Deoxyribonucleic Acid - DNA  Found primarily in the nucleus in chromosomes - stores and transmit information to make proteins.  Structure Consists of.

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Presentation transcript:

Deoxyribonucleic Acid - DNA  Found primarily in the nucleus in chromosomes - stores and transmit information to make proteins.  Structure Consists of two strands of nucleotide monomers Parts of a nucleotide Deoxyribose - 5-carbon sugar Phosphate group Nitrogen base

 Purine - nitrogen base with a double ring of carbon and nitrogen atoms. Adenine Guanine  Pyrimidine - nitrogen base having a single ring of carbon and nitrogen atoms. Thymine Cytosine

Two strands of nucleotides twist around a central axis to form a double helix First described by Watson and Crick in Similar to a twisted ladder Sides of alternating sugar and phosphate Rungs consist of pairs of nitrogen bases - equal in length. Purine always pairs with a pyrimidine -have hydrogen bonds. Adenine bonds with thymine Guanine bonds with cytosine

 Base sequence one strand is exact complement of base sequence in second strand. 1st Strand Sequence A - G - C - T - T - A - G - C 2nd Strand Sequence T - C - G - A - A - T - C - G

Replication Process of duplicating the DNA molecule Each strand serves as a template or mold for new complementary strand to be built.

Process of Replication  DNA helicase attaches to DNA molecule - "unzips" the 2 strands - breaks hydrogen bonds between bases.  Unpaired bases of strands react with complementary bases of nucleotides in nucleus - hydrogen bonds form.  DNA polymerase catalyzes formation of sugar to phosphate bonds - connect one nucleotide to the next.  Result - two new DNA molecules - each consists of 1 "old" strand and 1 "new" strand.  Process doesn't begin at one end and proceed to the other - may occur simultaneously at many points.

DNA may be damaged by body heat, radiation, chemicals, etc. Cell can "proofread" for mistakes Can be repaired and corrected

Ribonucleic Acid – RNA  Nucleic acid that uses information stored in DNA to synthesize proteins.  Structure Consists of a single strand of nucleotide monomers. Parts of nucleotide Ribose - 5-carbon sugar Phosphate group Nitrogen base

Nitrogen bases of RNA  Purines Adenine Guanine  Pyrimidines Uracil Cytosine

RNA differs from DNA in 3 ways  RNA consists of only one strand of nucleotides instead of the 2 strands of DNA.  RNA contains the 5-carbon sugar, ribose, instead of deoxyribose  RNA contains the nitrogen base, uracil, instead of thymine.

Types of RNA  Messenger RNA (mRNA) - single, uncoiled strand, transmits information from DNA for protein synthesis; acts as template for amino acid assembly during protein synthesis at ribosomes.  Transfer (tRNA) - single strand of RNA folded back on itself in hairpin fashion; allows some bases pairing; exists in 20 or more varieties each for only 1 specific type of amino acid.  Ribosomal RNA (rRNA) - globular form of RNA; major constituent of ribosomes.

Transcription  Process where mRNA is produced from the DNA - transcribed according to the information coded in the base sequence of DNA. Base sequence of mRNA complementary to sequence of DNA from which it was transcribed. Directed by enzyme, RNA polymerase  Process Enzyme binds to DNA causing strands to separate. Hydrogen bonds to form between DNA template and complementary RNA nucleotide bases. Enzyme moves to next section of DNA, bonds form between phosphate groups and ribose. RNA molecule released when enzyme reaches DNA sequence that acts as a termination signal.

