BIOL3236 General Zoology Exam 1 Review Slides PDF

Summary

This document is the review lecture for Exam 1 of BIOL3236 General Zoology, Spring 2025. The topics covered include the theory of evolution, including Darwin's concepts and Lamarckism, as well as different modes of reproduction.

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BIOL3236 General Zoology
Spring 2025
Exam 1 Review Lecture

Exam date: Feb. 5th, 8:30-9:45, WWH, room 135
Exam is in-person, on paper
Darwinian
Evolutionary Theory

Before Darwin’s theory, the first
scientific explanation for evolution
was from Jean Baptiste de Lamarck
(1809).
Known as Lamarckism,
this theory described
evolution as the
inheritance of acquired
characteristics.
Darwinian
Evolutionary Theory –
The Evidence

Darwin supported his theory with
key pieces of evidence. These
include:
Perpetual Change
The world is an ever-
changing place with
hereditary continuity from
past to present life.
This perpetual change can
be easily seen in the fossil
record, which reveals
dramatic changes in the
Earth’s environment.
Darwinian
Evolutionary Theory –
The Evidence (cont)
Evolutionary trends
Directional changes in
features or patterns of
diversity
Fossil trends demonstrates
Darwin’s principle of
perpetual change, showing
species arising and going
extinct repeatedly.
Darwinian Evolutionary
Theory – The Evidence
(cont)
Common descent
Life’s history is depicted as a branching tree:
phylogeny.
This means that all plants and animals have
descended from an ancestral form.
Last universal common ancestor (LUCA) of
living forms: over 4 billion years ago
Unicellular form resembling living
bacteria
Darwinian Evolutionary Theory – The
Evidence (cont)

Homology and Phylogenetic
Reconstruction
Evidence for common descent.
Characteristics inherited with
some modifications from a
corresponding feature in a
common ancestor.
Speciation
But how does an
ancestral species
branch, or split, to form
two or more descendant
species?
Answer: Speciation
Due to lack of gene flow
between populations
(reproductive barriers).
Allopatric Speciation
Geographically isolated populations: can not interbreed but
would.
Separated populations evolve independently and adapt to their
environment:
Reproductive barriers
Allopatric speciation can occur via two types of geographical
isolation:
Dispersal & colonization.
Vicariance
Dispersal and
Colonization

Process where individuals
disperse from their previous
population to colonize a new
habitat.
This leads to genetic
isolation that results in
divergence between the two
populations.
Vicariance

Process where some chance event
physically separates a population into
subgroups.
Sympatric
speciation
Speciation that occurs among
populations within the same
geographical area.
Individuals within a species
become specialized for occupying
different components of the
environment.
Sympatric speciation
Forces of Evolutionary Change
The driving force behind evolutionary change is a change in the
frequency of an allele in the gene pool of a population.
This change in allele frequency can occur by any combination of
these four processes:
1. Mutation: continually introducing new alleles.
2. Genetic Drift: random change of allele frequencies.
3. Gene flow (migration): individuals leave one population and join
another, bringing their alleles with them.
4. Natural Selection: increases frequency of alleles that contribute to
reproductive success
Mutation
Creates new alleles, not only new combinations of alleles.

Point mutation Lateral gene transfer
Genetic Drift
Change in allele frequencies in population due
to chance.
Causes allele frequencies to drift up and
down randomly over time.
Drift occurs in every population, in every
generation.
Especially prevalent in small
populations.
Gene flow

Movement of alleles between
populations.
Occurs when individuals
leave one population, join
another, and breed.
Gene flow equalizes allele
frequencies between source
and recipient populations.
Natural Selection

Can change both allelic frequencies
and genotypic frequencies in a
population.
Heritable variation leads to differential
survival and reproduction:
Increases frequency of alleles
that contribute to reproductive
success in a particular
environment.
Reproduction

Two types:
Asexual reproduction
Creation of new
genetically identical
individuals.
Sexual Reproduction
Promotes diversity,
enhancing long-term
survival of the lineage in
a world of perpetual
change.
Sexual Reproduction

Production of individuals from the
fusion of gametes.
Bisexual (or biparental)
reproduction: most common form
– involves two separate individuals.
Union of gametes from genetically
different parents.
Offspring will have a new genotype.
Asexual Reproduction

Production of new individuals without fusion of
gametes.
Offspring all have the same genotype – clones.
Can occur via a few different mechanisms, including:
Binary fission: division by mitosis used by
bacteria and unicellular organisms.
Budding: new individual arises as an outgrowth
(bud) from its parent.
Gametogenesis

The production of mature
gametes.
Spermatogenesis and
oogenesis.
 Spermatogenesis

Occurs in testes.
Takes place in differentiated germ cells within the
seminiferous tubules (ST).
Germ cells develop and produce male gametes with Sertoli
(sustentacular) cells
Outermost germ cells: spermatogonia (2n, increase in number by
mitosis)
Primary spermatocytes (PS)
PS move closer to the ST lumen – first meiotic division, secondary
spermatocytes (SS)
Each SS enters second meiotic division, produces two spermatids
Spermatid transforms into mature spermatozoa
Reduction of cytoplasm; condensation of nucleus,
formation of mitochondria, flagellar tail.
Oogenesis

