Biology Notes Chapter 1, 2.1-2.2 PDF

Summary

This document contains lecture notes on biology, specifically chapters 1, 2.1-2.2. It introduces different types of organisms, their characteristics, and different functions.

Full Transcript

Chapter 1

Introduction to Biology,
Anatomy, and Physiology
 1.2 Organization of
Living Things

All organisms can be categorized
based on certain characteristics into
one of three domains, then six
kingdoms

There is some debate about this
among scientists, so you may find
different answers, e.g. some include a
seventh kingdom.

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 1.2 Organization of
Living Things
The kingdoms are arranged based on organisms'
characteristics:
single-celled or multicellular
prokaryotic (no nucleus) or eukaryotic (with nucleus)
environment they live in
movement
how energy is acquired

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1.2 Organization of Living Things
Kingdoms

Domain Archaea

Domain Eukarya

Domain Bacteria

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 1.2 Prokaryotes and Eukaryotes
Prokaryotic organisms (pro:before)
Kingdoms: Archaea and Eubacteria
All unicellular (one cell per organism).
no membrane-bound organelles.
DNA is located in the cytoplasm. This Photo by Unknown Author is licensed under CC BY-SA

Sometimes called “primitive”

Eukaryotic organisms (eu: good or well)
Kingdoms: Protists, Fungi, Plants and Animals.
Membrane-bound organelles, DNA in nucleus,
more complex, also contain ribosomes.
SOME are unicellular.
This Photo by Unknown Author is licensed under CC BY-SA-
NC

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 Archaea
1.2 Organization of Living Things
Archaebacteria
Single-celled
Prokaryotic
Primitive
Live in extreme environments
→ very high temperatures
→ very low temperatures
→ highly saline environments
→ highly acidic environments

Look at definition of thermophiles,
halophiles, methanogens

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 Bacteria
1.2 Organization of Living Things
Eubacteria
Generally single-celled
(some may be multicellular)
Prokaryotic
Found almost everywhere on
Earth
Most are harmless or helpful
Some can cause human
diseases. Examples: tetanus,
syphilis, pneumonia,
tuberculosis

In the Human Gastro-Intestinal Tract: ~500 species and trillions of bacterial cells

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 Archaebacteria vs. Eubacteria
The difference between Archaebacteria and Eubacteria lies mainly in
their ancestral cell lineage. (i.e. they have an independent
evolutionary history)

Other key differences include:
the types of environments that they live in
biochemical variations in cell components

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 Eukarya
1.2 Organization of Living Things
Protists
Single-celled
Eukaryotic
Various species have characteristics
similar to:
→ Fungi (spores)
→ Plants (chloroplastsphotosynthetic)
→ Animals (locomotion)
May be photosynthetic
May have structures such as flagella
or cilia.
Protists associated with human disease: Plasmodium causes malaria;
Giardia causes severe diarrhea (beaver fever) 9
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 Eukarya
1.2 Organization of Living Things
Fungi
Multicellular (except for yeast)
Eukaryotic
Non-photosynthetic
Some are beneficial and some are
poisonous to humans.
Examples include mushrooms, mold,
and mildew.

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 Eukarya
1.2 Organization of Living Things

Plants
Multicellular
Eukaryotic
Photosynthetic
May live on land or in water

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 Eukarya
1.2 Organization of Living Things
Animals
Multicellular
Eukaryotic
Non-photosynthetic
Can live on land or in water
Have locomotion

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KAHOOT!
 Review:
Review the divisions of different organisms into
the 3 Domains and 6 Kingdoms.
What characteristics would you expect each of
the following to have?
→ Plants Eukaryotic, multicellular, photosynthetic
Eukaryotic, multicellular (except
→ Fungi yeast), non-photosynthetic
→ Archaea Prokaryotic, single-celled, harsh environments
→ Animals Eukaryotic,
locomotion
multicellular, non-photosynthetic,

→ Protists Eukaryotic, single-celled, maybe photosynthetic
→ Eubacteria Prokaryotic, single-celled, some are
photosynthetic

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 1.6 Properties of Living
Things: Macromolecules
All living things include the elements:
carbon, oxygen, hydrogen, and nitrogen (C
O H N).
These elements form molecules such as
sugars, amino acids, fatty acids, and
nucleotides.
Small molecules combine into various
macromolecules: polysaccharides
(complex carbohydrates), proteins, fats, and
nucleic acids.

