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-->''I find it elevating and exhilarating to discover that we live in a universe which permits the evolution of molecular machines as intricate and subtle as we.''
-->-'''Creator/CarlSagan'''
-->-'''Creator/CarlSagan'''
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-->-'''CarlSagan'''
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-->''I find it elevating and exhilarating to discover that we live in a universe which permits the evolution of molecular machines as intricate and subtle as we.''
-->-'''CarlSagan'''
-->-'''CarlSagan'''
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** Other factors can also affect expression of proteins besides just the cell reading the genes in the DNA itself. Some organisms have "alternative splicing", where one sequence of DNA can be read several different ways and produce different proteins depending on which sections of the transcribed RNA (which the cell's ribosomes read to create proteins) are cut and which ones are kept. How the protein is handled after translation is also important, as proteins that are improperly folded (they don't have the right three-dimensional structure) can't perform their necessary function. So even IF everything else is correct, these external factors within the cell can still prevent a gene from working properly.
to:
** Other factors can also affect expression of proteins besides just the cell reading the genes in the DNA itself. Some organisms organisms, including humans, have "alternative splicing", where one sequence of DNA can be read several different ways and produce different proteins depending on which sections of the transcribed RNA (which the cell's ribosomes read to create proteins) are cut and which ones are kept. How the protein is handled after translation is also important, as proteins that are improperly folded (they don't have the right three-dimensional structure) can't perform their necessary function. So even IF everything else is correct, these external factors within the cell can still prevent a gene from working properly.
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Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks.
to:
Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will may affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks.
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This is the cause of cancer, where a mutation in one of the genes that controls replication gets [=FUBARed=] and the cell divides out of control.
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This is the cause of cancer, where a mutation in one of the genes that controls replication gets [=FUBARed=] control genes suffers severe malfunction and the cell divides out of control.
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# Timing is crucial: Adding bits of DNA to a fully grown organism will have unpredictable results. It's like adding flour to a cake after it has been baked. It's not quite the same as adding it before putting the cake in the oven. By this point in the organism's life span, the vast majority of its development and cell division is over and done with, just like how the cake is already finished baking.
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# Timing is crucial: Adding bits of DNA to a fully grown organism adult will have negligible or unpredictable results. It's like adding flour to a cake after it has been baked. It's not quite the same as adding it before putting the cake baked, which will have a different taste and no effect in the oven. By this cake's fundamental structure. At some point in the an organism's life span, the vast majority of its development and cell division is over and done with, with (e.g., neuron production occurs primarily in the uterus and is minor in adults, hence why people say "brain cells don't regenerate"), just like how the cake is already finished baking.
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Reduced excess exclamation remarks. Twice a paragraph is just too much.
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However, not all changes to a gene are necessarily harmful. Our genetic code has some redundancy built in, and sometimes a single substitution from one nucleotide to a different one will have no effect on the final product at all. Also, changes made only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect!
to:
However, not all changes to a gene are necessarily harmful. Our genetic code has some redundancy built in, and sometimes a single substitution from one nucleotide to a different one will have no effect on the final product at all. Also, changes made only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect! effect.
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Making changes to different parts of an organism's genome can have different effects, because genes within DNA themselves serve different purposes, and not all parts of DNA actually code for proteins!
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Making changes to different parts of an organism's genome can have different effects, because genes within DNA themselves serve different purposes, and not all parts of DNA actually code for proteins!
proteins.
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But what about those sequences that are NOT coding regions? These spots serve as regulatory elements, which signal the cell to express (or stop expressing) other genes at certain times and places. Mutations here can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used.
* As an example, if a gene gets duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one!
* As an example, if a gene gets duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one!
to:
But what about those sequences that are NOT not coding regions? These spots serve as regulatory elements, which signal the cell to express (or stop expressing) other genes at certain times and places. Mutations here can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used.
* As an example, if a gene gets duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the oldone! one.
