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CH 25. Monomer of Nucleic Acids A molecular complex of three types of subunit molecules 1.Phosphate 2.Pentose sugar 3.Nitrogen-containing base NUCLEOTIDES.

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Presentation on theme: "CH 25. Monomer of Nucleic Acids A molecular complex of three types of subunit molecules 1.Phosphate 2.Pentose sugar 3.Nitrogen-containing base NUCLEOTIDES."— Presentation transcript:

1 CH 25

2 Monomer of Nucleic Acids A molecular complex of three types of subunit molecules 1.Phosphate 2.Pentose sugar 3.Nitrogen-containing base NUCLEOTIDES

3 DNA (deoxyribonucleic acid) Stores genetic material Codes for the order in which AA are joined to form a protein RNA (ribonucleic acid) Conveys DNA’s instructions regarding the amino acid sequence in a protein 3 types: 1.Messenger RNA 2.Ribosomal RNA 3.Transfer RNA NUCLEIC ACIDS

4 DNARNA Sugar DeoxyriboseRibose Bases Adenine, Guanine, Thymine, Cytosine Adenine, Guanine, Uracil, Cytosine Strands Double Stranded (with base pairing) Single Stranded Helix YesNo NUCLEIC ACIDS

5 DNA is double-stranded with complementary base pairing A-T C-G DNA STRUCTURE

6 Purines: Adenine and Guanine Two rings Found in DNA and RNA Pyrimidines: Cytosine, Thymine, Uracil One ring Cytosine found in DNA and RNA Thymine found in DNA only Uracil found in RNA only NUCLEOTIDES

7 In the mid-1900s, scientists knew that chromosomes, made up of DNA (deoxyribonucleic acid) and proteins, contained genetic information. However, they did not know whether the DNA or the proteins was the actual genetic material. HISTORY

8 Various researchers showed that DNA was the genetic material when they performed an experiment with a T 2 virus. By using different radioactively labeled components, they demonstrated that only the virus DNA entered a bacterium to take over the cell and produce new viruses. HISTORY

9 VIRAL DNA IS LABELED

10 VIRAL CAPSID IS LABELED

11 The structure of DNA was determined by James Watson and Francis Crick in the early 1950s. They deduced the following: DNA has a twisted, ladder-like structure (double helix) The sugar-phosphate molecules make up the sides of the ladder and the bases make up the rungs Since A bonds with T and G with C, the rungs have a constant width (purine paired with a pyrimidine) DNA STRUCTURE

12 BASE PAIRING

13 TWO DNA STRANDS ARE ANTI-PARALLEL – THEY RUN IN OPPOSITE DIRECTIONS.

14 DNA replication occurs during chromosome duplication; an exact copy of the DNA is produced with the aid of DNA polymerase (an enzyme) Hydrogen bonds between bases break and enzymes “ unzip ” the molecule. Each old strand of nucleotides serves as a template for each new strand. REPLICATION

15 New nucleotides move into complementary positions are joined by DNA polymerase. The process is semiconservative because each new double helix is composed of an old strand of nucleotides from the parent molecule and one newly-formed strand. REPLICATION

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17 LADDER CONFIGURATION & DNA REPLICATION

18 1.‘DNA: Structure, function and replication’ - WS 2.‘DNA’ notes booklet 3.‘Protein Synthesis’ – WS 4.CH 2 Review Q’s TO WORK ON:

19 25.2

20 A gene is a segment of DNA that specifies the amino acid sequence of a protein. Gene expression occurs when gene activity leads to a protein product in the cell. A gene does not directly control protein synthesis; instead, it passes its genetic information on to RNA, which is more directly involved in protein synthesis. GENE EXPRESSION

21 Bases: Adenine-Uracil, Cytosine-Guanine Types: 1.Messenger RNA (mRNA): takes message from DNA to ribosome 2.Ribosomal RNA (rRNA): along with proteins, makes up the ribosomes – where proteins are synthesized 3.Transfer RNA (tRNA): transfers amino acids to the ribosomes RNA

22 RNA STRUCTURE

23 1.Transcription: makes an RNA molecule complementary to a portion of DNA 2.Translation: occurs when the sequence of bases of mRNA directs the sequence of amino acids in a polypeptide PROTEIN SYNTHESIS

24 DNA specifies the synthesis of proteins because it contains a triplet code: every three bases stand for one amino acid. Each three-letter unit of an mRNA molecule is called a codon. Most amino acids have more than one codon; there are 20 amino acids with a possible 64 different triplets. The code is nearly universal among living organisms. THE GENETIC CODE

