Week 1 Biology 1110 PDF

Summary

These lecture notes cover introductory biology topics such as biosphere and taxonomy, evolution, viruses, and cell structure. The details include prokaryotic versus eukaryotic cells, and the general characteristics of living thing.

Full Transcript

Biosphere and Taxonomy
Evolution
Viruses

Lab: Dichotomous key
 Biosphere and Taxonomy
OBJECTIVES:

1. Describe some of the properties and processes
associated with living organisms and explain
why defining life is problematic
2. Define biosphere and describe the levels of
organisation within the biosphere.
3. Discuss the differences between prokaryotic and
eukaryotic cells. Identify the major components
of eukaryotic cells in a diagram and explain their
function.
4. Name the major taxonomical categories used in
classification and describe the binomial system
of nomenclature
5. Describe the 3- domain system of classification
6. Interpret the evolutionary relationships
represented in phylogenetic trees.
1. Describe some of the properties and processes
associated with living organisms and explain why
defining life is problematic

 Biology is the study of living things, or organisms.

 We are all familiar with and are able to recognise living
things, yet defining life and distinguishing living from
non-living is not a clear-cut matter.

 Can you describe some characteristics of living things?
Characteristics of living things
 Complex and highly organised
 Respond to fluctuations in the environment
 Use energy
 Reproduce
 Populations of living things evolve
 Growth and development
2. Define biosphere and describe the levels of
organisation within the biosphere

 The biosphere is all areas of the earth that contain life
 Ecosystems contain all living and non living
components of the environment in a particular with
which life interacts (e.g rain forests)
 A community refers to the different species that live in a
particular ecosystem.
 A population are all members of a single species that
occupy a given area.
 Organisms are the individuals of a population
 Organisms can be made up of organs systems which
have specialized functions.
Levels of Organisation
 These organ systems, are again, made up of structures
with specialized functions called organs
 Organs are made up of different types of tissues
 Tissues are composed of cells, which are the
fundamental units of life as they have all the
characteristics of life.
 Organelles are structures within cells that have
specialized functions
 Molecules are made up of atoms and when they join
together they can form larger structures.
Levels of Organisation
3. Discuss the differences between prokaryotic and eukaryotic
cells. Identify the major components of eukaryotic cells in a
diagram and their function.

Schleiden and Schwann’s Cell Theory

All organisms are made up of cells.

The cell is the simplest collection
of matter that can live.
 Prokaryotes vs Eukaryotes
No membrane around nuclei Membrane bound nuclei

No membrane bound organelles Has membrane bound organelles (e.g.
mitochondria, chloroplasts)

Cells are small Cells are large

Peptidoglycans in the cell wall (Bacteria) No peptidoglycans in cell wall

Circular chromosomes Linear chromosomes

No histones associated with the DNA Histones associated with the DNA
Prokaryotic Cell
E. coli
Overview of an animal cell
 ANIMAL CELLS
Organelles are specific subcellular structures
which perform specialised functions for the cell
 The plasma (cell) membrane controls what goes into
and out of the cell and separates the internal cell
environment from that outside environment
 Lysosomes contain enzymes and are responsible for the
digestion of organic particles in the cell
 Mitochondria produce adenosine triphosphate (ATP) by
cellular respiration (animal cells). ATP is an energy rich
molecule that drives metabolism in cells.
 Ribosomes are involved in the production of proteins.
They are non membranous organelles.
The endomembrane system consists of
endoplasmic reticulum and the Golgi apparatus.
 Endoplasmic reticulum
 Rough endoplasmic reticulum (RER) is associated
with the transport of proteins from attached
ribosomes. It provides protein containing vesicles to
the Golgi.
 Smooth endoplasmic reticulum (SER) has a function
in detoxification and can produce a number of
steroids in humans
 Golgi processes and packages material for export or
use within the cell. Various types of vesicles are
produced with different destinations.
The following are components of the cell nucleus
 The nuclear envelope encloses the genetic
material of the cells and controls what enters or
leaves the nucleus. It is comprised of a double
membrane with pores.
 The nucleolus is are specialised regions of some
chromosomes with multiple copies of genes for
the synthesis of ribosomes and other types
ribonucleic acids (RNA). It is considered to be
a non membrane bound organelle
 Chromatin is the name given to chromosomes
that have associated proteins bound to them
such as histones and histidine. It is generally
seen as long threads during interphase.
Overview of a plant cell
Plants have all the organelles just discussed but have a
few extra things
 They have a rigid cell wall used to protect the plant cell
 Many have a central vacuole that controls water content and
waste excretion in some plants
 Chloroplasts are present in plants and function to transduce
energy from sunlight to produce ATP
 Bacterial cell walls are composed of a carbohydrate polymer
called peptidoglycan while plant cell walls are composed of
cellulose
 Chloroplasts are similar to mitochondria in a number of
ways.
 Both have DNA in them
 Both have ribosomes
 Both have an inner and outer membrane system
 Both can produce ATP via chemiosmosis
 Prokaryotic or eukaryotic? Why?
Animal or plant cell? Why?
4. Name the major taxonomical categories used in
classification and describe the binomial system of
nomenclature

