Introduction:
Genetic Transformation is the process by which a segment of DNA of a specific organism is implanted into another organism that reads the foreign organisms DNA and presents the phenotype for the selected DNA segment. The genetic transformation can occur using three different methods, but in the case of the experiment conducted and described below, was performed using the method of heat shock. In the experiment, heat shock was used to genetically transform a piece of DNA from a jellyfish into a sample of E. coli bacteria to observe if the transformation would occur. The components necessary for the transformation were: pGLO, a plasmid acting as a vector for the transformation and contained the DNA segment extracted from jellyfish that encodes for the production of a protein that glows (GFP); Luria Bertani broth, the culture for the transformation; Ampicillin Resistant gene, to sort cells so only the cells having absorbed plasmid will survive; Arabinose, a sugar to aid in the growth of bacteria. The genetic transformation was tested using four samples, each having a different environment. The first sample’s environment consisted of +pGLO, the Luria Bertani broth, and a gene resistant to Ampicillin. The second sample’s environment consisted of +pGLO, the Luria Bertani broth, a gene resistant to Ampicillin, and arabinose. The third sample’s environment consisted of -pGLO, the Luria Bertani broth, and a gene resistant to Ampicillin. The fourth sample’s environment
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.
The purpose of the PGLO lab was to be able to perform a procedure known as a genetic transformation. We used a procedure to transform bacteria with the gene that codes for a Green Fluorescent Protein (GFP). The actual source of the GFP gene that we used in this complicated experiment is the bioluminescent jellyfish Aequorea victoria. This protein causes the jellyfish to glow under a UV light that was provided in the dark. After the transformation procedure, the bacteria showed their newly acquired gene from a jellyfish and produced the fluorescent protein, which as a result, causes it to glow. If the bacteria glowed in the dark, that was the initial sign that the experiment was successful.
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.
In the pGLO Bacterial Transformation lab, Escherichia coli is transformed with a gene encoding green fluorescent protein by inserting a plasmid containing the GFP gene, beta-lactamase, and arabinose into the bacterium. Successfully transformed bacteria will grow in the presence of ampicillin and glow a bright green color under ultraviolet light. The sugar arabinose is responsible for switching on the GFP gene in the transformed cells, without it, the gene will not be expressed.
The purpose of this experiment was to show the genetic transformation of E. coli bacteria with a plasmid that codes for Green Fluorescent Protein (GFP) and contains a gene regulatory system that confers ampicillin resistance. A plasmid is a genetic structure in a cell that can replicate independently of chromosomes. In this lab, the Green Fluorescent Protein, which is typically found in the bioluminescent jellyfish Aequorea Victoria, was cloned, purified, and moved from one organism to another with the use of pGlo plasmids. It was hypothesized that if bacteria that were transformed with +pGlo plasmids are given the gene for GFP, then transformed cell colonies
The pGLO plasmid will transform the E. coli bacteria with a gene called GFP that codes for the Green Fluorescent Protein in the genetic code. GFP was discovered in the jellyfish, Aequorea victoria as a green fluorescent light emitted from the jellyfish. It was typically seen in the dark upon its activation and since then has been used in studies relating to genetic transformation. (Chalfie and Tu 1994) The majority of the studies test the many different factors that are required in the transformation of pGLO which will determine the functionality of GFP in the E.coli bacterium. The first experiment in transforming GFP and E. coli was completed in 1994 by Chalfie and was further refined the same year. The experiment proved the importance of using restriction enzymes, and DNA ligase in the process of transforming GFP to identify arabinose as the primary activator, and to identify the ampicillin
The field of biotechnology involves the concept of genetic engineering, altering the DNA/genetic material of an organism using information from a different one. The process in which bacteria can obtain this manipulated genetic information from another source is called genetic transformation. The goal of this experiment was to genetically transform Escherichia coli bacteria’s DNA by inserting the vector pGLO plasmid which codes for ampicillin resistance as well as the green fluorescent protein, GFP. For the experiment, the E. coli bacteria were separated into two groups; control and
Genetic transformation occurs when genes are inserted into another gene to change the organism’s trait (Weedman2016). In this experiment, we proceeded to transform the E. coli bacteria with a gene that contained green fluorescent protein. The green fluorescent protein is used in experiments because it beams a green color under a UV light (Chalfie2008). Typically, it is used to mark the expression of genes, which is why it serves as the symbol for all gene expressions (Tsien1998). In the experiment, we will be using pGLO as the organisms that will transmit the disease, otherwise known as a vector. The pGLO in the experiment