25 MRNA CODONS

26 GENE EXPRESSION

27 During transcription in the nucleus, a segment of DNA unwinds and unzips, and the DNA serves as a template for mRNA formation. RNA polymerase joins the RNA nucleotides so that the codons in mRNA are complementary to the triplet code in DNA. TRANSCRIPTION

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29 DNA contains exons and introns. Before mRNA leaves the nucleus, it is processed and the introns are excised so that only the exons are expressed. The splicing of mRNA is done by ribozymes, organic catalysts composed of RNA, not protein. Primary mRNA is processed into mature mRNA. PROCESSING OF MRNA

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31 Translation is the second step by which gene expression leads to protein synthesis. During translation, the sequence of codons in mRNA specifies the order of amino acids in a protein. Translation requires several enzymes and two other types of RNA: transfer RNA and ribosomal RNA. TRANSLATION

32 During translation, transfer RNA (tRNA) molecules attach to their own particular amino acid and travel to a ribosome. Through complementary base pairing between anticodons of tRNA and codons of mRNA, the sequence of tRNAs and their amino acids form the sequence of the polypeptide. TRNA

33 TNA: AMINO ACID CARRIER

34 Ribosomal RNA, also called structural RNA, is made in the nucleolus. Proteins made in the cytoplasm move into the nucleus and join with ribosomal RNA to form the subunits of ribosomes. A large subunit and small subunit of a ribosome leave the nucleus and join in the cytoplasm to form a ribosome just prior to protein synthesis. RRNA

35 A ribosome has a binding site for mRNA as well as binding sites for two tRNA molecules at a time. As the ribosome moves down the mRNA molecule, new tRNAs arrive, and a polypeptide forms and grows longer. Translation terminates once the polypeptide is fully formed; the ribosome separates into two subunits and falls off the mRNA. Several ribosomes may attach and translate the same mRNA, therefore the name polyribosome. RIBOSOMES

36 POLYRIBOSOME

37 During translation, the codons of an mRNA base-pair with tRNA anticodons. Protein translation requires these steps: 1)Chain initiation 2)Chain elongation 3)Chain termination. Enzymes are required for each step, and the first two steps require energy. TRANSLATION: 3 STEPS

38 During chain initiation, a small ribosomal subunit, the mRNA, an initiator tRNA, and a large ribosomal unit bind together. First, a small ribosomal subunit attaches to the mRNA near the start codon. The anticodon of tRNA, called the initiator RNA, pairs with this codon. Then the large ribosomal subunit joins. CHAIN INITIATION

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40 The initiator tRNA passes its amino acid to a tRNA-amino acid complex that has come to the second binding site. The ribosome moves forward and the tRNA at the second binding site is now at the first site, a sequence called translocation. The previous tRNA leaves the ribosome and picks up another amino acid before returning. CHAIN ELONGATION

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42 Chain termination occurs when a stop-codon sequence is reached. The polypeptide is enzymatically cleaved from the last tRNA by a release factor, and the ribosome falls away from the mRNA molecule. A newly synthesized polypeptide may function alone or become part of a protein. CHAIN TERMINATION

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44 DNA in the nucleus contains a triplet code; each group of three bases stands for one amino acid. During transcription, an mRNA copy of the DNA template is made. The mRNA is processed before leaving the nucleus. The mRNA joins with a ribosome, where tRNA carries the amino acids into position during translation. REVIEW

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46 A gene mutation is a change in the sequence of bases within a gene. MUTATIONS

47 Frameshift mutations involve the addition or removal of a base during the formation of mRNA; these change the genetic message by shifting the “ reading frame. ” FRAMESHIFT MUTATION

48 The change of just one nucleotide causing a codon change can cause the wrong amino acid to be inserted in a polypeptide; this is a point mutation. In a silent mutation, the change in the codon results in the same amino acid. If a codon is changed to a stop codon, the resulting protein may be too short to function; this is a nonsense mutation. If a point mutation involves the substitution of a different amino acid, the result may be a protein that cannot reach its final shape; this is a missense mutation. An example is Hb s which causes sickle-cell disease. POINT MUTATIONS

49 SICKLE CELL DISEASE

50 Mutations can be spontaneous or caused by environmental influences called mutagens. Mutagens include radiation (X-rays, UV radiation), and organic chemicals (in cigarette smoke and pesticides). DNA polymerase proofreads the new strand against the old strand and detects mismatched pairs, reducing mistakes to one in a billion nucleotide pairs replicated. CAUSE & REPAIR OF MUTATIONS

51 Transposons are specific DNA sequences that move from place to place within and between chromosomes. These so-called jumping genes can cause a mutation to occur by altering gene expression. It is likely all organisms, including humans, have transposons. TRANSPOSONS: JUMPING GENES


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