Lesson 1: Cell Theory, Structure, and Function PDF

Summary

This document provides a lesson covering cell theory, structure, and function. It details the primary building blocks of life, and the fundamental components of plants and animals.

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Lesson 1: Cell Theory, Structure, and - prominent neurologist and
Function embryologist
- in 1852, published convincing
evidence that cells are derived
Cells
from other cells as a result of
- primary building blocks of life
cell division
- come in all shapes and sizes
- smallest cell: Mycoplasma
Rudolf Virchow
gallicepticum (0.3 nm)
- well-respected pathologist
- largest cell: ostrich egg (6 in)
- in 1855, published an editorial
essay entitled, “Cellular
Cell Theory
Pathology,” which popularized
the concept of cell theory using
1. All organisms are made up of cells.
the Latin phrase, “omnis cellula
- the cell is the structural &
a cellula,” (all cells arise from
functional unit of all living things
cells) which is essentially the
second tenet of modern cell
Robert Hooke
theory
- first recorded cells around 1665
- was improving his microscope
3. Cells contain hereditary information
design when he decided to
which is passed from cell to cell
observe a piece of cork and
during cell division.
saw box-like structures (cell
- life depends on the ability of
walls)
cells to store, retrieve, and
translate the genetic instructions
Profound Postulates of Cell Theory
required to make and maintain a
living organism
Matthias Schleiden
- these instructions are stored as
- German botanist
genes, which contain elements
- made extensive
that determine the
microscopic
characteristics of a species as a
observations of plant
whole and the individuals within
tissues in 1838
it

Theodor Schwann
4. All cells are basically the same in
- German physiologist
chemical composition.
- made similar
- hydrogen, oxygen, nitrogen,
observations in animal
carbon, phosphorus, and
tissues in 1839
sulfur normally make up more
than 99% of the mass of living
These laid the foundation for the
cells and form virtually all known
idea that cells are fundamental
organic biomolecules
components of plants and
- they are utilized in the synthesis
animals.
of a small number of building
blocks that are in turn used in
2. All cells come from pre-existing cells
the construction of
by division.
macromolecules (nucleic
acids, proteins,
Robert Remark
polysaccharides, and lipids)
 5. All energy flow (metabolism & - processes the proteins produced by the
biochemistry) of life occurs within endoplasmic reticulum and ribosomes,
cells. modifying and storing them until it
- nutrients and other molecules packages them into vesicles
are imported into the cell to - Lysosomes
meet these energy demands - sacs containing enzymes
- cellular processes such as the capable of breaking down cell
building and breaking down macromolecules
of complex molecules occur
through step-wise chemical Storage Organelles
reactions
Vesicles
Major and Subcellular Organelles - membranous sacs that transport or
store a variety of compounds
Nucleus
- the storehouse of genetic information in Vacuoles
the form of DNA inside the cells - fluid-filled sacs for the storage of
materials needed by the cell including
Cell Membrane water, food molecules, inorganic ions,
- a plasma membrane in plants that lies and enzymes
just underneath a rigid layer (cell wall),
giving protection, support, and shape to Energy-Producing Organelles
the cell
- in plants and algae, the cell wall Mitochondria
is made up of polysaccharide - sites of cellular respiration
cellulose - break down sugar to fuel the cell

Cytoplasm Chloroplasts
- fills the space between the nucleus and - contain chlorophyll
the cell membrane - photosynthesis occurs within them,
- cytosol is the fluid portion consisting allowing plant cells to form sugar from
mainly of water and excluding the air, water, and light
organelles in it
Breakdown Organelles
Manufacturing Organelles
Lysosomes
Endoplasmic Reticulum - contain powerful enzymes that can
- an extensive membrane complex defend a cell from invading bacteria and
extending throughout the cytoplasm viruses
from the outer membrane of the nuclear
envelope Peroxisomes
- Rough Endoplasmic Reticulum - contain digestive enzymes for breaking
- contains ribosomes that down toxic materials
produce proteins
- Smooth Endoplasmic Reticulum Structural Support, Movement, and
- manufactures lipids
Communication Organelles
Golgi Apparatus
Cytoskeleton
 - made up of a small protein subunit, Cytoplasm
forming long threads or fibers that can ○ jelly-like fluid within a cell that is
crisscross the entire cell providing sturdy composed primarily of water,
mechanical support salts, and proteins

