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Microbiology – Chapter 4, Bacteria Bacteria are Prokaryotes – No nucleus or organelles bound in membranes DNA is a single circular chromosome No Histones.

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Presentation on theme: "Microbiology – Chapter 4, Bacteria Bacteria are Prokaryotes – No nucleus or organelles bound in membranes DNA is a single circular chromosome No Histones."— Presentation transcript:

1 Microbiology – Chapter 4, Bacteria Bacteria are Prokaryotes – No nucleus or organelles bound in membranes DNA is a single circular chromosome No Histones associated with DNA Cell Walls of peptidoglycan (polymer of NAG and NAM cross-linked with polypeptide chain) Smaller ribosome unit Divide by binary fission (not mitosis)

2 Microbiology – Chapter 4, Bacteria Typical bacteria diagram

3 Microbiology – Chapter 4, Bacteria Another bacteria diagram

4 Microbiology – Chapter 4, Bacteria Bacterial Chromosme in “nucleoid area”

5 Microbiology – Chapter 4, Bacteria Bacterial chromosome and an extra-chromosomal “plasmid ”

6 Microbiology – Chapter 4, Bacteria Smaller ribosome than eukaryotes, same function: protein synthesis

7 Microbiology – Chapter 4, Bacteria Bacteria divide by “binary fission”

8 Microbiology – Chapter 4, Bacteria Eukaryotes – “true nucleus”, and membrane bound organelles DNA is membrane bound, inside nucleus, nuclear membrane is a double membrane Chromosomes are usually multiple (paired), and have special histone protein associated with the DNA molecules Membrane bound “organelles”: packages where specialized functions take place: mitochondria, lysosome, ER, Golgi, etc. Cell wall if present is chemically simple (cellulose, or chitin) Slightly larger ribosome Cells divide by a process like mitosis (and can have meiosis too)

9 Microbiology – Chapter 4, Bacteria Typical Eukaryote cell Diagram: More in chapter 5

10 Microbiology – Chapter 4, Bacteria Bacterial appendages: Pilli (fimbriae) and Flagella Pilli are short, hair-like, protein: function “adherence” – stick to each other, stick to surfaces, harder to wash away Specialized “sex” pilus - conjugation

11 Microbiology – Chapter 4, Bacteria Flagella: complex organ of motility, a “motor” VERY COOL A = monotrichous B = amphitrichous C = lophotrichous D = peritrichous

12 Microbiology – Chapter 4, Bacteria Bacterial “Envelope” – Structures on the outside of bacteria: Glycocalyx – sugar coat, if tightly bound = capsule –Protects and prevents from drying, also protects from phagocytes –Slimy, and often a significant component of “biofilms”

13 Microbiology – Chapter 4, Bacteria Outer membrane (outside of cell wall) found in Gram (-) bacteria

14 Microbiology – Chapter 4, Bacteria Outer membrane (outside of cell wall) found in Gram (-) bacteria Gram – bacteria have LPS (lipopolysaccharide), lipoprotein, and phospholipids These can cause some of the symptoms of Gram – bacterial infections (fever, shock, diarrhea)

15 Microbiology – Chapter 4, Bacteria Bacterial Cell Wall – macromolecule, polysaccharide, repeating sugars, NAG and NAM, cross-linked with shot chains of Amino Acids “Peptidoglycan, aka: murein” Tough outer coat, prevents rupture, protects cell, gives it its distinct shape Certain antibiotics work by inhibiting cell wall synthesis (penicillins)

16 Microbiology – Chapter 4, Bacteria Bacterial Cell Wall

17 Microbiology – Chapter 4, Bacteria Gram + and Gram – bacteria have differences in Cell Wall and outer envelope (the theory of why the grams stain works is based on this difference)

18 Microbiology – Chapter 4, Bacteria Gram + and Gram – bacteria have differences in Cell Wall and outer envelope (the theory of why the grams stain works is based on this difference) Gram – are less sensitive to penicillin as a result of thinner CW and outer membrane

