MCAT Biological and Biochemical Foundations of Living Systems Flashcards: 1b Nucleic Acid Structure Base Pairing

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This deck focuses on 1b Nucleic Acid Structure Base Pairing, giving you a quick way to review the definitions, rules, and examples that matter most for MCAT Biological and Biochemical Foundations of Living Systems.

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Flashcard 1: Identify the complementary RNA strand to $5'\text{-AUGC-}3'$ (write $5' \rightarrow 3'$).

Answer: $5'\text{-GCAU-}3'$. RNA complementarity uses A-U and G-C pairing, with the strand written in the conventional 5' to 3' orientation.

Flashcard 2: What type of bond links a base to the $1'$ carbon of the sugar in a nucleotide?

Answer: $\beta$-N-glycosidic bond. This bond connects the nitrogen of the base to the anomeric carbon of the sugar, forming nucleosides and nucleotides.

Flashcard 3: What is the defining structural difference between a nucleoside and a nucleotide?

Answer: Nucleotide = nucleoside + phosphate group(s). Nucleosides consist of a base and sugar, while nucleotides include an additional phosphate, defining their structural distinction.

Flashcard 4: What three components make up a nucleotide?

Answer: Nitrogenous base + pentose sugar + phosphate. Nucleotides form from these components, with the base linked to sugar via glycosidic bond and phosphate attached to sugar.

Flashcard 5: Which bases are purines in nucleic acids?

Answer: Adenine and guanine. Purines have a double-ring structure, distinguishing them from single-ring pyrimidines in nucleic acids.

Flashcard 6: Which bases are pyrimidines in nucleic acids?

Answer: Cytosine, thymine, and uracil. Pyrimidines feature a single-ring structure, contrasting with the double-ring purines in nucleic acids.

Flashcard 7: Identify the complementary DNA strand to $5'\text{-AGTC-}3'$ (write $5' \rightarrow 3'$).

Answer: $5'\text{-GACT-}3'$. Complementary strands follow Watson-Crick rules: A pairs with T, G with C, written in antiparallel 5' to 3' direction.

Flashcard 8: What is the sugar in RNA, and what functional group at the $2'$ position distinguishes it from DNA sugar?

Answer: Ribose; has the $2'\text{-OH}$ group. Ribose in RNA includes a hydroxyl at C2', enabling unique reactivity compared to deoxyribose in DNA.

Flashcard 9: If double-stranded DNA is $40\%$ guanine, what percentage is cytosine?

Answer: $40\%$. In double-stranded DNA, guanine pairs equally with cytosine, so their percentages match due to base pairing rules.

Flashcard 10: What is the sugar in DNA, and what key functional group difference distinguishes it from RNA sugar?

Answer: Deoxyribose; lacks the $2'\text{-OH}$ (has $2'\text{-H}$). Deoxyribose in DNA lacks the hydroxyl at C2', making it more stable than ribose against hydrolysis.

Flashcard 11: Which base is present in DNA but not RNA under standard cellular conditions?

Answer: Thymine. DNA incorporates thymine for pairing with adenine, unlike RNA which uses uracil in standard cellular processes.

Flashcard 12: If double-stranded DNA is $30\%$ adenine, what percentage is guanine?

Answer: $20\%$. Adenine pairs with thymine, leaving the remaining percentage split equally between guanine and cytosine.

Flashcard 13: Which base is present in RNA but not DNA under standard cellular conditions?

Answer: Uracil. RNA uses uracil instead of thymine to pair with adenine, a key difference from DNA under normal conditions.

Flashcard 14: How many hydrogen bonds form in a guanine–cytosine base pair?

Answer: 3 hydrogen bonds. G-C pairs involve three hydrogen bonds, providing greater stability compared to A-T pairs in nucleic acids.

Flashcard 15: What is meant by antiparallel strands in double-stranded DNA?

Answer: One strand is $5' \rightarrow 3'$ and the other is $3' \rightarrow 5'$. Antiparallel orientation allows complementary base pairing and maintains the double helix structure in DNA.

Flashcard 16: Which DNA groove (major or minor) provides more base-specific information for protein binding?

Answer: Major groove. The major groove exposes more of the base edges, enabling specific interactions with proteins like transcription factors.

Flashcard 17: How many hydrogen bonds form in an adenine–thymine (or adenine–uracil) base pair?

Answer: 2 hydrogen bonds. A-T or A-U pairs form two hydrogen bonds, contributing to the stability of the double helix structure.

Flashcard 18: What is the standard Watson–Crick base-pairing rule in RNA (including RNA duplexes)?

Answer: $\text{A-U}$ and $\text{G-C}$. In RNA, uracil replaces thymine to pair with adenine, while guanine-cytosine pairing remains consistent.

Flashcard 19: What is the standard Watson–Crick base-pairing rule in DNA?

Answer: $\text{A-T}$ and $\text{G-C}$. Watson-Crick pairing in DNA follows complementary rules where A pairs with T and G with C via hydrogen bonds.

Flashcard 20: What is the correct directionality for writing a nucleic acid sequence by convention?

Answer: $5' \rightarrow 3'$. Sequences are conventionally written from 5' to 3' to reflect the direction of synthesis and transcription.

Flashcard 21: What defines the $3'$ end of a nucleic acid strand in terms of functional groups?

Answer: Free $3'\text{-OH}$ group. The 3' end has an exposed hydroxyl on the 3' carbon, allowing for chain extension during synthesis.

Flashcard 22: What defines the $5'$ end of a nucleic acid strand in terms of functional groups?

Answer: Free $5'$ phosphate (or $5'\text{-OH}$ if unphosphorylated). The 5' end features an exposed phosphate or hydroxyl on the 5' carbon, marking the start of the polynucleotide chain.

Flashcard 23: Which atoms are connected by a $3'$-$5'$ phosphodiester linkage in nucleic acids?

Answer: $3'\text{-OH}$ of one sugar to $5'$ phosphate of the next. The linkage forms between the 3' carbon of one nucleotide's sugar and the 5' phosphate of the adjacent one, creating the backbone.

Flashcard 24: What type of covalent bond forms the nucleic acid backbone between nucleotides?

Answer: $3'$-$5'$ phosphodiester bond. Phosphodiester bonds link nucleotides via sugar-phosphate backbone, providing structural integrity to DNA and RNA.