1 / 123

Bacterial morphology, metabolism and growth

Bacterial morphology, metabolism and growth. Dr Ömer Küçükbasmacı. Cell. Fundemental unit of living things (smallest bacterium-largest plants-animals). Bacteria. The smallest cells Visible only with the aid of a microscope The smallest bacteria: Chlamydia and Rickettsia-0.1-0.2 micrometer

yael
Download Presentation

Bacterial morphology, metabolism and growth

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. Bacterial morphology, metabolism and growth Dr Ömer Küçükbasmacı

  2. Cell • Fundemental unit of living things (smallest bacterium-largest plants-animals)

  3. Bacteria • The smallest cells • Visible only with the aid of a microscope • The smallest bacteria: Chlamydia and Rickettsia-0.1-0.2 micrometer • Larger bacteria: many microns in length

  4. A newly described species • Hundred of times larger than the average bacterial cell • Is visible to the naked eye Diversity!

  5. Most bacterial cells • Approximately 1 micrometer in diameter • Visible by light microscope • Resolution: 0.2 micrometer

  6. Microscopes • Light: • Bright-field • Dark-field (Treponema pallidum-Syphilis_Frengi) • Fluorescence • Phase contrast (details of the living cell) • Electron

  7. Staining • Simple • Differential: Gram and Acid-fast stain Gram-stain: cell wall Acid fast stain: Mycobacterium • Negative stain: Indian ink (capsule) • Special staining

  8. Animal and plant cells • Much larger • Ranging from 7micrometer (red blood cells) • To several feet (certain nerve cell)

  9. Each cell • Genetic basis for reproduction (DNA genome) • Biochemical machinery (genetic information is transcribed in mRNA and mRNA translated in proteins) • The machinery for energy production and biosynthesis • This is all packaged by a membrane.

  10. Each cell • Replicates by cell division.

  11. Cells • Eukaryotic (Greek for true nucleus) • Prokaryotic (Greek for primitive nucleus)

  12. Eucaryotes • Animals • Plants • Fungi

  13. Procaryotes • Bacteria • Blue-green algae

  14. Major characteristics of Eucaryotic and prokaryotic cell Eucaryote Prokaryote • Size >5 μm 0,5-3 μm • Nuclear structure : Nucleus classic membrane no membrane Chromosomes strands of DNA single circular DNA diploid genome haploid genome

  15. Major characteristics of Eucaryotic and prokaryotic cell Eucaryote Prokaryote • Cytoplasmic Structures Mitokondria + - Golgi bodies + - Endoplasmic reticulum + - Ribosomes 80S(60S+40S) 70S(50S+30S) Cytoplasmic membrane with sterols no sterol

  16. Major characteristics of Eucaryotic and prokaryotic cell Eucaryote Prokaryote • Cell wall -/composed of kitin complex structure (protein, lipits and peptidoglycans) • Reproduction sexual and asexual asexual (binary fission) • Movement complex flagellum simple flagellum (If present) (If present) • Respiration via mitokondria via cytoplasmic membrane

  17. Bacteria • Lack nucleus membrane and membrane bound organelles • A smaller ribosome • Peptidoglycan cell wall which protects it from environtment with low osmotic pressure, at temperature extremes (both hot and cold), dryness and with very dilute and diverse energy sources. • They have evolved their structures and functions to adopt these conditions.

  18. Differences • Between Eukaryotes and prokaryotes

  19. Differences between Prokaryotes • Bacteria differ: -morphology (size, shape, stainig characteristics) -metabolic -antigenic and -genetic characteristics

  20. Size • They are diffucult to differentiate by size

  21. Shape • Spherical: coccus (Staphyloccus) • Rod-shaped: bacillus (Escherichia) • Snakelike: spirillum (Treponema) • Branched filamentous (Nocardia and Actinomyces) ( Clusters: diplococcus (Neisseria) chains (Streptococcus) grapelike (Staphylococcus) )

