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Study Guide Chapter 9, Study Guides, Projects, Research of Biology

Irvine Valley CollegeBiology

Study Guide Chapter 9 for Micro Biology class

Typology: Study Guides, Projects, Research

2023/2024

Uploaded on 07/02/2025

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Bio 15 Microbiology Ch 9 Biotechnology Study Guide
Key Terms
Biotechnology clone restriction enzymes vectors PCR gene therapy DNA fingerprinting forensic microbiology
1. Define biotechnology and explain the difference between biotechnology and recombinant DNA (rDNA) technology.
Biotechnology is a broad field that utilizes living organisms and their biological processes to develop products and
technologies for various applications, while recombinant DNA (rDNA) technology is a specific technique within
biotechnology that involves manipulating and combining DNA fragments from different organisms to create new
genetic sequences, essentially a method for genetic engineering within the broader field of biotechnology.0
Key points to differentiate:
Scope:
Biotechnology encompasses a wide range of techniques using biological systems, including fermentation, cell culture,
enzyme engineering, and genetic engineering (which includes rDNA technology).
Focus:
rDNA technology specifically focuses on manipulating DNA at the molecular level by cutting, splicing, and inserting DNA
fragments to create new genetic constructs.
Example applications:
Biotechnology:
Producing biofuels from plants, using bacteria to clean up pollutants (bioremediation), developing new vaccines using
cell culture techniques.
rDNA Technology:
Creating genetically modified crops with enhanced traits, producing therapeutic proteins like insulin in bacteria for
medical use, gene therapy to treat genetic diseases.
2. Explain restriction enzymes and outline how they are used to make rDNA.
Restriction enzymes are0proteins naturally produced by bacteria that act like molecular scissors, cutting DNA at specific
nucleotide sequences called recognition sites, allowing scientists to precisely isolate and manipulate specific DNA
fragments, which is crucial for creating recombinant DNA (rDNA) in genetic engineering techniques;0essentially, they
cut DNA at specific locations, enabling the insertion of desired genes into a vector like a plasmid to create a new DNA
molecule with combined genetic material from different sources.
How restriction enzymes are used to make rDNA:
Cutting DNA:
Researchers choose a specific restriction enzyme that recognizes a sequence present in both the desired gene (to be
inserted) and the vector (plasmid) DNA.0This enzyme cuts the DNA at the recognition site, creating complementary
"sticky ends" on both DNA fragments.
Inserting the gene:
The DNA fragment containing the desired gene, cut with the same restriction enzyme, will have compatible sticky ends
that can readily bind to the open ends of the cut plasmid.
Ligating the DNA:
Once the gene is properly aligned with the plasmid, an enzyme called DNA ligase is used to join the DNA fragments
together, creating a recombinant DNA molecule.
Transformation:
The recombinant plasmid is then introduced into a host cell (like bacteria) where it can replicate, producing multiple
copies of the desired gene.
Key points about restriction enzymes:
Specificity:
Each restriction enzyme recognizes a unique DNA sequence, ensuring precise cuts at specific locations.0
Sticky ends vs. blunt ends:
Some restriction enzymes create "sticky ends" with single-stranded overhangs, while others create "blunt ends" with
no overhangs.
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Bio 15 Microbiology Ch 9 Biotechnology Study Guide Key Terms Biotechnology clone restriction enzymes vectors PCR gene therapy DNA fingerprinting forensic microbiology

