1. A Brief History of Microbiology Des Moines Area Community College
Chapter 1
A Brief History of Microbiology
Azeem Ahmad, Ph.D
Des Moines Area Community College
(DMACC-URBAN)

2. Learning Objectives
Invisible world
Six classes of microorganisms
Prokaryotes, Archaea and Eukaryotes
Viruses
Spontaneous generation
Koch postulates
Gram stain
Infection and disease
Genetics
Modern microbiology

3. The Early Years of Microbiology
What Does Life Really Look Like?
Antoni van Leeuwenhoek (Dutch)
Began making and using simple microscopes
Often made a new microscope for each specimen
Examined water and visualized tiny animals, fungi, algae, and single-celled protozoa: “animalcules”
By end of 19th century, these organisms were called microorganisms
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4. Figure 1.2 Reproduction of Leeuwenhoek’s microscope
Lens
Specimen holder

5. Figure 1.3 The microbial world
Protozoa and bacteria-microbial world was looked at and started to describe

6. The Early Years of Microbiology
How Can Microbes Be Classified?
Carolus Linnaeus developed taxonomic system for grouping similar organisms together
Leeuwenhoek’s microorganisms grouped into six categories:
Bacteria
Archaea
Fungi
Protozoa
Algae
Small multicellular animals
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7. The Early Years of Microbiology
Bacteria and Archaea
Unicellular and lack nuclei
Much smaller than eukaryotes
Found everywhere there is sufficient moisture
Reproduce asexually
Two kinds
Bacteria – cell walls contain peptidoglycan
Archaea – cell walls composed of polymers other than peptidoglycan
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8. Figure 1.4 Cells of the bacterium Streptococcus
Prokaryotic bacterial cells
Nucleus of eukaryotic cheek cell

9. The Early Years of Microbiology
Fungi
Eukaryotic (have membrane-bound nucleus)
Obtain food from other organisms
Possess cell walls
Include
Molds – multicellular; grow as long filaments; reproduce by sexual and asexual spores
Yeasts – unicellular; reproduce by budding or sexual spores
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10. Figure 1.5 Fungi-overview

11. The Early Years of Microbiology
Protozoa
Single-celled eukaryotes
Similar to animals in nutrient needs and cellular structure
Live freely in water; some live in animal hosts
Asexual (most) and sexual reproduction
Most are capable of locomotion by
Pseudopodia
Cilia
Flagella
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12. Figure 1.6 Locomotive structures of protozoa-overview

13. The Early Years of Microbiology
Algae
Unicellular or multicellular
Photosynthetic
Simple reproductive structures
Categorized on the basis of pigmentation, storage products, and composition of cell wall
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14. Figure 1.7 Algae-overview

15. Figure 1.9 Viruses infecting a bacterium
Viruses assembling inside cell

16. The Golden Age of Microbiology
Scientists searched for answers to four questions
Is spontaneous generation of microbial life possible?
What causes fermentation?
What causes disease?
How can we prevent infection and disease?
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17. The Golden Age of Microbiology
Some thought living things arose from three processes
Asexual reproduction
Sexual reproduction
Nonliving matter
Aristotle proposed spontaneous generation
Living things can arise from nonliving matter
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18. The Golden Age of Microbiology
Pasteur’s Experiments
When the “swan-necked” flasks remained upright, no microbial growth appeared
When the flask was tilted, dust from the bend in the neck seeped back into the flask and made the infusion cloudy with microbes within a day
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19. Figure Louis Pasteur

20. Figure 1.12 Pasteur’s experiments with “swan-necked” flasks
Steam escapes from open end of flask.
Dust from air settles in bend.
Air moves in and out of flask.
Months
Infusion is heated.
Infusion sits; no microbes appear.
Infusion remains sterile indefinitely.

21. The Golden Age of Microbiology
The Scientific Method
Spontaneous generation debate led in part to scientific method
Observation leads to question
Question generates hypothesis
Hypothesis is tested through experiment(s)
Results prove or disprove hypothesis
Accepted hypothesis leads to theory/law
Reject or modify hypothesis
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22. Figure 1.13 The scientific method
Observations
Question
Repeat
Experimental data support hypothesis
Accept hypothesis
Theory or law
Experiment, including control groups
Hypothesis
Observations
Reject hypothesis
Experimental data do not support hypothesis
Modify hypothesis
Modified hypothesis

23. Figure 1.14 Pasteur's application of the scientific method
Observation:
Fermenting grape juice
Microscopic analysis shows juice contains yeasts and bacteria.
Hypothesis
Experiment
Observation
Conclusion
Day 1: Flasks of grape juice are heated sufficiently to kill all microbes.
Day 2 I.
Spontaneous fermentation occurs.
No fermentation; juice remains free of microbes
Reject hypothesis I.
Flask is sealed.
II.
Air ferments grape juice.
No fermentation; juice remains free of microbes
Reject hypothesis II.
Flask remains open to air via curved neck.
III.
Bacteria ferment grape juice into alcohol.
Bacteria reproduce; acids are produced.
Modify hypothesis III; bacteria ferment grape juice into acids.
Juice in flask is inoculated with bacteria and sealed.
IV.
Yeasts ferment grape juice into alcohol.
Yeasts reproduce; alcohol is produced.
Accept hypothesis IV; yeasts ferment grape juice into alcohol.
Juice in flask is inoculated with yeast and sealed.

