Pglo Transformation Lab Report

This pBlu lab had for purpose to present the changes of the strain of E. coli bacteria due to new genetic information being introduced into the cell. In this experiment we are freezing and heat shocking the E. Coli bacteria that is then forced to take the plasmid DNA. The E. coli then transforms the pBLu plasmid, which carries the genes coding for two identifiable phenotypes. After following the Carolina Biological steps our lab worked well and we able to see some colonies of bacteria on the plates. The x-gal plate showed a significant amount of bacteria to confirm that the pBlu plasmid took over the E. coli strain.

By subjecting these bacteria through sudden temperature changes or heat shock, a difference in pressure in the outside and the inside of the cell is made, that causes pores, through which the mobile supercoiled plasmid enters. After normalizing the cell temperature, its walls will heal. When the E. coli has now taken up the plasmid with GFP, it will be able to grow in agar plates with ampicillin, an

As predicted the E. coli colony transformed with either the PUC18 or the lux plasmid developed an ampicillin resistance. Which made it easier for them to not only survive but also replicate in both the LB agar plates and the LB ampicillin rich agar plate. However the E. coli colony not treated with the plasmids could not survive and colonize in the LB ampicillin rich agar plates. The plate that had no ampicillin in its environment and no plasmid treated E. coli served as a positive control for this experiment because it demonstrated how the E. coli would colonize and grow in a normal setting. The cells in the positive control plate grew into lawn colonies because they were not placed into a selective environment or transformed, so they had no need to acquire ampicillin resistance. Two plates in the experiment contained E. coli cells that were transformed with either the PUC18 or the lux plasmid but were placed in an ampicillin free environment. These two colonies grew

E. coli HB101 was transformed with pGLO plasmid then grown on media containing ampicillin and/or arabinose and on medium containing neither (Brown, 2011). This is done for selection of transformed cells since not all cells are expected to take up the plasmid (Brown, 2011). We also expect roughly the same CFU on any plate(s) receiving samples from the same microcentrifuge tube, since they are getting the exact same

This lab is about moving genes from one thing to another using plasmids. Plasmid has the ability to replicate, so it replicates independently, and separately from the chromosomal DNA. Plasmid are one or more small piece of DNA and they enter cells as a double strand DNA. When they enter the cell as a doubke strand they do not invade he chromosomal DNA. We will also transform bacteria into GFP which is mainly from the jelly fish Aequorea Victoria. The GFP causes the the jelly fish to fluorescent and glow in the dark. After the transformation, bacteria starts to make the GFP which causes them to glow a green color under a ultraviolet light.

Control plasmids lux and pUC18 were introduced into E. Coli through a process of transformation.

The color of the bacteria was a whitish color and the colony size is similar both before and after the transformation. The best way to do it is to compare the control of the experimental plates. Cells that were typically not treated with the plasmid could not grow on ampicillin, although cells that were treated with the plasmid can grow on the LB/AMP plate. The plasmid would have to confer resistance to ampicillin. Moving on, the GFP gene is what is glowing in the plate because it was activated by the sugar arabinose. The sugar arabinose and the plasmid DNA are also needed to be present because that is what initially turns on the GFP gene which makes the bacteria glow. Organisms can also turn on and off particular genes for camouflage reasons. An organism would benefit from turning on and off certain

This experiment was designed to test and observe the transformation efficacy of the pUC18 and lux plasmids in making E. coli resistant to ampicillin. Both plasmids code for ampicillin resistance, however, the lux plasmid codes for a bioluminescence gene that is expressed if properly introduced into the bacteria’s genome. The E. coli cultures were mixed with a calcium chloride solution and then heat shocked, allowing the plasmids to enter the bacteria and assimilate into the bacterial DNA. The plasmids and the bacteria were then mixed in different test tubes and then evenly spread onto petri dishes using a bacterial spreader, heating the spreader between each sample to make sure there is no cross contamination. Each of the dishes was labeled and then incubated for a period of 24 hours. The results were rather odd because every single one of the samples grew. Several errors could have occurred here, cross contamination or possibly an error in preparation as every single sample in the class grew, meaning all samples of the bacteria transformed and became ampicillin resistant.