* As an example, if a gene gets duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old
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However, while random mutations cause undirected changes to DNA, the recent establishment of Genetic Engineering allows us to take a more ''direct'' approach to tweaking genes. Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it to another, as in taking genes found in fish and putting them in tomatoes! In reality, it's much less horrifying then it sounds because our genetic code, using the 4 nucleotide bases that are arranged to code for certain amino acids, is universal across all organisms. Whether you're a tulip, a monkey, or an E. coli bacterium, we all use the same system. However, it's not as easy as just hitting Ctrl+C Ctrl+V...
to:
However, while random mutations cause undirected changes to DNA, the recent establishment of Genetic Engineering allows us to take a more ''direct'' approach to tweaking genes. Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it to another, as in taking genes found in fish and putting them in tomatoes! tomatoes. In reality, it's much less horrifying then it sounds because our genetic code, using the 4 nucleotide bases that are arranged to code for certain amino acids, is universal across all organisms. Whether you're a tulip, a monkey, or an E. coli bacterium, we all use the same system. However, it's not as easy as just hitting Ctrl+C Ctrl+V...
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The fundamental basis of all genetics is that UsefulNotes/{{DNA}} is transcribed in RNA which is then translated into proteins.
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The fundamental basis of all genetics is that UsefulNotes/{{DNA}} is transcribed in RNA into RNA, which is then translated into proteins.
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The fundamental basis of all genetics is that DNA is transcribed in RNA which is then translated into proteins.
to:
The fundamental basis of all genetics is that DNA UsefulNotes/{{DNA}} is transcribed in RNA which is then translated into proteins.
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While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the gene at some point along the line can potentially screw things up for a few different reasons:
to:
While that statement is pretty simply, simple, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the gene at some point along the line can potentially screw things up for a few different reasons:
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# The actual expression of genes will be influenced by other factors in the environment. Just as the results of a cake recipe may vary due to things like humidity, temperature, and altitude, there's evidence that the results of a DNA "recipe" will vary due to outside influences. Cloned animals often display striking superficial differences from their genetic progenitors because an environment which favors the expression of different genes can coax different results from the same DNA. Apparently, identical twins only are identical (mostly; this is why scientists tend to call them "monozygotic") because they share the same DNA ''and'' the same prenatal environment. And even then environmental factors during their lifetime can change how their genes are expressed, giving them distinct differences from the same genome.
*** Other factors can also affect expression of proteins besides just the cell reading the genes in the DNA itself. Some organisms have "alternative splicing", where one sequence of DNA can be read several different ways and produce different proteins depending on which sections of the transcribed RNA (which the cell's ribosomes read to create proteins) are cut and which ones are kept. How the protein is handled after translation is also important, as proteins that are improperly folded (they don't have the right three-dimensional structure) can't perform their necessary function. So even IF everything else is correct, these external factors within the cell can still prevent a gene from working properly.
*** Other factors can also affect expression of proteins besides just the cell reading the genes in the DNA itself. Some organisms have "alternative splicing", where one sequence of DNA can be read several different ways and produce different proteins depending on which sections of the transcribed RNA (which the cell's ribosomes read to create proteins) are cut and which ones are kept. How the protein is handled after translation is also important, as proteins that are improperly folded (they don't have the right three-dimensional structure) can't perform their necessary function. So even IF everything else is correct, these external factors within the cell can still prevent a gene from working properly.
to:
# The actual expression of genes will be influenced by other factors in the environment. Just as the results of a cake recipe may vary due to things like humidity, temperature, and altitude, there's evidence that the results of a DNA "recipe" will vary due to outside influences. Cloned animals often display striking superficial differences from their genetic progenitors because an environment which favors the expression of different genes can coax different results from the same DNA. Apparently, identical twins only are identical (mostly; this is why scientists tend to call them "monozygotic") because they share the same DNA ''and'' the same prenatal environment. And even then environmental factors during their lifetime can change how their genes are expressed, giving them distinct differences from the same genome.
*** ** Other factors can also affect expression of proteins besides just the cell reading the genes in the DNA itself. Some organisms have "alternative splicing", where one sequence of DNA can be read several different ways and produce different proteins depending on which sections of the transcribed RNA (which the cell's ribosomes read to create proteins) are cut and which ones are kept. How the protein is handled after translation is also important, as proteins that are improperly folded (they don't have the right three-dimensional structure) can't perform their necessary function. So even IF everything else is correct, these external factors within the cell can still prevent a gene from working properly.
