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DNA Deoxyribonucleic Acid

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Title: DNA Deoxyribonucleic Acid


1
DNADeoxyribonucleic Acid
  • (a little background, more in cell biology
    Chapter 16)

2
Background
  • Genes are portions of DNA molecules that contain
    genetic information that controls protein
    synthesis. DNA is one of the nucleic acids and
    RNA is the other.
  • Each chromosome is made up of DNA and associated
    proteins. The DNA of each chromosome contains
    many genes.

3
Background continued
  • The process whereby genes direct protein
    synthesis is called gene expression.
  • DNA gt RNA gt protein
  • DNA is transcribed into RNA
  • RNA is translated into proteins
  • DNA is also replicated (duplicated)

4
Central Dogma
5
DNA structure
  • DNA is composed of subunits, nucleotides, that
    consist of a 5Carbon sugar (deoxyribose),
    phosphate group(s), and nitrogenous bases Adenine
    (A), Thymine (T), Cytosine (C), and Guanine (G).
  • Nucleotides are linked by sugar-phosphate bonds
    that basically form a backbone (like the sides of
    a ladder).
  • Base pairing between A and T and between C and G
    connects two strands (sides of ladder) together
    (like the steps of a ladder).
  • The 3-D structure of DNA is a twisted spiral (or
    more commonly called a helix) consisting of two
    strand of DNA, thus it is called a double helix.

6
DNA nucleotide
7
The Nitrogenous bases
8
Base pairing
9
DNA Double Helix
10
III. DNA Replication
  • In addition to serving as the code for proteins,
    DNA also undergoes replication.
  • Replication is the duplication of DNA within a
    cell prior to cell division (occurring before
    mitosis before meiosis I)
  • The original strands of the double helix serve as
    a template for the new strands (replication is
    semi-conservative)
  • 1. The double strand of DNA unwinds and unzips.
  • 2. Then new DNA nucleotides base pair with
    those of the two original strands (C with G, and
    A with T)
  • Enzymes are involved in replication (e.g.,
    helicase and DNA polymerase)

11
DNA replication
12
Original and New -
  • T-A T-A T-A
  • A-C A-C A-C
  • C-G C-G C-G
  • C-G C-G C-G
  • T-A T-A T-A
  • G-C G-C G-C
  • G-C G-C G-C
  • A-T A-T A-T
  • T-A T-A T-A

13
Replication Animation
  • http//video.google.com/videoplay?docid-879370417
    9367037205qDNAreplicationtotal90start0num
    10so0typesearchplindex0

14
Chromosome structure.
  • DNA (about 40) associated proteins (about 60)
    chromosomes
  • Histones are the chromosomal proteins of
    eukaryotes
  • Nucleosomes are bead-like particles containing
    DNA wound around clusters of histone proteins
  • DNA can either be wound tightly (condensed) or
    relaxed (when replication or transcription are
    occurring but in different ways)

15
Chromosome Structure
16
  • Mitosis
  • (Chapter 12)

17
Background information
  • Mitosis is a part of the cell cycle when the
    chromosomes of a cell (parent cell) divide
    followed by cytokinesis forming two identical
    daughter cells.
  • Meiosis is the two stage (two divisions Meiosis
    I and Meiosis II) process whereby four (or in
    some cases only one) daughter cells receive ½ of
    the chromosomes of the parent cell. It is a
    special process that occurs in the formation of
    the sex cells or gametes in sexually reproducing
    organisms (animals and plants).

18
  • In eukaryotes, replication results in the
    presence of two sets of each chromosome in the
    cell. These replicated chromosomes are most
    closely attached by a structure called a
    centromere and are known as sister chromatids.

19
Sister chromatids
20
In most higher animals and plants the chromosomes
are paired
  • You have 23 pairs of chromosomes, a total of 46
    23 came from your mom 23 of them came from your
    dad. The members of these pairs are homologues.
    The two chromosomes of each pair carry genes
    controlling the same inherited characteristics.
  • After replication there will be 46 x 2 92 total
    chromosomes present in a given human cell.
    Remember that the replicates will be physically
    attached at a centromere, so that it will still
    look like you have only 46 chromosomes
  • In humans and other animals, there are two types
    of chromosomes
  • sex chromosomes which differ between the males
    and females of species
  • autosomal chromosomes or autosomes are the
    other chromosomes

21
Normal human (male) karyotype
22
Normal human female karyotype
23
Before the tech pairs the chromosomes
24
  • If an organism has two pairs of chromosomes, then
    this organism is said to be diploid (2n). If an
    organism or a cell (like our gametes) has only
    one set of unpaired chromosomes, then that
    organism or cell is said to be haploid (n). Some
    organisms are triploid, tetraploid (or just plain
    polyploid meaning many sets).