  22. Bacterial shape Sperical (coccus) Rod-shaped Spiral Spiral or spirillum Helix or spirochete

  23. Bacterial arrangement Diplococcus Chains: streptococcus Clusters: staphylococcus Packets of eight:sarcina

  24. Treponema by dark-field microscopy

  25. Gram stain • Two major classes of bacteria are distinguished: • Gram-positive and • Gram-negative bacteria • Except: • Mycobacteria (waxy outer shell , distinguished by acid fast stain) • Mycoplasmas(no peptidoglycan)

  26. Bacterial Ultrastructure • Internal structure • External structure • Gram-positive and gram-negative bacteria have -Similar internal structure -But different external structure

  27. Cytoplasm • DNA chromosome • mRNA • Ribosomes • Proteins • Metabolites

  28. Bacterial chromosome • Unlike eukaryotes • A single • Double stranded circle • Not in a membrane bound nucleus • In a discrete area called nucleoid

  29. Bacterial chromosome • Unlike eukaryotes • No histons

  30. Plasmids • Smaller • Circular • Extrachromosomal DNAs • Not usually essential for cellular survival • Most commonly found in gram-negative bacteria • Often provide a selective advantage: resistance to antibiotics

  31. Lack of a nuclear membrane • Simplifies the requirements and • Control mechanisms for the synthesis of proteins

  32. Ribosomes • Unlike the eukaryotic 80S(40S+60S)ribosome • Bacterial 70S chromosome (30+50S) • Proteins and RNA of the ribosome are significantly different • Major targets for antibacterial drugs

  33. Cytoplasmic membrane • Lipid bilayer • Similar to eukaryotic membranes • But no sterols (cholesterol) Exception: Mycoplasmas

  34. Cytoplasmic membrane • Responsible for many functions • Attributable to organelles in eukaryotes: -electron transport -energy production (mitokondria in eukaryotes)

  35. Cytoplasmic membrane • Transport proteins: uptake of metabolites release of other substances • Ion pumps: to maintain a membrane potential • Enzymes

  36. Mesosome • A coiled cytoplasmic membrane • An anchor to bind and pull apart daughter chromosomes during cell division.

  37. Cell wall • Distinguishes gram-positive and gram-negative bacteria

  38. The cytoplasmic membrane in most prokaryotes surrounded by • Rigid peptidoglycan (murein) layer • Except: Archaebacteria (pseudoglycan and pseudomurein) and mycoplasmas (no cell wall) • Peptidoglycan provides rigidity and determines the shape of a bacteria • Gram-negative bacteria. + outer membranes

  39. Gram positive bacteria • Thick multilayered cell wall • Consisting mainly of peptidoglycan

  40. Gram positive bacteria • Peptidoglycan • Sufficiently porous(allows diffusion of metabolites to the plasma membrane) • Essential for structure, replication, for survival

  41. Peptidoglycan • During infection • İnterferes with phagocytosis • Stimulates lymphoctes • Pyrogenic activity (induces fever)

  42. Peptidoglycan • Degraded by lysozyme • Enzyme in human tears, mucus (produced by bacteria and other organisms) • Degrades the glycan backbone of the peptidoglycan which protects it from osmotic pressure changes

  43. Protoplast • Removal of cell wall with lysozyme • Lysis unless it is osmotically stabilized

  44. Gram-positive cell wall • Peptidoglycan + • Teicoic acid • Lipoteichoic acid • Complex polisaccarides (C polysaccharides) • M protein of streptococci • R protein of staphylococci

  45. Gram-positive bacteria • Teicoic acid : covalently linked to peptidoglycan • Lipoteichoic acid : anchored in the cytoplasmic membrane • Common surface antigens • Distinguish bacterial serotypes • Promote attachment to other bacteria and to spesific receptors on mammalian cell surfaces (adherence)

  46. Gram positive-bacteria • Teicoic acid: important virulance factors • Lipoteicoic acid are shed into media and host • Although weaker • Can initiate endotoxic-like activities.

More Related