and peptide vaccine
Subunit and peptide vaccine
 
Cells & organs of immune system
Cells & organs of immune systemCells & organs of immune system
Cells & organs of immune system
 
Mechanism of bacterial pathogenesis and virulence
Mechanism of bacterial pathogenesis and virulenceMechanism of bacterial pathogenesis and virulence
Mechanism of bacterial pathogenesis and virulence
 
interferon
interferoninterferon
interferon
 
Bacterial Pathogenesis
Bacterial PathogenesisBacterial Pathogenesis
Bacterial Pathogenesis
 
ANTIGEN ( IMMUNOLOGY-1)
ANTIGEN ( IMMUNOLOGY-1)ANTIGEN ( IMMUNOLOGY-1)
ANTIGEN ( IMMUNOLOGY-1)
 
Brief history of immunology
Brief history of immunologyBrief history of immunology
Brief history of immunology
 
Viral assay
Viral assay Viral assay
Viral assay
 
Polyclonal and monoclonal antibody production
Polyclonal and monoclonal antibody productionPolyclonal and monoclonal antibody production
Polyclonal and monoclonal antibody production
 
Humoral immune response
Humoral immune responseHumoral immune response
Humoral immune response
 
Thermophile
ThermophileThermophile
Thermophile
 
Recombinant vaccine
Recombinant vaccineRecombinant vaccine
Recombinant vaccine
 
Isolation of Bacteriophage
Isolation of Bacteriophage Isolation of Bacteriophage
Isolation of Bacteriophage
 
Interferon
InterferonInterferon
Interferon
 
Vibrio by Dr. Rakesh Prasad Sah
Vibrio by Dr. Rakesh Prasad SahVibrio by Dr. Rakesh Prasad Sah
Vibrio by Dr. Rakesh Prasad Sah
 
Human retroviruses
Human retroviruses Human retroviruses
Human retroviruses
 
E coli
E coliE coli
E coli
 

Similar to Bacterial toxins

Bacterial-Toxigenesis.docx
Bacterial-Toxigenesis.docxBacterial-Toxigenesis.docx
Bacterial-Toxigenesis.docxMidhatSarfraz
 
Bacterial toxins ppt (powerpoint presentation) by Suraj soni
Bacterial toxins ppt (powerpoint presentation) by Suraj soniBacterial toxins ppt (powerpoint presentation) by Suraj soni
Bacterial toxins ppt (powerpoint presentation) by Suraj sonisuraj soni
 
Bacterial structure
Bacterial structureBacterial structure
Bacterial structureBruno Mmassy
 
Bacterial Protein Toxins
Bacterial Protein ToxinsBacterial Protein Toxins
Bacterial Protein ToxinsSD Syed
 
Gram positive and gram negative
Gram positive and gram negativeGram positive and gram negative
Gram positive and gram negativeLeona Sucilan
 
EXOTOXINS AND ENDOTOXINS.pptx
EXOTOXINS AND ENDOTOXINS.pptxEXOTOXINS AND ENDOTOXINS.pptx
EXOTOXINS AND ENDOTOXINS.pptxShreyaNair49
 
Respiratory burst by Phagocytosis
Respiratory burst by PhagocytosisRespiratory burst by Phagocytosis
Respiratory burst by PhagocytosisRamesh Pothuraju
 
Bacteria; structure, functions.pptx
Bacteria; structure, functions.pptxBacteria; structure, functions.pptx
Bacteria; structure, functions.pptxMusharafRehman1
 
Molecular pathogenesis
Molecular pathogenesisMolecular pathogenesis
Molecular pathogenesisMicrobiology
 
Antibiotics_Understanding_Basics
Antibiotics_Understanding_BasicsAntibiotics_Understanding_Basics
Antibiotics_Understanding_BasicsOssama Motawae
 
Molecular pathogenesis
Molecular pathogenesisMolecular pathogenesis
Molecular pathogenesisMicrobiology
 
Bacterial structure
Bacterial structureBacterial structure
Bacterial structurealiya yasir
 

Similar to Bacterial toxins (20)

Bacterial-Toxigenesis.docx
Bacterial-Toxigenesis.docxBacterial-Toxigenesis.docx
Bacterial-Toxigenesis.docx
 
