What is not true for genetic code?
1. A codon in mRNA is read in a non-contiguous fashion
2. It is nearly universal
3. It is degenerate
4. It is unambiguous
In the DNA molecule
(1) the total amount of purine nucleotides and pyrimidine nucleotides is not always equal
(2) there are two strands, which run parallel in the 5’ → 3’direction
(3) the proportion of adenine in relation to thymine varies with the organism
(4) there are two strands, which run antiparallel-one in 5’ → 3’ direction and other in 3’ → 5’
Which one of the following pairs of codons are correctly matched with their function or the signal for the particular amino acid?
1. GUU, GCU – Alanine
2. UAG, UGA – Stop
3. AUG, ACG – Start/methionine
4. UUA, UCA – Leucine
Haploids are more suitable for mutation studies than the diploids. This is because
(1) haploids are reproductively more stable than diploids
(2) mutagenes penetrate in haploids more effectively than is diploids
(3) haploids are more abundant in nature than diploids
(4) all mutations, whether dominant or recessive are expressed in haploids
Telomere repetitive DNA sequences control the function of eukaryotic chromosomes because they:
(1) act as replicons
(2) are RNA transcription initiator
(3) help chromosome pairing
(4) prevent chromosome loss
Molecular basis of organ differentiation depends on the modulation in transcription by:
(1) RNA polymerase
(2) ribosome
(3) transcription factor
(4) anticodon
The length of DNA molecule greatly exceeds the dimensions of the nucleus in eukaryotic cells. How is this DNA accommodated?
(1) Deletion of non essential genes
(2) Super-coiling in nucleosomes
(3) DNAse digestion
(4) Through elimination of repetitive DNA
During transcription RNA polymerase holoenzyme binds to a gene promoter and assumes a saddle-like structure. What is it’s DNA-binding sequence?
(1) TTAA
(2) AATT
(3) CACC
(4) TATA
Differentiation of organs and tissues in a developing organism, is associated with:
(1) developmental mutations
(2) differential expression of genes
(3) lethal mutations
(4) deletion of gens
The Okazaki fragments in DNA chain growth:
(1) result in transcription
(2) polymerize in the 3’-to-5’ direction and forms replication fork
(3) prove semi-conservative nature of DNA replication
(4) polymerize in the 5’-to-3’ direction and explain 3’-to-5’ DNA replication