1 / 36

Scope of Microbiology Microorganisms are widely distributed Earth air water solid liquid

Basic Microbiology and Immunology PM 401 Dr Mohammed A. Ramadan Professor of Microbiology and Immunology. Scope of Microbiology Microorganisms are widely distributed Earth air water solid liquid Pathogenic : Ability to cause disease non-pathogenic ????? Useful

shing
Download Presentation

Scope of Microbiology Microorganisms are widely distributed Earth air water solid liquid

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Basic Microbiology and ImmunologyPM 401 Dr Mohammed A. RamadanProfessor of Microbiology and Immunology

  2. Scope of Microbiology • Microorganisms are widely distributed • Earth air water solid liquid • Pathogenic: Ability to cause disease • non-pathogenic ????? Useful • - General microbiology • - Medical microbiology • - Veterinary microbiology • - Agricultural microbiology • - Industrial microbiology • - Environmental microbiology

  3. Microbiology and Pharmacy • 1- Biology of organisms • 2- Applications of antiseptics and Disinfectants • 3- Production of antibiotics and vitamins • 4- production of vaccines • 5- Production of therapeutic peptides by genetic engineering • 6- Sterile products • 7- Epidemiology of microorganisms • 8- Infectious diseases

  4. History of microbiology • Egyptian Ancients • 1-Microbial products mushroom fermented beverages medicine • 2-Microbial symptoms Quarantine for plague • Transmission of diseases Certain properties of diseases bread making using yeast • ِAnton van Leuwenhoek (1676) used his microscope • to describe bacteria & protozoa (animolecules) • Spontaneous generation Theory: : Aristotle (1700) • Living organisms (animolecules) are created do novo • Needham supported this theory • Spallanzani (1776) opposed this theory : • by sealing the container containing meat broth after boiling • The broth does not develop microorganisms • Gram staining of bacteria

  5. Louis Pasteur(1822-1895) The Father of Microbiology • 1- Microbes are responsible for fermentation???????? destroyed • 2- Pasteurization development • 3- Chemical changes occurring during fermentation • 4- Development of vaccines from killed or attenuated organisms • Robert Koch (1843-1910) • 1- Developed solid artificial medium for cultivation of mo • 2- Isolated B. anthracis in a pure form • 3- developed staining of organisms • 4- Discovered Tubercle bacilli • 5- few mo are pathogenic while others are non pathogenic • 6- Koch’s postulate • - mo should observed in every stage of the disease • be isolated on artificial medium • When mo infect healthy animal it should gives same symptoms

  6. Petri petri dishes • Christian Gram (1884) gram staining • Lister father of antiseptic surgery phenol as a disinfectant • Nomenclature • Staphylococcusaureus • Genusspeciesstrain • Escherichia coli colon • Classification of Biota (living cells)

  7. Prokaryotes and Eukaryotes • Pro: primitive Eu : true karyo : nucleus • Prokaryotes bacteria and cyanobacteria • Eukarotes fungi; single cell algae and protozoa • CharacterProkaryotesEukaryotes • Size microscopicmacroscopic • Nucleus absent present • Cell division binary fission mitosis • Cell membrane absence of sterol sterol • Ribosome 70 s 80 s • Mitochondria absent present • Cell wall peptidoglycan absent or • polysaccharide • Mesosome present absent • Endospores present absent • Example bacteria fungi, protozoa

  8. Kingdome Woese system Molecular level genetic analysis • 1- Kingdom Archaebaceteriae • 2- Kingdom Eubacteria • 3- Kingdom Eukaryotes • Kingdom Wittaker’s system • 1- Monera (bacteria) • 2- Fungi • 3-Protista ( Protozoa and algae) • 4- Plants • 5- animals

  9. Bacteria: Unicellular prokaryotes • Rickettsia: ????? • Viruses: Obligate intracellular parasites

  10. Nomenclature • Staphylococcusaureus • Genus species species strain • Archaebacteria • - Prokaryotes • - resist high salt concentration • - grow high temperature • - grow at acidic pH • - thermo-acidophiles • - some are methanogenic • - Cell wall ----- glycoprotein

  11. Eukaryotes • Fungi: mold and yeast • - non photosynthetic Heterotrophic • - aerobic or facultative anaerobic • Mold: long filament cells -- hyphae septated non-septated • Yeast : long oval cells multiply by budding pseudo mycelium • Filamentous fungi are multiply by sexual and a sexual spores • Fungi are classified into: • 1- Phycomycetes • Hyphae - ---- non-septated • Spores - ---  inside sac (sporangium) • Examples: Mucor and Rhizopus 2- Ascomycetes - asexual spores born on tips of hyphae -- conidiospores - septated hyphae - Examples: Aspergillus and Penicillium