Bacterial toxins ppt (powerpoint presentation) by Suraj soni
Bacterial toxins ppt (powerpoint presentation) by Suraj soniBacterial toxins ppt (powerpoint presentation) by Suraj soni
Bacterial toxins ppt (powerpoint presentation) by Suraj soni
 
Microbiology lec3
Microbiology lec3Microbiology lec3
Microbiology lec3
 
Bacterial structure
Bacterial structureBacterial structure
Bacterial structure
 
Bacterial Protein Toxins
Bacterial Protein ToxinsBacterial Protein Toxins
Bacterial Protein Toxins
 
Gram positive and gram negative
Gram positive and gram negativeGram positive and gram negative
Gram positive and gram negative
 
Toxins
ToxinsToxins
Toxins
 
Antigens and toxins
Antigens and toxinsAntigens and toxins
Antigens and toxins
 
Membrane active exotoxin.pptx
Membrane active exotoxin.pptxMembrane active exotoxin.pptx
Membrane active exotoxin.pptx
 
EXOTOXINS AND ENDOTOXINS.pptx
EXOTOXINS AND ENDOTOXINS.pptxEXOTOXINS AND ENDOTOXINS.pptx
EXOTOXINS AND ENDOTOXINS.pptx
 
Phagocytosis
PhagocytosisPhagocytosis
Phagocytosis
 
Respiratory burst by Phagocytosis
Respiratory burst by PhagocytosisRespiratory burst by Phagocytosis
Respiratory burst by Phagocytosis
 
Phagocytosis
PhagocytosisPhagocytosis
Phagocytosis
 
Neurotoxins in Food
Neurotoxins in FoodNeurotoxins in Food
Neurotoxins in Food
 
Bacteria; structure, functions.pptx
Bacteria; structure, functions.pptxBacteria; structure, functions.pptx
Bacteria; structure, functions.pptx
 
Molecular pathogenesis
Molecular pathogenesisMolecular pathogenesis
Molecular pathogenesis
 
Antibiotics_Understanding_Basics
Antibiotics_Understanding_BasicsAntibiotics_Understanding_Basics
Antibiotics_Understanding_Basics
 
Antifungal drugs
Antifungal drugsAntifungal drugs
Antifungal drugs
 
Molecular pathogenesis
Molecular pathogenesisMolecular pathogenesis
Molecular pathogenesis
 
Bacterial structure
Bacterial structureBacterial structure
Bacterial structure
 

More from Bruno Mmassy

Family rhabdoviridae
Family rhabdoviridaeFamily rhabdoviridae
Family rhabdoviridaeBruno Mmassy
 
Processing the crime scene
Processing the crime sceneProcessing the crime scene
Processing the crime sceneBruno Mmassy
 
Molecular forensics 2
Molecular forensics 2Molecular forensics 2
Molecular forensics 2Bruno Mmassy
 
Medical aspects of human identification
Medical aspects of human identificationMedical aspects of human identification
Medical aspects of human identificationBruno Mmassy
 
Forensic chemistry introduction
Forensic chemistry introductionForensic chemistry introduction
Forensic chemistry introductionBruno Mmassy
 
Sero and phage typing bls 206
Sero and phage typing bls 206Sero and phage typing bls 206
Sero and phage typing bls 206Bruno Mmassy
 
Selected gram positives bls 206
Selected gram positives bls 206Selected gram positives bls 206
Selected gram positives bls 206Bruno Mmassy
 
Rickettsia & chlamydia bls 206
Rickettsia & chlamydia bls 206Rickettsia & chlamydia bls 206
Rickettsia & chlamydia bls 206Bruno Mmassy
 
Pathogenic anaerobe gram positive bls 206
Pathogenic anaerobe gram positive bls 206Pathogenic anaerobe gram positive bls 206
Pathogenic anaerobe gram positive bls 206Bruno Mmassy
 
Lecture 2 diagnostic molecular microbiology bls
Lecture 2 diagnostic molecular microbiology blsLecture 2 diagnostic molecular microbiology bls
Lecture 2 diagnostic molecular microbiology blsBruno Mmassy
 
Antimicrobial susceptibility test and assay bls 206
Antimicrobial susceptibility test and assay bls 206Antimicrobial susceptibility test and assay bls 206
Antimicrobial susceptibility test and assay bls 206Bruno Mmassy
 