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Changed line(s) 20 (click to see context) from:
* As an example, genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one!
to:
* As an example, genes that get if a gene gets duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one!
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* Another way of affecting regulation of gene expression is to change genes that code for proteins that specifically turn ''other'' genes on or off (they bind to the regulatory sequences of DNA mentioned earlier, and either make it allow or restrict the cell's access to read a specific gene), and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
to:
* Another way of affecting regulation of gene expression is to change genes that code for proteins that specifically turn ''other'' genes on or off (they bind to the regulatory sequences of DNA mentioned earlier, and either make it allow or restrict the cell's access to read a specific gene), and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
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* A side note: this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control these early stages of development.
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* A side note: this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control these early stages of development.
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Changed line(s) 19 (click to see context) from:
But what about those sequences that ARE NOT coding regions? These spots serve as regulatory elements, which signal the cell to express (or stop expressing) other genes at certain times and places. Mutations here can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used.
to:
But what about those sequences that ARE are NOT coding regions? These spots serve as regulatory elements, which signal the cell to express (or stop expressing) other genes at certain times and places. Mutations here can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used.
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Phew! Time to put that biology degree to good use!
Changed line(s) 14,21 (click to see context) from:
Making changes to different parts of an organism's genome can have different effects.
The most fundamental function of DNA is obviously to contain genetic information in genes, which are then expressed to form proteins, as you undoubtedly know by now Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used. As an example, genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one! Other genes code for proteins that specifically turn ''other'' genes on or off, and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it to another. (As in fish-tomatos and other such 'horrors.') Our genetic code, using the nucleotide bases ACTG that are arranged to code for certain amino acids, is universal across all organisms. Whether you're a tulip, a monkey, or an E. coli bacterium, we all use the same system. However...
The most fundamental function of DNA is obviously to contain genetic information in genes, which are then expressed to form proteins, as you undoubtedly know by now Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used. As an example, genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one! Other genes code for proteins that specifically turn ''other'' genes on or off, and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it to another. (As in fish-tomatos and other such 'horrors.') Our genetic code, using the nucleotide bases ACTG that are arranged to code for certain amino acids, is universal across all organisms. Whether you're a tulip, a monkey, or an E. coli bacterium, we all use the same system. However...
to:
Making changes to different parts of an organism's genome can have different effects.
The most fundamental functioneffects, because genes within DNA themselves serve different purposes, and not all parts of DNA is obviously to contain genetic information in genes, which are then expressed to form proteins, as you undoubtedly know by now actually code for proteins!
Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one
*One common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other But what about those sequences that ARE NOT coding regions? These spots serve as regulatory elements elements, which signal the cell to express (or stop expressing) other genes at certain times and places. Mutations here can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used. As used.
*As an example, genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the oldone! Other one!
*Another way of affecting regulation of gene expression is to change genes that code for proteins that specifically turn ''other'' genes on oroff, off (they bind to the regulatory sequences of DNA mentioned earlier, and either make it allow or restrict the cell's access to read a specific gene), and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
However, while random mutations cause undirected changes to DNA, the recent establishment of Genetic Engineering allows us to take a more ''direct'' approach to tweaking genes. Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it toanother. (As another, as in fish-tomatos taking genes found in fish and other such 'horrors.') Our putting them in tomatoes! In reality, it's much less horrifying then it sounds because our genetic code, using the 4 nucleotide bases ACTG that are arranged to code for certain amino acids, is universal across all organisms. Whether you're a tulip, a monkey, or an E. coli bacterium, we all use the same system. However...
However, it's not as easy as just hitting Ctrl+C Ctrl+V...
The most fundamental function
Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks.
*One common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
*As an example, genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old
*Another way of affecting regulation of gene expression is to change genes that code for proteins that specifically turn ''other'' genes on or
However, while random mutations cause undirected changes to DNA, the recent establishment of Genetic Engineering allows us to take a more ''direct'' approach to tweaking genes. Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it to
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Changed line(s) 3,8 (click to see context) from:
While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the wrong genes are expressed, the right ones are never expressed at all, or the protein that is made doesn't work. (This is the cause of cancer, where a change in one of a cell's genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect! Incidentally, this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control these early stages of development.
