Introduction To Biology Lecture 3 PDF

Summary

This document is a lecture on introduction to biology, covering eukaryotic cells and their origins. It discusses features of eukaryotic cells and their potential predatorial behaviour. The document also mentions other types of cells, including protozoans.

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INTRODUCTION TO
BIOLOGY
BIO-106
Lecture-3
 Eucaryotic Cells may have originated
as Predators
Eukaryotic cells are typically 10 times the length and 1000 times the volume of
prokaryotic cells, although there is huge size variation within each category.
They also possess a whole collection of features—a cytoskeleton, mitochondria, and
other organelles—that set them apart from bacteria and archaea.
When and how eukaryotes evolved these systems remains something of a mystery.
Although eukaryotes, bacteria, and archaea must have diverged from one another very
early in the history of life on Earth, the eukaryotes did not acquire all of their distinctive
features at the same time (Figure 3–1).
According to one theory, the ancestral eukaryotic cell was a predator that fed by
capturing other cells. Such a way of life requires a large size, a flexible membrane, and a
cytoskeleton to help the cell move and eat. The nuclear compartment may have evolved
to keep the DNA segregated from this physical and chemical hurly-burly, so as to allow
more delicate and complex control of the way the cell reads out its genetic information.
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Figure 3-1: Where did eukaryotes
come from? The eukaryotic,
bacterial, and archaean lineages
diverged from one another very
early in the evolution of life on
Earth. Some time later,
eukaryotes are thought to have
acquired mitochondria; later still,
a subset of eukaryotes acquired
chloroplasts. Mitochondria are
essentially the same in plants,
animals, and fungi, and therefore
were presumably acquired
before these lines diverged.

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 Eucaryotic Cells may have originated
as Predators
Such a primitive cell, with a nucleus and cytoskeleton, was most likely the sort of cell that
engulfed the free-living, oxygen-consuming bacteria that were the likely ancestors of the
mitochondria (Figure 3-2).
This partnership is thought to have been established 1.5 billion years ago, when the
Earth’s atmosphere first became rich in oxygen.
A subset of these cells later acquired chloroplasts by engulfing photosynthetic bacteria
(Figure 3-3). The likely history of these endosymbiotic events is illustrated in Figure 3-4.
That single-celled eukaryotes can prey upon and swallow other cells is borne out by the
behavior of many of the free-living, actively motile microorganisms called protozoans.
Didinium, for example, is a large, carnivorous protozoan with a diameter of about 150
μm—roughly 10 times that of the average human cell. It has a globular body encircled by
two fringes of cilia, and its front end is flattened except for a single protrusion rather like
a snout (Figure 3-5A).
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Figure 3-2: Mitochondria most likely evolved from engulfed bacteria. It is virtually certain that mitochondria originate
from bacteria that were engulfed by an ancestral pre-eukaryotic cell and survived inside it, living in symbiosis with
their host. Note that the double membrane of present-day mitochondria is thought to have been derived from the
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plasma membrane and outer membrane of the engulfed bacterium.
Figure 3-3: Chloroplasts almost certainly evolved from engulfed photosynthetic bacteria. The bacteria are
thought to have been taken up by early eukaryotic cells that already contained mitochondria. 5
Figure 3.5 : One
protozoan eats
another.
(A) The
scanning
electron
micrograph
shows Didinium
on its own, with
its
circumferential
rings of beating
cilia and its
“snout” at the
top.
(B) Didinium is
seen ingesting
another ciliated
protozoan, a
Paramecium.

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 Eucaryotic Cells may have originated
as Predators
Didinium swims at high speed by means of its beating cilia. When it encounters a suitable
prey, usually another type of protozoan, it releases numerous small, paralyzing darts
from its snout region.
Didinium then attaches to and devours the other cell, inverting like a hollow ball to engulf
its victim, which can be almost as large as itself (Figure 3-5B).
Not all protozoans are predators. They can be photosynthetic or carnivorous, motile or
sedentary. Their anatomy is often elaborate and includes such structures as sensory
bristles, photoreceptors, beating cilia, stalk-like appendages, mouthparts, stinging darts,
and muscle-like contractile bundles (Figure 3-6).
Although they are single cells, protozoans can be as intricate and versatile as many
multicellular organisms.
Much remains to be learned about fundamental cell biology from studies of these
fascinating life-forms.
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Figure 3-6: An assortment of
protozoans illustrates the
enormous variety within this
class of single-celled
microorganisms. These
drawings are done to
different scales, but in each
case the scale bar represents
10 μm. The organisms in (A),
(C), and (G) are ciliates; (B) is
a heliozoan; (D) is an
amoeba; (E) is a
dinoflagellate; and (F) is a
euglenoid.