Antimicrobial agents and mechanisms of action 2
Antimicrobial agents and mechanisms of action 2Antimicrobial agents and mechanisms of action 2
Antimicrobial agents and mechanisms of action 2Bruno Mmassy
 
Antibiotics lecture may 2010
Antibiotics lecture may 2010Antibiotics lecture may 2010
Antibiotics lecture may 2010Bruno Mmassy
 
Streptococci and enterococci bls 206
Streptococci and enterococci bls 206Streptococci and enterococci bls 206
Streptococci and enterococci bls 206Bruno Mmassy
 
Bls 107 general microbiology
Bls 107 general microbiologyBls 107 general microbiology
Bls 107 general microbiologyBruno Mmassy
 

More from Bruno Mmassy (20)

Family rhabdoviridae
Family rhabdoviridaeFamily rhabdoviridae
Family rhabdoviridae
 
Antiviral 1
Antiviral 1Antiviral 1
Antiviral 1
 
Processing the crime scene
Processing the crime sceneProcessing the crime scene
Processing the crime scene
 
Molecular forensics 2
Molecular forensics 2Molecular forensics 2
Molecular forensics 2
 
Medical aspects of human identification
Medical aspects of human identificationMedical aspects of human identification
Medical aspects of human identification
 
Forensic
ForensicForensic
Forensic
 
Forensic chemistry introduction
Forensic chemistry introductionForensic chemistry introduction
Forensic chemistry introduction
 
Dna forensic
Dna forensicDna forensic
Dna forensic
 
Sero and phage typing bls 206
Sero and phage typing bls 206Sero and phage typing bls 206
Sero and phage typing bls 206
 
Selected gram positives bls 206
Selected gram positives bls 206Selected gram positives bls 206
Selected gram positives bls 206
 
Rickettsia & chlamydia bls 206
Rickettsia & chlamydia bls 206Rickettsia & chlamydia bls 206
Rickettsia & chlamydia bls 206
 
Pathogenic anaerobe gram positive bls 206
Pathogenic anaerobe gram positive bls 206Pathogenic anaerobe gram positive bls 206
Pathogenic anaerobe gram positive bls 206
 
Lecture 2 diagnostic molecular microbiology bls
Lecture 2 diagnostic molecular microbiology blsLecture 2 diagnostic molecular microbiology bls
Lecture 2 diagnostic molecular microbiology bls
 
Antimicrobial susceptibility test and assay bls 206
Antimicrobial susceptibility test and assay bls 206Antimicrobial susceptibility test and assay bls 206
Antimicrobial susceptibility test and assay bls 206
 
Antimicrobial agents and mechanisms of action 2
Antimicrobial agents and mechanisms of action 2Antimicrobial agents and mechanisms of action 2
Antimicrobial agents and mechanisms of action 2
 
Antibiotics lecture may 2010
Antibiotics lecture may 2010Antibiotics lecture may 2010
Antibiotics lecture may 2010
 
Streptococci and enterococci bls 206
Streptococci and enterococci bls 206Streptococci and enterococci bls 206
Streptococci and enterococci bls 206
 
Bls 107 general microbiology
Bls 107 general microbiologyBls 107 general microbiology
Bls 107 general microbiology
 
Bacteriophage 1
Bacteriophage 1Bacteriophage 1
Bacteriophage 1
 
Bacterial toxins
Bacterial toxinsBacterial toxins
Bacterial toxins
 

Recently uploaded

Transaction Management in Database Management System
Transaction Management in Database Management SystemTransaction Management in Database Management System
Transaction Management in Database Management SystemChristalin Nelson
 
4.16.24 21st Century Movements for Black Lives.pptx
4.16.24 21st Century Movements for Black Lives.pptx4.16.24 21st Century Movements for Black Lives.pptx
4.16.24 21st Century Movements for Black Lives.pptxmary850239
 
AUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptx
AUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptxAUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptx
AUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptxiammrhaywood
 
Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17
Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17
Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17Celine George
 
Student Profile Sample - We help schools to connect the data they have, with ...
Student Profile Sample - We help schools to connect the data they have, with ...Student Profile Sample - We help schools to connect the data they have, with ...
Student Profile Sample - We help schools to connect the data they have, with ...Seán Kennedy
 
