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In a practical application, we need a Book; it will also say which restriction enzymes leave the longest fragments.
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Which of the following cuts DNA molecules at specific locations?
restriction endonuclease enzymes
What cuts DNA into fragments?
cutting of DNA into fragments simply means application of suitable restriction enzyme to it.now a days two types of restriction enzymes are available,1)exonucleases,which cut at end portion of DNA and 2)endonucleases ,which cut at specific inner site.
What does a geneticist use to cut DNA at specific base sequences?
Restriction enzymes, also known as restriction endonucleases, are used to cut DNA into smaller fragments. Restriction enzymes are found in bacteria, where they act like molecular scissors by cutting up DNA from invading viruses or bacteriophages. Each restriction enzyme recognizes a specific nucleotide sequence and cuts the DNA at that site. This process makes restriction enzymes extremely useful in biotechnology where they are used in procedures such as DNA cloning, DNA fingerprinting, and genetic engineering. There are hundreds of known restriction enzymes, and each one was named for the bacteria from which it was isolated. For example, EcoRI was isolated from Escherichia coli and HaeIII from Haemophilus aegyptius.
What are restriction enzymes Explain the significance of these enzymes in recombinant DNA technology.?
A restriction enzyme (or restriction endonuclease) is an enzyme that cuts double-stranded or single stranded DNA at specific recognition nucleotide sequences known asrestriction sites....................refer in this website en.wikipedia.org/wiki/Restriction_enzyme
What is Example of restriction enzyme?
A restriction enzyme (also known as restriction endonuclease) is protein which cuts DNA up at specific sequences (called restriction sites) in a genome. For example, the commonly used restriction endonuclease EcoRI recognizes every DNA sequence GAATTC and cuts at the point between the guanine and the adenine in that sequence, forming blunt ends (or straight, even ends). Interestingly and coincidentially, the restriction site for most restriction enzymes are genetic palindromes (the sequence reads exactly the same backwards on the complementary strand). In the case of EcoRI, the two complementary DNA strands for the restriction site are:5'-- GAATTC --3'3'-- CTTAAG --5'After this DNA sequence is cut, it might look something like this:5'-- G AATTC --3'3'-- C TTAAG --5'
Which of the following cuts DNA molecules at specific locations?
restriction endonuclease enzymes
What cuts DNA into fragments?
cutting of DNA into fragments simply means application of suitable restriction enzyme to it.now a days two types of restriction enzymes are available,1)exonucleases,which cut at end portion of DNA and 2)endonucleases ,which cut at specific inner site.
What does a geneticist use to cut DNA at specific base sequences?
Restriction enzymes, also known as restriction endonucleases, are used to cut DNA into smaller fragments. Restriction enzymes are found in bacteria, where they act like molecular scissors by cutting up DNA from invading viruses or bacteriophages. Each restriction enzyme recognizes a specific nucleotide sequence and cuts the DNA at that site. This process makes restriction enzymes extremely useful in biotechnology where they are used in procedures such as DNA cloning, DNA fingerprinting, and genetic engineering. There are hundreds of known restriction enzymes, and each one was named for the bacteria from which it was isolated. For example, EcoRI was isolated from Escherichia coli and HaeIII from Haemophilus aegyptius.
What are restriction enzymes Explain the significance of these enzymes in recombinant DNA technology.?
A restriction enzyme (or restriction endonuclease) is an enzyme that cuts double-stranded or single stranded DNA at specific recognition nucleotide sequences known asrestriction sites....................refer in this website en.wikipedia.org/wiki/Restriction_enzyme
What determines how DNA will be cut by a restriction enzyme?
Restriction enzymes cut DNA at specific sites called restriction sites. These restriction sites are typically 6 - 8 nucleotides in length and have a defined set of nucleotide bases. For example, the restriction enzyme Eco R1 cuts at the site: AGGTTC. Therefore, if the target DNA contains the above sequence, Eco R1 is able to cut it within the restriction site. Hence, by looking into the target site and which restriction enzymes are being used, on can make an accurate estimate of where the target DNA will be cut
What evidence show is that each enzyme cuts the DNA at different locations?
Enzymes that are able to cut DNA are called rstriction enzymes. These enxymes are site specific. This means the cuts they produce are not ramdom events. They cut the DNA strand only when a particular sequence is encountered. This sequence on the DNA is called the restriction site. Restriction sites vary in length from 6 - 8 or more nucleotides. This evidence indiates restriction enzymes cut DNA at a unique site
What is Example of restriction enzyme?
A restriction enzyme (also known as restriction endonuclease) is protein which cuts DNA up at specific sequences (called restriction sites) in a genome. For example, the commonly used restriction endonuclease EcoRI recognizes every DNA sequence GAATTC and cuts at the point between the guanine and the adenine in that sequence, forming blunt ends (or straight, even ends). Interestingly and coincidentially, the restriction site for most restriction enzymes are genetic palindromes (the sequence reads exactly the same backwards on the complementary strand). In the case of EcoRI, the two complementary DNA strands for the restriction site are:5'-- GAATTC --3'3'-- CTTAAG --5'After this DNA sequence is cut, it might look something like this:5'-- G AATTC --3'3'-- C TTAAG --5'
What enzyme cuts and seals DNA?
HaeIIIrestriction enzymes
Why is DNA fingerprinting more accurate if the samples are cut with more than one restriction enzyme?
When EcoR1 cuts this DNA, it cuts it at three places into four different segments. EcoR1 is only one of many different restriction enzymes. Each different enzyme cuts DNA at a different site. By using different enzymes, a scientist can cut DNA into many smaller pieces that can be run out on a gel during electrophoresis. Remember that in gel electrophoresis, DNA fragments separate by size. Because these segments have different sizes, they will separate onto a gel at different rates. If different people's DNA is cut by restriction enzymes and then run out on a gel, each person's DNA will leave a different pattern.
Based on restriction maps of plasmid determine the number of DNA fragments and sizes of the fragments?
Plasmids are circular pieces of DNA, so the number of fragments equals the number of cuts from the restriction enzymes. You can easily see this if you start with one restriction enzyme that cuts the plasmid in only one place. Cutting the circle in one place yields you only one fragment. If the restriction cuts in two places, you end up with two fragments; with three places, three fragments, etc. With linear chromosomes, the situation is different. Cutting a linear chromosome in one place yields two fragments, cutting in two places yields three fragments, etc. So the number of fragments is always one more than the number of cuts. A restriction map of a plasmid will show all of the cuts the restriction enzymes made. Each cut is labeled with the enzyme that made it. One can count the spaces between cuts to determine the number of fragments that are produced. Restriction maps usually (but not always) also show the size of each fragment.
What cuts bacterial plasmids?
Enzymes called restriction endonucleases can cut plasmids. However, in order for a cut to be produced, the plasmid should contain a specific sequence of nucleotides called the restriction site
What is the role of restriction enzymes in bacteria?
Restriction enzyme in bacteria cuts of the foreign DNA inside the host, thus destroying them. The host DNA is protected against this destructive action due to methylation of the host DNA.