Note: there are many other elements that go
into making different components of
macromolecules. 15 15
1.6 Properties of
Living Things:
Cellular Structure
All living things are composed of
one or more cells.
All cells have a membrane that
separates the inside of the cell
from the outside of the cell.
Some organisms are single
celled, such as bacteria, yeast,
or some algae.
Some organisms are
multicellular, such as zebra
muscles, trees, and cobra
chickens (Canada geese).
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 Examples of cell types / cell structure

Airways in lung made up of epithelial Mucous-producing goblet cells in
cells (with bacteria in airways) gastro-intestinal tract.

This Photo by Unknown Author This Photo by Unknown Author
is licensed under CC BY-SA is licensed under CC BY

Striated muscle cells Red blood cells are one of the
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simplest cell types
 1.6 Properties of Living Things:
Growth and Metabolism

All living things use energy for metabolism, growth, movement, etc.

Most energy on our planet comes from the sun.

The sun’s energy is captured by photosynthetic organisms, that are consumed
by other organisms (herbivores, omnivores). Carnivores eat other animals for
energy.

Metabolism is the transfer of energy from one form to another: for example, our
muscles converting glucose into ATP for movement, growth, etc.
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 1.6 Properties of Living Things:
Reproduction

All organisms reproduce.
Reproduction can be just cellular, e.g. body cells reproducing.
Some organisms reproduce every 20 minutes (bacteria), some reproduce
every 6 weeks (mice), and some reproduce only a few times in their
lifetimes (humans).
Different ways to reproduce: binary fission (copies of DNA) and sexual
reproduction (intermixing of DNA).
more details in Chapter 5 later.

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 1.6 Properties of Living Things:
Heredity Material

All living organisms have genetic material: DNA
(some viruses, e.g. SARS COV-2, use RNA, but
they’re not considered “living”)

The DNA in all organisms must divide before the
organism itself can divide. (Chapter 8, next
semester)

DNA contains genes that partially determine an
organism’s characteristics. But the environment
can also affect characteristics.
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1.6 Properties of Living Things:
Evolution

All populations of organisms continuously
change genetically from one generation to the
next. This depends on occasional mutations.

Humans have 46 chromosomes, but the versions
of genes on those chromosomes vary, such as the
genes that encode for skin pigmentation or body
height.

This Photo by Unknown Author is licensed under CC BY-SA

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 1.6 Properties of Living
Things: Homeostasis
Every organism must maintain a stable internal
environment.

e.g. humans must maintain consistent blood pH,
blood sugar levels, and body temperature,
regardless of the food we eat or the weather.

To maintain homeostasis, organisms use
positive and negative feedback mechanisms.

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 1.6 Homeostasis: Receptors

Homeostasis depends on receptors to detect changes in the internal
environment:

Chemoreceptors detect chemical concentrations, such as of
neurotransmitters, drugs, or hormones.
Osmoreceptors detect changes in osmolarity; i.e. water and ion
concentrations.
Tactile receptors detect touch, pressure, and vibration.
Baroreceptors detect blood pressure.
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 1.6 Homeostasis: Receptors

Photoreceptors detect light (the retina in humans).
Mechanoreceptors detect stretching (e.g., spindle fibres in muscles).
Proprioceptors detect body position.
Nociceptors detect pain.
Thermoreceptors detect temperature.

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 1.6 Properties of Living Things:
Homeostasis (Feedback Mechanisms)
Response
Causes less stimulus
(negative feedback) OR  or 
increased stimulus (positive
Start here: feedback)
This is the change in a Stimulus
variable that moves away
from equilibrium.
This is the cell type,
Effector(s) tissue, or organ, that is
able to produce a
These sense the change. response to the stimulus.
See list and role of Receptors
different receptor types
on preceding slides.

Integrating This is the region that
Centre interprets the stimulus and
initiates a command to the
effector.

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 1.6 Homeostasis: Negative Feedback

Most systems in our body work this way.

It helps to restore things back to the “set
point”

The response tends to diminish the
stimulus, so eventually the loop will stop
itself.

e.g. sweating cools your blood, so the
thermoreceptors in your hypothalamus
(part of brain) are less stimulated.

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 1.6 Homeostasis: Positive Feedback

Sometimes called a “feed-forward” system.