Keynote by Prof. Wurzer at Nordex about IP-design
Keynote by Prof. Wurzer at Nordex about IP-designKeynote by Prof. Wurzer at Nordex about IP-design
Keynote by Prof. Wurzer at Nordex about IP-designMIPLM
 
THEORIES OF ORGANIZATION-PUBLIC ADMINISTRATION
THEORIES OF ORGANIZATION-PUBLIC ADMINISTRATIONTHEORIES OF ORGANIZATION-PUBLIC ADMINISTRATION
THEORIES OF ORGANIZATION-PUBLIC ADMINISTRATIONHumphrey A Beña
 
Virtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdf
Virtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdfVirtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdf
Virtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdfErwinPantujan2
 
How to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERPHow to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERPCeline George
 
4.16.24 Poverty and Precarity--Desmond.pptx
4.16.24 Poverty and Precarity--Desmond.pptx4.16.24 Poverty and Precarity--Desmond.pptx
4.16.24 Poverty and Precarity--Desmond.pptxmary850239
 
Influencing policy (training slides from Fast Track Impact)
Influencing policy (training slides from Fast Track Impact)Influencing policy (training slides from Fast Track Impact)
Influencing policy (training slides from Fast Track Impact)Mark Reed
 
The Contemporary World: The Globalization of World Politics
The Contemporary World: The Globalization of World PoliticsThe Contemporary World: The Globalization of World Politics
The Contemporary World: The Globalization of World PoliticsRommel Regala
 
ANG SEKTOR NG agrikultura.pptx QUARTER 4
ANG SEKTOR NG agrikultura.pptx QUARTER 4ANG SEKTOR NG agrikultura.pptx QUARTER 4
ANG SEKTOR NG agrikultura.pptx QUARTER 4MiaBumagat1
 
USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...
USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...
USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...Postal Advocate Inc.
 
ROLES IN A STAGE PRODUCTION in arts.pptx
ROLES IN A STAGE PRODUCTION in arts.pptxROLES IN A STAGE PRODUCTION in arts.pptx
ROLES IN A STAGE PRODUCTION in arts.pptxVanesaIglesias10
 
ClimART Action | eTwinning Project
ClimART Action | eTwinning ProjectClimART Action | eTwinning Project
ClimART Action | eTwinning Projectjordimapav
 

Recently uploaded (20)

Paradigm shift in nursing research by RS MEHTA
Paradigm shift in nursing research by RS MEHTAParadigm shift in nursing research by RS MEHTA
Paradigm shift in nursing research by RS MEHTA
 
YOUVE GOT EMAIL_FINALS_EL_DORADO_2024.pptx
YOUVE GOT EMAIL_FINALS_EL_DORADO_2024.pptxYOUVE GOT EMAIL_FINALS_EL_DORADO_2024.pptx
YOUVE GOT EMAIL_FINALS_EL_DORADO_2024.pptx
 
Transaction Management in Database Management System
Transaction Management in Database Management SystemTransaction Management in Database Management System
Transaction Management in Database Management System
 
4.16.24 21st Century Movements for Black Lives.pptx
4.16.24 21st Century Movements for Black Lives.pptx4.16.24 21st Century Movements for Black Lives.pptx
4.16.24 21st Century Movements for Black Lives.pptx
 
INCLUSIVE EDUCATION PRACTICES FOR TEACHERS AND TRAINERS.pptx
INCLUSIVE EDUCATION PRACTICES FOR TEACHERS AND TRAINERS.pptxINCLUSIVE EDUCATION PRACTICES FOR TEACHERS AND TRAINERS.pptx
INCLUSIVE EDUCATION PRACTICES FOR TEACHERS AND TRAINERS.pptx
 
AUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptx
AUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptxAUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptx
AUDIENCE THEORY -CULTIVATION THEORY - GERBNER.pptx
 
Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17
Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17
Incoming and Outgoing Shipments in 3 STEPS Using Odoo 17
 
YOUVE_GOT_EMAIL_PRELIMS_EL_DORADO_2024.pptx
YOUVE_GOT_EMAIL_PRELIMS_EL_DORADO_2024.pptxYOUVE_GOT_EMAIL_PRELIMS_EL_DORADO_2024.pptx
YOUVE_GOT_EMAIL_PRELIMS_EL_DORADO_2024.pptx
 
Student Profile Sample - We help schools to connect the data they have, with ...
Student Profile Sample - We help schools to connect the data they have, with ...Student Profile Sample - We help schools to connect the data they have, with ...
Student Profile Sample - We help schools to connect the data they have, with ...
 