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 Model Organisms
All cells are thought to be descended from a common ancestor, whose fundamental
properties have been conserved through evolution.
Thus, knowledge gained from the study of one organism contributes to our understanding
of others, including ourselves.
But certain organisms are easier than others to study in the laboratory. Some reproduce
rapidly and are convenient for genetic manipulations; others are multicellular but
transparent, so that one can directly watch the development of all their internal tissues and
organs.
For reasons such as these, large communities of biologists have become dedicated to
studying different aspects of the biology of a few chosen species, pooling their knowledge
to gain a deeper understanding than could be achieved if their efforts were spread over
many different species. Although the roster of these representative organisms is continually
expanding, a few stand out in terms of the breadth and depth of information that has been
accumulated about them over the years—knowledge that contributes to our understanding
of how all cells work. 9
 Molecular Biologists have focused on E. Coli

In molecular terms, we understand the workings of the bacterium Escherichia coli—E. coli
for short—more thoroughly than those of any other living organism (Figure 3-7).
This small, rod-shaped cell normally lives in the gut of humans and other vertebrates, but
it also grows happily and reproduces rapidly in a simple nutrient broth in a culture bottle.
Most of our knowledge of the fundamental mechanisms of life—including how cells
replicate their DNA and how they decode these genetic instructions to make proteins—
has come from studies of E. coli.
Subsequent research has confirmed that these basic processes occur in essentially the
same way in our own cells as they do in E. coli.

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Figure 3-7: The bacterium Escherichia coli (E. coli ) has served as an important model
organism. An electron micrograph of a longitudinal section is shown here; the cell’s
DNA is concentrated in the lightly stained region. 11
 Brewer’s Yeast is a Simple Eucaryotic Cell
We tend to be preoccupied with eukaryotes because we are eukaryotes ourselves. But
human cells are complicated and reproduce relatively slowly. To get a handle on the
fundamental biology of eukaryotic cells, it is often advantageous to study a simpler cell that
reproduces more rapidly. A popular choice has been the budding yeast Saccharomyces
cerevisiae (Figure 3-8)—the same microorganism that is used for brewing beer and baking
bread. S. cerevisiae is a small, single-celled fungus that is at least as closely related to animals
as it is to plants. Like other fungi, it has a rigid cell wall, is relatively immobile, and possesses
mitochondria but not chloroplasts. When nutrients are plentiful, S. cerevisiae reproduces
almost as rapidly as a bacterium. Yet it carries out all the basic tasks that every eukaryotic cell
must perform. Genetic and biochemical studies in yeast have been crucial to understanding
many basic mechanisms in eukaryotic cells, including the cell-division cycle—the chain of
events by which the nucleus and all the other components of a cell are duplicated and
parceled out to create two daughter cells. The machinery that governs cell division has been
so well conserved over the course of evolution that many of its components can function
interchangeably in yeast and human cells. Darwin himself would no doubt have been
stunned by this dramatic example of evolutionary conservation. 12
Figure 3-8: The yeast Saccharomyces
cerevisiae is a model eukaryote. In
this scanning electron micrograph, a
few yeast cells are seen in the
process of dividing, which they do by
budding. Another micrograph of the
same species is shown in Figure 3-9.

