Introduction to the Cell - PowerPoint PPT Presentation

About This Presentation
Title:

Introduction to the Cell

Description:

Introduction to the Cell – PowerPoint PPT presentation

Number of Views:223
Avg rating:3.0/5.0
Slides: 40
Provided by: Kennes6
Category:

less

Transcript and Presenter's Notes

Title: Introduction to the Cell


1
Introduction to the Cell
2
Introduction
  • Every living thing-from the tiniest bacterium to
    the largest whale-are made of one or more cells.
  • Before the seventeenth century, no one knew that
    cells existed.
  • Most cells are too small to be seen with the
    unaided eye.
  • Cells were not discovered until after the
    invention of the microscope in the early
    seventeenth century.

3
The Microscope
  • One of the first microscopes was made by the
    Dutch drapery store owner Anton von Leewenhoek
    (1632-1723).
  • With his hand-held microscope, Leewenhoek became
    the first person to observe and describe
    microscopic organisms and living cells.

4
  • Leeuwenhoek is known to have made over 500
    "microscopes," of which fewer than ten have
    survived to the present day. In basic design,
    probably all of Leeuwenhoek's instruments --
    certainly all the ones that are known -- were
    simply powerful magnifying glasses, not compound
    microscopes of the type used today.

5
  • In 1665, the English Scientist Robert Hooke
    (1635-1703) used a microscope to examine a thin
    slice of cork and described it as consisting of
    "a great many little boxes".  It was after his
    observation that Hook called what he saw "Cells".
    They looked like "little boxes" and reminded him
    of the small rooms in which monks lived, so he
    called the "Cells".

6
The invention of the microscope lead to several
important statements
  • In 1838, German Botanist Matthias Schleiden
    studied a variety of PLANTS and concluded that
    all PLANTS "ARE COMPOSED OF CELLS".
  • The next year, German Zoologist Theodor Schwann
    reported that ANIMALS are also made of CELLS and
    proposed a cellular basis for all life.
  • In 1855- 1858, German Physician Rudolf Virchow
    induced that "THE ANIMAL ARISES ONLY FROM AN
    ANIMAL AND THE PLANT ONLY FROM A PLANT" OR " THAT
    CELLS ONLY COME FROM OTHER CELLS".

7
Fundamental Ideas of Cell Theory
  1. All living matter is composed of cells.
  2. All cells arise from cells.
  3. The cell is the basic unit of structure and
    function. (Smallest unit of life.)

8
The Cell Theory
  • A. Major Contributors.
  • Robert Hooke- 1600s
  • Anton von Leewenhoek
  • Mattias Schleiden 1838 German botanist
  • Theodor Schwann 1839 German Zoologist
  • Rudolf Virchow 1858

9
How Cells are Studied - Microscopy
  • 1. Light Compound Microscope

10
(No Transcript)
11
How the light microscope works
  • Most microscopes are called light microscopes
    because they accomplish their task by using
    lenses to bend light rays.

12
Observing and Drawing Objects
  • Because the light rays from an object cross
    before reaching your eye, the image you see
    through our light microscopes will be inverted
    and upside down.

13
Important terms with the microscope
  • Magnification the increase of an object's
    apparent size.
  • Field of view the area visible through the
    microscope lenses. Field of view decreases as
    magnificaiton increases.
  • Resolution the power to show details clearly.
    Resolution allows the viewer to see two objects
    that are very close together as two objects
    rather than as one.

14
How Cells are Studied cont
  • 2. Scanning Electron Microscope (SEM)
  • 3. Transmission Electron (TEM)

15
Micrograph a photograph of the view through a
microscope
Light microscope
SEM
TEM
16
How Does an Electron Microscope Work?
  • Electrons are very tiny negatively-charged
    particles. Because they are negatively-charged,
    they are attracted to anything that is
    positively-charged.
  • By applying voltage to a metal plate, we are able
    to make the plate positively-charged so that it
    attracts the electrons.
  • Some of the electrons flow through a small hole
    that is in the plate, creating a beam of
    electrons that we aim at our sample with the help
    of magnetic lenses.
  • When the electrons hit our sample, the
    interaction is detected and transformed into an
    image.