Keynote by Prof. Wurzer at Nordex about IP-design
Keynote by Prof. Wurzer at Nordex about IP-designKeynote by Prof. Wurzer at Nordex about IP-design
Keynote by Prof. Wurzer at Nordex about IP-design
 
THEORIES OF ORGANIZATION-PUBLIC ADMINISTRATION
THEORIES OF ORGANIZATION-PUBLIC ADMINISTRATIONTHEORIES OF ORGANIZATION-PUBLIC ADMINISTRATION
THEORIES OF ORGANIZATION-PUBLIC ADMINISTRATION
 
Virtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdf
Virtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdfVirtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdf
Virtual-Orientation-on-the-Administration-of-NATG12-NATG6-and-ELLNA.pdf
 
How to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERPHow to do quick user assign in kanban in Odoo 17 ERP
How to do quick user assign in kanban in Odoo 17 ERP
 
4.16.24 Poverty and Precarity--Desmond.pptx
4.16.24 Poverty and Precarity--Desmond.pptx4.16.24 Poverty and Precarity--Desmond.pptx
4.16.24 Poverty and Precarity--Desmond.pptx
 
Influencing policy (training slides from Fast Track Impact)
Influencing policy (training slides from Fast Track Impact)Influencing policy (training slides from Fast Track Impact)
Influencing policy (training slides from Fast Track Impact)
 
The Contemporary World: The Globalization of World Politics
The Contemporary World: The Globalization of World PoliticsThe Contemporary World: The Globalization of World Politics
The Contemporary World: The Globalization of World Politics
 
ANG SEKTOR NG agrikultura.pptx QUARTER 4
ANG SEKTOR NG agrikultura.pptx QUARTER 4ANG SEKTOR NG agrikultura.pptx QUARTER 4
ANG SEKTOR NG agrikultura.pptx QUARTER 4
 
USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...
USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...
USPS® Forced Meter Migration - How to Know if Your Postage Meter Will Soon be...
 
ROLES IN A STAGE PRODUCTION in arts.pptx
ROLES IN A STAGE PRODUCTION in arts.pptxROLES IN A STAGE PRODUCTION in arts.pptx
ROLES IN A STAGE PRODUCTION in arts.pptx
 
ClimART Action | eTwinning Project
ClimART Action | eTwinning ProjectClimART Action | eTwinning Project
ClimART Action | eTwinning Project
 

