Protein Structure - Biology
Card 0 of 96
Which of the following refers to the bond between two amino acids?
Which of the following refers to the bond between two amino acids?
A peptide bond is formed between the carboxyl group and amino group of adjoining amino acids. The energy in proteins is released when peptide bonds are broken. Peptide bonds also determine the primary structure of proteins.
An ionic bond is formed when one element loses an electron and another element gains an electron. Ionic bonds most frequently form between metals and non-metals, and are not commonly seen in proteins.
A glycosidic bond is formed between a carbohydrate and another molecule. Glycosidic bonds can help form carbohydrate polymers, like glycogen, or link sugars to other groups, like in the DNA backbone.
An ester bond can be found in fatty acids, and contains a carbonyl group next to an ether linkage.
A peptide bond is formed between the carboxyl group and amino group of adjoining amino acids. The energy in proteins is released when peptide bonds are broken. Peptide bonds also determine the primary structure of proteins.
An ionic bond is formed when one element loses an electron and another element gains an electron. Ionic bonds most frequently form between metals and non-metals, and are not commonly seen in proteins.
A glycosidic bond is formed between a carbohydrate and another molecule. Glycosidic bonds can help form carbohydrate polymers, like glycogen, or link sugars to other groups, like in the DNA backbone.
An ester bond can be found in fatty acids, and contains a carbonyl group next to an ether linkage.
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Collagen is an example of which type of protein?
Collagen is an example of which type of protein?
Collagen is the most abundant protein in the human body. It adds great strength and flexibility to skin, tendons, and ligaments. These qualities are characteristic of structural proteins.
Globular proteins are generally rounded, protecting a nonpolar center from the aqueous environment around the protein. Most cytoplasmic proteins and enzymes are globular proteins. In contrast, fibrous proteins are generally elongated and designed for structural support; collagen is a fibrous protein, in addition to a structural protein. Integral proteins span the plasma membrane, often creating channels.
Collagen is the most abundant protein in the human body. It adds great strength and flexibility to skin, tendons, and ligaments. These qualities are characteristic of structural proteins.
Globular proteins are generally rounded, protecting a nonpolar center from the aqueous environment around the protein. Most cytoplasmic proteins and enzymes are globular proteins. In contrast, fibrous proteins are generally elongated and designed for structural support; collagen is a fibrous protein, in addition to a structural protein. Integral proteins span the plasma membrane, often creating channels.
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Which of the following types of protein can move around within the lipid bilayer?
Which of the following types of protein can move around within the lipid bilayer?
Proteins are classified into several categories based on where they perform their function. Peripheral membrane proteins span only one side of the lipid bilayer and thus have mobility. Unlike integral membrane proteins, which span the entire lipid bilayer, peripheral membrane proteins have the liberty of traveling from layer to layer as well as flip flop between the two bilayers.
Proteins are classified into several categories based on where they perform their function. Peripheral membrane proteins span only one side of the lipid bilayer and thus have mobility. Unlike integral membrane proteins, which span the entire lipid bilayer, peripheral membrane proteins have the liberty of traveling from layer to layer as well as flip flop between the two bilayers.
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Which type of enzyme is responsible for rearranging a substrate, but not altering its chemical formula?
Which type of enzyme is responsible for rearranging a substrate, but not altering its chemical formula?
Isomers are molecules that have the same molecular formula, but have different chemical structures. Isomerases are enzymes that are able to rearrange the structure of a molecule while keeping its chemical formula the same.
Isomers are molecules that have the same molecular formula, but have different chemical structures. Isomerases are enzymes that are able to rearrange the structure of a molecule while keeping its chemical formula the same.
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Complete and incomplete are classifications of .
Complete and incomplete are classifications of .
A protein consists of amino acids. Essential amino acids cannot be synthesized by the body, and must be included in the diet. A protein containing all of the essential amino acids is called a complete protein. An incomplete protein lacks one or more of the essential amino acids.
Neurotransmitters are chemicals that relay messages from one cell to the next. Enzymes are protein catalysts that speed up biological reactions. Minerals are inorganic compounds and are not present in the body in large amounts, with the exception of hydroxyapatite crystal found in bones. Electrolytes are ionic salts in the blood, tissue fluids, and cells, such as sodium, potassium, and chlorine.