Oogonia (germ cells in ovary) increase in number by mitosis (2n)
Grow in size: primary oocytes
First meiotic division (13 weeks of fetal development):
Arrests in prophase I until puberty
First maturation (reduction) division occurs
Secondary oocyte: large with most of the cytoplasm
Other cell: first polar body (very small)
Second meiotic division:
Oocyte divides into a large ovum
Another in small polar body
Each primary oocyte gives rise to only one functional gamete
Meiosis II is completed only when the secondary oocyte is penetrated by a
spermatozoon
Reproductive patterns

Oviparous
Egg-birth. Lay eggs outside their body
for development. Internal or external
fertilization.
Ovoviviparous
Egg-live-birth. Fertilized eggs remain
in the oviduct or uterus while they
develop. Embryos derive their
nourishment from yolk stored within
the egg.
Viviparous
Live-birth. Fertilized eggs develop in
the oviduct or uterus with embryos
deriving their nourishment directly from
the mother.
Developmental Studies

Preformation vs. Epigenesis
Preformation
Young animals were pre-formed in eggs
or sperm, would develop what was
already there. (17th and 18th century
naturalist philosophers)
Epigenesis
“ Origin upon or after”. A fertilized egg
contains building material only.
Developmental
Studies (cont)

Development:
Describes the progressive changes
in an individual from its beginning
to maturity.
Hierarchy of developmental stages:
Cell types arise from conditions
created in the preceding stages.
Early Development

Cleavage:
Embryo divides repeatedly.
One large cell becomes many smaller cells: blastomeres.
Blastula:
End of cleavage. Zygote divided into hundreds or
thousands of cells.
One layer of cells around a central fluid-filled cavity
Gastrulation:
Converts the spherical blastula into a two- or three-
layered embryo (germ layers).
Body parts develop from one or more germ layers.
 Formation of
mesoderm – a third
germ layer
Diploblastic
Two germ layers (ectoderm
and endoderm).
Triploblastic
Three germ layers
Mesoderm: between ectoderm
and endoderm.
Initial cells of mesoderm come
from endoderm.
Further
development
Development of Coelom:
A body cavity surrounded by
mesoderm.
Blastopore
First embryonic opening
Origin of what will become the
adult mouth:
Protostomes
Blastopore becomes
the mouth.
Deuterostomes
Blastopore becomes the
anus; second embryonic
opening becomes the
mouth.
Amniotes and the
amniotic egg
Amniotes (reptiles, birds, and
mammals)
Embryos develop within a
membranous sac: the
amnion.
Amnion
A fluid-filled sac that
encloses the embryo and
provides an aqueous
environment in which the
embryo floats, protected
from mechanical shock
and adhesions.
Development of
systems and organs
Gastrulation
Three germ layers are
formed.
Differentiation into primordial
cell masses
Differentiation into specific
organs and tissues:
Cells are committed to
specific directions of
differentiation.
 Hierarchical organization of animal complexity

Protoplasmic – unicellular organisms. Within a cell, protoplasm is differentiated into organelles capable of performing
specialized functions.

Cellular – aggregation of cells that are functionally differentiated. A division of labor is evident.

Cell-tissue – aggregation of similar cells into definite patterns or layers and organized to perform a common function,
to form tissues.

Tissue-organ – aggregation of tissues that form organs in a further step in complexity. Organs are usually composed
of more than one kind of tissue and have a more specialized function than tissues.

Organ-system – organs working together to perform some function, producing the highest level of organization.
Systems are associated with basic functions such as circulation, respiration, and digestion.
Animal Body Plans
Differ in grade of organization; body symmetry;
n of embryonic germ layers; number of body
cavities.
Animal Symmetry

Refers to balanced proportions, or correspondence in size and
shape of parts on opposite sides of a median plan.
Spherical symmetry:
Occurs in unicellular forms, rare in animals. Best suited for
floating and rolling.
Radial symmetry:
Can be divided into similar halves by more than two planes
(oral and aboral surfaces). Occurs usually in sessile, freely
floating, or weakly swimming animals. Interact with their
environment in all directions.
Bilateral symmetry:
Animals that can be divided along a sagittal plane into two
mirrored portions. Better fit for unidirectional movement.
Cellular
components:
Tissues
Tissue:
A group of similar cells
specialized for
performance of a
common function.
Histology:
study of tissues.
During embryonic
development, germ layers
become differentiated into
four kinds of tissues:
Epithelial, connective,
muscular, and nervous.
Complexity and Body Size

Complex grade of animal organization permit and promote evolution of
large body size.
As animals become larger, body volume increases more rapidly than
body surface area.
Small animals:
Absence of complex specialized tissue - rely on diffusion
Body geometry that maximizes surface area and keep diffusion
distances short (folding, invagination, flattening the body).
Larger, more complex animals:
Bring the environment functionally closer to each cell
Use of internal transport and exchange systems with large
surface areas
Chapter 10
Study guide at the end of Chapter 10 lecture.