HELP ASAP; Please help me understand my lab results, so be detailed to clearly understand

Then , Please include answers to the question below to include in your response

1. what role does ampicilin (amp) and arabinose (ara) play in the experiment.

2) Because GFP was isolated from jelly fisht, what modification to the GFP DNA had to be made to result in expression in E. coli?

BACKGROUND INFORMATION

Transformation of GFP and the pGLO Plasmid GFP is a commonly used reporter protein in research labs, as the fluorescence creates a marker protein that can be used in many types of cell biology and biochemical studies. In basic research, GFP is often fused to a specific target protein of interest, creating a chimeric reporter protein. GFP has been used as a reporter protein to study blood vessel and tumor progression in mice, brain activity in mice, and malaria eradication in mosquitoes for instance (see website mentioned in notes). In the first week you will use a procedure to genetically transform bacteria with the gene that codes for Green Fluorescent Protein. Following the transformation procedure, the bacteria express their newly acquired jellyfish gene and produce the fluorescent protein, which causes them to glow a brilliant green color under ultraviolet light. During the second week you will purify the protein away from all of the other proteins produced by the bacteria using chromatography, and during the third week you will evaluate the success of the purification procedure and estimate the size (molecular weight) of GFP by using sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE). Fundamental to the process of genetic transformation of bacteria are plasmids. In addition to one large chromosome, bacteria naturally contain one or more small circular pieces of DNA called plasmids. Plasmid DNA usually contains genes for one or more traits that may be beneficial to bacterial survival. In nature, bacteria can transfer plasmids back and forth allowing them to share these beneficial genes. This natural mechanism allows bacteria to adapt to new environments. The occurrence of bacterial resistance to antibiotics is due in large part to the transmission of plasmids which contain antibiotic resistance genes. The pGLO plasmid contains the gene for GFP, and also contains the gene for the enzyme β-lactamase (bla), which provides resistance to the antibiotic ampicillin. The β-lactamase protein is produced and secreted by bacteria that contain the plasmid. β-Lactamase inactivates the ampicillin present in the LB nutrient agar, allowing bacterial growth. Only transformed bacteria that contain the plasmid and express β-lactamase can survive on plates that contain ampicillin. Only a very small percentage of the cells take up the plasmid DNA and are transformed. Untransformed cells cannot grow on the ampicillin selection plates. pGLO also incorporates a special gene regulation system, which can be used to control expression of the fluorescent protein in transformed cells. The gene for GFP can be switched on in transformed cells by adding the sugar arabinose to the cells’ nutrient medium. Selection for cells that have been transformed with pGLO DNA is accomplished by growth on antibiotic plates. Transformed cells will appear white (wild-type phenotype) on plates not containing arabinose, and fluorescent green when arabinose is included in the nutrient agar medium.

The transformation procedure involves three main steps. These steps are intended to introduce the plasmid DNA into the E. coli cells and provide an environment for the cells to express their newly acquired genes. 1) Cells are first treated with a solution of CaCl2, which is thought to neutralize the repulsive negative charges of the phosphate backbone of DNA and the phospholipids of the cell membrane, allowing the DNA to adhere to the cells. This is referred to making the cells ‘competent’ (i.e. the cells are capable, or competent, to take-in exogenous DNA). 2) Cells are then subjected to a heat shock, which is thought to increase the permeability of the cell membrane, allowing the cells to take-in the plasmid DNA. 3) Cells are allowed to grow in a ‘recovery’ phase in the absence of ampicillin. During this time the cells begin to produce the β-lactamase protein, which will allow them to survive when they are subsequently placed on agar plates containing ampicillin.

For the first week section of lab

To eac

h of two microfuge tubes, add 250ul of transformation buffer. Keep these tubes on ice.

Using a sterile loop, pick one colony of bacteria from the LB plate. Transfer this colony to one of the microfuge tubes.

Gently vortex the tube until the colony is dispersed. Repeat for the second tube. Add 0.08ug of DNA to one of these tubes (+DNA tube).

Incubate both tubes on ice for 10 minutes. Incubate both tubes at 42°C for 50 seconds.

Incubate both tubes on ice for 2 minutes. Add 250ul of LB broth to each tube and incubate at room temperature for 10 minutes. Flick each tube gently. Add 100ul of t

his transformation mix to the appropriate plates.