There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used. Genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one! Other genes code for proteins that specifically turn ''other'' genes on or off, and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used. Genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one! Other genes code for proteins that specifically turn ''other'' genes on or off, and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
to:
While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code gene at any some point along the line can potentially screw things up chaotically as the for a few different reasons:
*The wrong genes areexpressed, the expressed
*The right ones are never expressed atall, or the all
*The protein that is made doesn'twork. (This work
This is the cause of cancer, where achange mutation in one of a cell's the genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate control.
However, not all changes to a gene are necessarily harmful. Our genetic code has some redundancy built in, andprecise alteration in an adult organism also can cause sometimes a non-harmful or even beneficial change, but it single substitution from one nucleotide to a different one will have no effect on the final product at all. Also, changes made only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect! Incidentally, effect!
* A side note: this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control these early stages of development.
There are also Making changes to different kinds parts of alterations that can be made to a an organism's genome that will affect the end product. can have different effects.
The most fundamental function of DNA is obviously to contain genetic information in genes, which are then expressed to form proteins, as you undoubtedly know by now Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used.Genes As an example, genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one! Other genes code for proteins that specifically turn ''other'' genes on or off, and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
*The wrong genes are
*The right ones are never expressed at
*The protein that is made doesn't
This is the cause of cancer, where a
However, not all changes to a gene are necessarily harmful. Our genetic code has some redundancy built in, and
* A side note: this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control these early stages of development.
The most fundamental function of DNA is obviously to contain genetic information in genes, which are then expressed to form proteins, as you undoubtedly know by now Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used.
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While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the wrong genes are expressed, the right ones are never expressed at all, or the protein that is made doesn't work. (This is the cause of cancer, where a change in one of a cell's genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect! Incidentally, this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control early development in the animal.
to:
While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the wrong genes are expressed, the right ones are never expressed at all, or the protein that is made doesn't work. (This is the cause of cancer, where a change in one of a cell's genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect! Incidentally, this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control these early development in the animal.
stages of development.
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Changed line(s) 3,4 (click to see context) from:
While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the wrong genes are expressed or the right ones are never expressed at all. (This is the cause of cancer, where a change in one of a cell's genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect! Incidentally, this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control early development in the animal.
to:
While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when certain proteins are produced and in which cells. The result of this complex regulatory system is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the wrong genes are expressed or expressed, the right ones are never expressed at all.all, or the protein that is made doesn't work. (This is the cause of cancer, where a change in one of a cell's genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. For example, if you change a gene that is expressed only early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect! Incidentally, this is one of the biggest challenges with cloning animals from adult cells, in that we haven't quite figured out how to reliably restart the expression of these genes that control early development in the animal.
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In the real world, the genetic code provides instructions for synthesizing proteins, and are regulated by various factors that affect when those proteins are produced and in which cells. The net end of this gene expression is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the new cells develop incorrectly. (This is the cause of cancer, where a change in one of a cell's genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. (For example, if you change a gene that is meant to control for development early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect!)
to:
While that statement is pretty simply, in reality the process is much more complex, with lots of details involved that can be changed to affect the final product. The cell itself has many natural checks and balances that control these details and determine when
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There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be used.
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There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. Proteins happen to be pretty modular in structure, and by inserting new sequences into regions that code for actual protein structure, scientists have been able to tack on new domains to already existing proteins that perform new tasks. For example, one common method of studying protein expression in cells is by inserting a sequence that codes for a green fluorescent protein structure into the gene that codes for the protein that they are interested in tracking. When that gene gets translated into the new protein, scientists can pick up the fluorescence from the new domain that is literally attached to the rest of the original protein.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to beused.
used. Genes that get duplicated in an organism's genome (an accidental hiccup that sometimes occurs during replication), the new copy can sometimes develop further mutations that affect when or where it is expressed and can evolve to perform new and different functions than the old one! Other genes code for proteins that specifically turn ''other'' genes on or off, and by changing the function of just one of these genes, you can affect entire processes of gene expression within the cell.