A protein consists of amino acids. Essential amino acids cannot be synthesized by the body, and must be included in the diet. A protein containing all of the essential amino acids is called a complete protein. An incomplete protein lacks one or more of the essential amino acids.
Neurotransmitters are chemicals that relay messages from one cell to the next. Enzymes are protein catalysts that speed up biological reactions. Minerals are inorganic compounds and are not present in the body in large amounts, with the exception of hydroxyapatite crystal found in bones. Electrolytes are ionic salts in the blood, tissue fluids, and cells, such as sodium, potassium, and chlorine.
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Bob, a biologist who was researching a new eukaryotic unicellular species, wanted to study a particular protein Y. After obtaining and purifying the sample, Bob discovered that this protein had 3 subunits: A, B, and C. Through substantive scientific analysis, Bob discovered that protein Y operated in a membrane; however, he could not deduce which particular membrane. Nonetheless, Bob found that only subunit B was traversed through the interior of the membrane. With Bob’s findings, please answer the following questions.
What is NOT a possible function of protein Y?
Bob, a biologist who was researching a new eukaryotic unicellular species, wanted to study a particular protein Y. After obtaining and purifying the sample, Bob discovered that this protein had 3 subunits: A, B, and C. Through substantive scientific analysis, Bob discovered that protein Y operated in a membrane; however, he could not deduce which particular membrane. Nonetheless, Bob found that only subunit B was traversed through the interior of the membrane. With Bob’s findings, please answer the following questions.
What is NOT a possible function of protein Y?
Receptor proteins in a signal transduction pathways can be found both within the plasma membrane or cytosol; as a result, protein Y could potentially function as a receptor. The electron transport chain occurs in the mitochondria, and relies on the movement of electrons; the proteins that “move” these electrons, and subsequently pump protons (creating a gradient), are located in the inner membrane. An antiporter functions in a membrane as well due to its importance in creating and maintaining a concentration gradient. In a similar fashion, nuclear trafficking refers to the regulation or movement of molecules in and out of the nuclear membrane. Last, DNA replication occurs in the nucleus and does not involve a membrane of any sort; therefore, the membrane dwelling protein Y cannot function in this process.
Receptor proteins in a signal transduction pathways can be found both within the plasma membrane or cytosol; as a result, protein Y could potentially function as a receptor. The electron transport chain occurs in the mitochondria, and relies on the movement of electrons; the proteins that “move” these electrons, and subsequently pump protons (creating a gradient), are located in the inner membrane. An antiporter functions in a membrane as well due to its importance in creating and maintaining a concentration gradient. In a similar fashion, nuclear trafficking refers to the regulation or movement of molecules in and out of the nuclear membrane. Last, DNA replication occurs in the nucleus and does not involve a membrane of any sort; therefore, the membrane dwelling protein Y cannot function in this process.
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Which of the following refers to the bond between two amino acids?
Which of the following refers to the bond between two amino acids?
A peptide bond is formed between the carboxyl group and amino group of adjoining amino acids. The energy in proteins is released when peptide bonds are broken. Peptide bonds also determine the primary structure of proteins.
An ionic bond is formed when one element loses an electron and another element gains an electron. Ionic bonds most frequently form between metals and non-metals, and are not commonly seen in proteins.
A glycosidic bond is formed between a carbohydrate and another molecule. Glycosidic bonds can help form carbohydrate polymers, like glycogen, or link sugars to other groups, like in the DNA backbone.
An ester bond can be found in fatty acids, and contains a carbonyl group next to an ether linkage.
A peptide bond is formed between the carboxyl group and amino group of adjoining amino acids. The energy in proteins is released when peptide bonds are broken. Peptide bonds also determine the primary structure of proteins.
An ionic bond is formed when one element loses an electron and another element gains an electron. Ionic bonds most frequently form between metals and non-metals, and are not commonly seen in proteins.
A glycosidic bond is formed between a carbohydrate and another molecule. Glycosidic bonds can help form carbohydrate polymers, like glycogen, or link sugars to other groups, like in the DNA backbone.
An ester bond can be found in fatty acids, and contains a carbonyl group next to an ether linkage.
Compare your answer with the correct one above
Collagen is an example of which type of protein?
Collagen is an example of which type of protein?
Collagen is the most abundant protein in the human body. It adds great strength and flexibility to skin, tendons, and ligaments. These qualities are characteristic of structural proteins.