Results For plates:

+DNA: Has the E. Coli pGlo plasmid and - DNA plates do no have EColi pGLo plasmid .

Amp means ampiclin and Ara means arabinose on agar plates

+ DNA Plate LB/amp/ara--> white 9 colonies, Glow: yes

+DNA LB/amp--> 7 colonies, GLow: no

--DNA LB/AMP- 1 colony so no colony growth and no glovw

-DNA: LB--> many colonies, Glow: no

Please explain significance of result or thand the reason for the results in scientific terms based on the background information provided and your own knowledge to be detailed. Would these results be expected as wll.

HELP ASAP;

Please help me understand my lab results, so be detailed to clearly understand . INclude answers to these questions what role does ampicilin (amp) and arabinose (ara) play in the experiment. Because GFP was isolated from jelly fisht, what modification to the GFP DNA had to be made to result in expression in E. coli?

BACKGROUND INFORMATION

Transformation of GFP and the pGLO Plasmid

GFP is a commonly used reporter protein in research labs, as the fluorescence creates a marker protein that can be used in many types of cell biology and biochemical studies. In basic research, GFP is often fused to a specific target protein of interest, creating a chimeric reporter protein. GFP has been used as a reporter protein to study blood vessel and tumor progression in mice, brain activity in mice, and malaria eradication in mosquitoes for instance (see website mentioned in notes).

In the first week you will use a procedure to genetically transform bacteria with the gene that codes for Green Fluorescent Protein. Following the transformation procedure, the bacteria express their newly acquired jellyfish gene and produce the fluorescent protein, which causes them to glow a brilliant green color under ultraviolet light. During the second week you will purify the protein away from all of the other proteins produced by the bacteria using chromatography, and during the third week you will evaluate the success of the purification procedure and estimate the size (molecular weight) of GFP by using sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE).

Fundamental to the process of genetic transformation of bacteria are plasmids. In addition to one large chromosome, bacteria naturally contain one or more small circular pieces of DNA called plasmids. Plasmid DNA usually contains genes for one or more traits that may be beneficial to bacterial survival. In nature, bacteria can transfer plasmids back and forth allowing them to share these beneficial genes. This natural mechanism allows bacteria to adapt to new environments. The occurrence of bacterial resistance to antibiotics is due in large part to the transmission of plasmids which contain antibiotic resistance genes.

The pGLO plasmid (Fig. 5, not a naturally occurring plasmid) contains the gene for GFP, and also contains the gene for the enzyme β-lactamase (bla), which provides resistance to the antibiotic ampicillin. The β-lactamase protein is produced and secreted by bacteria that contain the plasmid. β-Lactamase inactivates the ampicillin present in the LB nutrient agar, allowing bacterial growth. Only transformed bacteria that contain the plasmid and express β-lactamase can survive on plates that contain ampicillin. Only a very small percentage of the cells take up the plasmid DNA and are transformed. Untransformed cells cannot grow on the ampicillin selection plates. pGLO also incorporates a special gene regulation system, which can be used to control expression of the fluorescent protein in transformed cells. The gene for GFP can be switched on in transformed cells by adding the sugar arabinose to the cells’ nutrient medium. Selection for cells that have been transformed with pGLO DNA is accomplished by growth on antibiotic plates. Transformed cells will appear white (wild-type phenotype) on plates not containing arabinose, and fluorescent green when arabinose is included in the nutrient agar medium.

for the first week section of lab

To each of two microfuge tubes, add 250ul of transformation buffer. Keep these tubes on ice.

Using a sterile loop, pick one colony of bacteria from the LB plate.

Transfer this colony to one of the microfuge tubes. Gently vortex the tube until the colony is dispersed. Repeat for the second tube.

Add 0.08ug of DNA to one of these tubes (+DNA tube).

Incubate both tubes on ice for 10 minutes.

Incubate both tubes at 42°C for 50 seconds.

Incubate both tubes on ice for 2 minutes.

Add 250ul of LB broth to each tube and incubate at room temperature for 10 minutes.

Flick each tube gently. Add 100ul of this transformation mix to the appropriate plates.