19 Microbiology – Chapter 4, Bacteria Grams stain = a differential stain procedure, different results, + and (-)

20 Microbiology – Chapter 4, Bacteria Grams stain = a differential stain procedure, different results, + and (-)

21 Microbiology – Chapter 4, Bacteria Gram negative cell envelope much more complicated than Gram +: lipid, phospholipid, lipid A, peiplasmic space (fluid filled area between cell wall and outer membrane), various protein porons

22 Microbiology – Chapter 4, Bacteria Bacterial cell “shapes” A=bacillus or pl. bacilli B= round, coccus, cocci pl., in chains “Streptococcus) C. Staphylococcus – clusters D= diplococcus E=Spirillum, spirilla pl. (spirochete is a corkscrew shape – not shown) F= vibrio, more comma shaped

23 Microbiology – Chapter 4, Bacteria Cell shape is determined by the genetic character of the organism. Its genes code for the synthesis of the CW material and the cell division mechanism that results in a “round” or “rod” or “spiral” shape One of the criteria used in ID of bacteria Coupled with gram reaction = helpful –Ex. Gram + cocci in clusters is “Staphylococcus” Gram (-) bacilli, motile, green sheen on EMB is E.coli

24 Microbiology – Chapter 4, Bacteria Bacterial cell membrane: regulates what moves in and out of the cytoplasm Diffusion –concentration gradients > high to low Osmosis – diffusion of water across a semipermeable membrane –Isotonic –Hypertonic –Hypotonic***REVIEW ON YOUR OWN*** –Passive transport –Active transport –Engulfment (phagocytosis, pinocytosis) –Specialized group translocation

25 Microbiology – Chapter 4, Bacteria Inside the bacterial cytoplasm Nuceloid – area containing the bacterial chromosome (DNA)

26 Microbiology – Chapter 4, Bacteria Inside the bacterial cytoplasm Plasmid – Extrachromosomal DNA, not part of “genome”, different genes Can transfer in a process – conjugation across sex pilus, change the genetic character of the recipient Tool of “genetic”engineer

27 Microbiology – Chapter 4, Bacteria Inside the bacterial cytoplasm Ribosomes: structure made of RNA, site of protein synthesis Some antibiotics work by messing with the “ribosome” Slightly smaller than our eukaryote ribosome, so antibiotic can work on bacteria but not affect us (selective toxicity)

28 Microbiology – Chapter 4, Bacteria Inside the bacterial cytoplasm Inclusions: granules of sugar, lipid storage, etc. (storage) Endospores (Genus: Bacillus and Clostridium) Hardiest of bacterial structures. Difficult to kill with heat or chemical. Autoclave: 121 degree C, 15 lbs/sq. in. pressure – to penetrate thick coat and destroy genome of bacteria. Purpose: survival not reproduction Inclusions:

29 Microbiology – Chapter 4, Bacteria Inside the bacterial cytoplasm More spores:

30 Microbiology – Chapter 4, Bacteria Taxonomy and Bacteria: Yucch!!!!!! We use Bergey’s Manual for rapid ID of bacteria. Started in the 1940’s, before a lot of modern tech. invented

31 Microbiology – Chapter 4, Bacteria Taxonomy and Bacteria: Yucch!!!!!! We use Bergey’s Manual: Based on 3 primary things: 1. Cell Wall (or lack of cell wall) – Gram reaction (+) or (-) 2. Cell Morphology (shape) Bacillus, Coccus, Spirillum, Vibrio 3. Biochemical characteristics: sugars they ferment, enzymes like catalase and oxidase, decarboxylase, etc. More modern techniques used today to get very specific “strains” –Serological groups (antigen - antibody reactions) –DNA hybridization studiesEx. E.coli 0157H7 or –DNA fingerprintingAzotobacter vinelandii 12837 –Bacterial viruses (phage typing)

32 Microbiology – Chapter 4, Bacteria Taxonomy and Bacteria: Yucch!!!!!! Flow charts are useful – we will use them in our unknowns

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