However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be
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***Other factors can also affect expression of proteins besides just the cell reading the genes in the DNA itself. Some organisms have "alternative splicing", where one sequence of DNA can be read several different ways and produce different proteins depending on which sections of the transcribed RNA (which the cell's ribosomes read to create proteins) are cut and which ones are kept. How the protein is handled after translation is also important, as proteins that are improperly folded (they don't have the right three-dimensional structure) can't perform their necessary function. So even IF everything else is correct, these external factors within the cell can still prevent a gene from working properly.
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Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it to another. (As in fish-tomatos and other such 'horrors.') Our genetic code is universal, a code for mRNA x (and, alternative splicing aside, thus protein x) will read off as mRNA x in any cell it has been transformed to and is being expressed in. However...
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Almost all GM research is, yes, currently devoted to picking up genes from one species and moving it to another. (As in fish-tomatos and other such 'horrors.') Our genetic code is universal, a code, using the nucleotide bases ACTG that are arranged to code for mRNA x (and, alternative splicing aside, thus protein x) will read off as mRNA x in any cell it has been transformed to and certain amino acids, is being expressed in.universal across all organisms. Whether you're a tulip, a monkey, or an E. coli bacterium, we all use the same system. However...
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There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be.
to:
There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not normally supposed to have it, or during a time in the cell's life cycle when it's not normally supposed to be.
be used.
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In the real world, the genetic code provides instructions for synthesizing proteins, and are regulated by various factors that affect when those proteins are produced and in which cells. The net end of this gene expression is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the new cells develop incorrectly (this is the cause of cancer). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. (For example, if you change a gene that is meant to control for development early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect!)
to:
In the real world, the genetic code provides instructions for synthesizing proteins, and are regulated by various factors that affect when those proteins are produced and in which cells. The net end of this gene expression is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the new cells develop incorrectly (this incorrectly. (This is the cause of cancer).cancer, where a change in one of a cell's genes that controls replication gets [=FUBARed=] and the cell divides out of control). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as that altered gene is expressed in the cell. (For example, if you change a gene that is meant to control for development early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect!)
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Changed line(s) 1,2 (click to see context) from:
In the real world, the genetic code provides instructions for synthesizing proteins, and are regulated by various factors that affect when those proteins are produced and in which cells. The net end of this gene expression is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the new cells develop incorrectly (this is the cause of cancer). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as old cells die off and are replaced with the new and altered ones.
to:
In the real world, the genetic code provides instructions for synthesizing proteins, and are regulated by various factors that affect when those proteins are produced and in which cells. The net end of this gene expression is a carefully coordinated process of development that starts at conception and regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the new cells develop incorrectly (this is the cause of cancer). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as old cells die off and are replaced with the new and that altered ones.
gene is expressed in the cell. (For example, if you change a gene that is meant to control for development early on in life in an ADULT organism, that gene isn't ever going to be used by the organism, and the change will never come into effect!)
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** Note that rare exceptions do exist. Extending the analogy, it would be like taking the "par-boiled potatoes" genome and adding "prehaeat oven" and "put potatoes in oven," which will in fact provide you with something edible.
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** Note that rare exceptions do exist. Extending the analogy, it would be like taking the "par-boiled potatoes" genome and adding "prehaeat "preheat oven" and "put potatoes in oven," which will in fact provide you with something edible.
