1. An Introduction to the Prokaryotic Cell, Its Organization, and Members

2. 2 Characteristics of Cells All living things (single and multicellular) are made of cells that share some common characteristics: Basic shape – spherical, cubical, cylindrical Internal content – cytoplasm, surrounded by a membrane DNA chromosome(s), ribosomes, metabolic capabilities

3. 3 Characteristics of Cells Two basic cell types: Eukaryotic and Prokaryotic Eukaryotic cells: animals, plants, fungi, and protists Contain membrane-bound organelles that compartmentalize the cytoplasm and perform specific functions Contain double-membrane bound nucleus with DNA chromosomes Prokaryotic cells: bacteria and archaea No nucleus or other membrane-bound organelles

4. 4 Prokaryotic Profiles

5. 5  The structures that are essential to the functions of all prokaryotic cells are: cell wall cell membrane, cytoplasm, ribosomes, and one chromosome

6. 6 Structure of a Bacterial Cell

7. 7 External Structures  Appendages Two major groups of appendages: ○ Motility – flagella and axial filaments (periplasmic flagella) ○ Attachment or channels – fimbriae and pili  Glycocalyx – surface coating Slime layer capsule

8. 8 Flagella  3 parts: Filament – long, thin, helical structure composed of protein Flagellin Hook – curved sheath Basal body – stack of rings firmly anchored in cell wall  Rotates 360 o  Number and arrangement of flagella varies: Monotrichous, lophotrichous, amphitrichous, peritrichous  Functions in motility of cell through environment

9. 9 Flagella

10. 10 Flagellar Arrangements 1. Monotrichous – single flagellum at one end 2. Lophotrichous – small bunches emerging from the same site 3. Amphitrichous – flagella at both ends of cell 4. Peritrichous – flagella dispersed over surface of cell; slowest

11. 11 Flagellar Responses Guide bacteria in a direction in response to external stimulus: Chemical stimuli – chemotaxis Light stimuli – phototaxis Signal sets flagella into rotary motion clockwise or counterclockwise: Counterclockwise – results in smooth linear direction – run Clockwise – tumbles s

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13. 13 Periplasmic Flagella  Internal flagella, enclosed in the space between the outer sheath and the cell wall peptidoglycan  Produce cellular motility by contracting and imparting twisting or flexing motion

14. 14 Periplasmic Flagella

15. 15 Fimbriae  Fine, proteinaceous, hairlike bristles emerging from the cell surface  Function in adhesion to other cells and surfaces

16. E. Coli Fimbriae

17. 17 Pili  Rigid tubular structure made of pilin protein  Found only in gram-negative cells  Function to join bacterial cells for partial DNA transfer called conjugation

18. 18 Glycocalyx  Coating of molecules external to the cell wall, made of sugars and/or proteins  Two types: 1. Slime layer - loosely organized and attached 2. Capsule - highly organized, tightly attached  Functions: Protect cells from dehydration and nutrient loss Inhibit killing by white blood cells by phagocytosis, contributing to pathogenicity Attachment - formation of biofilms

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21. 21 Biofilm on a Catheter

22. 22 The Cell Envelope  External covering outside the cytoplasm  Composed of two basic layers: Cell wall and cell membrane  Maintains cell integrity  Two different groups of bacteria demonstrated by Gram stain: Gram-positive bacteria: thick cell wall composed primarily of peptidoglycan and cell membrane Gram-negative bacteria: outer cell membrane, thin peptidoglycan layer, and cell membrane

23. 23 Structure of Cell Walls  Determines cell shape, prevents lysis (bursting) or collapsing due to changing osmotic pressures  Peptidoglycan is primary component: Unique macromolecule composed of a repeating framework of long glycan chains cross-linked by short peptide fragments

24. 24 Peptidoglycan

25. 25 Gram-Positive Cell Wall  Thick, homogeneous sheath of peptidoglycan 20-80 nm thick Includes teichoic acid and lipoteichoic acid: function in cell wall maintenance and enlargement during cell division; move cations across the cell envelope; stimulate a specific immune response Some cells have a periplasmic space, between the cell membrane and cell wall

26. 26 Gram-Negative Cell Wall  Composed of an outer membrane and a thin peptidoglycan layer  Outer membrane is similar to cell membrane bilayer structure Outermost layer contains lipopolysaccharides and lipoproteins (LPS) ○ Lipid portion may become toxic (endotoxin) when released during infections ○ May function as receptors and blocking immune response ○ Contain porin proteins in upper layer – regulate molecules entering and leaving cell Bottom layer is a thin sheet of peptidoglycan ○ Periplasmic space above and below peptidoglycan

27. 27 Gram Positive vs. Gram Negative

28. 28 Gram Positive vs. Gram Negative Insert figure 4.12 Comparative cell envelopes

29. 29 Gram-Positive and Gram-Negative

30. 30 The Gram Stain  Differential stain that distinguishes cells with a gram-positive cell wall from those with a gram-negative cell wall Gram-positive - retain crystal violet and stain purple Gram-negative - lose crystal violet and stain red from safranin counterstain  Important basis of bacterial classification and identification  Practical aid in diagnosing infection and guiding drug treatment

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32. 32 Nontypical Cell Walls  Some bacterial groups lack typical cell wall structure, i.e., Mycobacterium and Nocardia Gram-positive cell wall structure with lipid mycolic acid (cord factor) ○ Pathogenicity and high degree of resistance to certain chemicals and dyes ○ Basis for acid-fast stain used for diagnosis of infections caused by these microorganisms  Some have no cell wall, i.e., Mycoplasma Cell membrane is stabilized by sterols Pleomorphic

