19: Nucleic Acids

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The blueprint for the reproduction and the maintenance of each organism is found in the nuclei of its cells, concentrated in elongated, threadlike structures called chromosomes. These complex structures, consisting of DNA and proteins, contain the basic units of heredity, called genes. The number of chromosomes (and genes) varies with each species. Human body cells have 23 pairs of chromosomes having 20,000–40,000 different genes.

Sperm and egg cells contain only a single copy of each chromosome; that is, they contain only one member of each chromosome pair. Thus, in sexual reproduction, the entire complement of chromosomes is achieved only when an egg and sperm combine. A new individual receives half its hereditary material from each parent. Calling the unit of heredity a “gene” merely gives it a name. But what really are genes and how is the information they contain expressed? One definition of a gene is that it is a segment of DNA that constitutes the code for a specific polypeptide. If genes are segments of DNA, we need to learn more about the structure and physiological function of DNA. We begin by looking at the small molecules needed to form DNA and RNA (ribonucleic acid)—the nucleotides.

19.0: Prelude to Nucleic Acids
This page outlines the history of insulin discovery, starting with its isolation from animals in 1921, which caused allergic reactions in some diabetics. It highlights advancements in the 1970s that led to the creation of genetically engineered human insulin, marking a breakthrough as the first medical product from this technology.
19.1: Nucleotides
This page explains nucleotides as the building blocks of nucleic acids, composed of phosphoric acid, a pentose sugar, and a nitrogenous base. It distinguishes between ribonucleotides (with ribose) and deoxyribonucleotides (with deoxyribose) and classifies nitrogen bases into pyrimidines and purines. Additionally, it highlights the functions of nucleotides in cell metabolism, where they are vital components of molecules like ADP and ATP and various coenzymes.
19.2: Nucleic Acid Structure
This page discusses nucleic acids, including DNA and RNA, as essential biological polymers composed of nucleotides. DNA functions in genetic storage, featuring a double helix formed by base pairing (adenine with thymine, and guanine with cytosine). RNA translates genetic information to synthesize proteins. Nucleotide connections are established through phosphate and sugar groups, and DNA stability arises from hydrogen bonds between complementary bases.
19.3: Replication and Expression of Genetic Information
This page discusses the synthesis of DNA and RNA and their roles in genetic information transfer, focusing on three processes: replication, transcription, and translation. DNA is replicated by base pairing with DNA polymerase, while RNA is synthesized from DNA through transcription using RNA polymerase.
19.4: Protein Synthesis and the Genetic Code
This page explains the genetic code's role in encoding polypeptides, highlighting messenger RNA (mRNA) as the transcribed gene copy. Each amino acid is defined by a codon, a triplet of nucleotides. The genetic code is nearly universal and follows specific rules for codon usage. Protein synthesis involves mRNA, transfer RNA (tRNA), ribosomal RNA (rRNA), and various enzymes, with aminoacyl-tRNA synthetase linking amino acids to tRNA before they are added to the polypeptide chain during translation.
19.5: Mutations and Genetic Diseases
This page explores genetic mutations' impacts on genetic diseases, highlighting common types and their effects, including conditions like PKU and Tay-Sachs. It discusses recombinant DNA technology for creating DNA libraries, where different bacterial colonies contain various DNA fragments. Researchers can screen these for desired genes for replication in host organisms, facilitating the production of crucial proteins and enhancing agricultural traits.
19.6: Viruses
This page discusses viruses as microscopic entities classified into DNA or RNA types, detailing RNA virus replication and retroviruses' reverse transcription. It highlights treatments for HIV, such as AZT and Raltegravir, and the challenge of drug resistance, promoting combination therapies. Additionally, it mentions the role of genetics counselors in aiding families with genetic disorders, which requires a master's degree.
19.E: Nucleic Acids (Exercises)
This page discusses nucleotides, nucleic acids, and their structures, detailing DNA and RNA composition, replication, transcription, and protein synthesis roles. It covers genetic mutations, their effects on amino acid sequences, and the classification of viruses, including DNA vs. RNA viruses.
19.S: Nucleic Acids (Summary)
This page explains the structure and function of DNA and RNA, noting that hereditary information is stored in chromosomes. It describes DNA's double helix and RNA's single chain, emphasizes the importance of DNA replication for cell growth, and outlines protein synthesis through transcription and translation. The page also discusses mutations, genetic diseases, and the role of retroviruses.

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