Globular proteins are generally rounded, protecting a nonpolar center from the aqueous environment around the protein. Most cytoplasmic proteins and enzymes are globular proteins. In contrast, fibrous proteins are generally elongated and designed for structural support; collagen is a fibrous protein, in addition to a structural protein. Integral proteins span the plasma membrane, often creating channels.
Collagen is the most abundant protein in the human body. It adds great strength and flexibility to skin, tendons, and ligaments. These qualities are characteristic of structural proteins.
Globular proteins are generally rounded, protecting a nonpolar center from the aqueous environment around the protein. Most cytoplasmic proteins and enzymes are globular proteins. In contrast, fibrous proteins are generally elongated and designed for structural support; collagen is a fibrous protein, in addition to a structural protein. Integral proteins span the plasma membrane, often creating channels.
Compare your answer with the correct one above
Which of the following types of protein can move around within the lipid bilayer?
Which of the following types of protein can move around within the lipid bilayer?
Proteins are classified into several categories based on where they perform their function. Peripheral membrane proteins span only one side of the lipid bilayer and thus have mobility. Unlike integral membrane proteins, which span the entire lipid bilayer, peripheral membrane proteins have the liberty of traveling from layer to layer as well as flip flop between the two bilayers.
Proteins are classified into several categories based on where they perform their function. Peripheral membrane proteins span only one side of the lipid bilayer and thus have mobility. Unlike integral membrane proteins, which span the entire lipid bilayer, peripheral membrane proteins have the liberty of traveling from layer to layer as well as flip flop between the two bilayers.
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Which type of enzyme is responsible for rearranging a substrate, but not altering its chemical formula?
Which type of enzyme is responsible for rearranging a substrate, but not altering its chemical formula?
Isomers are molecules that have the same molecular formula, but have different chemical structures. Isomerases are enzymes that are able to rearrange the structure of a molecule while keeping its chemical formula the same.
Isomers are molecules that have the same molecular formula, but have different chemical structures. Isomerases are enzymes that are able to rearrange the structure of a molecule while keeping its chemical formula the same.
Compare your answer with the correct one above
Complete and incomplete are classifications of .
Complete and incomplete are classifications of .
A protein consists of amino acids. Essential amino acids cannot be synthesized by the body, and must be included in the diet. A protein containing all of the essential amino acids is called a complete protein. An incomplete protein lacks one or more of the essential amino acids.
Neurotransmitters are chemicals that relay messages from one cell to the next. Enzymes are protein catalysts that speed up biological reactions. Minerals are inorganic compounds and are not present in the body in large amounts, with the exception of hydroxyapatite crystal found in bones. Electrolytes are ionic salts in the blood, tissue fluids, and cells, such as sodium, potassium, and chlorine.
A protein consists of amino acids. Essential amino acids cannot be synthesized by the body, and must be included in the diet. A protein containing all of the essential amino acids is called a complete protein. An incomplete protein lacks one or more of the essential amino acids.
Neurotransmitters are chemicals that relay messages from one cell to the next. Enzymes are protein catalysts that speed up biological reactions. Minerals are inorganic compounds and are not present in the body in large amounts, with the exception of hydroxyapatite crystal found in bones. Electrolytes are ionic salts in the blood, tissue fluids, and cells, such as sodium, potassium, and chlorine.
Compare your answer with the correct one above
Bob, a biologist who was researching a new eukaryotic unicellular species, wanted to study a particular protein Y. After obtaining and purifying the sample, Bob discovered that this protein had 3 subunits: A, B, and C. Through substantive scientific analysis, Bob discovered that protein Y operated in a membrane; however, he could not deduce which particular membrane. Nonetheless, Bob found that only subunit B was traversed through the interior of the membrane. With Bob’s findings, please answer the following questions.
What is NOT a possible function of protein Y?
Bob, a biologist who was researching a new eukaryotic unicellular species, wanted to study a particular protein Y. After obtaining and purifying the sample, Bob discovered that this protein had 3 subunits: A, B, and C. Through substantive scientific analysis, Bob discovered that protein Y operated in a membrane; however, he could not deduce which particular membrane. Nonetheless, Bob found that only subunit B was traversed through the interior of the membrane. With Bob’s findings, please answer the following questions.
What is NOT a possible function of protein Y?
