Intro to science and micro LECTURE TO BE POSTED.pdf

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INTRODUCTION TO SCIENCE AND INFECTIOUS
DISEASES
Chapters 1.3 and 2.3 - Types of microorganisms and Instruments of Microscopy
LEARNING OBJECTIVES
1. Describe and discuss the characteristics of science including the scientific
method (including a clear definition of the terms, hypothesis, testing and
theory) the requirement to publish, the material, quantitative,
probabilistic and tentative nature of scientific knowledge and the use of
modeling.
2. Use examples to distinguish between science and other ways of knowing
3. Describe the characteristics that distinguish the 6 kingdoms of life
4. Provide an overview of the field of microbiology
5. List the various types of microorganisms and describe their defining
characteristics
6. Give examples of different types of cellular and viral microorganisms and
infectious agents
7. Describe the distinguishing features and typical uses for various types of
light microscopes, electron microscopes, and scanning probe microscopes
 What is Science?

Why should we trust science?

https://slideplayer.com/slide/7570
434/
THE 6 KINGDOMS OF LIFE - TAXONOMY
Current phylogenetic
analyses include
information from a range of
sources, including
morphological, genetic, and
biochemical data*

https://smartclass4kids.com/6-kingdoms-of-life/
CHARACTERISTICS OF EACH KINGDOM

Biology 11, McGrawHill Ryerson
TAXONOMY

https://examples.yourdictionary.com/classification-of-living-things-basic-taxonomy-explained.html
MICROBIOLOGY, A FIELD OF STUDY

▪ Microbiology : the study of all different types of microorganisms.
▪ Subfields:
▪ bacteriology is the study of bacteria;
▪ mycology is the study of fungi;
▪ protozoology is the study of protozoa;
▪ parasitology is the study of helminths and other parasites;
▪ virology is the study of viruses.

▪ Immunology, the study of the immune system, is often included in
the study of microbiology because host–pathogen interactions are
central to our understanding of infectious disease processes.
 THE RELATIVE SIZES OF VARIOUS OBJECTS

The relative sizes of various microscopic and nonmicroscopic objects. Note that a typical
virus measures about 100 nm, 10 times smaller than a typical bacterium (~1 μm), which is
at least 10 times smaller than a typical plant or animal cell (~10–100 μm). An object must
measure about 100 μm to be visible without a microscope.
PROKARYOTIC MICROORGANISMS: BACTERIA
Bacteria are found in nearly every habitat on earth, including within and
on humans. Most bacteria are harmless or helpful, but some
are pathogens, causing disease in humans and other animals.
Bacteria have a wide range of metabolic capabilities and can grow in a
variety of environments, using different combinations of nutrients.
Bacteria are often described in terms of their general shape. Common
shapes include spherical (coccus), rod-shaped (bacillus), or curved
(spirillum, spirochete, or vibrio):

Common bacterial shapes. Note how coccobacillus is a combination of spherical (coccus)
and rod-shaped (bacillus). (credit “Coccus”: modification of work by Janice Haney Carr, Centers for Disease Control and
Prevention; credit “Coccobacillus”: modification of work by Janice Carr, Centers for Disease Control and Prevention; credit “Spirochete”:
Centers for Disease Control and Prevention)
PROKARYOTIC MICROORGANISMS: ARCHAEA

Archaea are also unicellular prokaryotic organisms.
Archaea and bacteria have different evolutionary histories, as
well as significant differences in genetics, metabolic pathways,
and the composition of their cell walls and membranes.
They mainly differ by the cell wall composition.
Like bacteria, archaea are found in nearly every habitat on earth,
even extreme environments that are very cold, very hot, very
basic, or very acidic. Some archaea live in the human body, but
none have been shown to be human pathogens.
EUKARYOTIC MICROORGANISM: PROTISTS
Protists are an informal grouping of eukaryotes that are not
plants, animals, or fungi. Algae and protozoa are examples of
protists.