33. 33 Extreme variation in shape of Mycoplasma pneumoniae

34. 34 Other Structures  Cell Membrane Phospholipid bilayer with embedded proteins – fluid mosaic model  Cell cytoplasm  Chromosome Single, circular, double-stranded DNA molecule that contains all the genetic information required by a cell Aggregated in a dense area called the nucleoid ○ DNA is tightly coiled

35. 35 Cell Membrane Structure

36. 36 Chromosome Structure

37. 37  Plasmids Small circular, double-stranded DNA Free or integrated into the chromosome Duplicated and passed on to offspring Not essential to bacterial growth and metabolism May encode antibiotic resistance, tolerance to toxic metals, enzymes, and toxins Used in genetic engineering - readily manipulated and transferred from cell to cell

38. Bacterial Plasmid

39. 39  Ribosomes Made of 60% ribosomal RNA and 40% protein Consist of two subunits: large and small Prokaryotic differ from eukaryotic ribosomes in size and number of proteins Site of protein synthesis Present in all cells

40. 40 Prokaryotic Ribosome

41. 41  Cytoskeleton Many bacteria possess an internal network of protein polymers that is closely associated with the cell wall

42. 42 Bacterial Internal Structures  Endospores Inert, resting, cells produced by some G+ genera: Clostridium, Bacillus, and Sporosarcina ○ Have a 2-phase life cycle: Vegetative cell – metabolically active and growing Endospore – when exposed to adverse environmental conditions; capable of high resistance and very long-term survival Sporulation - formation of endospores ○ Hardiest of all life forms ○ Withstands extremes in heat, drying, freezing, radiation, and chemicals ○ Not a means of reproduction Germination - return to vegetative growth

43. 43 Sporulation Cycle

44. 44 Bacterial Shapes, Arrangements, and Sizes  Vary in shape, size, and arrangement but typically described by one of three basic shapes: Coccus – spherical Bacillus – rod ○ Coccobacillus – very short and plump ○ Vibrio – gently curved Spirillum – helical, comma, twisted rod, ○ Spirochete – spring-like

45. 45 Bacterial Shapes, Arrangements, and Sizes  Arrangement of cells is dependent on pattern of division and how cells remain attached after division: Cocci: ○ Diplococci – in pairs ○ Tetrads – groups of four ○ Irregular clusters ○ Chains ○ Cubical packets (sarcina) Bacilli: ○ Diplobacilli ○ Chains ○ Palisades

46. 46 Arrangement of Cocci

47. 47 The Dimensions of Bacteria

48. 48 Classification Systems in the Prokaryotae 1. Microscopic morphology 2. Macroscopic morphology – colony appearance 3. Bacterial physiology 4. Serological analysis 5. Genetic and molecular analysis

49. 49 Bacterial Taxonomy Based on Bergey’s Manual  Bergey’s Manual of Determinative Bacteriology – five volume resource covering all known prokaryotes Classification based on genetic information – phylogenetic Two domains: Archaea and Bacteria Five major subgroups with 25 different phyla

50. 50 Major Taxonomic Groups of Bacteria  Domain Archaea – primitive, adapted to extreme habitats and modes of nutrition  Domain Bacteria: Phylum Proteobacteria – Gram-negative cell walls Phylum Firmicutes – mainly gram-positive with low G + C content Phylum Actinobacteria – Gram-positive with high G + C content

51. 51 General Classification Scheme

52. 52 Diagnostic Scheme for Medical Use  Uses phenotypic qualities in identification Restricted to bacterial disease agents Divides bacteria based on: ○ cell wall structure, ○ shape, ○ arrangement, ○ and physiological traits (nutrients, media, etc.)

53. 53 Species and Subspecies  Species – a collection of bacterial cells which share an overall similar pattern of traits in contrast to other bacteria whose pattern differs significantly  Strain or variety – a culture derived from a single parent that differs in structure or metabolism from other cultures of that species (biovars, morphovars)  Type – a subspecies that can show differences in antigenic makeup (serotype or serovar), susceptibility to bacterial viruses (phage type) and in pathogenicity (pathotype)

54. 54 Unusual Forms of Medically Significant Bacteria  Obligate intracellular parasites Rickettsias ○ Very tiny, gram-negative bacteria ○ Most are pathogens that alternate between mammals and blood-sucking arthropods ○ Obligate intracellular pathogens ○ Cannot survive or multiply outside of a host cell ○ Cannot carry out metabolism on their own ○ Rickettsia rickettisii – Rocky Mountain spotted fever ○ Rickettsia typhi – endemic typhus

55. 55 Unusual Forms of Medically Significant Bacteria Chlamydias ○ Tiny ○ Obligate intracellular parasites ○ Not transmitted by arthropods ○ Chlamydia trachomatis – severe eye infection and one of the most common sexually transmitted diseases ○ Chlamydia pneumoniae – lung infections

56. 56 Archaea: The Other Prokaryotes  Constitute third Domain Archaea  Seem more closely related to Domain Eukarya than to bacteria  Contain unique genetic sequences in their rRNA  Have unique membrane lipids and cell wall construction  Live in the most extreme habitats in nature, extremophiles  Adapted to heat, salt, acid pH, pressure, and atmosphere  Includes: methane producers, hyperthermophiles, extreme halophiles, and sulfur reducers