Results:

+DNA: LB/amp--> 1 colony, Glow: uncertain

+DNA: LB/amp/ara--> 9 colonies, Glow: yes

-DNA: LB/amp--> 7 colonies, GLow: no

-DNA: LB--> many colonies, Glow: no

Read the summary and answer questions in bold below:

In this post, we’ll be focusing on Tyler Jacks and his graduate student Francisco J. Sánchez-Rivera’s review, “Applications of the CRISPR-Cas9 system in cancer biology,” circa 2015 in Nature Reviews. So we understand the context of the authors, Jacks is the director of the Koch Institute for Integrative Cancer Research at MIT. His lab has a large mouse experimental component (MIT 2017). This sets the stage for the angle we’ll be reading from. In all, it’s a nice roundup of his and colleagues' cancer applications of CRISPR-Cas9 with great graphics, but leaves a bit desired in crossing the bridge from mouse to human.

Briefly, the CRISPR-Cas9 system stems from the prokaryotic immune system, where the RNA-guided DNA endonuclease Cas9 uses a single guide RNA (sgRNA) containing a CRISPR RNA (crRNA) and trans-activating crRNA (tracrRNA) that binds Cas9 and directs it to the genomic sequence of interest, adjacent to a photospacer adjacent motif (PAM). Cas9 causes a precisely-directed double-stranded break (DSB) in the DNA, that gets repaired via non-homologous end joining (NHEJ) or homology-directed repair (HDR).

With NHEJ, this can disrupt the gene by creating Indels: frameshifts and stop codons. In cancer, individual oncogenes or tumor suppressors can be targeted, or drug response modulators, or synthetic lethality genes. With a multiplexed knockout approach, combinatorial vulnerabilities and epistatic relationships can be assessed.

For gene modification via HDR, target single or double-stranded DNA can be introduced, resulting in precise gene knock-ins, with potential effects of introducing point mutations to mimic cancers, fluorescent reporters/synthetic tags can be created, conditional (Cre-lox/Flp-FRT) constructs can used to turn off/on a mutation, non-coding elements like enhancers/insulators/promoters can turn on proto-oncogenes, and ultimately, HDR can be used for gene correction.

With Cas9 and 2 sgRNAs, there can be genomic rearrangements, leading to deletions, inversions (like EML4-ALK), and translocations (like BCR-ABL).

Dead Cas9 (dCas), which lacks its endonuclease activity via mutation to its HNH and RuvC domains, can be used for reversible, transcriptional repression or activation of coding and non-coding genes, or chromatin modification, via an effector.

Much of the practical applications of CRISPR-Cas9 is in ES cells and mouse models, both germinal and somatic (GEMMs and nGEMMs). With this technology, a plethora of GEMM/nGEMM models of cancer can be created, some with the ability to turn on/off the Cas9 system, and multiplexed sgRNAs can help gain further understanding of multi-hit cancers. Patient derived xenografts (PDX) mice can be assayed with CRISPR-Cas9 to determine different treatment efficacies. Entire libraries of sgRNA can be screened in cancer cell lines for enrichment/depletion with Cas9, and dCas9-activators/repressors can be used for complementarity, both of which providing insights into drug targets, synthetic lethality, and chemotherapy modulators.

The delivery mechanisms for the system are diverse, and include plasmids, lentivirus, adenovirus, nanoparticles, hydrodynamic gene transfer, and protein-based. The authors also cite integrating Cas9 into the GEMMs, so it’s one less thing needed in the delivery vehicle. This of course would not be applicable to human.

Ultimately, human cancer treatment is the goal. Yes, we know the boundaries between ES/mice experimental models and human embryos have already been broken, with an international team targeting the autosomal dominant mutation in MYBPC3, which causes cardiac myopathy (Ledford 2017). But the current compromise position of CRISPR-Cas9 technology toward therapeutics and treatment, beyond basic science understanding, is using primary cells, organoids, PDX, or personalized GEMMs to create genetic and drug screens.

In theory, what would it take to bring CRISPR-Cas9 to the ultimate, targeted gene therapy via either NHEJ or HDR, in human cancer? Are there cancers that are better bets for CRISPR-Cas9 than others, delivery vehicles that are safer or better optimized? Is CRISPR-Cas9 really “on target” enough to introduce into a person, and how do we best assess?