Nucleic Acid Structure and Base Pairing (1B) - MCAT Biological and Biochemical Foundations of Living Systems

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

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

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

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

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

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

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

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

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.

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

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

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

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

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.

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

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

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

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

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

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

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.

$3'\text{-OH}$ 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.

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