Protein Synthesis  Structural and functional characteristics of proteins are determined by the sequence of amino acids in the protein  Sequence of amino acids in a protein encoded in DNA  Genetic Code - System that contains information needed by cells for proper functioning; built into the arrangement of nitrogen bases in a particular sequence of DNA. Codon - series of three bases in mRNA that codes for a specific amino acid. Anticodon - series of three bases in tRNA, complementary to a codon; pairs with the codon during translation

Translation - process where protein molecules are made from information encoded in mRNA.  mRNA moves out of nucleus through a nuclear pore  mRNA migrates to a group of ribosomes  Amino acids in the cytoplasm are transported to the ribosomes by tRNA - each specific for an amino acid.  Assembly of polypeptide begins when A - U - G codon attaches to the ribosome.  Codon pairs with its anticodon adding specific amino acid to the growing polypeptide chain.  Process continues until a "stop" codon reaches the ribosome.  mRNA is released and polypeptide is complete and released

Gene - region of DNA that directs the formation of a polypeptide.  Proteins usually consist of more than one polypeptide.  Several genes may direct protein synthesis

Process by which cells reproduce.  Cell Theory Cell is basic unit of life Living things are made of cells or cell fragments. All cells come form existing cells.  Reasons Cells Divide Maintenance Repair Growth Reproduction

Nucleus  Organelle that directs the everyday metabolic activities of the cell.  Composed of Chromatin Normally - grainy mass of material During cell division appear as bodies called chromosomes. Composed of DNA and protein Carries the "genetic code" Individual heredity units are genes - determine cell characteristics and how cell functions - by proteins that are synthesized.  Each time the cell divides the genetic material must be replicated – makes exact copy Must then be distributed to the new cell. Replication occurs during interphase.

Chromosome Number  The number of chromosomes found in the nucleus. Varies from one organism to another. Man - 46 Fruit Fly - 8 Bullfrog - 26  All cells of an organism will have the same number of chromosomes. Exception is the sex cells or Gametes Egg - female Sperm - male  Body cells called Somatic Cells or Somates.

Humans 23 pairs of chromosomes - total of 46 chromosomes.  Pairs of chromosomes are known as being Homologous. Individual members of the pair are called Homologs. Get one homolog of each pair from each parent Each homolog of pair has same size and shape.  Number of pairs of chromosomes in a somate is expressed as "n" - total number of chromosomes expressed as "2n" Humans: n = 23; 2n = 46  Total number of chromosomes is Diploid Number = 2n  Total number of different pairs in cell is its Haploid Number (Monoploid) = n  Features of the cell's chromosomes including size and number make up cell's Karyotype - arranged by size and shape.

Actually talking about division of nuclear material  Two types of nuclear division Mitosis Meiosis  Cytokinesis - division of the cytoplasm

Process by which the nucleus divides to produce 2 new nuclei, each with the same number of chromosomes as the parent nucleus. From the Greek - Mitos - Thread Occurs in somatic cells.  Requirements Precise replication of the genetic material Distribution of a complete set of chromosomes to each new cell - called Daughter Cells  Five Phases of Cell Cycle - continuous Interphase Prophase Metaphase Anaphase Telophase

Interphase – not really a part of mitosis  Once called the "resting" stage  Cell performing various metabolic activities  Occupies about 2/3 of cell's life cycle  Genetic material replicates during phase.  Nucleus clearly defined by membrane  Chromosomes not visible - chromatin appears grainy.  Consists of 3 subphases G1 Phase - first phase of interphase; cell doubles in size; enzymes and organelles,roughly double in size. S Phase - DNA in the chromatin replicates G2 Phase - Cell undergoes rapid growth that prepares it for mitosis, synthesizing necessary enzymes and structures.

Prophase  Early prophase - chromatin coils; forms chromosomes.  Chromosomes appear as rod-like structures.  Nucleolus and nuclear membrane breakdown and disappear.  Centrioles appear next to the disappearing nucleus - move to opposite ends or poles of cell (not plants).  Spindle fibers form - asters radiate from centrioles in animal cells.  Chromosomes appear as double stranded structure Each strand is a Chromatid Two chromatids are joined at a Centromere.

Metaphase  Chromosomes arrange themselves on equator of spindle  Chromosomes attach to spindle fibers at the centromere.  Centromeres aligned on the equator.

Anaphase  Centromere divides - one chromatid moves toward 1 pole of spindle while other chromatid moves to the opposite pole.