Binomial Nomenclature
 In the 18th century, Carolus Linnaeus published a
system of taxonomy based on resemblances
 Two key features of his system remain useful
today: two-part names for species and
hierarchical classification
 The two-part scientific name of a species is called
a binomial
 The first part of the name is the genus
 The second part, called the specific epithet, is
unique for each species within the genus
 The first letter of the genus is capitalised, and the
entire species name is italicized
 Both parts together name the species (not the
specific epithet alone)
Hierarchical Classification
 Linnaeus introduced a system for grouping species
in increasingly broad categories
 The taxonomic groups from broad to narrow are
domain, kingdom, phylum, class, order,
family, genus, and species
 Taxonomy is the ordered division and naming
of organisms
 A taxonomic unit at any level of hierarchy is called
a taxon
5. Describe the 3- domain system of classification

From Two Kingdoms to Three Domains
 Early taxonomists classified all species as either
plants or animals
 Later, five kingdoms were recognized: Monera
(prokaryotes), Protista, Plantae, Fungi, and
Animalia
 More recently, the three-domain system has
been adopted: Bacteria, Archaea, and Eukarya
 The three-domain system is supported by data
from many sequenced genomes
 The three domains of life
EUKARYA

Land plants Dinoflagellates
Green algae Forams
Ciliates Diatoms
Red algae

Amoebas
Cellular slime molds
Euglena
Trypanosomes
Animals
Leishmania
Fungi

Sulfolobus
Green nonsulfur bacteria
Thermophiles (Mitochondrion)

Spirochetes
Halophiles Chlamydia
COMMON
ANCESTOR Green
OF ALL sulfur bacteria
LIFE
Methanobacterium BACTERIA
Cyanobacteria
ARCHAEA (Plastids, including
chloroplasts)
A Comparison of the Three Domains of Life
6. Interpret the evolutionary relationships
represented in phylogenetic trees.

Systematists depict evolutionary relationships in
branching phylogenetic trees
Phylogenies show evolutionary relationships

 The discipline of systematics classifies organisms
and determines their evolutionary relationships
 Phylogeny is the evolutionary history of a species or
group of related species
 Systematists use fossil, molecular, and genetic data
to infer evolutionary relationships
 A clade is a grouping that includes a common
ancestor and all the descendants (living and
extinct) of that ancestor.
 Order Family Genus Species

Panthera
Felidae
Panthera
pardus

Taxidea
Carnivora

Taxidea

Mustelidae
taxus

Lutra
Lutra lutra

Canis
latrans
Canidae

Canis

Canis
lupus

The connection between classification and phylogeny
 A phylogenetic tree represents a hypothesis
about evolutionary relationships
 Each branch point represents the divergence of
two species
 Sister taxa are groups that share an immediate
common ancestor
 A rooted tree includes a branch to represent the
last common ancestor of all taxa in the tree
 A polytomy is a branch from which more than
two groups emerge
 Branch point
(node)
Taxon A

Taxon B
Sister
taxa
Taxon C
ANCESTRAL
LINEAGE Taxon D

Taxon E

Taxon F
Common ancestor of
taxa A–F Polytomy

How to read a phylogenetic tree
What We Can and Cannot Learn from
Phylogenetic Trees
 Phylogenetic trees do show patterns of
descent
 Phylogenetic trees do not indicate when
species evolved or how much genetic change
occurred in a lineage
 It shouldn’t be assumed that a taxon evolved
from the taxon next to it
 Phylogeny provides important information
about similar characteristics in closely related
species
 Evolution
OBJECTIVES:
1. Define evolution and distinguish between the
process of evolution and a mechanism of evolution
(eg. natural selection).