25
  • The gametes (in human sperm and ova) are haploid
    (in humans n 23 chromosomes) and thus when
    fertilization or syngamy occurs the diploid
    number is restored in the diploid zygote.
  • Germ cells are those that undergo meiosis and
    somatic cells (non reproductive cells) are those
    that divide only by mitosis.

26
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27
Mitosis
  • Mitosis can be divided into phases based on the
    appearance of the chromosomes through a compound
    light microscope. However, Interphase is the
    period of time before mitosis begins. During
    this phase the chromatin is spread out and is not
    visible using a compound light microscope. The
    nucleus and nucleolus are visible and DNA
    replication occurs. The actual phases of mitosis
    are as follows

28
Prophase
  • chromosomes shorten thicken become visible
    using a compound light microscope. The sister
    chromatids are attached at the centromeres.
  • The nuclear membrane breaks down and the nucleoli
    disappear.
  • In animals, the centrioles move to the opposite
    ends of the cell
  • Spindle fibers begin to form and attach to the
    kinetochore .
  • The nucleolus (or nucleoli) disappear

29
Metaphase
  • The chromosomes line up at the equator (or
    metaphase plate) of the cell (note the
    arrangement and compare it to Metaphase I of
    meiosis)
  • The spindles are complete and the centrioles are
    at the opposite poles of the cell.
  • The kinetochores attach the chromosomes to the
    mitotic spindle

30
Anaphase
  • The centromeres separate because the kinetochore
    microtubules shorten.
  • The sister chromatids separate and are pulled
    toward the opposite poles
  • The polar microtubules elongate preparing the
    cell for cytokinesis

31
Telophase
  • The sister chromatids have reached the opposite
    ends of the cell
  • The nuclear membranes form around each set of
    chromosomes and the nucleolus (or nucleoli)
    reappear
  • In most cases, the cytoplasm begins to divide
  • The chromosomes become less tightly coiled.
  • Kinetochores disappear

32
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33
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34
Mitosis in a Plant cell
35
Mitosis in an Animal cell
36
Mitosis animation
  • http//video.google.com/videosearch?qmitosishle
    nsitesearch

37
  • MEIOSIS

38
  • Like mitosis, meiosis can also be divided into
    phases, but it is more complex than mitosis.
    Meiosis involves two stages.
  • Be able to compare and contrast mitosis and
    meiosis.
  • The process involves

39
Prophase I (lasts longer and is more complex
than prophase of mitosis in fact it is divided
into five stages, but we will not cover them)
  • The chromosomes shorten thicken become
    visible using a compound light microscope
  • The nuclear membrane breaks down
  • In animals, the centrioles move to the opposite
    ends of the cell
  • Spindle fibers appear
  • The homologues pair up (remember these are not
    the same as sister chromatids which are already
    paired up). Crossing over or synapsis occurs.
    This process involves the swapping of DNA between
    the homologues. It is an important source of
    variation

40
Metaphase I
  • The chromosomes line up at the equator of the
    cell, but the homologues not the sister
    chromatids are arranged toward the opposite ends
    of the cell.
  • The spindles are attached to the homologues

41
Anaphase I
  • The chromosomes begin to separate
  • But, the homologues, not the sister chromatids
    are pulled apart

42
Telophase I
  • Now the homologues are positioned at the opposite
    ends of the cell
  • In some organisms, nuclear membranes reform
  • Cytokinesis

43
Prophase II
  • If the chromsomes lengthened, after cytokinesis
    they now shorten again

44
Metaphase II
  • Spindles form and attach
  • the chromosomes line up. Note the arrangement

45
Anaphase II
  • Now the sister chromatids separate

46
Telophase II
  • Now the sister chromatids of half of the original
    number of chromosomes are present in each of the
    haploid nuclei
  • Nuclear membranes form

47
  • Be able to compare and contrast mitosis and
    meiosis. See and know figure 13.9.

48
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49
Spermatogenesis
50
Oogenesis
51
(No Transcript)
52
  • http//video.google.com/videoplay?docid1107883966
    519514525qmeiosistotal160start0num10so0
    typesearchplindex0
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