Chapter 6 - A Tour of the Cell PDF

Summary

This document provides an overview of cell biology, including cell theory, different types of microscopes, prokaryotic and eukaryotic cells, and their various organelles. It also covers the structure and function of cell components such as the nucleus, ribosomes, and the endomembrane system. The document is well-suited for secondary school biology students.

Full Transcript

Chapter 6 - A Tour of the
Cell
 Cell Structure
and Function
Outline
Cell Theory
Microscopes : Light and Electron
Cell Size
Prokaryotic Cells
Eukaryotic Cells: Plant vs Animal
 Origin of Eukaryotic Cells
 Organelles
­ Nucleus and Ribosomes
­ Endomembrane System
­ Lysosomes and Vacuoles
­ Chloroplasts and Mitochondria
­ Cytoskeleton
 Organisms and
Some organisms are unicellular
Cells and some are
multicellular
 Cell Structure
and Function
Cell Theory

Cells were discovered with
microscopes (1665)
Led to the development of the
cell theory: (1838 – 1850)
All organisms are composed
of one or more cells.
Cells are the smallest units
of life.
Cells arise only by division
of a previously existing cell.
 Visualizing Cells
Different types of microscopes are used
to visualize different sized cellular

Unaided eye
structures
 Light Microscopes (LMs)
Use light and magnify
with lenses
Image formed on the
retina of the eye
Limitations: low
magnification (1000x)
and resolving power
Best for viewing living
cells and general cell
shape and structure
 Electron Microscopes (EMs)
Use beams of electrons
and electromagnets
Image formed on a
screen
Greater resolving and
magnification powers
 Up to 2,000,000X
Limitation: can’t view
living cells
Two types: TEM & SEM

Virtual electron microscope:
http://school.discoveryeducation.com/lessonplans/interact/vemwindow.html
Microscopy and Amoeba proteus
 Cell Structure
and Function
Why Are Cells So Small?
Some as small as one micrometer (m)
Size restricted by Surface/Volume (S/V) ratio
 As cell grows, volume increases faster than
surface
 Cells specialized to greatly increase surface area
per unit volume: frilly, long, concave
 Cell Structure
Prokaryotic Cells and Function

 Lack a membrane-bound nucleus
 Simple Structure
 Two Domains: Bacteria and Archaea
 Prokaryotic Cells
All have DNA, cytoplasm with ribosomes, a
plasma membrane and cell wall.
Genome - one single circular chromosome
 Found in a region called the nucleoid
 Some have plasmids - small rings of DNA

Bacterial Plasmids
Prokaryotic Cell
Structure
 Check for Understanding
Can you identify each part of the prokaryotic cell?
What is the function of each part?
 Cell Structure
and Function
Eukaryotic Cells

Found in all eukaryotes
 Domain Eukarya
Larger than prokaryotes
Membrane-bound nucleus
Internal membranes
- Increase surface area
- Form specialized
organelles
- Form an endomembrane
system
 Origin of Eukaryotic Cells
Invagination of plasma membrane gave rise to the nuclear
envelope and endomembrane system

Endosymbiotic theory: mitochondria and chloroplasts
originated from aerobic and photosynthetic prokaryotes that
were eaten but not digested; became permanent residents
and eventually organelles

Animation: Origin of Eukaryotic Organelles
 Differences in Structure & Function
Eukaryotic cells vary in structure
Division of labor In multicellular eukaryotes
- Cells are specialized
- Structure fits function

Animal Cell Plant Cell

Animation: Tour of An Animal Cell

Animation: Tour of a Plant Cell
 Cell Walls
Found in plants, bacteria, fungi, some protists
Protect, support and prevents excessive water
uptake
Composition varies:
­Plants – cellulose
­Fungi – chitin
­Bacteria - peptidoglycan
 Plasma Membrane
Structure: lipid bilayer embedded with proteins
attached with carbohydrates; semipermeable
Controls passage of materials into and out of the
cell
Also plays role in cell communication and
identification
 Nucleus
Containing genetic material packaged in chromatin
Chromatin – DNA plus protein; when highly coiled
forms a chromosome.
Nuclear envelope – separates nucleoplasm from
cytoplasm; has pores
Nucleolus - produces subunits of ribosomes
 Cell Structure
and Function
Ribosomes: Protein Factories