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Figure 3-9: Yeasts are simple free-living
eukaryotes. The cells shown in this micrograph
belong to the species of yeast, Saccharomyces
cerevisiae, used to make dough rise and turn
malted barley juice into beer. As can be seen in
this image, the cells reproduce by growing a
bud and then dividing asymmetrically into a
large mother cell and a small daughter cell; for
this reason, they are called budding yeast.
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 Arabidopsis has been chosen out of
300,00 Species as a Model Plant
Whereas bacteria, archaea, and eukaryotes separated from each other more than 3 billion
years ago, plants, animals, and fungi diverged only about 1.5 billion years ago, and the
different species of flowering plants less than 200 million years ago.
The close evolutionary relationship among all flowering plants means that we can gain
insight into their cell and molecular biology by focusing on just a few convenient species for
detailed analysis.
Out of the several hundred thousand species of flowering plants on Earth today, molecular
biologists have focused their efforts on a small weed, the common wall cress Arabidopsis
thaliana (Figure 3-10), which can be grown indoors in large numbers: one plant can produce
thousands of offspring within 8–10 weeks.
Because genes found in Arabidopsis have counterparts in agricultural species, studying this
simple weed provides insights into the development and physiology of the crop plants upon
which our lives depend, as well as into the evolution of all the other plant species that
dominate nearly every ecosystem on Earth.
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Figure 3-10: Arabidopsis thaliana, the common
wall cress, is a model plant. This small weed has
become the favorite organism of plant
molecular and developmental biologists. 16
 The Model Animal include Flies, Fish, Worms
and Mice
Multicellular animals account for the majority of all named species of living organisms,
and the majority of animal species are insects.
It is fitting, therefore, that an insect, the small fruit fly Drosophila melanogaster (Figure 3-
11), should occupy a central place in biological research.
In fact, the foundations of classical genetics were built to a large extent on studies of this
insect. More than 80 years ago, genetic analysis of the fruit fly provided definitive proof
that genes—the units of heredity—are carried on chromosomes.
In more recent times, Drosophila, more than any other organism, has shown us how the
genetic instructions encoded in DNA molecules direct the development of a fertilized egg
cell (or zygote) into an adult multicellular organism containing vast numbers of different
cell types organized in a precise and predictable way.

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Figure 3-11: Drosophila
melanogaster is a favorite
among developmental
biologists and geneticists.
Molecular genetic studies
on this small fly have
provided a key to the
understanding of how all
animals develop.

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 The Model Animal include Flies, Fish, Worms
and Mice
Drosophila mutants with body parts strangely misplaced or oddly patterned have
provided the key to identifying and characterizing the genes that are needed to make a
properly structured adult body, with gut, wings, legs, eyes, and all the other bits and
pieces in their correct places.
These genes—which are copied and passed on to every cell in the body—define how
each cell will behave in its social interactions with its sisters and cousins, thus controlling
the structures that the cells can create.
Moreover, the genes responsible for the development of Drosophila have turned out to
be amazingly similar to those of humans—far more similar than one would suspect from
outward appearances. Thus, the fly serves as a valuable model for studying human
development and disease.

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 The Model Animal include Flies, Fish, Worms
and Mice
Another widely studied organism is the nematode worm Caenorhabditis elegans (Figure 3-
12), a harmless relative of the eelworms that attack the roots of crops.
Smaller and simpler than Drosophila, this creature develops with clockwork precision from
a fertilized egg cell into an adult that has exactly 959 body cells (plus a variable number of
egg and sperm cells)—an unusual degree of regularity for an animal.
We now have a minutely detailed description of the sequence of events by which this
occurs—as the cells divide, move, and become specialized according to strict and
predictable rules. And a wealth of mutants are available for testing how the worm’s genes
direct this developmental ballet.
Some 70% of human genes have some counterpart in the worm, and C. elegans, like
Drosophila, has proved to be a valuable model for many of the developmental processes
that occur in our own bodies. Studies of nematode development, for example, have led to
a detailed molecular understanding of apoptosis, a form of programmed cell death by
which surplus cells are disposed of in all animals—a topic of great importance for cancer
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research.
Figure 3-12: Caenorhabditis elegans is a small nematode worm that normally lives in the soil. Most
individuals are hermaphrodites, producing both sperm and eggs (the latter of which can be seen
along the underside of the animal). C. elegans was the first multicellular organism to have its
complete genome sequenced.