Assorted diatoms, a kind of algae, live in annual sea ice in McMurdo Sound, Antarctica.
Diatoms range in size from 2 μm to 200 μm and are visualized here using light
microscopy. (credit: modification of work by National Oceanic and Atmospheric
Administration)
EUKARYOTIC MICROORGANISM: ALGAE
Algae (singular: alga) are protists that can be either unicellular
or multicellular and vary widely in size, appearance, and habitat.
Their cells are surrounded by cell walls made of cellulose.
Algae are photosynthetic organisms
Many consumer products contain ingredients derived from
algae, such as carrageenan or alginic acid, which are found in
some brands of ice cream, salad dressing, beverages, lipstick,
and toothpaste.
Agar, a gel derived from algae plays a prominent role in the
microbiology laboratory. can be mixed with various nutrients
and used to grow microorganisms in a Petri dish.
Algae are also being developed as a possible source for biofuels.
EUKARYOTIC MICROORGANISMS: PROTOZOANS
Protozoa (singular: protozoan) are
protists that make up the backbone
of many food webs by providing
nutrients for other organisms.
Protozoa are very diverse. Some
protozoa are photosynthetic; others
feed on organic material. Some are
free-living, whereas others are Giardia lamblia, an intestinal
protozoan parasite that infects
parasitic, only able to survive by humans and other mammals,
extracting nutrients from a host causing severe diarrhea. (credit:
modification of work by Centers
organism. for Disease Control and
Prevention)
Most protozoa are harmless, but
some are pathogens that can cause
disease in animals or humans.
EUKARYOTIC MICROORGANISMS: FUNGI
Fungi (singular: fungus) are also eukaryotes. Some
multicellular fungi, such as mushrooms, resemble plants,
but they are actually quite different.
Fungi are not photosynthetic.
EUKARYOTIC MICROORGANISMS: FUNGI
Unicellular fungi—yeasts—are included within the study of
microbiology.
Some yeasts have beneficial uses, such as causing bread to
rise and beverages to ferment; but yeasts can also cause
food to spoil.
Some even cause diseases,
such as vaginal yeast infections
and oral thrush.

Candida albicans is a unicellular fungus, or yeast. It is the causative
agent of vaginal yeast infections as well as oral thrush, a yeast
infection of the mouth that commonly afflicts infants. C. albicans has a
morphology similar to that of coccus bacteria; however, yeast is a
eukaryotic organism (note the nuclei) and is much larger. (credit:
modification of work by Centers for Disease Control and Prevention)
EUKARYOTIC MICROORGANISMS: FUNGI
Molds are multicellular organisms
made up of long filaments
(Hyphae) that form visible
colonies.
Molds are found in many different
environments, from soil to rotting
food to dank bathroom corners. Large colonies of microscopic fungi can often be observed
with the naked eye, as seen on the surface of these moldy
oranges.
Molds play a critical role in the decomposition of dead plants and
animals.
Some molds can cause allergies, and others produce disease-causing
metabolites called mycotoxins.
Molds have been used to make pharmaceuticals, including penicillin,
which is one of the most commonly prescribed antibiotics, and
cyclosporine, used to prevent organ rejection following a transplant.
EUKARYOTIC MICROORGANISMS: HELMINTHS
Multicellular parasitic worms called helminths are not technically
microorganisms, as most are large enough to see without a
microscope. However, these worms fall within the field of
microbiology because diseases caused by helminths involve
microscopic eggs and larvae.
Dracunculus medinensis, causes
dizziness, vomiting, diarrhea,
and painful ulcers on the legs
and feet when the worm works
its way out of the skin. (a) The beef tapeworm, Taenia saginata, infects both
cattle and humans. T. saginata eggs are
Infection typically occurs after a microscopic (around 50 μm), but adult worms like
the one shown here can reach 4–10 m, taking up
person drinks water containing residence in the digestive system.
water fleas infected by guinea- (b) An adult guinea worm, Dracunculus medinensis, is
removed through a lesion in the patient’s skin by
worm larvae. winding it around a matchstick. (credit a, b:
modification of work by Centers for Disease
Control and Prevention)
ACELLULAR MICROORGANISMS: VIRUSES
Viruses are acellular microorganisms,
which means they are not composed
of cells.
Essentially, a virus consists of
proteins and genetic material—
either DNA or RNA, but never both—
that are inert outside of a host
organism. However, by incorporating
themselves into a host cell, viruses
are able to co-opt the host’s cellular
mechanisms to multiply and infect (a) Members of the Coronavirus family can cause
other hosts. respiratory infections like the common cold, severe
acute respiratory syndrome (SARS), and Middle East
Viruses can infect all types of cells, respiratory syndrome (MERS). Here they are viewed
from human cells to the cells of other under a transmission electron microscope (TEM).
microorganisms. (b) Ebolavirus, a member of the Filovirus family, as
In humans, viruses are responsible visualized using a TEM. (credit a: modification of work
by Centers for Disease Control and Prevention; credit
for numerous diseases, from the b: modification of work by Thomas W. Geisbert)
common cold to deadly Ebola.
However, many viruses do not cause
disease.
INSTRUMENTS OF MICROBIOLOGY

In this section, we will survey the broad range of modern
microscopic technology and common applications for each type
of microscope:
Light Microscopes: use lenses to focus light on a specimen
to produce an image. Commonly
Electron Microscopes: focus electrons on the specimen
using magnets, producing much greater magnification than
light microscopy.
LIGHT MICROSCOPES
The brightfield microscope,
perhaps the most commonly
used type of microscope, is a
compound microscope with
two or more lenses that
produce a dark image on a
bright background. Components of a typical brightfield microscope.

