1. MICRO. 555 (555 Microbial Molecular Genetics)�Dr.Afaf Ibrahim Shehata�Botany and Microbiology Department �King Saud University�
2. MOLECULAR GENETICS� � molecular basis of inheritance � Genes ---> Enzymes ---> Metabolism (phenotype) � Central Dogma of Molecular Biology*� DNA -transcription--> RNA -translation--> Protein� Student CD Activity - 13.2 Events Protein Synthesis: INFORMATION FLOW � �
3. What is a GENE = ? DNA is the genetic material...� [ but what about, retroviruses, as HIV & TMV, contain RNA ]� - a discrete piece of deoxyribonucleic acid� - linear polymer of repeating nucleotide monomers � nucleotides* --> A adenine, C cytosine� T thymidine, G guanine --> polynucleotide*��
4. Understanding Genetics� �INFORMATION PROCESSING & the CENTRAL DOGMA� � - the letters of the genetic alphabet... are the nucleotides A, T, G, & C of DNA� - the unit of information is CODON = genetic 'word'� a triplet sequence of nucleotides 'CAT' in a polynucleotide� 3 nucleotides = 1 codon (word) = 1 amino acid� - the definition of (codon) word = amino acid�
5. - Size of Human Genome: ˜ 3,000,000,000 base pairs or 1.5b in single strand of DNA genes� ˜ 500,000,000 possible codons (words or amino acids)� - average page your textbook = approx 850 words � thus, human genome is equal to 590,000 pages or 470 copies of bio text book� reading at 3 bases/sec it would take you about 47.6 years @ 8h/d - 7d/w� WOW... extreme nanotechnology
6. µ Mice & humans (indeed, most or all mammals including dogs, cats, rabbits, monkeys, & apes)� have roughly the same number of nucleotides in their genomes -- about 3 billion bp. �
7. Experimental Proof of DNA as Genetic Material...� 1. Transformation Experiments of Fred Griffith... (1920's) � Streptococcus pneumoniae - pathogenic S strain & benign R � transforming 'principle'* (converting R to S cells) is the genetic element� � 2. Oswald Avery, Colin MacLeod, & Maclyn McCarty... (1940's)� suggest the transforming substance* is DNA molecules, but...� � 3. Alfred Hershey & Martha Chase's* 1952 bacteriophage experiments*...� VIRAL REPLICATION* [ pic 1 phage infection & pic-2* & lytic/lysogenic ] � a genetically controlled biological activity (viral reproduction)� they did novel experiment... 1st real use radioisotopes in biology*� CONCLUSION - DNA is genetic material because � (32P) nucleic acid not (35S) protein guides* viral replication� Sumanas, Inc. animation - Life cycle of HIV virus
8. Replication of DNA... (Arthur Kornberg - 1959 Nobel - died 10/26/07) � copying of DNA into DNA is structurally obvious??? [figure*] � � Patterns of Replication* = conservative, semi-conservative, & dispersive � Matt Meselson & Frank Stahl 1958 - experimental design*� can we separate 15N-DNA from 14N-DNA - (OLD DNA from NEW DNA)? � sedimentation of DNA's (sucrose gradients --> CsCl gradients* & picture*) � we can predict results... figure* & overview & all possible results � Sumanas, Inc. animation - Meselson-Stahl DNA Replications
9. DNA polymerase: enzyme that copies DNA... prokaryotic Pol I-IV eukaryotic a & d � Pol III (pic) req: 4-deoxy-NTP's & ssDNA template piece � reads template and adds a complimentary nucleotide* � reads 3' to 5' and synthesizes in 5' to 3' direction... [quicktime movie]� proofreads* & bidirectional synthesis*... & EM pic* � Replication forks - leading & lagging strands - Campbell figure* � � Arthur Kornberg - 1st to synthesize DNA in test tube, died 26 Oct 2007� �
10. � � Model of Replication is bacterial with DNA polymerase III...� � several enzymes* form a Replication Complex (Replisome) & include: � helicase - untwists DNA � topoisomerase [DNA gyrase] - removes supercoils,� single strand binding proteins - stabilize replication fork,� Primase - makes RNA primer� POL III - synthesizes new DNA strands � DNA polymerase I - removes RNA primer 1 base at a time, adds DNA bases� DNA ligase repairs Okazaki fragments (seals lagging strand 3' open holes) � � �� �
11. Structure of DNA polymerase III*� copies both strands simultaneously, as DNA is Threaded Through a Replisome*� a "replication machine", which may be stationary by anchoring in nuclear matrix� Continuous & Discontinuous replication occur simultaneously in both strands � �
12. EVENTS:� 1. DNA pol III binds at the origin of replication site in the template strand� 2. DNA is unwound by replisome complex using helicase & topoisomerase� 3. all polymerases require a preexisting DNA strand (PRIMER) to start replication,� thus Primase adds a single short primer to the LEADING strand � and adds many primers to the LAGGING strand� 4. DNA pol III is a dimer adding new nucleotides to both strands primers� direction of reading is 3' ---> 5' on template� direction of synthesis of new strand is 5" ---> 3'� rate of synthesis is substantial 400 nucleotide/sec� 5. DNA pol I removes primer at 5' end replacing with DNA bases, leaves 3' hole� 6. DNA ligase seals 3' holes of Okazaki fragments on lagging strand � the sequence and DNA Repair*�
13. Rates of DNA synthesis: myDNAi movie of replication*� native polymerase: 400 bases/sec with 1 error per 109 bases� artificial: phophoramidite method (Marvin Caruthers, U.Colorado); ssDNA synthesis� on polystyrene bead @ 1 base/300 sec with error rate of 1/100b
14. GENE Expression � the Central Dogma of Molecular Biology depicts flow of genetic information � Transcription - copying of DNA sequence into RNA� Translation - copying of RNA sequence into protein� � DNA sequence -------> RNA sequence -----> amino acid sequence� TAC AUG MET� triplet sequence in DNA --> codon in mRNA ----> amino acid in protein�
15. Information : triplet sequence in DNA is the genetic word [codon]� � � Compare Events:� Procaryotes* vs. Eucaryotes* = Separation of labor � Differences DNA vs. RNA (bases & sugars) and its single stranded� Flow of Gene Information (FIG*) - One Gene - One enzyme (Beadle & Tatum
16. Transcription - RNA polymerase � RNA*polymerase - in bacteria Sigma factor* binds promoter & initiates* copying*� [pnpase] Student CD Activity 15.1 - DNA Regulatory Regions� transcription factors* are needed to recognize specific DNA sequence [motif*], � binds to promoter DNA region [ activators & transcription factors*] * � makes a complimentary copy* of one of the two DNA strands [sense strand] � Quicktime movie of transcription* myDNAi Roger Kornberg's movie of transcription (2006 Nobel)*�
17. Kinds of RNA [table*] � tRNA - small, 80n, anticodon sequence, single strand with 2ndary structure* � function = picks up aa & transports it to ribosome � � rRNA - 3 individual pieces of RNA - make up the organelle = RIBOSOME� primary transcript is processed into the 3 pieces of� rRNA pieces (picture*) & recall structure of ribosome � � hnRNA - heterogeneous nuclear RNA : large Primary Transcript RNA� function - is the precursor of mRNA in eukaryotes � �
18. hnRNA - heterogeneous nuclear RNA : large Primary Transcript RNA� function - is the precursor of mRNA in eukaryotes � � mRNA - intermediate sizes - 100n to 400n ( split genes*) primary transcript & mRNA � function - codes for amino acid sequence were not same size?� � processing (cutting) of introns & exons* � � Splicesome splicing of eucaryotic genes* [glossary] (Sumanas, Inc. advanced animation)� � � structure of mRNA* - caps & tails � � � role of 5' CAP and Poly-A Tails* [glossary] luciferase� � summary of eukaryotic RNA processing* � � � � �
19. Other classes of RNA:� � small nuclear RNA (snRNP's) - plays a structural and catalytic role in spliceosome*� there are 5 snRNP's making a spliceosome [U1, U2, U4, U5, & U6]; � they and participate in several RNA-RNA and RNA-protein interactions � SRP (signal recognition particle) - scRNA is a component of the protein-RNA complex� that recognizes the signal sequence of polypeptides targeted to the ER - figure*� small nucleolar RNA (snoRNA) - aids in processing of pre-rRNA transcripts for� ribosome subunit formation in the nucleolus