Centrosome Ribosomes
- small dense region of cytoplasm that ○ organelles that make proteins
serves as the main microtubule
organizing center Differences
Feature Eukaryotic Prokaryotic
Cilia & Flagella
- two locomotory projections in Nucleus - nucleus - no nucleus
eukaryotes surrounded by - membraneless
- cilia look like hairs while flagella look nuclear envelope nucleoid region
- free floating DNA
like a tail
Organelles - membrane - appendages from
Lesson 2: Prokaryotic and Eukaryotic bound organelles the cell surface
such as (flagellum,
Cells mitochondria, fimbriae, pili)
rough and - bacteria may
Three Basic Domains of All Living Things smooth ER, and have
golgi complex carboxysomes
- Bacteria (P)
- Archea (P) Ribosomes - bigger, more - smaller and free
- Eukarya (E) complex, and floating
membrane - 50-s & 30-s
bounded subunits
Prokaryotes - 60-s & 40-s
- primarily single-celled organisms
- smallest, simplest, and most ancient Reproduction - sexually or - binary fission or
cells through mitosis genetic
variations (
transformation,
Eukaryotes transduction,
- made up of more complex cells conjugation)
- can be unicellular or multicellular
Cell Walls - fungal cell walls - rigid wall made
- include animals, plants, fungi, and are made up of up of
protists chitin peptidoglycans
- vertebrates do
not have cell
Common Features walls

DNA
○ genetic coding that determines
Plant Tissues and Cells
all the characteristics of living
things Plant Cells
- formed at meristems and develop into
Cell (or Plasma) Membrane cell types, which are grouped into
○ outer layer that separates the tissues
cell from the surrounding - Dermal
environment and acts as a - Ground
selective barrier for incoming - Vascular
and outgoing materials
Dermal Tissue (EG) Muscle Tissue (SSC)
- covers the outer surface of herbaceous - facilitates movement of the animal by
plants contraction of individual muscle cells
- Epidermal - Skeletal Muscle Fiber
- Guard - Smooth Muscle Fiber
- Cardiac
Ground Tissue (PCS)
- comprises the bulk of the primary plant Nervous Tissue (NG)
body - integration of stimulus and control of
- Parenchyma response to stimulus
- Collenchyma - Nerve
- Sclerenchyma - Glial

Vascular Tissue (PCX)
Plants Animals
- transports food, water, hormones, and
minerals within the plant DGV ECMN
- Xylem
- Phloem D - EG E - SCC
- Cambium G - PCS C - BBL
V- PCX M - SSC
3N - NG
Animal Tissues and Cells

Animal Cells Lesson 3: Microscopy
- Epithelial
- Connective Microscope
- Muscle - used to view objects too small to be
- Nervous seen with the unaided eye

Epithelial Tissue (SCC) Antonie van Leeuwenhoek
- covers body surfaces and lines body - observed first living cells using his own
cavities single lens microscope in 1676
- protects and forms glands
- Squamous Epithelium Types of Microscopes
- Cuboidal Epithelium
Simple Microscope
- Columnar Epithelium
Compound Microscope
Electron Microscope
Connective Tissue (BBL)
○ SEM (Scanning Electron)
- binding, supporting, protecting, forming
○ TEM (Transmission Electron)
blood, storing fats, and filling space
- Bone
Simple Microscope
- Loose Connective Tissue
- the first microscope
- Adipose
- can magnify between 200 and
- Areolar
300 times; essentially a
- Reticular
magnifying glass
- Blood
- combined convex lens
- RBC
- not used often due to the
- WBC
introduction of a second lens
- Platelets
Compound Microscope
Mechanical Parts
- most common microscope found in labs - give support and strength
- uses two lenses Magnifying Parts
- involved with magnifying power
Monocular Microscope Illuminating Parts
- one ocular lens - used to collect light for better resolution