Receptor proteins in a signal transduction pathways can be found both within the plasma membrane or cytosol; as a result, protein Y could potentially function as a receptor. The electron transport chain occurs in the mitochondria, and relies on the movement of electrons; the proteins that “move” these electrons, and subsequently pump protons (creating a gradient), are located in the inner membrane. An antiporter functions in a membrane as well due to its importance in creating and maintaining a concentration gradient. In a similar fashion, nuclear trafficking refers to the regulation or movement of molecules in and out of the nuclear membrane. Last, DNA replication occurs in the nucleus and does not involve a membrane of any sort; therefore, the membrane dwelling protein Y cannot function in this process.
Receptor proteins in a signal transduction pathways can be found both within the plasma membrane or cytosol; as a result, protein Y could potentially function as a receptor. The electron transport chain occurs in the mitochondria, and relies on the movement of electrons; the proteins that “move” these electrons, and subsequently pump protons (creating a gradient), are located in the inner membrane. An antiporter functions in a membrane as well due to its importance in creating and maintaining a concentration gradient. In a similar fashion, nuclear trafficking refers to the regulation or movement of molecules in and out of the nuclear membrane. Last, DNA replication occurs in the nucleus and does not involve a membrane of any sort; therefore, the membrane dwelling protein Y cannot function in this process.
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Which of the following inhibitors will block the active site of a protein?
Which of the following inhibitors will block the active site of a protein?
Proteins can be inhibited in numerous ways by different types of inhibitors. Competitive inhibitors will compete with substrate for the active site to block the protein from performing its function. If there is enough substrate and very little competitive inhibitor, proteins will perform their functions almost as if there were no competitive inhibitors.
In contrast, allosteric inhibitors bind to regions of the protein away from the active site, but change the shape of the active site such that substrate cannot bind. Since there is no direct competition, increasing substrate concentration cannot overcome allosteric inhibition. Non-competitive inhibition is a type of allosteric inhibition. Uncompetitive inhibition occurs when the inhibitor will only bind to the enzyme-substrate complex, locking the substrate in place and preventing other substrates from binding.
Proteins can be inhibited in numerous ways by different types of inhibitors. Competitive inhibitors will compete with substrate for the active site to block the protein from performing its function. If there is enough substrate and very little competitive inhibitor, proteins will perform their functions almost as if there were no competitive inhibitors.
In contrast, allosteric inhibitors bind to regions of the protein away from the active site, but change the shape of the active site such that substrate cannot bind. Since there is no direct competition, increasing substrate concentration cannot overcome allosteric inhibition. Non-competitive inhibition is a type of allosteric inhibition. Uncompetitive inhibition occurs when the inhibitor will only bind to the enzyme-substrate complex, locking the substrate in place and preventing other substrates from binding.
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The active site of a protein works in a way similar to .
The active site of a protein works in a way similar to .
The active site on a protein is the area where a substrate can attach. This relationship is most often described using a metaphor of a lock and a key because each protein has an active site specific to one substrate much like a lock can only be opened by one key.
The active site on a protein is the area where a substrate can attach. This relationship is most often described using a metaphor of a lock and a key because each protein has an active site specific to one substrate much like a lock can only be opened by one key.
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modification of an enzyme permits an effector molecule to bind the enzyme at a site other than the active site. This can modulate the enzyme's activity to make it either more or less active.
modification of an enzyme permits an effector molecule to bind the enzyme at a site other than the active site. This can modulate the enzyme's activity to make it either more or less active.
The key here is to know that if something binds the enzyme at a location other than the active site, the type of modification is defined as allosteric. The other words more generally describe things that can bind to receptors, enzymes, etc., but the best and most specific answer is "allosteric."
The key here is to know that if something binds the enzyme at a location other than the active site, the type of modification is defined as allosteric. The other words more generally describe things that can bind to receptors, enzymes, etc., but the best and most specific answer is "allosteric."
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Which of the following best describes why an enzyme loses its catalytic capabilities when exposed to extremely high temperatures?
Which of the following best describes why an enzyme loses its catalytic capabilities when exposed to extremely high temperatures?
It is important to know that when exposed to high temperatures, all proteins become denatured, and lose their native shape/conformation.
This has nothing to do with the activation energy of the reaction (eliminating that answer). While some substrates may be degraded at high temperatures, the word "all" renders this answer incorrect, nor does this describe what happens to the enzyme. Covalent modificatinos can change enzymatic function, but do not have anything to do with higher temperature.