20. micro RNA's (micro-RNA) - also called antisense RNA & interfereing RNA; c7-fig 19.9*� short (20-24 nucleotide) RNAs that bind to mRNA inhibiting it. figure* � present in MODEL eukaryotic organisms as: roundworms, fruit flies, mice, humans, & plants (arabidopsis);� seems to help regulate gene expression by controlling the timing of developmental events via mRNA action� also inhibits translation of target mRNAs. ex: siRNA --> [BARR Body*]� � TRANSLATION - Making a Protein
21. process of making a protein in a specific amino acid sequence � from a unique mRNA sequence... [ E.M. picture* ]� polypeptides are built on the ribosome (pic) on a polysome [ animation*]� � Sequence of 4 Steps in Translation... [glossary] � � 1. add an amino acid to tRNA -- > aa-tRNA - ACTIVATION*� � 2. assemble players [ribosome*, mRNA, aa-tRNA] - INITIATION*� � 3. adding new aa's via peptidyl transferase - ELONGATION*� � 4. stopping the process - TERMINATION
22. Review the processes - initiation, elongation, & termination� myDNAi real-time movie of translation* & Quicktime movie of translation � Review figures & parts: Summary fig*� [ components, locations, AA-site, & advanced animation ] � [ Nobel Committee static animations of Central Dogma
23. GENETIC CODE... � � ...is the sequence of nucleotides in DNA, but routinely shown as a mRNA code*� ...specifies sequence of amino acids to be linked into the protein � � coding ratio* - # of n's... how many nucleotides specify 1 aa� 1n = 4 singlets, 2n= 16 doublets, 3n = 64 triplets� Student CD Activity - 11.2 - Triplet Coding� � S. Ochoa (1959 Nobel) - polynucleotide phosphorylase can make SYNTHETIC mRNA� Np-Np-Np-Np <----> Np-Np-Np + Np
24. Marshall Nirenberg (1968 Nobel) - synthetic mRNA's � 5'-UUU-3' = phe U + C --> UUU, UUC, UCC, CCC� UCU, CUC, CCU, CUU� � the Genetic CODE* - 64 triplet codons [61 = aa & 3 stop codons]� universal (but some anomalies), 1 initiator codon (AUG), � redundant but non-ambiguous, and exhibits "wobble*".�
25. GENETIC CHANGE - a change in DNA nucleotide sequence � - 2 significant ways mutation & recombination
26. 1. MUTATION - a permanent change in an organism's DNA*that results in� a different codon = different amino acid sequence� Point mutation - a single to few nucleotides change... � - deletions, insertions, frame-shift mutations* [CAT]� Student CD Activity - 11.2 - Triplet Coding � - single nucleotide base substitutions* :� non-sense = change to no amino acid (a STOP codon)� UCA --> UAA ser to non� mis-sense = different amino acid � UCA --> UUA ser to leu
27. Sickle Cell Anemia* - a mis-sense mutation... (SCA-pleiotropy)� another point mutation blood disease - thalassemia � - Effects = no effect, detrimental (lethal), +/- functionality, beneficial � 2. Recombination (Recombinant DNA) newly combined DNA's that [glossary]*� can change genotype via insertion of NEW (foreign) DNA molecules into recipient cell�
28. 1. fertilization* - sperm inserted into recipient egg cell --> zygote [n + n = 2n]� 2. exchange of homologous chromatids via crossing over* = new gene combo's� 3. transformation* - absorption of 'foreign' DNA by recipient cells changes cell� 4. BACTERIAL CONJUGATION* - involves DNA plasmidsg* (F+ & R = resistance)� conjugation may be a primitive sex-like reproduction in bacteria [Hfr*] � 5. VIRAL TRANSDUCTION - via a viral vector ( lysogeny* & TRANSDUCTION* )� general transduction - pieces of bacterial DNA are � packaged w viral DNA during viral replication� restricted transduction - a temperate phage goes lytic� carrying adjacent bacterial DNA into virus particle�
29. 6. DESIGNER GENES - man-made recombinant DNA molecules�Designer Genes - Genetic Engineering - Biotechnology� RECOMBINANT DNA TECHNOLOGY...� a collection of experimental techniques, which allow for � isolation, copying, & insertion of new DNA sequences into � host-recipient cells by A NUMBER OF laboratory protocols & methodologies��
30. Restriction Endonucleases-[glossary]*... diplotomic cuts* at unique DNA sequences, � Eco-R1-figure* mostly palindromes... [Never odd or even]� ?� 5' GAATTC 3' 5' G . . . . . + AATTC 3'� 3' CTTAAG 5' 3' CTTAA . . . . G 5'� ? campbell 7/e movie*� DNA's cut this way have sticky (complimentary) ends & can be reannealed� or spliced* w other DNA molecules to produce new genes combos� and sealed via DNA ligase. myDNAi movie of restriction enzyme action
31. Procedures of Biotechnology? [Genome Biology Research]� � A. Technology involved in Cloning a Gene... [animation* & the tools of genetic analysis]� making copies of gene DNA�� 1. via a plasmid* [ A.E. fig & human shotgun plasmid cloning & My DNAi movie] �� 2. Librariesg... [ library figure* & Sumanas animation - DNA fingerprint library ]�� 3. Probesg... [ cDNAg & reverse transcriptaseg � cDNA figure* & cDNA library* ] � � 4. Polymerase Chain Reactiong & figure 20.7* & animation* + Sumanas, Inc. animation* � PCR reaction protocol & Xeroxing DNA & Taq polymerase�
32. B. Detection of a Gene... Locating a gene (or its activity) - Restriction Maps.� � 1. Restriction mapsg... via gel electrophoresis* & DNA-electropherogram*� � 2. DNA fingerprintg... CSI Miami - how to make one*� a murder case* & a rape case* + DNA prints in Health & Society & DNA Forensic Science � 3. DNA Probe Hybridizationg... to detect specific DNA with a probe fig 20.5*�
33. 4. Comparing Restriction Fragments... to a probe� Southerng Blotting fig* Sumanas, Inc. animation - DNA electrophoresis & blotting*� one can detect specific gene sequence in samples by binding to labeled probes
34. 5. DNA micro-arrays - monitor gene expression in thousands of genes & changes� by passing cDNA of the cell's mRNA over slide with ssDNA of all cell's genes;� DNA microchips are fabricated by high speed robotics akin to Intel chip making� cDNA (mRNA's) are fluorescently tagged so easy to see in slide's wells.� [microchips arrays made simultaneously by phopshoramidite method of Caruthers]� Sumanas animation - DNA chip technology* & myDNAi DNA microarrays
35. 5. Gene Sequencing - Human Genome Project �� strategy - shotgun approach* developed by Celera Genomics� random fragments are sequenced and then ordered � relative to each other via overlap & supercomputing� Student CD Activity - 16.1 - Sequencing Strategies � methodology dideoxy procedure* (development by Fred Sanger)� �
36. Surprising Size Estimates of Human Genome & figure*� NHGRI researchers* have confirmed the existence of 19,599 protein-coding genes � in the human genome and identified another 2,188 DNA segments that are� predicted to be protein-coding genes = 21,787 genes�� mtDNA & Y-chromosome DNA aid in search for our human ancestry � Practical Applications of DNA Technology - Some examples of What's been Do
37. 1. Medical... disease often involves changes in gene expression� a. disease/infection diagnosis:� PCR & labeled DNA probes from pathogens can help identify microbe types... � isolate HIV RNA --RT--> cDNA --PCR--> probe can id... AIDS infection� b. RFLP - Restriction Fragment Length Analysis - markers often inherited with disease� what is RFLP* genetic testing & polymorphism ---> RFLP markers to disease � DdeI cuts Sickle gene* (also MST II cuts Sickle Cell)
38. fragment analysis (DNA fingerprinting) also used for paternity testing � c. Gene Therapy... idea is to replace defective genes via microinjection of DNA* � requires VECTORS - fig 20.16* (patient: ADA Deficiency & Ashanti DeSilva update)� SCID (severe combined immunodeficiency - a single gene enzyme defect):� clinical trials in 2000 resulted in 2 of 9 cured, but they developed leukemia:� a retroviral vector inserted a repair gene in bone marrow cells� near genes involved in blood cell division, thus leukemia. trials stopped. � �
39. 2. Pharmaceutical Products... manufactured drugs
40. Recombinant bacteria* = Humulin & protropin (an ethical dilemma)* � Student CD Activity - 17.1 - Producing Human Growth Hormone� �
41. Control of Gene Expression� How do we know a gene has been active (turned on) within cells????� we look for gene's product, i.e., protein or RNA�� an increase in enzyme activity implies gene action? � no enzyme activity suggests no gene action �
42. but, what about pre-existing inactive enzymes converting to --> active forms � ZYMOGENS - pepsinogen -----> pepsin� - trypsinogen -----> trypsin�
43. thus, we have 2 possibilities: � 1) pre-existing inactive enzyme --> active� 2) de novo (new) enzyme synthesis (gene action)�
44. Mechanism of Gene Action (turning on/off genes) in PROCARYOTES...� � model: LACTOSE OPERON - Jacob & Monod [glossary]*� � E. coli (grown on)� glucose lactose� NO beta-galactosidase beta-galacotsidase
45. OPERON* = series of mapable-linked genes controlling synthesis of protein� p Rg crp p O Sg1 Sg2 Sg3 � Rg (i gene) regulator - makes repressor protein what if regulator binds lactose*� p promoter - binds RNA polymerase figure � O operator - binds repressor protein figure � S structural - make enzyme proteins figure* � � Sumanas, Inc. animation - Lac Operon* Catabolic Repression
46. Control of Gene Expression - in EUKARYOTES� � Mechanism of Gene Action (turning on/off genes) is more complex� � much more DNA & it's inside a compartment (nucleus)� and, there are no operons present� have many more promoters - sites where RNA polymerase binds� enhancer sequence - sites where enhancers/transcription factors bind� transcription factors - proteins that help transcription� but, individual genes are not contiguous, thus no operons�
47. 3 levels for eukaryotic controls* - transcriptional, translational, post-translational�� multiple places for control* - of whether a gene make a protein or not� � McGraw-Hill higher Ed movie on control of gene expression
48. Some examples for Eukaryotic gene expression controls: � � Differential Gene Activity... is the selective expression of genes � i.e., different cell types express different genes [liver vs. lens cell]� � 1. role of activators in selective gene expression (Differential Gene Activity*)� � ex: Steroid Hormones (figure*)�
49. 2. Molecular turnover - ½ life mRNA's* & longevity of some proteins* �� 3. Processing of RNA transcript (figure*)� cut/spliced in nucleus and capped for transport� intron - pieces cut out (non gene-proteins) � exons - pieces transported to cytoplasm� alternative splicing = figure C17.11* and some examples*�� ex. cont. Eukaryotic gene expression controls: � �
50. 5. cancer often results from gene changes affecting cell cycle control. � cancer genes, such as adenomatous polyposis coli, which cause 15% of
51. colorectal cancers is a tumor suppressor gene, a type of Oncogenesg*� � 2 kinds of human cancer genes:� Ras (proto-oncogene) causes 30% human cancers:� is a G-protein that promotes other cell division proteins� a Ras mutation --> hyperactive Ras protein --> cell division fig 19.12a
52. p53 (tumor suppressor geneg = 50% human cancers) fig 19.12b*� p53 is a transcription factor that promotes the synthesis of cell cycle� inhibiting proteins [DNA damage --> active p53 --> p51 gene --> protein binds to � cyclin dependent kinase stops cell division]� thus a p53 mutation --> leads to excess cell division (cancer) � � - other cancer genes can lead to new gene actions resulting in cancer � BRCA1 and BRCA2 (tumor suppressor genes) are involved in 50% of breast cancers in humans� �
53. Organization of the Genome* - � the structural organization of genome in eukaryotes influence its expression.� Size of Human genome:� 3million+ base pairs, or some 500,000 pages of journal Nature.� reading a 5 bases/sec it would take you about 60 year @ 8h/d 7d/w � � A definition of a GENE*. �
54. Definition of a Gene� Mendel's Particles... unit of heredity responsible for phenotype� Morgan's Loci... he placed genes on a chromosome, i.e., � it's a cellular entity, that is part of chromosome & is mapable� Watson & Crick... it's a sequence of specific nucleotides along the� length of a double helical DNA molecule� Molecular Definition... � length: 1 nucleotide = 0.34nm thus tRNA = 81n x 0.34 = 27.5nm� mass: 1 nucleotide = 340amu thus tRNA = 81n x 340 = 27,540amu�
55. Modern functional definition... � a DNA sequence coding for a specific polypeptide: but, also must include...� Split Genes... presence of Introns & Exons :� eukaryotic genes contain non-coding segments (introns) � and coding segments (exons - that make proteins)�
56. Others DNA pieces... any definition must also include:� segments that code for rRNA, tRNA, & snRNP's� also promoters, enhancer segments, regulator genes, operators ? � BEST ˜ "a GENE is a region of DNA that CODES for an RNA" end.�� �MST II restriction cuts of normal sickle beta-gene � ( pink is DNA sequence & blue = 4 gel fragments)� _________|__________________|CCTNAGG GAA _____________|____________� � a b c d
57. In 1978, Yuet Wai Kan and Andrees Dozy of the University of California-San Francisco showed that the restriction enzyme Mst II, which cuts normal b globin DNA at a particular site, but will not recognize and therefore will not cut DNA that contains the sickle cell mutation. Mst II recognized the sequence CCTNAGG (where N = any nucleotide). Sickle cell disease is due to a single point mutation in the beta globin gene on chromosme 11 that changes CCTGAGG to CCTGTGG. �MST II restriction cuts of recessive sickle beta-gene (blue = 3 gel fragments)� _________|___________________CCTGTGG ________________|____________� �
58. ¥ �Sickle Cell disease occurs when the DNA sequence for glutamic acid is converted to valine. This results from a change in the nucleotide T to A. This change eliminates a site recognized by the restriction enzyme DdeI.�� Restriction enzyme: DdeI (recognition sequence: 5'-C^TNAG-3')� Southern blotting probe: fragment of ß-globin coding sequence� Pattern result: normal cell = 3 fragments (1 large, a 201bp piece, and a 175bp piece� sickle cell = 2 fragments (1 large, and a 376bp piece)��
59. fig 20.9* Thus the number of RFLP piece can indicate presence of defective alleles.� reading frame (1 codon) = CAT point mutations at hot spots - [fig]� C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-�1st point insertion or deletion�
60. C-A-T-X-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A = mutant �2nd insertion or deletion� C-A-T-X-Y-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C = mutant�3rd insertion or deletion� C-A-T-X-Y-Z-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T-C-A-T = norma
61. DO NOT study the material below� Gene expressions in pharmacogenomics & toxicogenomics via microarrays� 1 cM = about 1 Mb� TRANSPOSONS - pieces of DNA prone to moving & creating repeat sequences� LINE - long interspersed nuclear element holds promoter & 2 genes: RT & integrase� an anomaly - RNA Recoding*
62. Simple Tandem Repeats (short- 5n to 6n) or trinucleotide (3n) repeats can undergo an increase in copy� number by a process of dynamic mutation; # of tandem repeats is unique to a genetic indiv.� Variation in the length of these repeats is polymorphic. figure*� individual A has ACA repeated 65 times @ loci 121, 118, and 129� individual B has a different repeat pattern at these loci� STR'sa can cause genetic diseases as well: � CCG trinucleotide occur in fragile sites on human chromosomes (folate-sensitive group).� fragile X (FRAXA) is responsible for familial mental retardation.� another FRAXE is responsible for a rarer mild form of mental retardation.� mutations of AGC repeats give rise to a number of neurological disorders
