GENETIC CONTROL OF PROTEIN SYNTHESIS, CELL FUNCTION, AND CELL REPRODUCTION PART 1.

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Presentation transcript:

GENETIC CONTROL OF PROTEIN SYNTHESIS, CELL FUNCTION, AND CELL REPRODUCTION PART 1

OBJECTIVES 1. DISCUSS THE GENETIC CONTROL AND PROCESSES (TRANSCRIPTION, TRANSLATION) INVOLVED IN PROTEIN SYNTHESIS 2. DISCUSS THE GENETIC CONTROL AND ENZYMATIC MECHANISMS OF REGULATING BIOCHEMICAL ACTIVITIES OF THE CELL

DNA (genes) RNA Proteins Cell function Structural Enzymes CENTRAL DOGMA OF MOLECULAR BIOLOGY Figure 3-2

GENES & CHROMOSOMES DID YOU KNOW THAT IF YOU UNWRAP ALL OF THE DNA IN ALL OF YOUR CELLS AND LINED IT UP END-TO-END, YOU COULD REACH THE MOON AND BACK OVER 3000 TIMES?

DNA ONLY ABOUT 2-3% OF ALL THAT DNA ACTUALLY CODES FOR TRAITS INSIDE OUR BODIES. THOSE IMPORTANT PARTS ARE CALLED GENES GENES: A DNA SEGMENT SEQUENCES THAT CODE FOR MANY DIFFERENT TRAITS DNA HAS THOUSANDS OF GENES (ESTIMATED 20,000 TO 25,000 GENES IN THE HUMAN GENOME) THE AVERAGE GENE IS 10,000 TO 15,000 BASE PAIRS LONG

WHERE TO PUT ALL THAT DNA? WONDERING HOW 5 ½ FEET OF DNA FIT INTO EACH ONE OF YOUR TINY CELL NUCLEI?? THEY ARE PACKED NEATLY INTO STRUCTURES CALLED CHROMOSOMES CHROMOSOME: DNA AND PROTEINS COILED TOGETHER Histones

GENES NUCLEIC ACID (DEOXYRIBONUCLEIC ACID) CONTROLS FUNCTION OF RNA (RIBONUCLEIC ACID) RNA SPREADS THROUGHOUT CELL TO CONTROL FORMATION OF SPECIFIC PROTEIN

GENES CONTROLS HEREDITY CONTROLS SUBSTANCES SYNTHESIZED STRUCTURES ENZYMES CHEMICALS

DNA IS THE MOST IMPORTANT MOLECULE FOR LIFE CONTROLS ALL TRAITS CANNOT FUNCTION WITHOUT IT DETERMINES MANY HAIR COLOR DISEASE IMPORTANT: ALL CELLS IN THE BODY HAS THE ENTIRE DNA CODE CSI: PLAYING DETECTIVE--- HAIR FOLLICLE, SAMPLES GENE REGULATION: NOT ALL DNA ARE TURNED ON ALL THE TIME

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THE ORGANIZATION OF THE DNA CHROMOSOMES MADE UP OF DNA & PROTEIN IN THE NUCLEI, THERE ARE 46 CHROMOSOMES HAS TO BE DUPLICATED BEFORE DIVISION DNA IS ORGANIZED IN CHROMOSOMES

CHROMOSOME = DNA + HISTONE HISTONES ACT AS GLUE BALLS TO HOLD THE DNA TIGHTLY WOUND TOGETHER

DNA TURNING TO CHROMOSOME

PARTS OF A CHROMOSOME CHROMATID: ½ OF A CHROMOSOME– TWO CHROMATIDS MAKE UP A CHROMOSOME CHROMATIDS ARE IDENTICAL COPIES (ORIGINAL + COPY) CENTROMERE: ATTACHMENT POINT OF SISTER CHROMATIDS

NUCLEOTIDE SMALLEST UNIT OF DNA 3 COMPONENTS DEOXYRIBOSE SUGAR PHOSPHATE GROUP 4 NITROGENOUS BASES PURINES: GUANINE & ADENINE PYRIMIDINES: THYMINE & CYSTOSINE

THE BASES ARE IN EACH SIDE OF THE HELIX ADENINE GUANINE THYMINE CYSTOSINE

BASIC BUILDING BLOCKS OF DNA BASIC CHEMICAL COMPOUNDS INVOLVED IN THE FORMATION OF DNA. (1) PHOSPHORIC ACID (2) DEOXYRIBOSE (A SUGAR) (3) FOUR NITROGENOUS BASES TWO PURINES, ADENINE AND GUANINE, TWO PYRIMIDINES, THYMINE AND CYTOSINE THE PHOSPHORIC ACID AND DEOXYRIBOSE FORM THE TWO HELICAL STRANDS THAT ARE THE BACKBONE OF THE DNA MOLECULE, AND THE NITROGENOUS BASES LIE BETWEEN THE TWO STRANDS AND CONNECT THEM

HOW THE DNA FITS DNA IS FOLDED AND WRAPPED VERY TIGHTLY AROUND PROTEIN CALLED HISTONES AS THE DNA AND PROTEINS COIL TOGETHER, THEY FORM BEAD LIKE STRUCTURES CALLED NUCLEOSOMES. THEY ALLOW EVEN MORE OF THE DNA TO BE WRAPPED AND FOLDED UP AS THE NUCLEOSOMES PACK TOGETHER, THEY FORM THICK COILED FIBERS CALLED CHROMATIN

WHEN THE CHROMATIN COILS TOGETHER EVEN MORE, YOU GET SUPER COILS OF DNA THESE COILS ARE KNOWN AS CHROMOSOMES

EVERY TIME THE DNA IS COPIED, TELOMERES (THE ENDS OF THE DNA) GET SMALLER, TELOMERASE KEEPS THE TELOMERES ON (PREVENTS IT FROM GETTING SMALLER) IF TELOMERES GET TOO SMALL, DNA CANNOT BE COPIED ANYMORE AND THE CELL DIES