24. Table 1.1 Some Industrial Uses of Microbes

25. The Golden Age of Microbiology
What Causes Disease?
Pasteur developed germ theory of disease
Robert Koch studied causative agents of disease
Anthrax
Examined colonies of microorganisms
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26. Figure Robert Koch

27. The Golden Age of Microbiology
Koch’s Contributions
Simple staining techniques
First photomicrograph of bacteria
First photomicrograph of bacteria in diseased tissue
Techniques for estimating CFU/ml
Use of steam to sterilize media
Use of Petri dishes
Techniques to transfer bacteria
Bacteria as distinct species
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28. Figure 1.16 Bacterial colonies on agar
Bacterium 6
Bacterium 7
Bacterium 5
Bacterium 8
Bacterium 4
Bacterium 9
Bacterium 3
Bacterium 10
Bacterium 2
Bacterium 11
Bacterium 1
Bacterium 12

29. The Golden Age of Microbiology
Koch’s Postulates
Suspected causative agent must be found in every case of the disease and be absent from healthy hosts
Agent must be isolated and grown outside the host
When agent is introduced into a healthy, susceptible host, the host must get the disease
Same agent must be found in the diseased experimental host
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30. The Golden Age of Microbiology
Gram’s Stain
Danish scientist Hans Christian Gram developed more important staining technique than Koch’s in 1884
Involves the applications of a series of dyes
Some microbes are left purple, now labeled Gram-positive
Other microbes are left pink, now labeled Gram-negative
Gram procedure used to separate into two groups
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31. Figure 1.17 Results of Gram staining
Gram-positive
Gram-negative

32. Figure 1.19 Some scientific disciplines and applications
BIOLOGISTS
MODERN DISCIPLINES
Bacteriology (bacteria) Protozoology (protozoa) Mycology (fungi) Parasitology (protozoa and animals) Phycology (algae)
Pre-1857
Leeuwenhoek
Linnaeus
Taxonomy
Semmelweiss Snow
Infection control Epidemiology
The Golden Age of Microbiology (1857–1907)
Industrial microbiology
Pasteur
Pasteurization
Food and beverage technology
Microbial metabolism
Genetics Genetic engineering
Buchner
Koch
Koch’s postulates
Etiology
Ivanowski
Virology
Beijerinck Winogradsky
Environmental microbiology Ecological microbiology
Gram
Microbial morphology
Lister Nightingale
Antiseptic medical techniques Hospital microbiology
Jenner von Behring Kitasato
Serology Immunology
Ehrlich
Chemotherapy
Fleming
Pharmaceutical microbiology

33. Table 1.3 Fields of Microbiology

34. The Modern Age of Microbiology
What Are the Basic Chemical Reactions of Life?
Biochemistry
Began with Pasteur’s and Buchner’s works
Microbes used as model systems for biochemical reactions
Practical applications
Design of herbicides and pesticides
Diagnosis of illness and monitoring responses to treatment
Treatment of metabolic diseases
Drug design
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35. The Modern Age of Microbiology
How Do Genes Work?
Microbial genetics
Molecular biology
Recombinant DNA technology
Gene therapy
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36. The Modern Age of Microbiology
Microbial Genetics
Avery, MacLeod, and McCarty: genes are contained in molecules of DNA
Beadle and Tatum: a gene’s activity is related to protein function
Translation of genetic information into protein explained
Rates and mechanisms of genetic mutation investigated
Control of genetic expression by cells described
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37. The Modern Age of Microbiology
Molecular Biology
Explanation of cell function at the molecular level
Pauling proposed that gene sequences could
Provide understanding of evolutionary relationships/processes
Establish taxonomic categories
Identify microbes that have never been cultured
Woese determined cells belong to bacteria, archaea, or eukaryotes
Cat scratch disease caused by unculturable organism
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38. The Modern Age of Microbiology
Recombinant DNA Technology
Genes in microbes, plants, and animals manipulated for practical applications
Production of human blood-clotting factor by E. coli to aid hemophiliacs
Gene Therapy
Inserting a missing gene or repairing a defective one in humans by inserting desired gene into host cells
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39. The Modern Age of Microbiology
What Roles Do Microorganisms Play in the Environment?
Bioremediation uses living bacteria, fungi, and algae to detoxify polluted environments
Recycling of chemicals such as carbon, nitrogen, and sulfur
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40. The Modern Age of Microbiology
How Do We Defend Against Disease?
Serology
The study of blood serum
Blood contains chemicals and cells that fight infection
Immunology
The study of the body’s defense against specific pathogens
Chemotherapy
Fleming discovered penicillin
Domagk discovered sulfa drugs
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41. Fungus colony (Penicillium)
Figure Effects of penicillin on a bacterial “lawn” in a petri dish
Fungus colony (Penicillium)
Zone of inhibition
Bacterial colonies (Staphylococcus)

42. The Modern Age of Microbiology
What Will the Future Hold?
Microbiology is built on asking and answering questions
The more questions we answer, the more questions we have
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