2. Describe at least three sources of scientific
evidence supporting evolution.
1. Define evolution and distinguish between the process
of evolution and a mechanism of evolution (eg. natural
selection).
Definition of evolution

Evolution is the observation that changes occur in the
genetic material of populations of organisms over time

Genetic variation is the raw material of evolution.

It can be defined as differences among individuals in the
composition of their DNA or other DNA segments
 Table 1. Some Sources of Genetic Variation
Source of variation Description

Existing variation Populations of all organisms have existing
genetic variation in many traits.

Meiosis/Fertilization In sexually-reproducing organisms, both the
rearrangement of the genetic material during
production of gametes (meiosis) and the genetic
contributions from male and female parents
(fertilization) contribute to the production of
new genetic combinations.
Mutations Changes occur in DNA and are passed to the
next generation creating new genetic variation in
populations. Mutations can occur spontaneously,
or be caused by radiation or chemicals.
 Some genetic vocabulary
 Heredity: the biological process whereby genetic factors are
transmitted from one generation to the next
 Character: An observable, heritable feature such as hair colour
or eye colour
 Trait: a variant of a character, such as purple or white flowers
 Gene: A hereditary unit consisting of a sequence of DNA that
occupies a specific location on a chromosome and determines a
particular characteristic in an organism
 Allele: One member of a pair or series of genes that occupy a
specific position on a specific chromosome.
 A population is a group of individuals living in the same
geographical area and sharing a common gene pool.
 The gene pool is the sum of all genetic information carried by
the members of a population.
 Principal Mechanisms of Evolution.
Mechanism Key Features

Gene flow Genetic changes may occur in populations as a
consequence of migration of individuals among
populations.
Natural Differential survival or reproduction occurs within a
Selection population such that certain genetic makeups are
“selected” or favoured under the influence of
environmental factors (eg. predators, competitors,
weather, food supply). The genetic makeup of the
population changes over time as organisms interact
with their environment.
Genetic Drift Genetic changes occur in populations due only to
chance or random factors (eg. bottleneck effects,
founder effects). Random factors may enhance or
eliminate certain genetic makeups.
Gene Flow

 Gene flow consists of the movement of alleles
among populations
 Alleles can be transferred through the movement
of fertile individuals or gametes (for example,
pollen)
 Gene flow tends to reduce differences between
populations over time
 Gene flow is more likely than mutation to alter
allele frequencies directly
Gene flow and human evolution
Gene flow can increase the fitness of a population
 Insecticides have been used to target mosquitoes
that carry West Nile virus and malaria
 Alleles have evolved in some populations that
confer insecticide resistance to these mosquitoes
 The flow of insecticide resistance alleles into a
population can cause an increase in fitness
Gene flow can decrease the fitness of a population
 In bent grass, alleles for copper tolerance are
beneficial in populations near copper mines, but
harmful to populations in other soils
 Windblown pollen moves these alleles between
populations
 The movement of unfavorable alleles into a
population results in a decrease in fit between
organism and environment
Fig. 23-12

70
NON- MINE NON-
MINE SOIL MINE
60 SOIL
SOIL
50 Prevailing wind direction

40

30

20

10

0
20 0 20 0 20 40 60 80 100 120 140 160
Distance from mine edge (meters)
 Genetic Drift
 The smaller a sample, the greater the chance of
deviation from a predicted result
 Genetic drift describes how allele frequencies
fluctuate unpredictably from one generation to
the next
 Genetic drift tends to reduce genetic variation
through losses of alleles
 The Founder Effect
 The founder effect occurs when a few
individuals become isolated from a larger
population
 Allele frequencies in the small founder
population can be different from those in the
larger parent population
 The Bottleneck Effect
 The bottleneck effect is a sudden reduction in
population size due to a change in the
environment
 The resulting gene pool may no longer be
reflective of the original population’s gene pool
 If the population remains small, it may be further
affected by genetic drift
Fig. 23-9

Original Bottlenecking Surviving
population event population
 Understanding the bottleneck effect can increase
understanding of how human activity affects
other species
Bottleneck effect and reduction of genetic variation
Pre-bottleneck Post-bottleneck
(Illinois, 1820) (Illinois, 1993)

Range
of greater
prairie
chicken
(a)

Number Percentage
Location Population
of alleles of eggs
size
per locus hatched

Illinois
1930–1960s 1,000–25,000 5.2 93
1993