Binocular Microscope
- two ocular lenses Calculating Magnifying Power
- can be determined by multiplying the
Electron Microscope magnification power of the ocular lens to
- uses electron beams to magnify an the magnification power of the objective
object lenses

Scanning Electron Microscope
- uses a focused beam of high-energy
electrons to generate a variety of signals
at the surface of solid specimens
- magnification ranging from 20X to
approximately 30,000X, spatial
resolution of 50 to 100 nm
- used to generate high-resolution images
of shapes of objects and to show spatial
variations in chemical compositions
Storing the Microscope
Transmission Electron Microscope 1. Turn the nosepiece to put the LPO or
- uses electrons in creating a magnified the scanner back into position.
image, and samples are scanned in a 2. Raise the body tube or lower the stage
vacuum with the coarse adjustment knob to
- magnification up to 250,000x prevent the lens from striking the stage
- can reveal the finest details of internal accidentally.
structure 3. Turn off the light if your microscope light
source is an electric light bulb.
Parts and Functions of a Compound 4. Use a clean piece of lens paper, wipe
Microscope the ocular and the objective lenses
gently.

Lesson 4: Cell Reproduction

Cell Division
- all cells are derived from pre-existing
cells
- new cells are produced for growth and
to replace damaged or old cells
- differs in prokaryotes (bacteria) and
eukaryotes (protists, fungi, plants, and
animals)
DNA - examples are mitosis and binary fission
- where the instructions for making cell
parts are encoded Sexual Reproduction
- each new cell must get a complete set - involves two cells (egg and sperm)
of DNA molecules joining to make a new cell (zygote) that
- must be replicated before cell division; is not identical to the original cells
each new cell will then have an identical - an example is meiosis
copy of the DNA (one parent cell
creates two identical daughter cells) Cell Division in Prokaryotes
- they divide into 2 identical cells by the
Prokaryotic Chromosomes process of binary fission
- the DNA of prokaryotes is one, circular - a single chromosome makes a copy of
chromosome attached to the inside of itself
the cell membrane - cell wall forms between the
chromosomes, dividing the cell
Eukaryotic Chromosomes
- all eukaryotic cells store genetic Cell Cycle
information in chromosomes
- most eukaryotes have between 10 to 50
chromosomes in their body cells Interphase
- humans have 46 chromosomes or 23 G1 - primary growth phase
identical pairs S - synthesis; DNA replication
- each chromosome is composed of a G2 - secondary growth phase
single, tightly coiled DNA molecule Mitosis (M)
- can’t be seen when cells aren’t Prophase
dividing (called chromatin) Metaphase
Anaphase
Compacting DNA into Chromosomes Telophase
- DNA is tightly coiled around proteins Cytokinesis (C)
called histones
Interphase
Chromatids
- duplicated chromosomes called sister G1 Stage
chromatids - first growth stage after cell division
- held together by the centromere - cells mature by making more cytoplasm
and organelles
Karyotype - cell carries on its normal metabolic
- a picture of a human cell’s activities
chromosomes arranged in pairs by size
- the first 22 are called autosomes S Stage
- last pair are the sex chromosomes (XX - synthesis stage
for females and XY for males) - DNA is copied or replicated

Types of Cell Reproduction G2 Stage
- second growth stage; after DNA has
Asexual Reproduction been copied
- involves a single cell dividing to make 2 - all cell structures needed for division
new, identical daughter cells (e.g. centrioles) are made
 - both organelles and proteins are
synthesized Anaphase
- occurs rapidly
Mitosis - sister chromatids are pulled apart to
- division of the nucleus; also called opposite poles of the cell by kinetochore
karyokinesis fibers
- only occurs in eukaryotes
- doesn’t occur in some cells such as Telophase
brain cells - sister chromatids at opposite poles
- spindle disassembles
Early Prophase - nuclear envelope forms around each
- chromatin in nucleus condense to form set of sister chromatids
visible chromosomes - nucleolus reappears
- mitotic spindle forms from fibers in - cytokinesis occurs
cytoskeleton or centrioles (animals) / - chromosomes reappear as chromatin
microtubules (plants)
Cytokinesis
Late Prophase - division of cytoplasm
- nuclear membrane and nucleolus are - division of cell into two, identical halves
broken down or have disintegrated called daughter cells
- chromosomes continue condensing and - in plants, cell plate forms at the equator
are clearly visible to divide the cell; in animals, cleavage
- spindle fibers called kinetochores furrow forms
attach to the centromere of each
chromosome Daughter Cells of Mitosis
- spindle finishes forming between the - have the same number of chromosomes
poles of the cell as each other and as their parent cell
- identical to each other but smaller than
Spindle Fibers parent cell
- must grow in size to become mature
Polar Fibers cells (G1 of Interphase)
- extend from one pole of the cell
to the opposite Cell Division in Eukaryotes
- used for growth and repair
Kinetochore Fibers - produces two new cells identical to the
- extend from the pole to the original cell
centromere - cells are diploid (2n)

