Problem 162
Question
Choose one of the following terms to match the description 1 given in statements \((1)-(17) .\) All of the following pertain to proteins or carbohydrates. a. aldohexose b. saliva c. cellulose d. \(\mathrm{CH}_{2} \mathrm{O}\) e. cysteine f. denaturation g. disaccharides h. disulfide i. globular j. glycogen k. glycoside linkage I. hydrophobic m. ketohexoses n. oxytocin o. pleated sheet p. polypeptide q. primary structure (1) polymer consisting of many amino acids (2) linkage that forms between two cysteine species (3) peptide hormone that triggers milk secretion (4) proteins with roughly spherical shape (5) sequence of amino acids in a protein (6) silk protein secondary structure (7) water-repelling amino acid side chain (8) amino acid responsible for permanent wave in hair (9) breakdown of a protein's tertiary and/or secondary structure (10) animal polymer of glucose (11) \(-\mathrm{C}-\mathrm{O}-\mathrm{C}-\) bond between rings in disaccharide sugars (12) empirical formula leading to the name carbohydrate (13) where enzymes catalyzing the breakdown of glycoside linkages are found (14) six-carbon ketone sugars (15) structural component of plants, polymer of glucose (16) sugars consisting of two monomer units (17) six-carbon aldehyde sugars
Step-by-Step Solution
Verified Answer
(1) p: polypeptide
(2) h: disulfide
(3) n: oxytocin
(4) i: globular
(5) q: primary structure
(6) o: pleated sheet
(7) l: hydrophobic
(8) e: cysteine
(9) f: denaturation
(10) j: glycogen
(11) k: glycoside linkage
(12) d: CH₂O
(13) b: saliva
(14) m: ketohexoses
(15) c: cellulose
(16) g: disaccharides
(17) a: aldohexose
1Step 1: Match term to statement
The correct term for this statement is 'polypeptide' (p).
(2) Linkage that forms between two cysteine species
2Step 2: Match term to statement
The correct term for this statement is 'disulfide' (h).
(3) Peptide hormone that triggers milk secretion
3Step 3: Match term to statement
The correct term for this statement is 'oxytocin' (n).
(4) Proteins with roughly spherical shape
4Step 4: Match term to statement
The correct term for this statement is 'globular' (i).
(5) Sequence of amino acids in a protein
5Step 5: Match term to statement
The correct term for this statement is 'primary structure' (q).
(6) Silk protein secondary structure
6Step 6: Match term to statement
The correct term for this statement is 'pleated sheet' (o).
(7) Water-repelling amino acid side chain
7Step 7: Match term to statement
The correct term for this statement is 'hydrophobic' (l).
(8) Amino acid responsible for permanent wave in hair
8Step 8: Match term to statement
The correct term for this statement is 'cysteine' (e).
(9) Breakdown of a protein's tertiary and/or secondary structure
9Step 9: Match term to statement
The correct term for this statement is 'denaturation' (f).
(10) Animal polymer of glucose
10Step 10: Match term to statement
The correct term for this statement is 'glycogen' (j).
(11) -C-O-C- bond between rings in disaccharide sugars
11Step 11: Match term to statement
The correct term for this statement is 'glycoside linkage' (k).
(12) Empirical formula leading to the name carbohydrate
12Step 12: Match term to statement
The correct term for this statement is 'CH₂O' (d).
(13) Where enzymes catalyzing the breakdown of glycoside linkages are found
13Step 13: Match term to statement
The correct term for this statement is 'saliva' (b).
(14) Six-carbon ketone sugars
14Step 14: Match term to statement
The correct term for this statement is 'ketohexoses' (m).
(15) Structural component of plants, polymer of glucose
15Step 15: Match term to statement
The correct term for this statement is 'cellulose' (c).
(16) Sugars consisting of two monomer units
16Step 16: Match term to statement
The correct term for this statement is 'disaccharides' (g).
(17) Six-carbon aldehyde sugars
17Step 17: Match term to statement
The correct term for this statement is 'aldohexose' (a).
Key Concepts
Protein StructureCarbohydratesAmino AcidsPolysaccharidesEnzymatic Reactions
Protein Structure
Understanding protein structure is essential for grasping how these molecular machines carry out a multitude of functions in living organisms. Proteins are made up of amino acids that link together to form long chains called polypeptides. These chains fold into specific shapes dictated by interactions between the amino acids, such as hydrogen bonds and disulfide bonds.