  12. 3-Basidiomycete • Sexual spores --- clup shaped (basidium) ( 4 basidiospores) • Example: Agaricus • 4- Deutromycetes (fungi imperfecti) • Sexual fusion is not observed • Examples: Epidermophyton • Asexual spores include: • 1- Sporangiospores; hyphae - sporangiophore sporangium • 2- Conidiophores conidiophore conidium • 3- Arthrospores Fragmented hyphae • 4- Blastospores from parent cell as a bud some yeast • 5- Chlamidospores formed by enlargement within hyphae Dimorphism : pathogenic fungi could exist in 2 forms a- yeast like at 37 C in tissue b- mould like at 25 C in artificial medium

  13. Slime Molds • - have fungal and amoeboid characteristics • - Life cycle--- mold • - Some stage---- creeping amoeboid movement • Algae • - Photosynthetic organisms • - Cellular with cell wall • - Cell wall --- cellulose and pectinate; alginate • - autotrophic • Protozoa • - Eukaryotic unicellular without cell wall • - Motile through pseudopodia cilia or flagella • - Non photosynthetic • - Reproduction by sexual and asexual

  14. Other Structures • Prions • 1- smallest infectious agent • 2- infect cattle and cause Bovine spongiform encephalopathy (BSE) • 3- Neurological disease • 4- can infect human also Viroids 1- cause for plant diseases 2- short pieces of RNA with no protein coat 3- does not code for protein Viruses 1- obligate intracellular parasite 2- non living 3- small filtrable 4- specific host 5- phage 6- contain either DNA OR RNA 7- Have a protein coat (capsid) 8- some viruses are enveloped

  15. Lipid Envelope Nucleic Acid Protein Capsid Virion Associated Polymerase Spike Projections Virus structure

  16. Viral replication • 1- Attachment or adsorption chemical interaction • 2- Penetration • Injection of DNA into bacterium • Phage release lysozyme which lysis of bacterial cell wall • Capsid remains outside the bacterium 3- Biosynthesis - Phage use its template DNA instead of bacterial DNA for synthesis a new DNA - use of bacterial ribosome for synthesis of the capsid (protein) - Eclipse period 4- Maturation Bacteriophage DNA and capsid are assembled into virion 5– Release Phage lysozyme - lysis of cell wall

  17. Structure of Bacterial cell

  18. Bacterial cell • Eubacteria Archaebacteria Rickettsia Actinomycetes • Size of bacterial cell 1 u • weight 1 g - 5 x 10 11 cells • No of species 200,000

  19. Bacterial cell structures • Main structure • - cell wall • - cell membrane • - cytoplasm • - nuclear materials • - ribosomes • ُExtra-cellular • structures • - capsule • - flagella • - pili • - endospore • - plasmid

  20. CELL WALL • - maintain the shape of the cell • - Semirigid structure - virulent factor • - Site of action of antibiotics • Structure of cell wall • Peptidoglycan: composed of N-acetyl glucosamin and N-acetyl muramic acid linked with bridge composed of tetrapeptide chain of both D and L • Two these aa are unique for bacteria: diaminopemilic acid & D-alanine • In Gram positive Bacteria • Teichoic acid -- polymer of glycerol or sorbitol linked to phosphate • 1- role in cell growth 2- antigenic structure • In Gram negative Bacteria • It contains outer membrane (OM) - lipoprottein + LPS+ phspholipid • The space between OM and plasma membrane  periplasmic space • 1- evade phagocytosis and the action of complment • 2- barrier to certain antibiotics, lysoszyme, detergent, heavy metals • 3- Part of permeability of OM is due to protein channel (Porins)

  21. Upon lysis of cell wall of –ve ---- LPS --- endotoxins or pyrogens  • fever and schock • LPS --- (i) outer polysaccharide (O antigen) • (ii) phospholipid called Lipid A ---- endotoxin • Damage to cell wall • 1- Peptidoglycan except archaebacteria 2- no cell wall PG in human • 3- rupture in hypertonic solutions • N.B. Archaebacteriae : glycoprotein • Mycoplasma : have no cell wall • Cell wall could be removed by lysozyme or by chemical • Protoplast spheroplast L-form • LPS ------ pyrogen or endotoxin LPS ????? Function of cell wall • it is a rigid structure protect the cell from mechanical stress • It maintains the shape of the cell

  22. Gram positive Gram negative • - peptidoglycan thick thin • - teichoic acid present absent • - outer membrane absent present • - Lipopolysaccharide absent present • - Gram reaction purple red • - Periplasmic space absent present • - Lysozyme high low • A typical cell wall: • - acid fast bacteria mycolic acid a waxy lipid, and peptidoglycan • - Archaebacteria have peptidoglycan cell wall