Asters Uncontrolled Mitosis
- short fibers radiating from - unlimited cell division occurs, causing
centrioles cancerous tumors
- oncogenes are special proteins that
Metaphase increase the chance of a normal cell
- chromosomes, attached to developing into a tumor cell
kinetochores, move to the center of the
cell Meiosis
- chromosomes are now lined up at the - the fundamental basis of sexual
equator reproduction
 - preceded by interphase which includes - homologous pair
chromosome replication - crossing-over (pieces of chromosomes
- two meiotic divisions (Meiosis I and or genes are exchanged; produces
Meiosis II) genetic recombination in the offspring)
- called reduction-division
- original cell is diploid (2n) but four Late Prophase I
produced daughter cells are haploid - chromosomes condense
(1n); they contain half the number of - spindle forms
chromosomes as the original cell - nuclear envelope fragments
- produces gametes (eggs and sperm)
- occurs in the testes for males Five Substages of Prophase I
(spermatogenesis) or the ovaries for
females (oogenesis) Leptonema
- occurs in germ cells that produce - replicated chromosomes have coiled
gametes and are already visible
- reduces the chromosome number by - number of chromosomes is the same as
half so fertilization can then restore the the number in the diploid cell
2n number (two haploid gametes form a
diploid zygote) Zygonema
- homologue chromosomes begin to pair
and twist around each other in a highly
specific manner called synapsis
- because the pair consists of four
chromatids it is referred to as bivalent
tetrad

Pachynema
- chromosomes become much shorter
and thicker
- a physical exchange between homologs
called crossing-over takes place at
specific regions

Diplonema
- two pairs of sister chromatids begin to
separate from each other
- after crossing over, the area of contact
between two non-sister chromatids
called chiasma becomes evident

Diakinesis
- four chromatids of each tetrad are even
more condensed and the chiasma often
Prophase I terminalize or move down the
- chromosome number is doubled chromatids to the ends; this delays the
- homologous chromosomes join to form separation of homologous
tetrads (called synapsis) chromosomes

Early Prophase I
 - nucleoli disappear and the nuclear - men produce about 250,000,000 per
membrane begins to break down day

Metaphase I Oogenesis
- homologous pairs align along the - occurs in the ovaries
equator of the cell - two divisions produce 3 polar bodies
that die and 1 egg
Anaphase I - polar bodies die because of unequal
- homologs separate and move to division of cytoplasm
opposite poles - immature egg is called an oocyte
- sister chromatids remain attached at - starting at puberty, one oocyte matures
their centromeres into an ovum every 28 days (menstrual
cycle)
Telophase I
- nuclear envelopes reassemble and
spindle disappears
Mitosis Meiosis
- cytokinesis divides cell into two
Divisions 1 2
Meiosis II
Daughter Cells 2 4

Genetically Yes No
Identical?