The primary structure refers simply to the sequence of amino acids, which determines the higher-level structures the protein can adopt. Secondary structures include alpha helices and beta pleated sheets, which are stabilized by hydrogen bonding and create patterns within the protein. Tertiary structure is the overall three-dimensional shape of a single protein molecule, while quaternary structure refers to the complex of multiple protein molecules or polypeptide chains. Changes in structure, such as denaturation, can lead to a loss of function, underscoring the importance of protein structure in biochemistry education.
The primary structure refers simply to the sequence of amino acids, which determines the higher-level structures the protein can adopt. Secondary structures include alpha helices and beta pleated sheets, which are stabilized by hydrogen bonding and create patterns within the protein. Tertiary structure is the overall three-dimensional shape of a single protein molecule, while quaternary structure refers to the complex of multiple protein molecules or polypeptide chains. Changes in structure, such as denaturation, can lead to a loss of function, underscoring the importance of protein structure in biochemistry education.
Carbohydrates
Carbohydrates play a pivotal role in providing energy and structural materials in living organisms. They are composed of carbon, hydrogen, and oxygen, typically with the empirical formula \( CH_2O \), hence their name. Carbohydrates are categorized based on their size or the number of sugar units they contain: monosaccharides like glucose are the simplest form, with disaccharides, such as lactose, being formed by two sugar units linked by glycoside linkages.
Aldohexoses and ketohexoses are six-carbon sugars that differ in the placement of their carbonyl groups. Aldohexoses, such as glucose, have an aldehyde group at the end of the carbon chain, while ketohexoses, like fructose, have a ketone group in the middle of the chain. Both types of hexoses are important energy sources and building blocks for larger carbohydrates.
Aldohexoses and ketohexoses are six-carbon sugars that differ in the placement of their carbonyl groups. Aldohexoses, such as glucose, have an aldehyde group at the end of the carbon chain, while ketohexoses, like fructose, have a ketone group in the middle of the chain. Both types of hexoses are important energy sources and building blocks for larger carbohydrates.
Amino Acids
Amino acids are the building blocks of proteins, each featuring a central carbon atom, an amino group, a carboxyl group, and a distinctive side chain. The side chains, also known as R groups, can be categorized based on their properties such as hydrophobic, which avoids water, or hydrophilic, which is attracted to water. Some amino acids, such as cysteine, can form disulfide bonds, which are sulfur-sulfur links that help stabilize proteins' three-dimensional structures. The diversity of amino acids and the sequence in which they are arranged determine a protein's structure and function.
Polysaccharides
Polysaccharides are long carbohydrate molecules composed of monosaccharide units bonded together. They serve various functions, from storage of energy to providing structural support. Glycogen, for instance, is an animal polysaccharide that efficiently stores glucose for energy. Cellulose, on the other hand, is a crucial structural component in plant cell walls. Though both glycogen and cellulose are polymers of glucose, the glycoside linkages in cellulose make it tough and indigestible for most animals, highlighting the importance of bond types and arrangements in polysaccharide functions.
Enzymatic Reactions
Enzymatic reactions are fundamental to metabolic processes, with enzymes acting as catalysts that accelerate chemical reactions without being consumed. For instance, enzymes in saliva, such as amylase, catalyze the breakdown of glycoside linkages in starches to sugars, aiding in digestion. Enzymes work by lowering the activation energy of a reaction, ensuring that bodily processes occur rapidly enough to sustain life. They have remarkable specificity, usually catalyzing only one kind of reaction, which is a testament to the intricacy of biological function at the molecular level.
Other exercises in this chapter
Problem 160
Integrative Problems. These problems require the integration of multiple concepts to find the solutions. Helicenes are extended fused polyaromatic hydrocarbons
View solution Problem 161
Marathon Problems. These problems are designed to incorporate several concepts and techniques into one situation. For each of the following, fill in the blank w
View solution Problem 163
For each of the following, fill in the blank with the correct response(s). All of the following pertain to nucleic acids. a. The substance in the nucleus of the
View solution Problem 159
Integrative Problems. These problems require the integration of multiple concepts to find the solutions. An organometallic compound is one containing at least o
View solution