Bacterial toxins

  • 1. BACTERIAL TOXINS HOZA, A.S BLS 2009
  • 2. TOXIGENESIS Two types of bacterial toxins 1. Lipopolysaccharides: are associated with the cell walls of Gram-ve bacteria.  The lipopolysaccharide (LPS) component of the Gram-ve bacterial outer membrane bears the name endotoxin because of its association with the cell wall of bacteria. 2. Proteins: may be released into the extracellular environment of pathogenic bacteria. Most of the protein toxins are thought of as exotoxins, since they are "released" from the bacteria and act on host cells at a distance. A.S. HOZA
  • 3. 1. BACTERIAL PROTEIN TOXINS The protein toxins are soluble proteins secreted by living bacteria during exponential growth. The production of protein toxins is specific to a particular bacterial species - (e.g. only Clostridium tetani produces tetanus toxin. - only Corynebacterium diphtheriae produces the diphtheria toxin. Usually, virulent strains of the bacterium produce the toxin (or range of toxins) while non-virulent strains do not.  Toxin is the major determinant of virulence. Both Gram-positive and Gram-negative bacteria produce soluble protein toxins. Bacterial protein toxins are the most potent poisons known and may show activity at very high dilutions. A.S. HOZA
  • 4. 1. BACTERIAL PROTEIN TOXINS The protein toxins resemble enzymes. Like enzymes, bacterial exotoxins are: proteins denatured by heat, acid, proteolytic enzymes have a high biological activity (most act catalytically) exhibit specificity of action Bacterial protein toxins are highly specific in the substrate utilized and in their mode of action. Usually the site of damage caused by the toxin indicates the location of the substrate for that toxin. Terms such as "enterotoxin", "neurotoxin", "leukocidin" or "hemolysin" are used to indicate the target site of some well-defined protein toxins. A.S. HOZA
  • 5. BACTERIAL PROTEIN TOXINS Certain protein toxins have very specific cytotoxic activity (i.e., they attack specific cells, for example, tetanus or botulinum toxins) Some (as produced by staphylococci, streptococci, clostridia, etc.) have fairly broad cytotoxic activity and cause nonspecific death of tissues (necrosis). Toxins that are phospholipases may be relatively nonspecific in their cytotoxicity. This is also true of pore-forming "hemolysins" and "leukocidins". A few protein toxins cause death of the host and are known as "lethal toxins", (e.g. anthrax toxin). A.S. HOZA
  • 6. BACTERIAL PROTEIN TOXINS Protein toxins are strongly antigenic. In vivo, specific antibody (antitoxin) neutralizes the toxicity of these bacterial proteins. In vitro, specific antitoxin may not fully inhibit their enzymatic activity. Protein toxins are inherently unstable: In time they lose their toxic properties but retain their antigenic ones. Toxoids: are detoxified toxins which retain their antigenicity and their immunizing capacity (first discovered by Ehrlich) A.S. HOZA
  • 7. BACTERIAL PROTEIN TOXINS The formation of toxoids can be accelerated by:  treating toxins with a variety of reagents including formalin, iodine, pepsin, ascorbic acid, ketones, etc. The mixture is maintained at 37o at pH range 6 to 9 for several weeks. Toxoids can be use for artificial immunization against diseases caused by pathogens where the primary determinant of bacterial virulence is toxin production. E.g immunizing against diphtheria and tetanus that are part of the DPT vaccine. A.S. HOZA
  • 8. 1. BACTERIAL PROTEIN TOXINS A + B Subunit Arrangement of Protein Toxins Many protein toxins, consist of two components: 1. Subunit A: responsible for the enzymatic activity of the toxin. 2. Subunit B: concerned with binding to a specific receptor on the host cell membrane and transferring the enzyme across the membrane.  The enzymatic component is not active until it is released from the native toxin.  Isolated A subunits are enzymatically Tertiary structure of the active and but lack binding and cell entry pertussis toxin produced by capability. Bordetella pertussis. Pertussis  Isolated B subunits may bind to target toxin is a member of the A-B bacterial toxin superfamily. It is cells (and even block the binding of the a hexameric protein comprising native A+B toxin), but they are nontoxic. five distinct subunits, A.S. HOZA
  • 9. 2. ENDOTOXINS Endotoxins are: Part of the outer cell wall of bacteria. Invariably associated with Gram-ve bacteria as constituents of the outer membrane of the cell wall. NB: Endotoxin: Occasionally used to refer to any "cell-associated" bacterial toxin. But should be reserved for the lipopolysaccharide complex associated with the outer envelope of Gram-ve bacteria such as E. coli, Salmonella, Shigella, Pseudomonas, Neisseria, Haemophilus, and other leading pathogens. Lipopolysaccharide (LPS) participates:  in a number of outer membrane functions essential for bacterial growth and survival, especially within the context of a host-parasite interaction. A.S. HOZA
