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Molecular Biology. Molecular Biology. Section H Cloning Vectors. Molecular Biology. Cloning vectors. Content. . DESIGN OF PLASMID VECTORS . BACTERIOPHAGE VECTORS . COSMIDS, YACs AND BACs . EUKARYOTIC VECTORS. Molecular Biology. Cloning vectors. H1 Design of Plasmid Vectors.
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Molecular Biology Molecular Biology Section H Cloning Vectors
Molecular Biology Cloning vectors Content . DESIGN OF PLASMID VECTORS . BACTERIOPHAGE VECTORS . COSMIDS, YACs AND BACs . EUKARYOTIC VECTORS
Molecular Biology Cloning vectors H1 Design of Plasmid Vectors Fig. 1. (a) Screening by insertional inactivation of a resistance gene; (b) replica plating.
Molecular Biology Cloning vectors H1 Design of Plasmid Vectors The insertion of a DNA fragment interrupts the ORF of lacZ’ gene, resulting in non-functional gene product that can not digest its substrate x-gal. Fig. 2. (a) A plasmid vector designed for blue–white screening; (b) the colonies produced by blue–white screening.
Lac promoter MCS (Multiple cloning sites, 多克隆位点) Ampr pUC18 (3 kb) lacZ’ ori Molecular Biology Cloning vectors H1 Design of Plasmid Vectors Fig. 3. A multiple cloning site at the 5′-end of lacZ′
Molecular Biology H1 Design of Plasmid Vectors H1-2 A plasmid vector for gene expression Expression vectors:allowing the exogenous DNA to be inserted, stored and expressed. • Promoter and terminator for RNA transcription are required. • Intact ORF and ribosomal binding sites (RBS) are required for translation.
Molecular Biology H1 Design of Plasmid Vectors Expression vector (transcription and translation). Promoters • lacUV-5: a mutant lac promoter which is independent of cAMP receptor protein. • lPL promoter • Phage T7 promoter Fused proteins Individualproteins
Molecular Biology H1 Design of Plasmid Vectors Fig. 4. A plasmid designed for expression of a gene using the T7 system
Molecular Biology Cloning vectors H2 Bacteriophage vector Tow examples: H2-1 λ phage bacteriophageλ λ replacement vector H2-2 M13 phage M13 phage vector Cloning in M13 Hybrid plasmid-M13 vectors
Molecular Biology λ phage H2 Bacteriophage vector .viruses that can infect bacteria. .48.5 kb in length .Linear or circular genome (cos ends) Lytic phase (Replicate and release) Lysogenic phase (integrate into host genome) Fig. 1. (a) Phage λ and its genome; (b) the phage λ cos ends.
Molecular Biology H2 Bacteriophage vector λ replacement vector . Replace the nonessential region of the phage genome with exogenous DNA . high transformation efficiency (1000-time higher than plasmid)
Molecular Biology H2 Bacteriophage vector Protein coat Fig. 2. Cloning in a λ replacement vector.
Molecular Biology H2 Bacteriophage vector Plaques:the clear areas within the lawn where lysis and re-infection have prevented the cells from growing. Recombinant l DNAmay be purified from phage particles from plaques or from liquid culture.
Molecular Biology H2 Bacteriophage vector H2-2 M13 phage vector • Replication form (RF, dsDNA)of M13 phage can be purified and manipulated like a plamid. • Phage particles (ssDNA):DNA can be isolated in a single-stranded form . DNA sequencing. . Site-directed mutagenesis.
Molecular Biology M13 mp18 vector
Molecular Biology Cloning vectors H3 COSMIDS, YACs AND BACs . Cloning large DNA fragments . Cosmid vectors . YAC vectors . Selection in S. cerevisiae . BAC vector
Molecular Biology H3 Cosmids and YACs H3-1 Cloning large DNA fragments (Eukaryotic Genome project) Analysis of eukaryotic genes and genome organization of eukaryotic requires vevtors with a larger capacity for cloned DNA than plasmids or phage λ.
Molecular Biology H3 Cosmids and YACs H3-2 Cosmid vectors Cosmids use the λ packaging system to package large DNA fragments bounded by λ cos sites, which circularize and replicate as plasmids after infection of E.coli cells. Some cosmid vectors have two cos sites, and are cleaved to produce two cos ends, which are ligated to the ends of target fragments and packaged into λ particles. Cosmids have a capacity for cloned DNA of 30-45 kb.
Molecular Biology Formation of a cosmid clone Fig. 1. Formation of a cosmid clone.
Molecular Biology H3 Cosmids and YACs H3-3 YAC vectors Yeast artifical chromosomes can be constructed by ligating the components required for replication and segreation of natural yeast chromosomes to very large fragments of target DNA, which may be more than 1 Mb in length. Yeast artifical chromosome(YAC) vectors contain two telomeric sequences(TEL), one centromere(CEN), one autonomously replicating sequence(ARS) and genes which can act as selectable markers in yeast.
Molecular Biology H3 Cosmids and YACs
Molecular Biology H3 Cosmids and YACs H3-4 Selection in S.cerevisiae Selection for the presence of YACs of other vectors in yeast is achived by complementation of a mutant strain unable to produce an essential metabolite, with the correct copy of the mutant gene carried on the vector.
Molecular Biology Cloning vectors H4 Eukaryotic Vectors 1. Shuttle vectors 2. Yeast episomal plasmids (Yeasts) 3. Agrobacterium tumefaciens Ti plasmid (Plants) 4. Baculovirus (Insects) 5. Mammalian viral vectors (Mammalian)
Molecular Biology H4 Eukaryotic Vectors Shuttle vectors
Molecular Biology H4 Eukaryotic Vectors H4-1 Yeast episomal plasmids (YEps) Vectors for the cloning and expression of genes in Saccharomyces cerevisiae.
Molecular Biology Replicate as plasmid from 2m origin H4 Eukaryotic Vectors YEp vector integrate by recombinantion
Molecular Biology H4 Eukaryotic Vectors H4-2 Agrobacterium tumefaciens Ti plasmid
Molecular Biology H4 Eukaryotic Vectors crown gall or tumor
Molecular Biology H4 Eukaryotic Vectors Plant gene engineering using T-DNA vector
Molecular Biology H4 Eukaryotic Vectors H4-3 Baculovirus baculovirus is an insect virus which is used for the overexpression of animal proteins in insect cell culture.
Molecular Biology H4 Eukaryotic Vectors H4-4 Mammalian viral vectors Fig 1. Gene expression by SV40. Early genes are in red, late genes are in green. Note: - - - - indicates regions of the primary transcript which are removed in the alternatively processed mRNA. Cross-hatched area indicates region of RNA translated in different reading frames according to which alternatively spliced transcript is being translated Modified from Fiers et al.,Nature 273:113 Fig 2. retrovirus lifecycle
Molecular Biology H4 Eukaryotic Vectors Gene transfer Genes may be introduced into plant of animal cultured cells without the use of a special eukaryotic vector. Bacterial plasnids carrying eukaryotic genes may remain transiently in cells without replication or may integrate into the host genome by recombination at low frequency.