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∙ 14y agoAdenosine triphosphate, or ATP.
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∙ 14y agoAdenosine triphosphate (ATP) is a molecule that stores energy by linking negatively charged phosphate groups near each other. ATP is a high-energy molecule that functions as the primary energy carrier in cells, providing energy for various cellular processes.
Sugar phosphate is the backbone of the DNA molecule, providing structural support by linking the nucleotide bases together. It also helps stabilize the double helix structure of DNA by forming a strong, stable backbone. Additionally, sugar phosphate plays a role in the overall charge of the DNA molecule, contributing to its interaction with other molecules in the cell.
A phosphodiester bond is the type of bond that is present between phosphorus and oxygen in a DNA molecule. This bond forms between the phosphate group of one nucleotide and the hydroxyl group of another nucleotide, linking the nucleotides together in a DNA backbone.
Phospholipids are comprised of a phosphate group linking a diglyceride to a nonlipid group. These molecules can be synthesized primarily from fatty acids in the body to form important components of cell membranes.
The bond linking amino acids is called a peptide bond. It forms between the carboxyl group of one amino acid and the amino group of another, resulting in the formation of a dipeptide and releasing a molecule of water.
A phosphodiester bond is formed between the hydroxyl group of one nucleotide and the phosphate group of an adjacent nucleotide when linking nucleotides to form the sugar-phosphate backbone of DNA. This bond involves the condensation reaction between the hydroxyl group of the 3' carbon of one nucleotide and the phosphate group of the 5' carbon of the adjacent nucleotide.
Adenosine triphosphate (ATP) stores energy by linking charged phosphate groups near each other. This molecule releases energy when one of the phosphate groups is removed, leading to the formation of adenosine diphosphate (ADP) and an inorganic phosphate molecule.
The phosphate groups are on the exterior of the DNA molecule. They form the backbone of the DNA molecule and are involved in binding to other molecules in the cell.
Deoxyribose sugar alternates with phosphate to make up the sides of the DNA molecule. This forms the backbone of the DNA structure, with the phosphate group linking the sugar molecules together through phosphodiester bonds.
The key component of an ion in DNA is the phosphate group, which carries a negative charge due to the presence of phosphate ions. These phosphate groups help to form the backbone of the DNA molecule, linking the nucleotide units together through phosphodiester bonds.
Deoxyribose sugar molecules are involved in the structure of DNA. These sugar molecules are part of the backbone of the DNA double helix, linking with phosphate groups to form the sugar-phosphate backbone of the DNA strand.
Phosphodiester bonds hold the sugar and phosphate groups together in DNA and RNA molecules. These bonds form between the phosphate group of one nucleotide and the 3'-hydroxyl group of the sugar in the adjacent nucleotide.
Sugar phosphate is the backbone of the DNA molecule, providing structural support by linking the nucleotide bases together. It also helps stabilize the double helix structure of DNA by forming a strong, stable backbone. Additionally, sugar phosphate plays a role in the overall charge of the DNA molecule, contributing to its interaction with other molecules in the cell.
A phosphodiester bond is the type of bond that is present between phosphorus and oxygen in a DNA molecule. This bond forms between the phosphate group of one nucleotide and the hydroxyl group of another nucleotide, linking the nucleotides together in a DNA backbone.
Phospholipids are comprised of a phosphate group linking a diglyceride to a nonlipid group. These molecules can be synthesized primarily from fatty acids in the body to form important components of cell membranes.
No, helicase enzymes unwind and separate the double-stranded DNA helix by breaking the hydrogen bonds between complementary nucleotide base pairs. They do not break the sugar-phosphate backbone of the DNA molecule.
Deoxyribose is a key component of the DNA molecule as it forms the "backbone" of the DNA strand. It provides stability and structure to the DNA molecule by linking the individual nucleotides together. Without deoxyribose, DNA could not exist in its double helix structure and carry out its functions in storing genetic information.
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