2027 | (23 QUESTIONS AND CORRECT
ANSWERS) | ALREADY GRADED A+ | 100%
VERIFIED
Genetics | Portage Learning | Key Domains: Molecular Genetics, Mendelian Inheritance,
Chromosomal Abnormalities, DNA Replication and Protein Synthesis, Population Genetics,
Genetic Technologies, and Clinical Genetics | Expert-Aligned Structure | Exam-Ready
Format
Introduction
This structured BIOD 210 Modules 1–7 & Final Exam format for 2026–2027 provides the
complete layout for generating high-quality exam-style questions with correct answers and
rationales. It emphasizes genetic principles, molecular biology, inheritance patterns, and
clinical applications critical to professional genetics knowledge and successful Portage
Learning course completion.
Answer Format
All correct answers must appear in bold and cyan, accompanied by concise rationales
explaining scientific reasoning, code adherence, and why alternative options are less
appropriate.
,Question 1: A molecular biologist is investigating the chemical composition of a newly isolated
viral genome. Chemical analysis demonstrates the presence of adenine, guanine, cytosine, and
uracil, alongside a five-carbon sugar containing a hydroxyl group (-OH) attached to the 2'
carbon of the pentose ring. Based on these biochemical properties, what is the correct
classification of this viral nucleic acid?
A. Single-stranded DNA (ssDNA)
B. Double-stranded DNA (dsDNA)
C. Ribonucleic acid (RNA); confirmed by the presence of uracil and a 2'-hydroxyl group on the
ribose sugar ring
D. Polypeptide protein chain
Correct Answer: C. Ribonucleic acid (RNA); confirmed by the presence of uracil and a
2'-hydroxyl group on the ribose sugar ring
Rationale: There is a fundamental biochemical distinction between Deoxyribonucleic Acid
(DNA) and Ribonucleic Acid (RNA). The pentose sugar in RNA is ribose, which
characteristically possesses a hydroxyl group (-OH) attached to the 2' carbon ring position.
By contrast, the pentose sugar in DNA is deoxyribose, which lacks this oxygen atom,
possessing only a hydrogen atom (-H) at the 2' carbon position. Furthermore, RNA
incorporates the pyrimidine nitrogenous base uracil in place of thymine (which is found
exclusively in DNA). The presence of uracil combined with a 2'-hydroxyl group provides
absolute biochemical proof that the viral genome is composed of RNA. Polypeptides (option
D) are composed of amino acids linked by peptide bonds.
Question 2: In the double-helical structure of DNA proposed by Watson and Crick, the two
antiparallel polynucleotide strands are held together by complementary base pairing across
the central axis. Which of the following statements correctly identifies the specific hydrogen
bonding pairing rules between purines and pyrimidines?
A. Adenine pairs with Cytosine via two hydrogen bonds; Guanine pairs with Thymine via
three hydrogen bonds
B. Adenine pairs with Thymine via two hydrogen bonds; Guanine pairs with Cytosine via
three hydrogen bonds
C. Adenine pairs with Guanine via three hydrogen bonds; Thymine pairs with Cytosine via
two hydrogen bonds
D. Purines pair exclusively with purines via covalent phosphodiester bonds
Correct Answer: B. Adenine pairs with Thymine via two hydrogen bonds; Guanine
pairs with Cytosine via three hydrogen bonds
Rationale: According to Chargaff's rules and the Watson-Crick double helix model, the two
antiparallel strands of DNA are maintained by non-covalent hydrogen bonding between
complementary purine and pyrimidine bases. The purine Adenine (A) pairs exclusively with
the pyrimidine Thymine (T) via exactly two hydrogen bonds (A=T). The purine Guanine (G)
pairs exclusively with the pyrimidine Cytosine (C) via exactly three hydrogen bonds (G≡C).
, Because G-C base pairs possess three hydrogen bonds, DNA sequences possessing a high G-C
content exhibit a significantly higher melting temperature (Tm) than A-T rich sequences.
Purine-purine pairing (option C/D) would distort the uniform 2.0 nm diameter of the double
helix. Covalent phosphodiester bonds link adjacent nucleotides along the vertical sugar-
phosphate backbone, not across the base pairs.
Question 3: An investigator studies the enzymatic formation of the sugar-phosphate backbone
during polynucleotide synthesis. Which specific carbon atoms of adjacent pentose sugars are
joined by covalent phosphodiester linkages in a growing DNA strand?
A. The 1' carbon of one sugar is linked to the 4' carbon of the adjacent sugar
B. The 2' carbon of one sugar is linked to the 5' carbon of the adjacent sugar
C. The 3' carbon of one sugar is linked to the 5' carbon of the adjacent sugar via a phosphate
group
D. The 5' carbon of one sugar is linked directly to the 5' carbon of the adjacent sugar
Correct Answer: C. The 3' carbon of one sugar is linked to the 5' carbon of the adjacent
sugar via a phosphate group
Rationale: The structural backbone of DNA and RNA polymers is formed by repeating
phosphodiester linkages connecting adjacent nucleotide monomers. During polymerization,
DNA and RNA polymerases catalyze a nucleophilic attack by the free 3'-hydroxyl group (-OH)
of the existing terminal pentose sugar upon the alpha 5'-phosphate group of the incoming
deoxynucleoside triphosphate (dNTP), releasing pyrophosphate (PPi). This establishes a
covalent phosphodiester bond linking the 3' carbon of one pentose sugar to the 5' carbon of
the adjacent pentose sugar via a central phosphate group. This specific chemical orientation
establishes the foundational structural polarity of nucleic acids, causing all enzymatic
synthesis to proceed strictly in the 5'-to-3' direction.
Question 4: During the semi-conservative replication of the bacterial chromosome
(Escherichia coli), an enzyme actively unwinds the double helix at the replication fork, creating
severe positive supercoiling ahead of the fork. Which enzyme is responsible for breaking,
swiveling, and rejoining DNA strands to relieve this positive torsional stress?
A. DNA Helicase
B. DNA Gyrase (Topoisomerase II)
C. DNA Polymerase III
D. DNA Ligase
Correct Answer: B. DNA Gyrase (Topoisomerase II)
Rationale: As DNA Helicase (option A) unzips and separates the double helix at the active
replication fork, it induces intense positive supercoiling and torsional tension in the
unreplicated double-stranded DNA ahead of the fork. If unmanaged, this mechanical stress
would completely arrest replication fork progression. DNA Gyrase, a highly specialized
bacterial Type II Topoisomerase, binds ahead of the replication fork and utilizes ATP to