Site of protein synthesis
Consists of a 2 subunits
Many locations is cell

Animation: Protein Synthesis
 Endomembrane System

System of membranes
that functions in
synthesis, storage, and
export of cell proteins
and lipids
 Endoplasmic
reticulum (ER)
 Golgi apparatus
 Vesicles
 Plasma membrane
Rough and Smooth Endoplasmic Reticulum
Rough ER - studded with ribosomes which synthesize
cellular proteins (membrane proteins, enzymes,
antibodies, hormones)
Allows proteins to fold inside its lumen
Smooth ER- embedded with enzymes that synthesize
cellular lipids (fats, oils, steroids)
Also detoxifies poisons such as drugs and alcohol

Protein synthesis by Rough ER
 Golgi Apparatus
Modifies, sorts, packages and distributes ER
products (proteins and lipids)
Has a receiving and shipping side
Some products are exported

ER products move to Golgi in
transport vesicles
Golgi products may:
be secreted from the cell or
exported.
become part of membranes
become organelles such as
lysosomes

Animation: Vesicles and Golgi
 Cell Structure
and Function
Endomembrane System Check
 Cell Structure
and Function
Lysosomes: Digestive Compartments

Membranous vesicles
with hydrolytic-digestive
enzymes

Functions:
Intracellular digestion of
food or pathogens
Autophagy – digest
nonfunctional
organelles; recycle
of cellular resources
 Cell Vacuoles: Storage Sacs
Membranous sacs that store
materials
Food vacuole – stores food
Contractile vacuole – stores
and eliminates water
Central vacuole – stores
water, nutrients, pigments,
enzymes, and wastes
Maintains turgor pressure
for support
 Chloroplasts: Sugar Factories
Energy transforming
organelles in plants and
some protists
Light energy  Chemical
energy (sugar)

Site of photosynthesis:
process of making food
using visible light from sun
CO2 + H2O  C6H12O6 + O2
 Mitochondria: Powerhouses
Energy transforming organelles in all eukaryotes
Sites of cellular respiration: process of making
ATP using the energy in organic molecules such
as
- C6H12O6 + O2  CO2 + H2O + Energy
(Energy released is used to build ATP)
Origin of Chloroplasts and Mitochondria
 Cytoskeleton
Scaffold of protein fibers
throughout cytoplasm
 Three types

Function:
Maintain shape of cell
Cell motility
Anchor organelles
Movement of organelles
 Cell Structure
and Function
Cytoskeleton: Actin Filaments

Thinnest filaments

Dense web just under
plasma membrane

Function:
 Support shape of cell
 Ameoboid movement
 Cytoplasmic steaming
 Muscle contraction
Cytoskeleton: Intermediate Filaments

Rope-like assembly of
fibrous polypeptides
Found in cells that
require strength (Ex.
epithelial cells)
Functions:
Support and strength
Form cell junctions
which hold cells
tightly together
Anchor organelles

Animation: Intermediate filaments of the Cytoskeleton
 Cell Structure
The Cytoskeleton: and Function
Microtubules

Hollow cylinders made of globular proteins
Interacts with motor proteins (kinesin and dynein)
Function:
Movement of organelles
Movement of cells by
flagella and cilia
 Cell Structure
and Function
Cilia and Flagella

Locomotor appendages of
some cells
 Contain specialized
arrangements of paired
microtubules
 How do flagella and cilia bend to
produce motility?
The protein dynein is responsible for the
bending movement of cilia and flagella
Powered by ATP, the dynein arms of one
microtubule pair grip the adjacent doublet,
push it up, release and grip again.

Microtubule Outer doublets ATP
doublets ATP cross-linking
proteins

Anchorage
in cell
Dynein arm
(a) (b)
 Animal Cell: Check for Understanding
Can you identify each part and describe its function?
 Plant Cell: Check for Understanding
Can you identify each part and describe its function?
 Additional Web Resources

http://www.usoe.k12.ut.us/curr/science/sciber00/7th/cells/sciber/
micrpart.htm
*Quick study sheet on parts of a compound light microscope.

http://www.udel.edu/Biology/ketcham/microscope/scope.html
*Interactive tutorial on how to use the microscope. Excellent
site!!!

http://www.microscopy-uk.org.uk/micropolitan/index.html
* Beautiful micrographs taken with light microscopes.

http://www.cellsalive.com
*Select Cell Biology: How Big Is A Cell? Cell Models

http://www.biology4kids.com/files/cell_main.html
*Great site for learning about cell organelles