Number of Same as Half of
Chromosomes parent parent

Where Somatic Germ
Cells Cells

When throughout at sexual
life maturity

(essentially the same as mitosis but doubled) Role Growth and Sexual
Repair Reproduction
Results of Meiosis
- gametes form Lesson 5: Chromosomal Aberrations
- four haploid cells with one copy of each
chromosome - disruptions in the normal chromosomal
- one allele of each gene content of a cell
- different combinations of alleles for - morphological or numerical alteration of
different genes along the chromosome chromosomes
- affects autosomes, sex chromosomes,
Gametogenesis or both
- Deletion, Duplication, Inversion,
Spermatogenesis Translocation
- occurs in the testes - originates as a result of an error during
- two divisions produce 4 spermatids that meiosis (nondisjunction), specifically in
mature into sperm ANAPHASE stage
Klinefelter Syndrome
- people born with an extra X, causing Physical Characteristics
their cells to have XXY chromosomes - excessive drooling
- happens randomly during conception - behavioral problems
- often intellectually disabled
Physical Characteristics - gastrointestinal and cardiac
- weaker bones; osteoporosis complications
- heart and blood vessel disease - abnormal development of larynx and
- diabetes glottis
- underactive thyroid gland
(hypothyroidism)
- autoimmune diseases like rheumatoid Jacobsen’s Syndrome
- arthritis, lupus - deletion of a terminal region of
- a rare tumor called an extragonadal chromosome 11 that includes band 11
germ cell tumor q 24.1
- male breast cancer (although this is - rare congenital disorder also known as
quite rare) 11 q deletion disorder
- can cause intellectual disabilities, a
distinctive facial appearance, and a
Wolf-Hirschhorn Syndrome variety of physical problems including
- deletion of short arm of chromosome 4 heart defects and a bleeding disorder
- also known as Pitt-Rogers-Danks - first identified by Danish physician Petra
Syndrome or Pitt Syndrome Jacobsen and is believed to occur in 1
- first described in 1961 by Herbert L. out of every 100,000 births
Cooper and Kurt Hirschhorn
Physical Characteristics
Physical Characteristics - bleeding disorder
- short philtrum - heart defects
- immunodeficient - wide set eyes
- microcephaly (small head) - low set misshapen ears
- seizures - large toes
- muscle hypotonia
- renal anomalies
- deafness Pallister-Killian Syndrome
- presence of the anomalous extra
isochromosome 12p, the short arm of
Cri Du Chat Syndrome the twelfth chromosome (Tetrasomy -
- deletion of short arm of chromosome 5 2n+2 or 48 chromosomes)
- also known as chromosome 5p - mosaic condition and extremely rare
deletion syndrome, 5p minus genetic disorder also known as
syndrome, or Leejeune’s syndrome Tetrasomy 12p Mosaicism or Pallister
- a French term meaning, “cat-cry” or “call Mosaic Aneuploidy Syndrome
of the cat” referring to the characteristic
catlike cry of affected children Physical Characteristics
- first described in 1963 by Jerome - hypo/hyper pigmentation
Leejeune - epilepsy
- affects 1 in 50,000 live births, strikes all - high foreheads
ethnicities, and is more common in - flat nose
females by a 4:3 ratio - supernumerary nipples
 - psychomotor retardation - identified as a chromosome 21 Trisomy
by Dr. Jerome Lejeune in 1959

Patau Syndrome Physical Characteristics
- additional chromosome 13 (Trisomic - - epicanthal folds in the eye
47 chromosomes) due to - short stature and short neck
non-disjunction during meiosis, causing - delayed language development
heart and kidney defects - tongue tends to stick out of the mouth
- some are caused by Robertsonian - some are mentally retarded
Translocations - flattened face, especially nose bridge
- also known as Trisomy 13 and
Trisomy D
- affects between 1 in 10,000 and 1 in
21,700 live births

Physical Characteristics
- polydactyl
- cleft palate
- cutis aplasia
- kidney failures

Isodicentric 15
- 47 chromosomes instead of 46
- extra genetic material in chromosome
15

Physical Characteristics
- poor muscle tone in newborn
- developmental delay
- flattened nasal bridge
- button nose
- high arched palate
- some features of autism

Trisomy 21
- extra genetic material in chromosome
21 (47 chromosomes)
- average IQ of affected children is 50
(normal is 100)
- Down Syndrome
- named after John Langdon Down, the
British physician who described the
syndrome in 1866
- clinically described earlier in the 19th
century by Jean Etienne Dominique
Esquirol in 1838 and Edouard Seguin in
1844