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 The Model Animal include Flies, Fish, Worms
and Mice
Another organism that is providing molecular insights into developmental processes,
particularly in vertebrates, is the zebrafish.
Because this creature is transparent for the first 2 weeks of its life, it provides an ideal system
in which to observe how cells behave during development in a living animal (Figure 3-13).
Mammals are among the most complex of animals, and the mouse has long been used as the
model organism in which to study mammalian genetics, development, immunology, and cell
biology.
Thanks to modern molecular biological techniques, it is now possible to breed mice with
deliberately engineered mutations in any specific gene, or with artificially constructed genes
introduced into them.
In this way, one can test what a given gene is required for and how it functions. Almost every
human gene has a counterpart in the mouse, with a similar DNA sequence and function.
Thus, this animal has proven an excellent model for studying genes that are important in
both human health and disease. 22
Figure 3-13: Zebrafish are popular
models for studies of vertebrate
development.
(A) These small, hardy, tropical fish are
a staple in many home aquaria. But
they are also ideal for developmental
studies, as their transparent embryos
(B) make it easy to observe cells moving
and changing their characters in the
living organism as it develops.
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 Biologists also directly study Human
Beings and their Cells
Humans are not mice—or fish or flies or worms or yeast—and so we also study human beings
themselves. Like bacteria or yeast, our individual cells can be harvested and grown in culture,
where we can study their biology and more closely examine the genes that govern their
functions.
Given the appropriate surroundings, most human cells—indeed, most cells from animals or
plants—will survive, proliferate, and even express specialized properties in a culture dish.
Experiments using such cultured cells are sometimes said to be carried out in vitro (literally,
“in glass”) to contrast them with experiments on intact organisms, which are said to be carried
out in vivo (literally, “in the living”).
Although not true for all types of cells, many types of cells grown in culture display the
differentiated properties appropriate to their origin: fibroblasts, a major cell type in
connective tissue, continue to secrete collagen; cells derived from embryonic skeletal muscle
fuse to form muscle fibers, which contract spontaneously in the culture dish; nerve cells
extend axons that are electrically excitable and make synapses with other nerve cells; and
epithelial cells form extensive sheets, with many of the properties of an intact epithelium
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(Figure 3-14).
Figure 3-14: Cells in culture often display properties that reflect their origin.
(A) Phase-contrast micrograph of fibroblasts in culture.
(B) Micrograph of cultured myoblasts, some of which have fused to form multinucleate muscle cells that
spontaneously contract in culture.
(C) Cultured epithelial cells forming a cell sheet.
 Biologists also directly study Human
Beings and their Cells
Because cultured cells are maintained in a controlled environment, they are accessible to
study in ways that are often not possible in vivo. For example, cultured cells can be
exposed to hormones or growth factors, and the effects that these signal molecules have
on the shape or behavior of the cells can be easily explored.
Although naturally occurring mutations in any given human gene are rare, the
consequences of many mutations are well documented. This is because humans are
unique among animals in that they report and record their own genetic defects: in no
other species are billions of individuals so intensively examined, described, and
investigated.
Nevertheless, the extent of our ignorance is still daunting. The mammalian body is
enormously complex, being formed from thousands of billions of cells, and one might
despair of ever understanding how the DNA in a fertilized mouse egg cell makes it
generate a mouse rather than a fish, or how the DNA in a human egg cell directs the
development of a human rather than a mouse. 26
 Biologists also directly study Human
Beings and their Cells
Yet the revelations of molecular biology have made the task seem eminently
approachable.
As much as anything, this new optimism has come from the realization that the genes of
one type of animal have close counterparts in most other types of animals, apparently
serving similar functions (Figure 3-15).
We all have a common evolutionary origin, and under the surface it seems that we share
the same molecular mechanisms.
Flies, worms, fish, mice, and humans thus provide a key to understanding how animals in
general are made and how their cells work.

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Figure 3-15: Different species share similar genes. The human baby and the mouse shown here have similar white
patches on their foreheads because they both have defects in the same gene (called Kit), which is required for the
development and maintenance of some pigment cells.

