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(a)
To draw and name: The amino acids from which alpha keto acids were derived
Introduction:
An autosomal
(b)
To determine: The reason for most likely amino acid precursor of taurine.
Introduction:
An autosomal metabolic problem in the body indicates the maple syrup urine disease. This disease directly affects the branched chain amino acids. This situation results in sweet odor in urine. This is mainly seen in the children. Taurine is the amino acid that is majorly found in the tissues of animals. Taurine is an amino acid that is not normally found in proteins. Taurine is often produced as a byproduct of cell damage.
(c)
To determine: The amino acid that shows significant elevated level in the patient blood in January 1957 and also determine which amino acid is present in the urine of patient.
Introduction:
An autosomal metabolic problem in the body indicates the maple syrup urine disease. This disease directly affects the branched chain amino acids. This situation results in sweet odor in urine. This is mainly seen in the children. Dancis and coauthors concluded that although it appears most likely to the authors that the principal block is in the metabolic degradative pathway of the branched-chain amino acids.
(d)
To determine: The way in which data presented here supports the conclusion.
Introduction:
An autosomal metabolic problem in the body indicates the maple syrup urine disease. This disease directly affects the branched chain amino acids. This situation results in sweet odor in urine. This is mainly seen in the children. The data include the information about amino acids. Taurine is an amino acid which is not normally found in proteins. The amino acids combine with each other and form a protein structure.
(e)
To determine: The data which do not fit this model of maple syrup urine disease. Also determine the way in which these different data are contradictory.
Introduction:
An autosomal metabolic problem in the body indicates the maple syrup urine disease. This disease directly affects the branched chain amino acids. This situation results in sweet odor in urine. This is mainly seen in the children.
(f)
To determine: The data that need to be collected to be more secure in the conclusion.
Introduction:
An autosomal metabolic problem in the body indicates the maple syrup urine disease. This disease directly affects the branched chain amino acids. This situation results in sweet odor in urine. This is mainly seen in the children. The amino acids combine with each other and form a protein structure. Taurine is an amino acid that is not normally found in proteins. The data include the information about the amino acids.
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Chapter 18 Solutions
EBK LEHNINGER PRINCIPLES OF BIOCHEMISTR
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- Four distinct classes of interactions (inter and intramolecular forces) contribute to a protein's tertiary and quaternary structures. Name the interaction then describe the amino acids that can form this type of interaction. Draw and annotate a diagram of the interaction between two amino acids.arrow_forwardExamine the metabolic pathway. The enzymes that catalyze each step are identified as "e" with a numeric subscript. e₁ e3 e4 A B с 1° B' 02 e5 e6 e7 E F Which enzymes catalyze irreversible reactions? ப e ez ☐ ez e4 ☐ ப es 26 5 e7 Which of the enzymes is likely to be the allosteric enzyme that controls the synthesis of G? €2 ез e4 es 26 5 e7arrow_forwardAn allosteric enzyme that follows the concerted model has an allosteric coefficient (T/R) of 300 in the absence of substrate. Suppose that a mutation reversed the ratio. Select the effects this mutation will have on the relationship between the rate of the reaction (V) and substrate concentration, [S]. ㅁㅁㅁ The enzyme would likely follow Michaelis-Menten kinetics. The plot of V versus [S] would be sigmoidal. The enzyme would mostly be in the T form. The plot of V versus [S] would be hyperbolic. The enzyme would be more active.arrow_forward
- Penicillin is hydrolyzed and thereby rendered inactive by penicillinase (also known as ẞ-lactamase), an enzyme present in some penicillin-resistant bacteria. The mass of this enzyme in Staphylococcus aureus is 29.6 kDa. The amount of penicillin hydrolyzed in 1 minute in a 10.0 mL. solution containing 1.00 x 10 g of purified penicillinase was measured as a function of the concentration of penicillin. Assume that the concentration of penicillin does not change appreciably during the assay. Plots of V versus [S] and 1/V versus 1/[S] for these data are shown. Vo (* 10 M minute"¹) 7.0 6.0 5.0 4.0 3.0 20 1.0 0.0 о 10 20 30 1/Vo (* 10 M1 minute) 20 103 90 BO 70 50 [S] (* 100 M) 40 50 60 y=762x+1.46 × 10" [Penicillin] (M) Amount hydrolyzed (uM) 1 0.11 3 0.25 5 0.34 10 0.45 30 0.58 50 0.61arrow_forwardConsider the four graphs shown. In each graph, the solid blue curve represents the unmodified allosteric enzyme and the dashed green curve represents the enzyme in the presence of the effector. Identify which graphs correctly illustrate the effect of a negative modifier (allosteric inhibitor) and a positive modifier (allosteric activator) on the velocity curve of an allosteric enzyme. Place the correct graph in the set of axes for each type of modifier. Negative modifier Reaction velocity - Positive modifier Substrate concentration - Reaction velocity →→→→ Substrate concentration Answer Bankarrow_forwardConsider the reaction: phosphoglucoisomerase Glucose 6-phosphate: glucose 1-phosphate After reactant and product were mixed and allowed to reach at 25 °C, the concentration of each compound at equilibrium was measured: [Glucose 1-phosphate] = 0.01 M [Glucose 6-phosphate] = 0.19 M Calculate Keq and AG°'. Код .0526 Incorrect Answer 7.30 AG°' kJ mol-1 Incorrect Answerarrow_forward
- Classify each phrase as describing kinases, phosphatases, neither, or both. Kinases Phosphatases Neither Both Answer Bank transfer phosphoryl groups to acidic amino acids in eukaryotes may use ATP as a phosphoryl group donor remove phosphoryl groups from proteins catalyze reactions that are the reverse of dephosphorylation reactions regulate the activity of other proteins catalyze phosphorylation reactions PKA as an example turn off signaling pathways triggered by kinasesarrow_forwardConsider the reaction. kp S P kg What effects are produced by an enzyme on the general reaction? AG for the reaction increases. The rate constant for the reverse reaction (kr) increases. The reaction equilibrium is shifted toward the products. The concentration of the reactants is increased. The activation energy for the reaction is lowered. The formation of the transition state is promoted.arrow_forwardThe graph displays the activities of wild-type and several mutated forms of subtilisin on a logarithmic scale. The mutations are identified as: • The first letter is the one-letter abbreviation for the amino acid being altered. • The number identifies the position of the residue in the primary structure. ⚫ The second letter is the one-letter abbreviation for the amino acid replacing the original one. • Uncat. refers to the estimated rate for the uncatalyzed reaction. Log₁(S-1) Wild type S221A H64A -5 D32A S221A H64A D32A -10 Uncat. How would the activity of a reaction catalyzed by a version of subtilisin with all three residues in the catalytic triad mutated compare to the activity of the uncatalyzed reaction? It would have more activity, because the reaction catalyzed by the triple mutant is approximately three-fold faster than the uncatalyzed reaction. It would have less activity, because the reaction catalyzed by the triple mutant is approximately 1000-fold slower than the…arrow_forward
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