  23. Cell membrane (plasma membrane) • Composed of : bilayer of phospholipid and protein • Phospholipid molecule: hydrophilic (PO4 and glycerol) • hydrophobic (fatty acids) • Sterol is available in eukaryotic bacteria: EXCEPT: Mycoplasma • Protein molecule • 1- peripheral: easily removed by mild treatment • 2- Integral : can be removed after disruption of bilayer (by detergent) • Function of cell membrane: • 1- selective permeability • Macromolecules are degraded by extracellular enzyme into micromolecules • - passive transport: movement according to concentration gradient • - simple diffusion from high from high to low conc simple molecule ), CO2 • - facilitated diffusion glucose bound to protein as a carrier • - active transport 2 - respiration and energy production 3 – site of synthesis of cell wall subunits 4 – site of enzyme and toxin production

  24. Extracellular structures Glycocalyx - mucopolysaccharidemucilagenous - exhibit mucoid structure - attachment to surfaces dental caries - biofilm (growing of bacteria on a surface) - virulence factor - can protect cell against dehydration Capsule - polysaccharide polypeptide - protect the cell from phagocytosis - might help in bacterial adherence

  25. Flagella • Whip-like structure; used for motility -Composed of protein (flagellin) • Originating from cell membrane • movement of bacteria by hydrolysis of ATP • The number and distribution of flagella is a characteristic for each organism • Monotrichous amphitrichous lophotrichous peritrichous • Flagella composed of • 1- Filament long contain flagellin 2- Hook slightly wider • 3- Basal body small rod inserted into a series of ring • -movement is resulted from rotation of its basal body • -Some bacteria like Proteus (surrounded by many flagella) - swarming • -Taxis: is the movement of bacteria away from a specific stimuli -- • Chemotaxis Phototaxis • Axial filament: specific for spirochetes for spiral movement at one end • - Fimbria and pili • - gram negative bacteria hair like shorter straight thin than flagella • Fimbria • Function: adhere and colonize the mucous membrane • =Virulent factor

  26. Pili : • similar to fimbrai But longer and only 1 or 2 per cell • Functions 1- adherence 2- sexual conjugation • Bacterial endospores • 1- a structure developed under unfavorable conditions • 2- difficult in staining 3- does not multiply ( no cell division) • one gram negative species - Coxiella  forms endospore like structure • 4- containing a. ca dipicolinate b. hard cortex • c. low water content d. presence of disulfide bond • Spore forming bacteria: Bacillus (aerobic) • Clostridium (anaerobic) Spherical or oval central terminal subterminal Bulging or non bulging Germination: transfer of spore into vegetative cell

  27. Ribosomes • 1- site for protein synthesis • 2- 2 subunits protein + rRNA • 3- 70 s 80 s s Svedberg units sedimentation • 4- 70 s 30s one mol of rRNA 50 s 2 mol of r RNA

  28. Osmosis: movement of solvent across membrane from high to low • In living system - water • Osmotic pressure: • pressure required to prevent movement of water into a solution • Isotonic • Conc of solute are equal on both side • Hypotonic • Conc of solute outside are lower than that inside the cell • Result: swelling---- cell lysis • Hypertonic • Conc of solute outside are ligher than that inside the cell • Result: shrink and collapse

  29. Bacterial Metabolism • Metabolism: all chemical reactions that takes place in a living cell • Catabolism: biodegradation of organic molecule into simple molecules • Anabolism : assimilation of simple molecules into structural unit • Requirement for survival and growth: • -Nutritive requirements: C source : structural and functional molecules E source : anabolic (building ) and catabolic ( degradation) N source : synthesis of amino acids, vitamins and nucleic acids P source : for synthesis of nucleic acids • Environmental sources: • pH - temp - oxygen requirement • C SOURCE • Autotrophes: C from CO2 • Heterotrophes : C from organic compounds • Chemoorganotroph • Chemolithotrophes

  30. Energy sources • Oxidative phosphorylation coupling • Oxidation : release of electrons reduction ; accept electrons • Oxidation-reduction intermediates: • These are compounds which are easily capture and release of electrons • Examples : NAD; NADP; NADH; FAD Terminal electron acceptor : O • Phosphorylation reactions: formation of phosphate bond ???????? • Carried out at the cell membrane • AMP + PO3 --------------------- ADP + PO3 -------------- ATP energy energy ENERGY GENERATION Glycolysis Glucose ---- pyruvate 2 ATP ATP is synthesized by substrate phosphrylation Pyruvate pathways Pyruvate ----- acetyl co A kreb’s cycle Kreb’s cycle -------- electron transport chain

  31. Conclusion • Catabolism of glucose is completed by: • (i) glycolysis 2 ATP • (ii) kreb’s cycle 2 ATP • (iii) oxidative phosphorylation 34 ATP • Oxidative phosphorylation is the main source for ATP • A total of 38 ATP is formed from glucose metabolism • Anaerobic respiration • Inorganic compound act as a terminal electron acceptor, instead of O • For examples, nitrate, sulfate • Fermentation • Organic compound act as a terminal electron acceptor • For examples: glucose, fructose and lactose

More Related