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DNA to Protein – 12 Part one. AP Biology. What is a Gene?. A gene is a sequence of DNA that contains the information or the code for a protein or an RNA What is a code? A code is a molecular message in the language of DNA or RNA that instructs the cell how to make a protein or a
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DNA to Protein – 12Part one AP Biology
What is a Gene? • A gene is a sequence of DNA that contains the information or the code for a protein or an RNA • What is a code? A code is a molecular message in the language of DNA or RNA that instructs the cell how to make a protein or a RNA molecule
What is the code? • The code is written with the DNA alphabet of A,T,C, and G’s • The words of DNA are in groups of three bases called triplets
Genes • It had been estimated that because there are 100,000 proteins that there must be 100,000 genes • The Genome Project has revealed that there are actually less than 50,000 probably between 30,000 and 40,000
The Early Concept of a Gene • In the 1940s, Beadle and Tatum showed that when an altered gene resulted in an altered phenotype, that altered phenotype always showed up as an altered enzyme.
Wild type vs. mutant • The normal enzyme is referred to as the wild type • An altered enzyme is referred to as a mutant and reflects a change in the genetic message to make the protein
The Experiment That Demonstrated the Relationship Between Gene and Protein
A Biochemical Pathway • The pathway requires three enzymes to produce the product • Each enzyme is a protein coded for by a gene
What is Gene Expression • When the code of the gene is read and translated from the language of nucleic acids to the language of proteins( from bases to amino acids)
The structure of a gene -100bp -40bp -30bp start GENE stop GCGCGC CCAAT TATA BOX 3’ TAC EXON! AT INTRON CG EXON ATT5’
Transcription • The process of making a copy of messenger RNA complementary to the DNA strand • The molecule that copies the DNA is a RNA Polymerase • RNA polymerase reads 3’-5’ and makes the RNA 5’---------3’
RNA Polymerase • Looks for the signals of the CAT BOX • Sees the TATA • Binds to the promoter( conserved or similar in eukaryotes) • Transcription begins with 3’TAC
Messenger RNA is made continuously • Messenger RNA is made by the transcription of the bases in DNA into an RNA sequence • This is called the primary sequence • This sequence includes the introns and the exons • As the m RNA( primary transcript) is made it is edited by a complex
Termination • When the one of the three stop messages are reached the process of transcription ends • The three stop messages are ATC 3’ ATT 3’ ACT 3’
RNA • The first two steps of processing pre-mRNA take place in the nucleus: • The G cap, a modified GTP, is added to the 5¢ end. It facilitates the binding of mRNA to the ribosome and protects the mRNA from being digested by ribonucleases. • A poly A tail is added to the 3¢ end. It is 100 to 300 residues of adenine (poly A) in length.
RNA Splicing • RNA splicing removes the introns and splices the exons together: • At the boundaries between introns and exons are consensus sequences. • A small ribonucleoprotein particle (snRNP) binds to the consensus sequence at the 5¢ exon–intron boundary. • Another snRNP binds near the 3¢ exon–intron boundary. • Then other proteins bind, forming a large RNA–protein complex called a spliceosome. This complex cuts the RNA, releases the introns, and joins the ends of the exons.
Spliceosome • The spliceosome edits the messenger RNA transcript • It works with small RNAs • This removes the introns by recognizing the intron border • The exons are connected and the code for the protein is now continuous
Figure 14.10 The Spliceosome, an RNA Splicing Machine (Part 1) Spliceosome and snurps I