These usually only function short-term
because they are unsustainable: the response
feeds the stimulus again, which creates more
of a response

e.g) In the initial stages of inflammation, cells
produce proteins that bind receptors to trigger
more inflammatory protein production.

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 Chapter 2:
Water, Macromolecules and
Protein

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 2.1 Water

Often called “the universal solvent” because so
many molecules dissolve into it. More
substances dissolve into water than any other
solvent.

The substance something dissolves into is the
solvent.

The substance which dissolves into the solvent
is the solute.

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 2.1 Water
All living things contain water.
Infants: about 75% water, which
decreases with age (mostly in the first 10
years of life but continues into old age)
Healthy adult males: about 60% water
Healthy adult females: about 55% water
(and usually have more body fat than
men)
Obese people: can have as little as 45%
water
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 2.1 Water
The water in your body is divided into two
compartments:

1. Intracellular: inside your cells. This is
where most of your body’s water is found.

2. Extracellular: outside your cells
Interstitial fluid: between your cells
Blood plasma: non-cellular part, made
of proteins, ions and mostly water

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 2.1 Water is Polar
Oxygen pulls the hydrogen’s electrons
closer, so that end has a slight negative
charge. The H ends have a slight
positive charge.
Polar molecules have a slight charge on
opposite ends. e.g.) water, sugars,
amnio acids. They are neutral overall.

Polar molecules are hydrophilic (water-
loving).

Non-polar molecules are hydrophobic
(water-hating).
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 2.1 Water: Hydrogen Bonding

Since a single water molecule has
both positive and negative ends:
Many water molecules together will
attract each other’s oppositely-
charged ends and form hydrogen
bonds.
This causes surface tension.

Hydrogen bonds are very weak, but
biologically very important
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 2.1 Water: Dissolving Solutes
Non-polar molecules don’t dissolve in water
Charged or polar molecules dissolve in water (hydrophobic) e.g.) cholesterol, steroids, fats
(hydrophilic). (triglycerides), oils.
Ions are molecules with a full positive or negative Some molecules have a polar and a non-polar
charge because of an extra or missing electron e.g.) region (amphipathic). These types of molecules are
Na+, Cl-, Ca2+, (sulfate) SO42-, (phosphate) PO43- very important for cell membranes (Chapter 3).

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 Three Types of Bonds
Ionic Bonds between charged ions (e.g. Na+, Cl–)

Hydrogen Bonds – dipole-dipole interactions
between –OH, – NH, or –FH bonds and other
polar or charged molecules. Often depicted by
dotted line.

H
O
H C H
Covalent Bonds involve sharing of electrons (e.g.
H H
H2O, CH3) often depicted by a solid line.
H
KAHOOT!
 2.2 Macromolecules
All living things are based on carbon atoms and
make organic molecules.

The four primary atoms that make up all living
things:
Carbon, oxygen, hydrogen and nitrogen

COHN

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 2.2 Macromolecules
The building materials of the body are known as
macromolecules because they can be very large.
There are four types of macromolecules.
1. Proteins
2. Nucleic acids
3. Carbohydrates (not just sugar!)
4. Lipids/fats

You are probably familiar with foods that contain a lot
of each of these.

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 2.2 Macromolecules:
Polymers
Large macromolecules are assembled from many
similar small components called monomers
(building blocks).

Many similar monomers covalently bound together
form a polymer.

All biological polymers are assembled by
dehydration synthesis.

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 2.2 Macromolecules:
Dehydration Synthesis
A covalent bond is formed by removing a hydroxyl group
(OH) from one subunit and a hydrogen (H) from another
subunit.

This process of linking together two subunits to form a
polymer is called dehydration synthesis because this
amounts to the removal of a molecule of water (H2O).

Dehydration synthesis requires an enzyme to complete the
chemical reaction.

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 2.2 Macromolecules: Dehydration Synthesis

Note: the new dipeptide has a hydroxyl group at the end. What does this mean for continuing the polymer?

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 2.2 Macromolecules:
Hydrolysis
Breaking polymers into their monomers
(disassembling) is the reverse of
dehydration synthesis.

A molecule of water is added to break the
covalent bond between the monomers.

This process is known as hydrolysis
(water-breaking) and usually requires an
enzyme.
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2.2 Macromolecules: Hydrolysis

—OH

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 Make a Chart for Studying
Polymer Type of Monomer Special Features

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