Telophase  Two identical sets of chromatids are clustered at opposite ends of the cell.  Centrioles and spindle fibers disappear.  Chromatids unwind and elongate into chromatin - chromosomes disappear  Nuclear membrane and nucleolus reappear.

 Process completed with cytokinesis - get two distinct cells Animals – Cleavage Furrow forms from outside toward the center – pinches cell in two. Plants – Cell Plate forms from center and grows to the outside.  No reduction in chromosome number Parent Cell = 2n ----> Each Daughter Cell = 2n

Process by which the cell nucleus divides resulting in a reduction of chromosome number from the diploid number (2n) to the haploid number (n)  Involves 2 divisions Chromosome number reduced in first division - Meiosis I Second division - mitotic - Meiosis II  Cell division that results in formation of gametes or sex cells. Occurs in the Gonads (sex organs) Ovary - female Testes - male Process in males - called Spermatogenesis Process in females - called Oogenesis

Phases  Interphase  Prophase I  Metaphase I  Anaphase I  Telophase I  Prophase II  Metaphase II  Anaphase II  Telophase II

Interphase - same as in mitosis  Chromosomes replicate

Prophase I  DNA strands coil, shorten, and thicken- Chromosomes become visible.  Nuclear membrane disappears, spindle fibers appear.  Homologous pairs of chromosomes move together - Homologs pair Pairing movement is called Synapsis Two double stranded chromosomes are so close they appear to be joined at their centromeres. Looks like 4 chromatids connected – group called a Tetrad. Crossing Over of chromatids may occur during synapsis

Metaphase I  Tetrads align on the equator of the cell  Have 2 chromosomes with 4 chromatids attached to single spindle fiber.

Anaphase I  Homologous pairs of chromosomes separate - one chromosome of the pair goes to each pole - centromeres do not divide.  Each chromosome still consists of 2 chromatids joined by a centromere.

Telophase I  Cytoplasm divides to form 2 daughter cells.  Nuclear membrane begins to reappear, double stranded chromosomes disappear; spindle may disappear.  Each daughter cell contains one half the original number of chromosomes that parent cell had.  Cells may enter resting state – Interkinesis

Prophase II  No further replication of DNA occurs  Spindle reappears; chromosomes reappear

Metaphase II  Chromosomes move to cell's equator.  Centromere attaches to spindle fiber.  Each chromosome composed of sister chromatids joined at centromere.

Anaphase II  Centromere joining chromatids divides.  Each chromatid moves toward the opposite pole.

Telophase II  Spindle disappears  Nuclear membrane forms around chromosomes of each daughter cell.  Each of the 4 cells formed from the original parent cell has 1/2 the number of chromosomes of the parent.

Summary  First Meiotic Division - produces 2 haploid cells; double stranded chromosomes.  Second Meiotic Division - 2 haploid cells divide to produce 4 haploid cells.  4 haploid cells can develop into gametes.

 Spermatogenesis - Production of sperm  Oogenesis - Production of egg

Cells at the end of Prophase I  Male - Primary Spermatocyte – at puberty  Female - Primary Oocyte - formed as early as 3rd month of development - meiosis stops until sexual maturity

Two cells at the end of Telophase I  Male - secondary spermatocyte  Female - cells unequal - 1 secondary oocyte, 1 polar body

Cells at end of Telophase II  Male - 4 haploid cells – Spermatids  Female - 1 Ootid and 3 Polar Bodies (die) - ootid has most of the cytoplasm.

 Spermatids - mature to form sperm  Ootid - matures to form egg.

Importance  Ensures that chromosome number remains constant in sexual reproduction  Egg (n) + Sperm (n) -- Fertilization --> Zygote (2n)  Chromosome number of zygote is thus the same as the two parents.

Asexual - production of offspring from one parent  No fusion of gametes  Offspring is identical to parent.  Occurs due to mitosis.  No genetic variation between parent and offspring

Sexual - production of offspring through meiosis and subsequent fusion of gametes from two parents  Offspring is different from either parent  Half of genetic material has come from one parent; other half has come from the other parent.  Introduces variation between the parents and offspring.