17
Microscopy and Amoeba proteus
18
Microscopy and Cheek Cells
19
How Cells are Studied (even more!)
  • 4. Cell Fractionation and Differential
    Centrifugation

20
Cell Fractionation and Differential Centrifugation
  • Cell fractionation is the breaking apart of
    cellular components
  • Differential centrifugation
  • Allows separation of cell parts
  • Separated out by size density
  • Works like spin cycle of washer
  • The faster the machine spins, the smaller the
    parts that settled out

21
Cell Structure and Size
  • Structure is related to function!
  • Cells take the shape that best allows them to
    perform their job.
  • Ex. Nerve cells
  • Ex. Skin cells
  • The ratio of cell surface
    to cell volume
    limits cell size.

22
Cell Size
  • Most much smaller than one millimeter (mm)
  • Some as small as one micrometer (mm)
  • Size restricted by Surface/Volume (S/V) ratio
  • Surface is membrane, across which cell acquires
    nutrients and expels wastes
  • Volume is living cytoplasm, which demands
    nutrients and produces wastes
  • As cell grows, volume increases faster than
    surface
  • Cells specialized in absorption modified to
    greatly increase surface area per unit volume

23
Surface to Volume Ratio
































TotalSurfaceArea (Height?Width?NumberOfSides?Numbe
rOfCubes) 96 cm2 192 cm2 384 cm2
TotalVolume (Height?Width?LengthXNumberOfCubes)
64 cm3 64 cm3 64 cm3 SurfaceAreaPerCube/Volume
PerCube (SurfaceArea/Volume) 1.5/1 3/1 6/1
24
Structure and Function
25
The Prokaryotic Cell
  • Two domains Bacteria and Archaea
  • Lacks a nucleus and most other organelles
  • DNA concentrated in nucleoid region
  • Contains ribosomes, cell wall, and in some cases
    a capsule, pili, and flagella.
  • 1-10 micrometers
  • Appear earliest in earths fossil record

26
Figure 7.4x1 Bacillus polymyxa
27
Figure 7.4x2 E. coli
28
Prokaryotes
  • PROKARYOTES were the only life form for 2 BY!

29
Prokaryotic Cells Visual Summary
30
Prokaryotic Cells The Envelope
  • Cell Envelopes
  • Glycocalyx
  • Layer of polysaccharides outside cell wall
  • May be slimy and easily removed, or
  • Well organized and resistant to removal (capsule)
  • Cell wall
  • Plasma membrane
  • Like in eukaryotes
  • Form internal pouches (mesosomes)

31
Prokaryotic Cells Cytoplasm Appendages
  • Cytoplasm
  • Semifluid solution
  • Bounded by plasma membrane
  • Contains inclusion bodies Stored granules of
    various substances
  • Appendages
  • Flagella Provide motility
  • Fimbriae small, bristle-like fibers that sprout
    from the cell surface
  • Sex pili rigid tubular structures used to pass
    DNA from cell to cell

32
The Eukaryotic Cell
  • True nucleus
  • Membrane-bounded organelles
  • Size 10-100 microns (much
    bigger!)
  • Members of Kingdom Animalia, Plantae, Fungi and
    Protista

33
Eukaryotic cell
  • Nucleus surrounded by its membrane
  • Internal organelles bounded by membranes
  • 10 100 micrometers
  • Domain Eukarya
  • Kingdoms Protists, Fungi, Plants, Animals

34
Membranes Allow for More Efficient Cellular
Metabolism
  • Membranes separate areas to maintain specific
    chemical conditions. (Think about your stomach
    and intestines!)
  • This way different chemical processes can take
    place simultaneously.
  • Membranes increase the surface area needed for
    many chemical reactions.

35
  • In other words, the cell can increase in size and
    combine together to form tissues!
  • There is no such thing as a multicellular
    prokaryotic organism!
  • More on the eukaryotic cell in the next power
    point
  • Wait how did membranes and organelles evolve?

36
Hypothesized Origin of Eukaryotic Cells
Theory of Endosymbiosis
37
Prokaryotes vs. Eukaryotes
  • Eukaryotes
  • nuclear membrane
  • membrane bound organelles (Golgi bodies,
    lysososome, mitochondria, vacuoles, etc.)
  • 10-100 microns
  • Found in the kindgoms Plantae, Animalia, Fungi,
    Protista
  • Prokaryotes
  • NO nuclear membrane
  • No membrane bound organelles
  • contain ribosomes
  • 1-10 microns
  • Found in the kindgoms Eubacteria,
    Archaebacteria

38
Sizes of Living Things
39
The size range of cells
Write a Comment
User Comments (0)
About PowerShow.com