The correct answer is that the enzyme itself is denatured, thus changing the shape and the way the active site is shaped, resulting in an inability to efficiently bind its substrate. The structure of the enzyme is dictated by intermolecular forces, which are susceptible to interference from temperature changes (unlike covalent bonds).
It is important to know that when exposed to high temperatures, all proteins become denatured, and lose their native shape/conformation.
This has nothing to do with the activation energy of the reaction (eliminating that answer). While some substrates may be degraded at high temperatures, the word "all" renders this answer incorrect, nor does this describe what happens to the enzyme. Covalent modificatinos can change enzymatic function, but do not have anything to do with higher temperature.
The correct answer is that the enzyme itself is denatured, thus changing the shape and the way the active site is shaped, resulting in an inability to efficiently bind its substrate. The structure of the enzyme is dictated by intermolecular forces, which are susceptible to interference from temperature changes (unlike covalent bonds).
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Which mode of enzyme inhibition involves an inhibitor molecule binding the active site of the enzyme?
Which mode of enzyme inhibition involves an inhibitor molecule binding the active site of the enzyme?
Competitive inhibition is the only type of inhibition in which the inhibitor molecule directly binds the active site of the enzyme, thereby 'competing' with the actual substrate for location on the enzyme. The other choices involve binding elsewhere on the enzyme (non-competitive) or binding the enzyme-substrate complex but not an isolated enzyme (mixed), but none of them describe binding the active site except for competitive.
Competitive inhibition is the only type of inhibition in which the inhibitor molecule directly binds the active site of the enzyme, thereby 'competing' with the actual substrate for location on the enzyme. The other choices involve binding elsewhere on the enzyme (non-competitive) or binding the enzyme-substrate complex but not an isolated enzyme (mixed), but none of them describe binding the active site except for competitive.
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Which of the following inhibitors will block the active site of a protein?
Which of the following inhibitors will block the active site of a protein?
Proteins can be inhibited in numerous ways by different types of inhibitors. Competitive inhibitors will compete with substrate for the active site to block the protein from performing its function. If there is enough substrate and very little competitive inhibitor, proteins will perform their functions almost as if there were no competitive inhibitors.
In contrast, allosteric inhibitors bind to regions of the protein away from the active site, but change the shape of the active site such that substrate cannot bind. Since there is no direct competition, increasing substrate concentration cannot overcome allosteric inhibition. Non-competitive inhibition is a type of allosteric inhibition. Uncompetitive inhibition occurs when the inhibitor will only bind to the enzyme-substrate complex, locking the substrate in place and preventing other substrates from binding.
Proteins can be inhibited in numerous ways by different types of inhibitors. Competitive inhibitors will compete with substrate for the active site to block the protein from performing its function. If there is enough substrate and very little competitive inhibitor, proteins will perform their functions almost as if there were no competitive inhibitors.
In contrast, allosteric inhibitors bind to regions of the protein away from the active site, but change the shape of the active site such that substrate cannot bind. Since there is no direct competition, increasing substrate concentration cannot overcome allosteric inhibition. Non-competitive inhibition is a type of allosteric inhibition. Uncompetitive inhibition occurs when the inhibitor will only bind to the enzyme-substrate complex, locking the substrate in place and preventing other substrates from binding.
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The active site of a protein works in a way similar to .
The active site of a protein works in a way similar to .
The active site on a protein is the area where a substrate can attach. This relationship is most often described using a metaphor of a lock and a key because each protein has an active site specific to one substrate much like a lock can only be opened by one key.
The active site on a protein is the area where a substrate can attach. This relationship is most often described using a metaphor of a lock and a key because each protein has an active site specific to one substrate much like a lock can only be opened by one key.
Compare your answer with the correct one above
modification of an enzyme permits an effector molecule to bind the enzyme at a site other than the active site. This can modulate the enzyme's activity to make it either more or less active.
modification of an enzyme permits an effector molecule to bind the enzyme at a site other than the active site. This can modulate the enzyme's activity to make it either more or less active.
The key here is to know that if something binds the enzyme at a location other than the active site, the type of modification is defined as allosteric. The other words more generally describe things that can bind to receptors, enzymes, etc., but the best and most specific answer is "allosteric."
The key here is to know that if something binds the enzyme at a location other than the active site, the type of modification is defined as allosteric. The other words more generally describe things that can bind to receptors, enzymes, etc., but the best and most specific answer is "allosteric."
Compare your answer with the correct one above