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Zoology 145 course

Zoology 145 course. General Animal Biology. For Premedical Student. Zoology Department Lecture 5: Prokaryotic Cell (Bacteria and Archaea). 1436-1437H. A)- Prokaryotes. Objectives. What are Prokaryotes? Domain: Archaea Domain: Bacteria Prokaryotic Cell Shapes of Bacteria

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Zoology 145 course

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  1. Zoology 145 course General Animal Biology For Premedical Student Zoology Department Lecture 5: Prokaryotic Cell (Bacteria and Archaea) 1436-1437H

  2. A)- Prokaryotes

  3. Objectives • What are Prokaryotes? • Domain: Archaea • Domain: Bacteria • Prokaryotic Cell • Shapes of Bacteria • The Gram’s stain. • Cell-Surface Structures • Major Nutritional Modes

  4. What are Prokaryotes? • It includes two Major Domains: Archaea and Bacteria • Prokaryotes are single-celled organisms that do not have a membrane-bound nucleus, and can live in nearly every environment on Earth. • Although tiny, prokaryotes differ greatly in their genetic traits, their modes of nutrition, however, their habitats are similar. • Based on genetic differences, prokaryotes are grouped in two domains: Domain Archaea and Domain Bacteria.

  5. 1. Domain: Archaea Archaea are extremophiles, of extreme environments and can be classified into: a)- Extreme halophiles: live in such saline places as the Great Salt Lake and the Dead Sea. Some species require an extremely salty environment to grow. b)- Extreme thermophiles live in hot environments. The optimum temperatures for most thermophiles are 60 - 80°C.

  6. 2. Domain: Bacteria Bacteria occur in many shapes and sizes. Most bacteria have one of three basic shapes: rod-shaped, sphere-shaped, or spiral-shaped.

  7. Plasma membrane Cell Wall Capsule Ribosomes Nucleoid Cytoplasm (Cytosol) Prokaryotic Cell

  8. Shapes of Bacteria • Bacteria occur in many shapes and sizes. Most bacteria have one of three basic shapes: rod-shaped, sphere-shaped, or spiral-shaped. • Spiral shaped bacteria in the form of spirilla(singular, spirillum) or vibrio (comma like). • Sphere-shaped bacteria are called cocci(singular, coccus). An example of cocci is Micrococcus luteus. Cocci that form chains similar to a string of beads are called streptococci. • Rod-shaped bacteria are called bacilli(singular, bacillus). An example of bacilli is Escherichia coli.

  9. It is a tool for identifying bacteria, based on differences in their cell walls. A)- Gram-positive (Gram +ve) bacteria: Their cell walls have large amountsof peptidoglycans that react with Gram’s stain (appear violet-stained). The Gram’s stain

  10. B)- Gram-negative(Gram -ve) bacteria: their cell walls have no or small amount of peptidoglycan. So, do not react or very weakly react withGram’s stain (appear red-stained) The Gram’s stain

  11. The Gram’s stain • Gram Stain • Most species of bacteria are classified into two categories based on the structure of their cell walls as determined by a technique called the Gram stain. • Gram-positive bacteria have a thick layer of peptidoglycan in their cell wall, and they appear violet under a microscope after the Gram-staining procedure. • Gram-negative bacteria have a thin layer of peptidoglycan in their cell wall, and they appear reddish-pink under a microscope after the Gram-staining procedure.

  12. Gram Staining of Bacteria Gram +ve bacteria: have Large amount of peptidoglycan that stained violet. Gram –ve bacteria: Have small amount or no peptidoglycan stainedred. • Most Gram-negative species are pathogenic more threatening than gram-positive species. • Gram-negative bacteria are commonly more resistant than gram-positive species to antibiotics.

  13. I - the bacterial capsule • Many prokaryotes (bacteria) secrete a sticky protective layer called capsule outside the cell wall. • Capsule has the following functions: • Adhere bacterial cells to their substratum. • Increase bacterial resistance to host defenses. • Stick bacterialcells togetherwhen live incolonies. • Protect bacterial cell.

  14. II - The bacterial cell wall • In all prokaryotes, the functions of the cell wall are as following: • maintains the shape of the cell, • affords physical protection • prevents the cell from bursting in a hypotonic environment. • Most bacterial cell walls contain peptidoglycan (a polymer of modified sugars cross-linked by short polypeptides). • The walls of Archaea lack peptidoglycan.

  15. Structural Characteristics of a Bacterial Cell

  16. Reproduction of Bacteria • Prokaryotes reproduceonly asexuallyby binary fission. • A single cell produces a colony of offspring.

  17. Nutrition of Prokaryotes • Nutrition refers to how an organism obtains energy and a carbon source from the environment to build the organic molecules of its cells. • Prokaryotes are grouped into four categories according to how they obtain energy and carbon

  18. Nutrition of Prokaryotes • Phototrophs:Organisms that obtain energy from light. • Chemotrophs:Organisms that obtain energy from chemicals in their environment. • Autotrophs:Organisms that use CO2 as a carbon source. • Heterotrophs:Organisms that use organic nutrients as a carbon source.

  19. There are four major modes of nutrition • Photoautotrophs: • use light energy as an energy source, and CO2 as a carbon source to synthesize organic compounds. • Chemoautotrophs: • usechemical inorganic substances as an energy source, and CO2 as a carbon source. • Photoheterotrophs: • use lightas an energy source, and organic substances as carbon sources. • Chemoheterotrophs: use organic substances as a source for both energy and carbon.

  20. Organic compounds as Carbon Source CO2 as Carbon Source Prokaryotic modes of nutrition Based on Carbon sourceand Energy source that can be used by a prokaryotic organism to synthesize organic compounds. Prokaryotes Autotrophs Heterotrophs Photo-autotroph Chemo-autotroph Photo-Heterotroph Chemo-Heterotroph - Light as energy source -CO2 as C source - Chemicals as energy source -CO2 as C source - Light as energy source -Organic compounds as C source - Chemicals as energy source - Organic compounds as C source

  21. Reference

  22. Thank you

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