DNA REPLICATION IS THE COPYING OF DNA IN PREPARATION FOR CELL DIVISION (MITOSIS) SEMI-CONSERVATIVE REPLICATION MODEL ONE MOLECULE WILL SPLIT IN HALF, AND EACH HALF WILL ACT AS A TEMPLATE TO BUILD ITS COMPLEMENTARY STRAND

HOW DNA REPLICATION OCCURS USES A SERIES OF ENZYMES TO START AND RUN REPLICATION DNA HELICASE UNZIPS THE MOLECULE BY BREAKING THE HYDROGEN BONDS BETWEEN NITROGEN BASES DNA POLYMERASE ADDS BASES AND THEN REMOVES THE RNA PRIMERS

NUCLEOTIDE THE FIRST STAGE OF DNA FORMATION: COMBINE ONE MOLECULE OF PHOSPHORIC ACID, ONE MOLECULE OF DEOXYRIBOSE, AND ONE OF THE FOUR BASES BASE ADENINE THYMINE GUANINE CYTOSINE THIS FORMS THE NUCLEOTIDES (ONE FOR EACH OF THE FOUR BASES)

DNA STRAND PHOSPHATE SUGAR ADENINE PHOSPHATE SUGAR GUANINE PHOSPHATE SUGAR THYMINE SUGAR PHOSPHATE SUGAR PHOSPHATE SUGAR THYMINE CYSTOSINE ADENINE HYDROGEN BONDS

BASES HAVE TO BE PAIRED CORRECTLY IF MISMATCHED= MUTATION “ A PPLES IN THE T REE, C AR IN THE G ARAGE” ADENINE TO THYMINE CYSTOSINE TO GUANINE

GENETIC CODE ABILITY OF THE DNA TO CONTROL THE FORMATION OF PROTEINS TWO STRANDS OF DNA MOLECULE ARE SPLIT APART PURINE AND PYRIMIDINE BASES PROJECTING TO THE SIDE OF EACH DNA ARE EXPOSED THESE PROJECTING BASES THAT FORM THE GENETIC CODE

GENETIC CODE DNA-CONTROLS FORMATION OF PROTEINS BY MEANS OF A GENETIC CODE CODE CONSISTS OF TRIPLETS (CODONES) -CODE WORD CODONES WILL CONTROL THE SEQUENCE OF AMINO ACIDS CODE TRANSFERRED TO THE RNA IN PROCESS CALLED TRANSCRIPTION

TRANSFER OF CODE TO RNA DNA IS IN NUCLEUS CODE IS TRANSFERRED TO ANOTHER NUCLEIC ACID—RNA IN PROCESS CALLED TRANSCRIPTION COMPLIMENTARY CODONES IN THE RNA

FORMATION OF RNA NUCLEOTIDES RNA NUCLEOTIDE SIMILAR TO NUCLEOTIDES OF DNA FOUR NUCLEOTIDES ADENINE GUANINE CYTOSINE URACIL * (REPLACES THYMINE IN DNA) SINGLE STRANDED SUGAR DEOXYRIBOSE NOT USED; INSTEAD RIBOSE

ACTIVATION OF RNA NUCLEOTIDES ACTIVATED BY ENZYME RNA POLYMERASE BEGINS THE TRANSCRIPTION

FILM: GENES AND HOW THEY WORK

TYPES OF RNA RNA MRNA- COPY OF DNA RRNA- ALONG WITH PROTEINS IS WHAT MAKES UP THE RIBOSOMES (WHERE PROTEINS ARE MADE) TRNA-TRANSFER RNA. BRINGS AMINO ACIDS TO THE RIBOSOME FOR PROTEIN ASSEMBLY OTHERS PRECURSOR MESSENGER RNA SMALL NUCLEAR RNA (SNRNA) MICRORNA (MIRNA)

TRANSCRIPTION DNA & GENE USED AS TEMPLATE TO MAKE MESSENGER RNA WITH HELP OF ENZYME RNA POLYMERASE BUILDING BLOCKS OF RNA SAME AS DNA EXCEPT 1. SUGAR DEOXYRIBOSE IS NOT USED RIBOSE IS SUBSTITUTED 2. THYMINE IS REPLACED BY URACIL (ANOTHER PYRIMIDINE)

3 STAGES OF TRANSCRIPTION INITIATION ELONGATION TERMINATION

INITIATION STAGE PROMOTER REGION IS SIGNAL SITE FOR RNA POLYMERASE TO BIND THIS IS WHERE MAJORITY OF TRAIT EXPRESSION IS CONTROLLED BINDING CAUSES THE DOUBLE HELIX TO UNWIND AND OPEN

ELONGATION STAGE RNA POLYMERASE SLIDES THROUGH STRAND COMPLIMENTARY BASES PAIR UP TERMINATION STAGE POLYMERASE REACHES TERMINATOR REGION OF GENE RNA TRANSCRIPTION IS COMPLETE RNA POLYMERASE AND STRAND SEPARATE

HOW DOES A MATURE RNA TRANSCRIBE PROTEIN? THE NITROGENOUS BASES GROUPED INTO 3 LETTER CODES CALLED CODONS THE GENETIC CODE INCLUDES 64 CODONS MOST CODONS CODE FOR SPECIFIC AMINO ACIDS

DNA TRANSCRIPTION UNWINDING OF HELIX COPIES OF MRNA MRNA TO NUCLEAR PORE INSIDE RIBOSOME TRANSLATION BEGINS CHAIN OF AMINO ACIDS PACKAGED AND TRANSPORTED

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