  • 10. 2. ENDOTOXINS The biological activity of endotoxin is associated with the lipopolysaccharide (LPS). Toxicity is associated with the lipid component (Lipid A) and Immunogenicity (antigenicity) is associated with the polysaccharide components. The cell wall antigens (O antigens) of Gram-negative bacteria are components of LPS. LPS activates complement by the alternative (properdin) pathway and may be a part of the pathology of most Gram-negative bacterial infections. A.S. HOZA
  • 11. 2. ENDOTOXINS NB 2: Most part of endotoxins remain associated with the cell wall until disintegration of the bacteria. In vivo, this results from autolysis, external lysis, and phagocytic digestion of bacterial cells. Small amounts of endotoxin may be released in a soluble form, especially by young cultures. Compared to the classic exotoxins of bacteria, endotoxins are less potent and less specific in their action, since they do not act enzymatically. Endotoxins are heat stable (boiling for 30 min does not destabilize endotoxin). but certain powerful oxidizing agents such as , superoxide, peroxide and hypochlorite degrade them. Endotoxins, although strongly antigenic, cannot be converted to toxoids. A.S. HOZA
  • 12. CHARACTERISTICS OF BACTERIAL ENDOTOXINS AND EXOTOXINS PROPERTY ENDOTOXIN EXOTOXIN Lipopolysaccharide (mw = Chemical nature Protein (mw = 50-1000kDa) 10kDa) Relationship to cell Part of outer membrane Extracellular, diffusible Denatured by boiling No Usually Antigenic Yes Yes Form toxoid No Yes Potency Relatively low (>100ug) Relatively high (1 ug) Specificity Low degree High degree Enzymatic activity No Usually Pyrogenicity Yes Occasionally A.S. HOZA
  • 13. 2. ENDOTOXINS Lipopolysaccharides:  Are complex amphiphilic molecules with a mw of about 10kDa, that vary widely in chemical composition both between and among bacterial species.  In a basic ground plan common to all endotoxins, LPS consists of three components: (1) Lipid A (2) Core polysaccharide (3) O polysaccharide A.S. HOZA
  • 14. 2. Endotoxins: heat stable A.S. HOZA
  • 15. 2. ENDOTOXINS 1. Lipid A :  Lipid component of LPS.  Contains the hydrophobic, membrane-anchoring region of LPS.  Lipid A consists of a phosphorylated N-acetylglucosamine (NAG) dimer with 6 or 7 fatty acids (FA) attached.  6 FA are found. All FA in Lipid A are saturated.  Some FA are attached directly to the NAG dimer and others are esterified to the 3-hydroxy fatty acids that are characteristically present.  The structure of Lipid A is highly conserved among Gram-ve bacteria.  Among Enterobacteriaceae Lipid A is virtually constant A.S. HOZA
  • 16. 2. ENDOTOXINS 2. Core (R) polysaccharide: Is attached to the 6 position of one NAG. The R antigen consists of a short chain of sugars. For example: KDO - Hep - Hep - Glu - Gal - Glu - GluNAc. Two unusual sugars - present Heptose and 2-keto-3-deoxyoctonoic acid (KDO), in the core polysaccharide. KDO is unique and invariably present in LPS and so has been an indicator in assays for LPS (endotoxin). A.S. HOZA
  • 17. 2. ENDOTOXINS Core polysaccharide is common to all members of a bacterial genus with minor variations (e.g. Salmonella). but it is structurally distinct in other genera of Gram-negative bacteria. Salmonella, Shigella and Escherichia have similar but not identical cores. A.S. HOZA
  • 18. 2. ENDOTOXINS 3. O polysaccharide (also referred to as the O antigen or O side chain): Is attached to the core polysaccharide. Consists of repeating oligosaccharide subunits made up of 3-5 sugars. The individual chains vary in length ranging up to 40 repeat units. O polysaccharide is much longer than the core polysaccharide and it maintains the hydrophilic domain of the LPS molecule. A.S. HOZA
  • 19. 2. ENDOTOXINS A unique group of sugars, called dideoxyhexoses, occurs in the O polysaccharide. A major antigenic determinant (antibody-combining site) of the Gram-negative cell wall resides in the O polysaccharide. Great variation occurs in the composition of the sugars in the O side chain between species and even strains of Gram-negative bacteria. A.S. HOZA
  • 20. 2. ENDOTOXINS LPS and virulence of Gram-negative bacteria Endotoxins are toxic to most mammals. They are strong antigens but they seldom elicit immune responses which give full protection to the animal against secondary challenge with the endotoxin. Cannot be toxoided. Endotoxins released from multiplying or disintegrating bacteria significantly contribute to the symptoms of Gram-ve bacteremia and septicemia important pathogenic factors in Gram-ve infections. A.S. HOZA