63. 3. Forensics - DNA fingerprinting is the vogue judicial modus operandi� a murder case* & a rape case* + DNA prints in Health & Society & DNA Forensic Science� DNA fingerprinting usually looks a 5 RFLP markers and blood is tested via� Southern Blotting (20.10) using probes for these alleles� ��
64. 4. Environmental Clean-up... � bacteria can extract heavy metals (Cu, Pb, Ni) from the environment� & convert them into non-toxic compounds � genetically modified bacteria may be the "miner's" of the future
65. 5. Franken Food... genetically modified (GM) animals & agricultural crops� Transgenics - organisms with inserted foreign DNA in their genomes� Animals* - GFP novelties* + Dolly� - animal cloning companies ---> mammalian cloning success?� - "pharm" animals (20.18*) ---> transgenic animal movie � sheep carry human blood protein gene that inhibits enzymes
66. fibrosis; � artificially insemination, microinjection of human gene, fertilized ova are put� into a surrogate sheep:� chimeras mated to produce homozygote- Milk tested for active protein. � Plants - genetically modified crop plants - fig 20.19*� - to get Ti plasmids in = a DNA gun* Purdue University Gene Gun movie� - Frankenfood & Edible Vaccines � - National Plant Genome Initiative Plan update future
67. 6. Synthetic Biology... artificially manufactured biological systems� - virus models* (synthetic Biology)� ð An overview of biotechnology � History of Biotechnology � Human Genome Project & Biotech Companies � HHMI funded DNA Interactive tutorial�
68. What are Introns? and What is the Role of Intron DNA?�don't really know, but Percentage of non-coding DNA during evolution* goes up.� �
69. INTRONS - DNA Junk or sophisticated Genetic Control Elements?� �� �Current dogma of Molecular Biology � DNA --> RNA --> Proteins, (proteins supposedly regulate gene expression) figure*� �in 1977 Phillip Sharp & Richard Roberts discovered DNA contains introns� intervening DNA segments that do NOT code for proteins� a primary RNA transcript is processed by splicing to assemble protein coding exons� �
70. Presence of Introns: Absent in prokaryotes: they have few non-coding DNA sequences� as eukaryotic complexity grows so does non-coding DNA [figure]� makes up greater than 95% of the DNA � less than 1.5% of human genome encodes proteins, but all of DNA is transcribed� 40% of human genome is Transposons & repeat genetic elements.� � Evolutionary Origins? may have been self-splicing mobile genetic elements� that inserted themselves into host genomes � Advent of Spliceosomes: catalytic RNA/protein complexes � that snip RNAs out of mRNAs,� would encourage introns to proliferate, mutate, evolve
71. that inserted themselves into host genomes � Advent of Spliceosomes: catalytic RNA/protein complexes � that snip RNAs out of mRNAs,� would encourage introns to proliferate, mutate, evolve
72. Role of Introns? Not Junk, but rather Genetic Control Elements [figure*]� Micro RNAs - derived from introns? - occur in plants, animals, & fungi� a) help control timing of developmental processes as cell proliferation,� apoptosis, and stem cell maintenance� b) help tag chromatin with methyl and acetyl groups� c) may help in alternative splicing mechanisms
73. COMPLEXITY: to build a complex structure one must have bricks & mortar, � as well as an architectural plan.� DNA, therefore should contain both - the materials and the plan:� a) component molecules - proteins, carbs, lipids, and nucleic acids:� all known living organism use the same bricks and mortar� b) the difference between Man & Monkey is the architectural plan
74. Where is the Architectural Information? we've always assumed in the regulatory proteins� Maybe it's in the non-coding mirco-RNAs (intronic elements)� Thus the greater proportion of the genome of complex organisms, the introns, isn't junk,� but rather, it is functional RNA that regulates time dependent complexity?�� �
