BIOL 240 Topic 1 PDF

Summary

This document is a lecture or study guide on the topic of microbiology, covering microbial classification and historical background. The document references early microbiologists like Hooke and van Leeuwenhoek, discusses microbial metabolism, and explores biogeochemical cycles.

Full Transcript

Topic 1
The Microbial World
 What is microbiology?
the study of microbes
examines how microbes interact with
humans, with food, and how they can
be used by humans
Disciplinary basis for molecular
biology and biotechnology
Definitions (microbe, microorganism)
 Classifying Microbes

Prokaryotic cell Eukaryotic cell
↳ unicellular
,
no nucleus Le multi-cellular wy nucleus

Figure 1.7
Microorganisms versus
macroorganisms

↳ unicellular , ↳ multicellisher
no

nucleus
w/ nucleus
 Historical Roots of Microbiology
first to see microrganism
- ↳ Fung,

Robert Hooke (1635-1703)
– early microscopes allowed first
description of microbes: fruiting
structures of “molds” (i.e., fungi)

compound sacope

L
Historical Roots of Microbiology
first to see bacteria
-
1/

"Father of Microbiology

Antonie van Leeuwenhoek (1632-1723)
– improvements in lens construction
allowed first description of bacteria
as
gos
sample
Two plates of
metal that holds
glass ball(lens)
 I then most always saw, with great wonder, that in the said matter
there were many very little living animalcules, very prettily a-moving.
&

-antonie van Leeuwenhoek
#
 Why study microbiology?
Microorganisms were the first
life on Earth
Microorganisms established
biosphere conditions that
allowed multicellular organisms
to evolve – O2!
Multicellular organisms evolved
from microorganisms
>50% of the biomass on Earth
is comprised of microorganisms
Microorganisms will be on Earth
forever
Why study microbiology?
Our understanding of
life (e.g., evolution,
metabolism,
biochemistry, and
↑

genetics) has arisen
largely from studies
of microorganisms

We still know very
little about the
microorganisms that
are present on Earth
Figure 1.10
 Why study microbiology?

fast, cheap, and easy to grow
produce enzymes and other
molecules for
industrial/medical uses
most have small numbers of
genes, making them simpler to
study
genetic manipulation of single-
celled bacteria is usually much
easier than multicellular
eukarya

Figure 1.10
For example,
studying the
genetics of
microbes can help
us use them to
benefit humans

mass-production of
molecules

Figure 1.25
Biogeochemistry
BiotechnologyThanks

Handelsman J. 2007. Encyclopedia of Life Sciences
Environment
Health
Agriculture
Food

Jo Handelsman
 The Basis for Life
metabolism
growth
reproduction
And at least on Earth, these are
achieved by…
genetic variation/evolution
response/adaptation
homeostasis* keep the same
Dont die

*maintaining internal organization and order,
usually by expending energy to do so
How do microbes get energy?
heterotroph: ingests preformed organic
molecules
autotroph: produces organic molecules
↳ self-sufficent ,
base of food chain

Figure 1.17
How do microbes get energy?
One example:
Organic molecules
are broken down by
microbes to harness
chemical energy
(ATP)
fermentation
aerobic respiration

Figure 1.18
Microbes can also help in biogeochemical
cycling as they interact with the environment
– cycling inorganic molecules to organic molecules and back
microbes live in diverse groups in nature
many different members (populations) form
a microbial community and ecosystem
 &

Macromolecules

of polypeptides !
↳
production
structurealytic functions

↳
glycogen starch-energy
↳ cellulose + chitin =
structural
 The Phylogenetic Tree
divided into three domains
based on ribosomal RNA sequences

Archaea
Bacteria
Eukarya

Figure 1.8
 Carl Woese, 1928-2012

Thanks to [Carl] Woese, the tree of life gained a third great trunk, more solid branches, and new
twigs. Woese died in 2012, and Nobels cannot be awarded posthumously, but it's absurd that
someone who unveiled the full extent of life should be denied by something as trivial as death”
Homework (pgs 9-10 in 3rd ed)
Question #1 an exam question
 clicker for
know this stuff on
monday

each of the three domains have important
commonalities and defining characteristics
 Viruses
Technically, viruses aren’t
considered “alive”

don’t replicate outside of
a host cell
little to no biochemical
activity outside of a host
cell
inert and nonreactive
outside of a host cell

Figure 1.9 C
 The Phylogenetic Tree

divided into three domains
based on ribosomal RNA sequences

Archaea
Bacteria
Eukarya

Figure 1.8
 Figure 1.12

Origin of Life
Early Earth conditions were
harsh

little oxygen in the
atmosphere
high temperatures
high CO2
g
planet surface was a
chemical soup, with a reducinoure !

reducing atmosphere
initial synthesis of first
macromolecules
 First life molecules
In the 1950s, a grad student named Stanley Miller
worked with his mentor, Harold Urey, to simulate
the “spark” that might have started forming
organic molecules from the primordial soup

Figure B1.3
Requirements of early life
genetic information storage
the ability to catalyze biochemical
reactions
a way of separating the cell interior
from the external environment
 Ribozymes cates

=>
en

RNA behaving like
enzymes
reaction catalyst
genetic information
storage
self-replicating

Figure B5.4
 Micelles
Micelles :

may have been an early form of
plasma membrane

Figure 1.14
 RNA world -

Carl Woese
-

4 &

Prior to the
last universal
>
=

separate
common Zinferior

O
~ from
ancestor exterior

(LUCA)
Conceived by
Carl Woese
=>

-

=>
=> -

O =>

=>
=>

=>
Figure 1.15 transcription
Franslation
 Double-Stranded DNA

provides a “backup copy”
of the genetic information
more stable than RNA

Figure 1.19
- - - -

- -
- -
- -

- - -
- -
-
- -

- -

- -

>
-

Last Universal
Common
Ancestor
 https://en.wikipedia.org/wiki/Hydrothermal_vent
Features
Membrane bound cell -
membrane

ATP as chemical energy
DNA to RNA to protein
-

Eats CO2
Fixes N2 Converts N2 to useful
>
-

form such as ammonia

Anaerobefree environment NHy
↓

↳ Of
Thermophile
 Figure 1.12

Origin of Life
How to circumvent the
scarcity of readily oxidized
electron donors away from
hydrothermal vents?