  • 21. 2. ENDOTOXINS Regardless of the bacterial source all endotoxins produce the same range of biological effects in the animal host. Injection of living or killed Gram-ve cells, or purified LPS, into experimental animals wide spectrum of nonspecific pathophysiological reactions related to inflammation such as: fever changes in white blood cell counts disseminated intravascular coagulation tumor necrosis hypotension shock A.S. HOZA
  • 22. 2. ENDOTOXINS The role of Lipid A Physiological activities of endotoxins- mediated mainly by the Lipid A component of LPS. Lipid A is the toxic component of LPS. Its biological activity depends on a peculiar conformation determined by the glucosamine disaccharide, PO4 groups, Acyl chains, and KDO-containing inner core. Lipid A is known to react at the surfaces of macrophages release cytokines that mediate the pathophysiological response to endotoxin. A.S. HOZA
  • 23. 2. ENDOTOXINS The role of the O polysaccharide Although nontoxic, the polysaccharide side chain (O antigen) of LPS may act as a determinant of virulence in Gram-ve bacteria. O polysaccharide is responsible for the property of "smoothness" of bacterial cells, which may contribute to their resistance to phagocytic engulfment. O polysaccharide is hydrophilic and may allow diffusion or delivery of the toxic lipid in the hydrophilic (in vivo) environment. A.S. HOZA
  • 24. 2. ENDOTOXINS Long side chains of LPS afforded by the O polysaccharide may prevent host complement from depositing on the bacterial cell surface which would bring about bacterial cell lysis. O polysaccharide may supply a bacterium with its specific ligands (adhesins) for colonization which is essential for expression of virulence. O-polysaccharide is antigenic, and the usual basis for antigenic variation in Gram-ve bacteria rests in differences in their O polysaccharides. A.S. HOZA
  • 25. Pathogenicity Islands Pathogenicity Islands (PAI): Are a distinct class of genomic islands which are acquired by horizontal gene transfer. Incorporated in the genome of pathogenic bacteria usually absent from non-pathogenic organisms of the same or closely related species. They occupy relatively large genomic regions ranging from 10-200 kb encode genes which contribute to virulence of the pathogen. Typical examples: adhesins, toxins, iron uptake systems, invasins, etc. A.S. HOZA
  • 26. Pathogenicity Islands One species of bacteria may have more than one pathogenicity island. For example, in Salmonella, five pathogenicity islands have been identified. Found mainly in Gram-ve bacteria, but have been shown in a few Gram-positives. Found in pathogens that undergo gene transfer by plasmid, phage, or a conjugative transposon and are typically transferred through mechanisms of horizontal gene transfer (HGT). A.S. HOZA
  • 27. Pathogenicity Islands May be located on the bacterial chromosome or may be a part of a plasmid. Are rich in Guanine + Cytosine content. They are flanked by direct repeats i.e., the sequence of bases at two ends are the same. Are associated with tRNA genes, which target sites for the integration of DNA. Have characteristics of transposons in that they carry functional genes  e.g. integrase, transposase, or part of insertion sequences may move from one tRNA locus to another on the chromosome or plasmid. A.S. HOZA
  • 28. Pathogenicity Islands Play a vital role in the virulence of bacterial pathogens of humans , animals and plants. The availability of a large number of genome sequences of pathogenic bacteria and their nonpathogenic relatives identification of novel pathogen-specific genomic islands. PAI apparently -acquired during the speciation of pathogens from their nonpathogenic or environmental ancestors. The acquisition of PAI is an ancient evolutionary event that led to the appearance of bacterial pathogens on a timescale of millions of years May also represent a mechanism that contributes to the appearance of new pathogens. A.S. HOZA
  • 29. Pathogenicity Islands Knowledge about PAI, their structure, their mobility, and the pathogenicity factors they encode is helpful: a) In gaining a better understanding of bacterial evolution and interactions of pathogens with eucaryotic host cells b) Also may have important practical implications such as providing delivery systems for vaccination and tools for the development of new strategies for therapy of bacterial infections. A.S. HOZA
  • 30. Pathogenicity Islands PAIs represent distinct genetic elements encoding virulence factors of pathogenic bacteria Belong to a more general class of genomic islands Common genetic elements sharing a set of unifying features. Genomic islands have been acquired by horizontal gene transfer. In recent years many different genomic islands have been discovered in a variety of pathogenic as well as non-pathogenic bacteria. Because they promote genetic variability, genomic islands play an important role in microbial evolution A.S. HOZA