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 Comparing Genome Sequences reveals Life’s
common Heritage
At a molecular level, evolutionary change has been remarkably slow. We can see in present-
day organisms many features that have been preserved through more than 3 billion years of
life on Earth—about one-fifth of the age of the universe.
This evolutionary conservatism provides the foundation on which the study of molecular
biology is built.
To set the scene for the chapters that follow, therefore, we end this chapter by considering a
little more closely the family relationships and basic similarities among all living things.
This topic has been dramatically clarified in the past few years by technological advances
that have allowed us to determine the complete genome sequences of thousands of
organisms, including our own species.
The first thing we note when we look at an organism’s genome is its overall size and how
many genes it packs into that length of DNA.
Prokaryotes carry very little superfluous genetic baggage and, nucleotide-for-nucleotide,
they squeeze a lot of information into their relatively small genomes. 29
 Comparing Genome Sequences reveals Life’s
common Heritage
E. coli, for example, carries its genetic instructions in a single, circular, double-stranded
molecule of DNA that contains 4.6 million nucleotide pairs and 4300 genes.
The simplest known bacterium contains only about 500 genes, but most prokaryotes have
genomes that contain at least 1 million nucleotide pairs and 1000–8000 genes. With these
few thousand genes, prokaryotes are able to thrive in even the most hostile environments
on Earth.
The compact genomes of typical bacteria are dwarfed by the genomes of typical
eukaryotes. The human genome, for example, contains about 700 times more DNA than the
E. coli genome, and the genome of an amoeba contains about 100 times more than ours
(Figure 3-16).
The rest of the model organisms we have described have genomes that fall somewhere in
between E. coli and human in terms of size. S. cerevisiae contains about 2.5 times as much
DNA as E. coli; Drosophila has about 10 times more DNA per cell than yeast; and mice have
about 20 times more DNA per cell than the fruit fly (Table 3-1).
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Figure 3-16: Organisms
vary enormously in the
size of their genomes.
Genome size is measured
Figure 1–40 Organisms vary enormously
in nucleotide pairs of DNA
in the size of their genomes. Genome size
per haploid genome, that
is measured in nucleotide pairs of DNA per
is, per single copy of the
haploid genome, that is, per single copy
genome. (The body cells of
of the genome. (The body cells of sexually
sexually reproducing
reproducing organisms such as ourselves
organisms such as
are generally diploid: they contain two
ourselves are generally
copies of the genome, one inherited from
diploid: they contain two
the mother, the other from the father.)
copies of the genome, one
Closely related organisms can vary widely
inherited from the mother,
in the quantity of DNA in their genomes (as
the other from the father.)
indicated by the length of the green bars),
Closely related organisms
even though they contain similar numbers
can vary widely in the
of functionally distinct genes. (Adapted from
quantity of DNA in their
T.R. Gregory, 2008, Animal Genome Size
genomes (as indicated by
Database: www.genomesize.com)
the length of the green
bars), even though they
contain similar numbers of
functionally distinct genes. 31
Table 3-1: Some model organisms and their genomes

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 Comparing Genome Sequences reveals Life’s
common Heritage
In terms of gene numbers, however, the differences are not so great. We have only about six
times as many genes as E. coli. Moreover, many of our genes—and the proteins they
encode—fall into closely related family groups, such as the family of hemoglobins, which has
nine closely related members in humans. Thus, the number of fundamentally different
proteins in a human is not very many times more than in a bacterium, and the number of
human genes that have identifiable counterparts in the bacterium is a significant fraction of
the total.
This high degree of “family resemblance” is striking when we compare the genome
sequences of different organisms. When genes from different organisms have very similar
nucleotide sequences, it is highly probable that both descended from a common ancestral
gene. Such genes (and their protein products) are said to be homologous. Now that we have
the complete genome sequences of many different organisms from all three domains of
life—archaea, bacteria, and eukaryotes—we can search systematically for homologies that
span this enormous evolutionary divide.
By taking stock of the common inheritance of all living things, scientists are attempting
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to
trace life’s origins back to the earliest ancestral cells.
 Genomes contain more than just Genes

Although our view of genome sequences tends to be “gene-centric,” our genomes
contain much more than just genes. The vast bulk of our DNA does not code for proteins
or for functional RNA molecules. Instead, it includes a mixture of sequences that help
regulate gene activity, plus sequences that seem to be dispensable.
The large quantity of regulatory DNA contained in the genomes of eukaryotic
multicellular organisms allows for enormous complexity and sophistication in the way
different genes are brought into action at different times and places.
Yet, in the end, the basic list of parts—the set of proteins that the cells can make, as
specified by the DNA—is not much longer than the parts list of an automobile, and many
of those parts are common not only to all animals, but also to the entire living world.
That DNA can program the growth, development, and reproduction of living cells and
complex organisms is truly amazing.
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 Essential Cell Biology
Fourth Edition 2014
Bruce Alberts, Dennis Bray, Karen Hopkin,
Reading Alexander Johnson, Julian Lewis, Martin Raff,
Keith Roberts and Peter Walter
Taylor and Francis NY USA

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Thank you

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