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a) Timing is crucial: Adding bits of DNA to a fully grown organism will have unpredictable results. It's like adding flour to a cake after it has been baked. It's not quite the same as adding it before putting the cake in the oven. By this point in the organism's life span, the vast majority of its development and cell division is over and done with, just like how the cake is already finished baking.
b) The meaning of a gene depends on how it interacts with other genes: Sticking to the analogy here, if you take the "preheat oven" gene from the cake DNA and insert it into the salad DNA it will be useless because the salad DNA doesn't even have genes like "put the salad in the oven". The salad will be unaffected. If you then decide to add "put the salad in the oven" you will simply burn the salad. You can't just give the salad cake properties by taking instructions from the cake recipe and inserting them into the salad recipe (rare exceptions exist).
c) The actual expression of genes will be influenced by other factors in the environment. Just as the results of a cake recipe may vary due to things like humidity, temperature, and altitude, there's evidence that the results of a DNA "recipe" will vary due to outside influences. Cloned animals often display striking superficial differences from their genetic progenitors because an environment which favors the expression of different genes can coax different results from the same DNA. Apparently, identical twins only are identical (mostly; this is why scientists tend to call them "monozygotic") because they share the same DNA ''and'' the same prenatal environment. And even then environmental factors during their lifetime can change how their genes are expressed, giving them distinct differences from the same genome.
b) The meaning of a gene depends on how it interacts with other genes: Sticking to the analogy here, if you take the "preheat oven" gene from the cake DNA and insert it into the salad DNA it will be useless because the salad DNA doesn't even have genes like "put the salad in the oven". The salad will be unaffected. If you then decide to add "put the salad in the oven" you will simply burn the salad. You can't just give the salad cake properties by taking instructions from the cake recipe and inserting them into the salad recipe (rare exceptions exist).
c) The actual expression of genes will be influenced by other factors in the environment. Just as the results of a cake recipe may vary due to things like humidity, temperature, and altitude, there's evidence that the results of a DNA "recipe" will vary due to outside influences. Cloned animals often display striking superficial differences from their genetic progenitors because an environment which favors the expression of different genes can coax different results from the same DNA. Apparently, identical twins only are identical (mostly; this is why scientists tend to call them "monozygotic") because they share the same DNA ''and'' the same prenatal environment. And even then environmental factors during their lifetime can change how their genes are expressed, giving them distinct differences from the same genome.
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b)
# The meaning of a gene depends on how it interacts with other genes: Sticking to the analogy here, if you take the "preheat oven" gene from the cake DNA and insert it into the salad DNA it will be useless because the salad DNA doesn't even have genes like "put the salad in the oven". The salad will be unaffected. If you then decide to add "put the salad in the oven" you will simply burn the salad. You can't just give the salad cake properties by taking instructions from the cake recipe and inserting them into the salad
** Note that rare exceptions
c)
# The actual expression of genes will be influenced by other factors in the environment. Just as the results of a cake recipe may vary due to things like humidity, temperature, and altitude, there's evidence that the results of a DNA "recipe" will vary due to outside influences. Cloned animals often display striking superficial differences from their genetic progenitors because an environment which favors the expression of different genes can coax different results from the same DNA. Apparently, identical twins only are identical (mostly; this is why scientists tend to call them "monozygotic") because they share the same DNA ''and'' the same prenatal environment. And even then environmental factors during their lifetime can change how their genes are expressed, giving them distinct differences from the same genome.
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Just cleaning up a few misleading explanations (and the bit about homeotic genes I think is more confusing than helpful to someone who\'s not familiar with the material)
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In the real world, the genetic code instructs a body how to grow. This process takes the creature in question from conception to adulthood, and makes sure that any replacement cells are in their proper place. An accidental alteration to the code at any point can screw things up chaotically as the new cells develop incorrectly (this is the cause of cancer). A deliberate and precise alteration also can cause a non-harmful or even beneficial change, but it will only appear as fast as old cells die off and are replaced with the new and altered ones. It should take months if not years to see results either way.
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In the real world, the genetic code instructs provides instructions for synthesizing proteins, and are regulated by various factors that affect when those proteins are produced and in which cells. The net end of this gene expression is a body how to grow. This carefully coordinated process takes the creature in question from of development that starts at conception to adulthood, and makes sure that any replacement cells are in their proper place.regulates the organism's growth, development, and eventual aging and death. An accidental alteration to the code at any point can screw things up chaotically as the new cells develop incorrectly (this is the cause of cancer). A deliberate and precise alteration in an adult organism also can cause a non-harmful or even beneficial change, but it will only appear as fast as old cells die off and are replaced with the new and altered ones. It should take months if ones.