  1. Define biotechnology and explain the difference between biotechnology and recombinant DNA (rDNA) technology. Biotechnology is a broad field that utilizes living organisms and their biological processes to develop products and technologies for various applications, while recombinant DNA (rDNA) technology is a specific technique within biotechnology that involves manipulating and combining DNA fragments from different organisms to create new genetic sequences, essentially a method for genetic engineering within the broader field of biotechnology. Key points to differentiate: Scope: Biotechnology encompasses a wide range of techniques using biological systems, including fermentation, cell culture, enzyme engineering, and genetic engineering (which includes rDNA technology). Focus: rDNA technology specifically focuses on manipulating DNA at the molecular level by cutting, splicing, and inserting DNA fragments to create new genetic constructs. Example applications: Biotechnology: Producing biofuels from plants, using bacteria to clean up pollutants (bioremediation), developing new vaccines using cell culture techniques. rDNA Technology: Creating genetically modified crops with enhanced traits, producing therapeutic proteins like insulin in bacteria for medical use, gene therapy to treat genetic diseases.
  2. Explain restriction enzymes and outline how they are used to make rDNA. Restriction enzymes are proteins naturally produced by bacteria that act like molecular scissors, cutting DNA at specific nucleotide sequences called recognition sites, allowing scientists to precisely isolate and manipulate specific DNA fragments, which is crucial for creating recombinant DNA (rDNA) in genetic engineering techniques; essentially, they cut DNA at specific locations, enabling the insertion of desired genes into a vector like a plasmid to create a new DNA molecule with combined genetic material from different sources. How restriction enzymes are used to make rDNA: Cutting DNA: Researchers choose a specific restriction enzyme that recognizes a sequence present in both the desired gene (to be inserted) and the vector (plasmid) DNA. This enzyme cuts the DNA at the recognition site, creating complementary "sticky ends" on both DNA fragments. Inserting the gene: The DNA fragment containing the desired gene, cut with the same restriction enzyme, will have compatible sticky ends that can readily bind to the open ends of the cut plasmid. Ligating the DNA: Once the gene is properly aligned with the plasmid, an enzyme called DNA ligase is used to join the DNA fragments together, creating a recombinant DNA molecule. Transformation: The recombinant plasmid is then introduced into a host cell (like bacteria) where it can replicate, producing multiple copies of the desired gene. Key points about restriction enzymes: Specificity: Each restriction enzyme recognizes a unique DNA sequence, ensuring precise cuts at specific locations. Sticky ends vs. blunt ends: Some restriction enzymes create "sticky ends" with single-stranded overhangs, while others create "blunt ends" with no overhangs.

Naming convention: Restriction enzymes are named based on the bacteria they are isolated from, for example, EcoRI is a restriction enzyme from Escherichia coli. Example of a restriction enzyme application: Inserting a human insulin gene into a bacterial plasmid: By using a restriction enzyme to cut both the human insulin gene and a bacterial plasmid at specific sites, the insulin gene can be inserted into the plasmid, allowing bacteria to produce human insulin protein when cultured.

  1. Explain what PCR is, outline the steps of PCR and provide two examples for its use. Explain how one can specifically control which section of the genome is amplified (what particular section or gene) PCR, which stands for Polymerase Chain Reaction, is a laboratory technique used to rapidly amplify a specific segment of DNA by creating millions to billions of copies of it through repeated cycles of DNA synthesis, allowing for detailed analysis of a targeted DNA sequence;. The key steps in PCR are: denaturation (separating DNA strands), annealing (primers binding to the target sequence), and extension (new DNA strands are synthesized using the primers as starting points) - this cycle is repeated multiple times to exponentially increase the DNA copies. Steps of PCR: Denaturation: The DNA sample is heated to a high temperature, causing the double-stranded DNA to separate into single strands. Annealing: The temperature is lowered to allow short DNA sequences called primers to bind to complementary regions on the single-stranded DNA, flanking the target sequence. Extension: The temperature is raised to the optimal temperature for the DNA polymerase enzyme, which then extends the DNA strands by adding nucleotides to the primers, creating new DNA copies. Two examples of PCR usage: Genetic testing: PCR is used to identify specific genetic mutations associated with diseases, such as sickle cell anemia, by amplifying the relevant gene region and analyzing the DNA sequence. Forensic analysis: DNA profiling in criminal investigations relies on PCR to amplify specific regions of DNA (like short tandem repeats) from a sample (e.g., blood, hair) to compare with a suspect's DNA. To specifically control which section of the genome is amplified, scientists use techniques like polymerase chain reaction (PCR) with specially designed primers that target the desired DNA sequence, essentially "selecting" which region gets copied during amplification; this is achieved by designing primers that only bind to the specific start and end points of the target gene, ensuring only that specific region is amplified, not the surrounding genomic DNA. Key points about controlling amplification: Primer design: The most crucial aspect is designing primers with sequences that are highly specific to the desired gene region, preventing binding to other similar sequences elsewhere in the genome. Specificity of primers: Primers should have a high melting temperature to ensure they only bind to the intended target sequence at the correct annealing temperature during PCR. Genome editing techniques: Advanced techniques like CRISPR-Cas9 can be used to introduce specific mutations or deletions at a target locus before amplification, allowing for precise control over the amplified region. Methods for targeted amplification: Standard PCR: Uses a pair of forward and reverse primers that flank the desired gene region, allowing only that sequence to be amplified. Quantitative PCR (qPCR):

Nutritional enhancement: Scientists can modify crops to contain higher levels of essential vitamins and minerals, improving nutritional value. Problems: Environmental concerns: There are worries about GMOs potentially impacting ecosystems by transferring modified genes to wild plants, disrupting biodiversity. Antibiotic resistance: A common method for identifying successfully modified cells involves using antibiotic resistance genes as markers, which raises concerns about the potential for transferring these resistance genes to bacteria in the environment.