Ancestors of the
cyanobacteria are first to
solve the problem and
produce O2 as a toxic
byproduct
event
↳
great oxygenation
multicellular fossils dating to about 0.5 billion ybp
have been found—meaning microbes dominated the
planet for approximately 3.5 billion years!
microbial fossil records exist, largely in fossilized
“stromatolites” (carbonate pedestals with
photosynthetic microbial mat on top) STORMATOLITES

photosyntmtas

Figure 1.13
carbonateoestals
Modern stromatolites
Steep Rock Lake Belt,
NW Ontario

2.7-billion-year-old
“The ones in the Ottawa
river are Ordivician…
they’re around 250-260
million years old.”

“But they’re actually just
an example of the most
primitive life form that Stormatolite
started way back around 8 -
billion years ago…”
photosynthetic
carbonate microbial mats
“They're still growing pedestals
today. So [a] first life
form [and] they're still
with us and they'll Allan Donaldson, a retired professor
probably be here after we in the earth sciences department at
destroy ourselves” Carleton University.
 Modern RNA

Figure 1.20

DNA is transcribed into messenger RNA (mRNA)

mRNA is translated into proteins
>
-
transfer RNA
CARNA)
other forms of RNA (transfer RNA - tRNA,
ribosomal RNA - rRNA) show RNA versatility for
critical life processes
Knowing the way basic systems work allows us to
examine microbial genomes from two different
perspectives:
1. Examining effects of single mutations in DNA
individually (microbial genetics)

Figure 1.22
2. Studying and comparing pieces of genomes to each
other across domains (phylogeny)

Figure 1.23
 Origin of Eukaryotes
Endosymbiotic theory:
Primitive prokaryotic microbes ingested other
microbes, starting a symbiotic relationship,
forming the first basic eukaryotes.

Figure 1.16
 Microbes and Disease

microbes weren’t always
associated with disease
historically, disease
believed to be caused by wordinfo

“bad air” or “angry gods”
when microbes were
discovered, it was thought
they could spontaneously
form from nonliving matter
Wikipedia
 Microbes and Disease
can discriminate between isomers
organisms
-fermentation
-

is catalyzed by microorganisms

Louis Pasteur (1822-1895)
discovered that living organisms
discriminate between optical
isomers
explained biological nature of
alcoholic fermentation catalyzed by microorganisms
>
-

developed vaccines for anthrax,
fowl cholera, and rabies
developed pasteurization
↳ increasing shelf life for a product

introduced sanitization in
hospitals
disproved spontaneous
for anthrax cholera
generation and developed
↳ vaccine +

↳ vaccine for rabies
methods for controlling growth
 Louis Pasteur
late 1800s
↳
disproved in

disproved spontaneous generation theory
in the late 1800s
e

tile there

~ swan
stay
~

Figure 1.26
 Robert Koch
(1843-1910)

determined Bacillus
anthracis was the
cause of anthrax and
Mycobacterium was
the cause of
tuberculosis

Figure 1.27B
 Robert Koch
(1843-1910)
established basic rules for
determining which
microbes caused which
diseases
– Koch’s postulates

Figure 1.27A
Koch’s postulates can be
used to show a specific
microbe causes a specific Identify
potential
disease pathogen

The cause and effect are proven if:
the suspected microbe is
identified in every person with
the disease, but not those Isolate the

without the illness pathogen
↳ give it

a pure culture of the suspected
to healthy
individual

microbe is obtained
experimental inoculation of the
suspected microbe into a healthy causing diseased
individua l Leven
test host causes the same illness though was
healthy before
the suspected microbe is
recovered from the
experimentally inoculated host
organism
Kochdied from stomach issues
- -
Koch’s postulates in action: gastric ulcers
ulcers are sores on the lining of the stomach, thought
to be caused by excess acid
in the 1980s, researchers isolated the microbe
Helicobacter pylori from ulcerated tissue
by applying classic Koch’s postulate rules, this microbe
was found to be the causative agent of stomach ulcers
Some microbial diseases have had a profound
impact on humanity, such as bubonic plague

Black Death
Figure 1.28
Figure 1.29
Diseases have long ravaged human populations
Bubonic plague (“Black Death”) in the 1300s
Exploration of the Americas in the 1500‒1600s bringing
-

European diseases to indigenous humans
Spanish flu in the early 1900s (H1N1)

Figure 18.1
In the twentieth century, we have seen a
dramatic drop in deaths from infectious
diseases.

Figure 1.30
 Causes of Death:
North America, 1900
 Causes of Death:
North America, 2000
 Prevention of Infection
use of antiseptics
sanitation improvements
food/water safety
personal hygiene
improvements
vaccination
antibiotics
 Despite advances in vaccinations, antibiotics,
sanitation, and medical care, infectious diseases still
take a heavy toll on human life.
Figure 18.2