In 1928, Fred Griffith first discovered genetic transformation by infecting mice with unencapsulated and non-pathogenic pneumococci (Lacks 2003). This was the start that opened up the field of biotechnology. Genetic transformation is a process where foreign DNA crosses a membrane of another cell and then alters the genetic material (Encyclopædia Britannica 2015). Genetic transformation can occur in a few different ways: projectile bombardment, electroporation, and heat shock (Weedman 2015). Heat shock is defined by increasing the temperature of cells environment making the plasma membrane become more permeability allowing new DNA to transfer into the cell (Weedman 2015). The cell receiving the new DNA, also known as competent cells, can either amplify the DNA or clone the DNA (JoVE 2015). The most common type of DNA used to perform genetic transformations is plasmids: small, round DNA molecules that still contains two strands of DNA that has the ability
This experiment was performed to assess the efficacy of genetic transformations on bacteria via plasmid DNA coding for ampicillin resistance and green fluorescent protein. Genetic transformation was studied by taking transformed and untransformed Escherichia Coli (E. coli) and placing them on various media to observe gene expression via growth and color under UV light. The transformed E. coli were able to grow on ampicillin while the untransformed E. coli, which lacked the plasmid genes for ampicillin resistance, only grew on nutrient broth. In the presence of arabinose, the transformed E. coli glowed green. These results support the previous scientific understanding of bacterial competency, vectors, and gene expression and support gene transformations as an effective method to transfer the desirable DNA of one organism into another organism’s DNA. These results can be applied to real world issues such as medical treatments, food production, and environmental conservation.
The transformation of E. coli using plasmid DNA was a success. The positive control plate had a near lawn of blue colonies growing on the plate. This indicated that the E. coli cells took up the plasmid and became ampicillin resistant. The blue colonies formed because the cells were able to produce β galactoisdase and in presence of X-gal the colonies turned blue. There were light blue colonies formed near the edge of the plate. This could due to the lower concentration of X-gal near the edge of the plate so those colonies were not really blue. In addition, there were too many colonies to count so we estimated the transformation efficiency of the positive control to be around 2000 units/μg. On the other hand, the negative is shown in figure
Introduction Genetic transformation is known to be the conversion of a genotype into another with the addition of DNA from an external source. Frederick Griffith was the first person to use genetic transformation in 1928 with Streptococcus pneumoniae (Griffiths et al. 2000). There are three different methods that are used in genetic transformation to get the vector DNA into the nucleus of the competent cell. The methods are, projectile bombardment, electroporation, and heat shock. Heat shock is the most common method is projectile bombardment because it guarantees the mixture of the two DNA (APSnet…2014).
According to our lab manual, Genetic transformation is when the genetic makeup of an organism is altered by incorporating external genetic material (Barnhart and Hopper 2014). Genetic transformation was discovered on accident by the scientist Frederic Griffith in 1928. He was trying to create a vaccine for pneumonia, but instead discovered bacterial transformation (Barnhart and Hopper 2014). Plasmids, which are a genetic structure in a cell that can replicate independently of the chromosomes, are used as a form of extra genetic material in order to transform bacteria. They are expressed by both the bacterial cell and the daughter cell. In the case for our genetic transformation lab, our cells we are using are E. coli cells, and
A bacterial transformation is the process by which a cell is introduced to foreign DNA. Bacteria can use their ability to take up DNA to make them resistant to antibiotics. In order for the bacteria to do this, the bacteria must be in a state of competence. This can occur in response to environmental conditions such as cell density or starvation. Transformations can occur in one of three ways, on is by transformations or when the bacterial cell is being introduced to genetic material, conjugation or genetic material being transferred between two bacterial cells, or transduction or when genetic material is injected by a virus into the host bacterium. During transformations, DNA is only taken up when there is a high density of cells
This experiment was performed to test the hypothesis if LB nutrient broth, +pGLO and -pGLO Ampicillin, and Arabinose was placed in the E. coli plates, then there will be a significant growth in the newly transformed bacteria and it will possess the ability to glow under UV light. The measurements were recorded from the bent glass tube in each glass test tube. The transformation protocol tested for the newly possessed traits in E.coli bacteria. Throughout the experiment there were many probable reasons for failure. If the pipettes and sterile loop were not thrown out in between each use, a cross contamination could cause a miscalculation in the experiment causing the data results to fail. The hypothesis that was tested was validated due to the positive results with each experiment stating that newly transformed organisms due in fact pass on traits.