There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are notyears normally supposed to see results either way.
have it, or during a time in the cell's life cycle when it's not normally supposed to be.
There are also different kinds of alterations that can be made to a genome that will affect the end product. Mutations made within the "exons" of a gene (that is, the segments of DNA that actually code for the structure of the protein gene product itself) will affect the structure, and thus the function of the protein made. However, mutations in other regulatory elements can change when and where the protein is expressed, meaning it is made in cells that are not
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a) Timing is crucial: Adding bits of DNA to a fully grown organism will have unpredictable results. It's like adding flour to a cake after it has been baked. It's not quite the same as adding it before putting the cake in the oven.
to:
a) Timing is crucial: Adding bits of DNA to a fully grown organism will have unpredictable results. It's like adding flour to a cake after it has been baked. It's not quite the same as adding it before putting the cake in the oven.
oven. By this point in the organism's life span, the vast majority of its development and cell division is over and done with, just like how the cake is already finished baking.
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c) The actual expression of genes will be influenced by other factors in the environment. Just as the results of a cake recipe may vary due to things like humidity, temperature, and altitude, there's evidence that the results of a DNA "recipe" will vary due to outside influences. Cloned animals often display striking superficial differences from their genetic progenitors because an environment which favors the expression of different genes can coax different results from the same DNA. Apparently, identical twins only are identical (mostly; this is why scientists tend to call them "monozygotic") because they share the same DNA ''and'' the same prenatal environment.
Genetics are not understood enough to make definitive statements. Experiments have shown that a particular segment of genes in fruit flies is identical to some that humans have; removing these genes from fruit flies causes them to develop without eyes. Altering them and putting in other genes from the same fly can cause the fly to grow [[{{Squick}} legs]] or [[BodyHorror wings]] where its [[NightmareFuel eyes should be]]. Of course, fruit flies are a favorite of geneticists because they have short life spans and smaller genomes which makes their genes easy to understand and figure out; doing something like that to more complex organisms might not be so easy.
Genetics are not understood enough to make definitive statements. Experiments have shown that a particular segment of genes in fruit flies is identical to some that humans have; removing these genes from fruit flies causes them to develop without eyes. Altering them and putting in other genes from the same fly can cause the fly to grow [[{{Squick}} legs]] or [[BodyHorror wings]] where its [[NightmareFuel eyes should be]]. Of course, fruit flies are a favorite of geneticists because they have short life spans and smaller genomes which makes their genes easy to understand and figure out; doing something like that to more complex organisms might not be so easy.
to:
c) The actual expression of genes will be influenced by other factors in the environment. Just as the results of a cake recipe may vary due to things like humidity, temperature, and altitude, there's evidence that the results of a DNA "recipe" will vary due to outside influences. Cloned animals often display striking superficial differences from their genetic progenitors because an environment which favors the expression of different genes can coax different results from the same DNA. Apparently, identical twins only are identical (mostly; this is why scientists tend to call them "monozygotic") because they share the same DNA ''and'' the same prenatal environment. \n\nGenetics are not understood enough to make definitive statements. Experiments have shown that a particular segment of And even then environmental factors during their lifetime can change how their genes in fruit flies is identical to some that humans have; removing these genes from fruit flies causes are expressed, giving them to develop without eyes. Altering them and putting in other genes distinct differences from the same fly can cause the fly genome.
Genetics is also still a field that is undergoing extensive continued research and is nowhere close togrow [[{{Squick}} legs]] or [[BodyHorror wings]] where its [[NightmareFuel eyes should be]]. Of course, fruit flies are a favorite of geneticists because they being explained completely yet (although we certainly have short come a long way since Mendel's experiments with peas). New ways of regulating gene expression, clues into how mutations help to drive evolution in organisms, and other breakthroughs are still being made even today. This, combined with the potential benefits of such research, like eradicating diseases, prolonging lifespans, and generally improving life spans and smaller genomes which makes their genes easy to understand and figure out; doing something like conditions for people, make it a scientific area that to more complex organisms might not be so easy.
has gained a lot of attention and interest in the general population recently.
Genetics is also still a field that is undergoing extensive continued research and is nowhere close to