The experimental part of the lab consists of setting up the materials needed. A sample of E.coli and a solution of calcium chloride are first obtained and placed in different test tubes. 630µL of Calcium Chloride (CaCl2) are then removed from the test tube and inserted into the test tube containing E.coli cells (Alberte et al., 2012). The newly formed substance of Calcium Chloride and E.coli is then mixed and incubated in ice for 10 minutes, making the cells more competent. Two test tubes are obtained and labeled; the first test tube is labeled with pUC18 and the second one with “Lux” to represent the plasmids being used. These two test tubes are then incubated in ice. 3µl of the set plasmid are added to each of the two test tubes. The test tubes are tapped to guarantee the cells are well

The plasmid pGLO contains an antibiotic-resistance gene, ampR, and the GFP gene is regulated by the control region of the ara operon. Ampicillin is an antibiotic that kills E. coli, so if E. coli, so if E. coli cells contain the ampicillin-resistance gene, the cells can survive exposure to ampicillin since the ampicillin-resistance gene encodes an enzyme that inactivates the antibiotic. Thus, transformed E. coli cells containing ampicillin-resistance plasmids can easily be selected simply growing the bacteria in the presence of ampicillin-only the transformed cells survive. The ara control region regulates GFP expression by the addition of arabinose, so the GFP gene can be turned on and

Transformation is the transfers of virulence from one cell to another, through the transferring of genetic material. It was originally postulated in 1928 through the works of Federick Griffith, a British microbiologist. Griffith observed that the mutant form, non-virulent form, of the bacteria Streptococcus Pnumoniae could be transformed into the normal, virulent form, when injected into mice along with heat killed normal forms. He concluded that somehow the information the dead virulent form had transformed the mutant form into a virulent form.

How does the addition of pGLO plasmid to a solution containing E. coli bacteria affect the growth and characteristics of the bacteria? Genetic transformation is the incorporation of foreign DNA into an organism to potentially change the organism’s trait. Plasmids are small circular DNA that replicate separately from the bacterial chromosome. In nature, these plasmids can be transferred between bacteria allowing for the sharing of beneficial genes. Due to this characteristic, plasmids allow for genetic manipulation and can be moved between bacteria easily. The pGLO plasmid utilized in this experiment encodes the gene for Green Fluorescent Protein (GFP), which under the right conditions can produce a glow. The gene regulation system present in the pGLO plasmid requires

For this experiment, E. coli was best for genetic engineering because of their size, and their fast reproduction (Spilios, 2017). E. coli will be genetically transformed using an engineered plasmid. A plasmid is a circular piece of DNA which independently replicates and multiplies because it has its own origin of replication (Spilios, 2017). The pGLO is the plasmid used in this experiment. Plasmids are used as vectors and they contain manipulated genes such as genes coding for antibiotic resistance for drugs like ampicillin. This antibiotic resistance of such serves as the selectable marker in genetic transformation and for genetic transformation to proceed, the cell must reach competency which is the physiological state that is required for the vector plasmid to get into the cell for transformation (Spilios, 2017). While competency can be reached naturally in some organism, it must be reached artificially in E. coli through treatment with CaCl2 and exposing them to heat shock using incubation (Spilios, 2017).

The transposon in this experiment is contains kanR in between the inverted repeats on either end, which will be transposed from the plasmid pVJT128 to the chromosome of the recipient bacteria.

Bacterial transformation is the process of moving genes from a living thing to another with the help of a plasmid.The plasmid is able to help replicate the chromosomes by themselves; laboratories use these to aid in gene multiplication. Bacterial transformation is relevant in everyday lives due to the fact that almost all plasmids carry a bacterial origin of replication and an antibiotic resistance gene(“Addgene: Protocol - How to Do a Bacterial