Total magnification = ocular x objective
if a 40⨯ objective lens is selected and the ocular lens is
10⨯, the total magnification would be (40×)(10×)=400×

At very high magnifications, resolution may be compromised.
To solve this problem, a drop of oil can be used to fill the space
between the specimen and an oil immersion lens, a special lens
designed to be used with immersion oils.
DARKFIELD MICROSCOPE

Use of a darkfield microscope allows us to view living, unstained samples of the spirochete Treponema
pallidum. Similar to a photographic negative, the spirochetes appear bright against a dark background.
(credit: Centers for Disease Control and Prevention)
PHASE-CONTRAST MICROSCOPE

This figure compares a brightfield image (left) with a phase-contrast image (right) of the same unstained
simple squamous epithelial cells. The cells are in the center and bottom right of each photograph (the
irregular item above the cells is acellular debris). Notice that the unstained cells in the brightfield image are
almost invisible against the background, whereas the cells in the phase-contrast image appear to glow
against the background, revealing far more detail.
DIFFERENTIAL INTERFERENCE CONTRAST MICROSCOPE

A DIC image of Fonsecaea pedrosoi grown on modified Leonian’s agar. This fungus causes chromoblastomycosis, a
chronic skin infection common in tropical and subtropical climates.
FLUORESCENCE MICROSCOPES

(a)A direct immunofluorescent stain is used to visualize Neisseria gonorrhoeae, the bacterium that causes gonorrhea.
(b)An indirect immunofluorescent stain is used to visualize larvae of Schistosoma mansoni, a parasitic worm that
causes schistosomiasis, an intestinal disease common in the tropics. In direct immunofluorescence, the stain is
absorbed by a primary antibody, which binds to the antigen.
(c)In indirect immunofluorescence, the stain is absorbed by a secondary antibody, which binds to a primary antibody,
which, in turn, binds to the antigen. (credit a: modification of work by Centers for Disease Control and Prevention;
credit b: modification of work by Centers for Disease Control and Prevention)
CONFOCAL MICROSCOPE

Confocal microscopy can be used to visualize structures such as this roof-dwelling cyanobacterium biofilm.
(credit: modification of work by American Society for Microbiology)
 FIGURE 2.28

(credit “Brightfield”: modification of
work by American Society for
Microbiology; credit “Darkfield”:
modification of work by American
Society for Microbiology; credit
“Phase contrast”: modification of
work by American Society for
Microbiology; credit “DIC”:
modification of work by American
Society for Microbiology; credit
“Fluorescence”: modification of work
by American Society for Microbiology;
credit “Confocal”: modification of
work by American Society for
Microbiology; credit “Two-photon”:
modification of work by Alberto
Diaspro, Paolo Bianchini, Giuseppe
Vicidomini, Mario Faretta, Paola
Ramoino, Cesare Usai)
ELECTRON MICROSCOPES

The magnifying power of an electron microscope (EM) is very high,
as it uses short-wavelength electron beams rather than light to
increase magnification and resolution.
Electrons, like electromagnetic radiation, can behave as waves,
they can produce much better resolution than visible light. An EM
can produce a sharp image that is magnified up to 100,000⨯.
Thus, EMs can resolve subcellular structures as well as some
molecular structures (e.g., single strands of DNA);
however, electron microscopy cannot be used on living material
because of the methods needed to prepare the specimens.
ELECTRON MICROSCOPES

(credit “TEM”: modification
of work by American Society
for Microbiology; credit
“SEM”: modification of work
by American Society for
Microbiology)
A TRANSMISSION ELECTRON MICROSCOPE (TEM).
FIGURE 2.24

(a) This TEM image of cells in a biofilm shows well-defined internal structures of the cells because of varying
levels of opacity in the specimen.
(b) This color-enhanced SEM image of the bacterium Staphylococcus aureus illustrates the ability of scanning
electron microscopy to render three-dimensional images of the surface structure of cells. (credit a:
modification of work by American Society for Microbiology; credit b: modification of work by Centers for
Disease Control and Prevention)
FIGURE 2.26

In this image, multiple species of bacteria grow in a biofilm on stainless steel (stained with DAPI for
epifluorescence miscroscopy). (credit: Ricardo Murga, Rodney Donlan)
FIGURE 2.27

STMs and AFMs allow us to view images at the atomic level.
(a) This STM image of a pure gold surface shows individual atoms of gold arranged in columns.
(b) This AFM image shows long, strand-like molecules of nanocellulose, a laboratory-created substance
derived from plant fibers. (credit a: modification of work by “Erwinrossen”/Wikimedia Commons)
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