Biomolecules MCQs With Answers – Part 4 (Class 12 Chemistry)
GKaim: Measure. Improve. Achieve.

Biomolecules MCQs with Answers – Part 4 (Class 12 Chemistry)

Timer: Off
Random: Off

301. A graph plots average net charge of an amino acid on the vertical axis against \(\mathrm{pH}\) on the horizontal axis. The curve decreases as \(\mathrm{pH}\) rises and crosses the zero-charge line at \(\mathrm{pH=5.8}\). The value \(5.8\) represents:
ⓐ. the isoelectric point of the amino acid
ⓑ. the maximum positive charge of the amino acid
ⓒ. the number of ionisable groups in the amino acid
ⓓ. the temperature at which the amino acid denatures
302. Three amino acids are placed in a buffer of \(\mathrm{pH=6.0}\).
Amino acid\(\mathrm{pI}\)
P\(3.0\)
Q\(6.0\)
R\(9.0\)
Their expected behaviour in an electric field is:
ⓐ. P moves to the negative electrode, Q remains nearly stationary, and R moves to the positive electrode
ⓑ. P remains nearly stationary, Q moves to the negative electrode, and R moves to the positive electrode
ⓒ. P moves to the positive electrode, Q remains nearly stationary, and R moves to the negative electrode
ⓓ. P and R remain nearly stationary, while Q moves to the positive electrode
303. An amino acid solution is initially maintained at its \(\mathrm{pI}\). Addition of sufficient acid will cause the amino acid to:
ⓐ. become more negatively charged through deprotonation
ⓑ. become more positively charged through protonation
ⓒ. lose both its amino and carboxyl groups
ⓓ. remain at zero net charge regardless of the new \(\mathrm{pH}\)
304. In the peptide \[ \mathrm{H_2N-Ala-Gly-Ser-COOH} \] the N-terminal and C-terminal residues are, respectively:
ⓐ. Gly and Ser
ⓑ. Ser and Ala
ⓒ. Gly and Ala
ⓓ. Ala and Ser
305. Alanylglycine and glycylalanine are different compounds mainly because:
ⓐ. their residues occur in opposite N-to-C sequences
ⓑ. one is a dipeptide whereas the other is a free amino-acid mixture
ⓒ. they contain different numbers of amino-acid residues
ⓓ. their peptide bonds belong to different functional-group classes
306. Complete hydrolysis of \(0.150\,mol\) of a linear hexapeptide consumes water. The mass of water required is:
ⓐ. \(5.40\,g\)
ⓑ. \(9.00\,g\)
ⓒ. \(13.5\,g\)
ⓓ. \(16.2\,g\)
307. Partial hydrolysis of an unknown tripeptide gives the dipeptides Ala–Gly and Gly–Val. Independent end-group analysis shows alanine at the N terminus and valine at the C terminus. The tripeptide sequence is:
ⓐ. Gly–Ala–Val
ⓑ. Val–Gly–Ala
ⓒ. Ala–Val–Gly
ⓓ. Ala–Gly–Val
308. Examine the following statements about peptide hydrolysis. Statement I: Complete hydrolysis breaks all peptide bonds. Statement II: A linear peptide with \(n\) residues consumes \(n-1\) water molecules during complete hydrolysis. Statement III: Complete hydrolysis normally changes every amino-acid side chain into the same group. The acceptable statements are:
ⓐ. I only
ⓑ. I and II only
ⓒ. II and III only
ⓓ. I, II and III
309. Fibrous proteins are generally characterised by:
ⓐ. elongated shapes and predominantly structural functions
ⓑ. compact shapes and exclusively catalytic functions
ⓒ. nucleotide chains joined by phosphodiester bonds
ⓓ. highly branched glucose chains used for energy storage
310. The most appropriate comparison between keratin and collagen is:
ⓐ. Keratin mainly supports connective tissues, whereas collagen forms the principal structural protein of hair and nails
ⓑ. Keratin is mainly a compact catalytic protein, whereas collagen is an elongated structural protein
ⓒ. Keratin contributes to the structure of hair and nails, whereas collagen provides strength and support in connective tissues
ⓓ. Keratin and collagen are both compact proteins whose principal function is molecular transport
Subscribe
Notify of
guest
0 Comments
Scroll to Top