Covalent bonds that sugar as one of one nucleotide to the next bond is together done come together as a DNA strand. This is taught in science.
Covalent bond
Phosphate
helix
sugar
base
phosphate
Phophodiester bonds are the one that connect the nucleotides next to each other on the same strand. Weak hydrogen bonds join the two complementary nucleotides and thus the two strands of the DNA together.
Between nucleotides, there is a phosphodiester bond between the phosphate group of one nucleotide and the sugar of another nucleotide. Nucleotides (such as Adenine and Thymine) are held together on two strands of DNA through hydrogen bonding. This doesn't keep nucleotides together in a strand, but helps in the structure of two corresponding strands of DNA.
Nucleotides in both DNA and RNA are bound by phosphate ester bonds. See the following link for a detailed discussion: http://www.ncc.gmu.edu/dna/structur.htm
The bond is a phosphodiester bond, which forms a strong covalent bond between the sugar of one nucleotide and the phosphate group of the next nucleotide in a DNA or RNA molecule. This bond is important in creating the backbone of the nucleic acid strand and plays a role in stabilizing the overall structure of the molecule.
Covalent bonds between a sugar molecule (deoxyribose) and a phosphate group make up the backbone of DNA. These are very strong covalent bonds and are broken only with great expenditure of energy--x-rays, for example.
The connection between nucleotides is between the sugar of the first nucleotide and the phosphate of the second. These are covalent bonds yielding a covalently attached sugar-phosphate backbone.
Nucleotides polymerize through a condensation reaction between the phosphate group of one nucleotide and the sugar group of another nucleotide. This forms a phosphodiester bond, linking the nucleotides together to form a nucleic acid chain. DNA and RNA are examples of nucleic acids formed by polymerization of nucleotides.
Nucleic acids are held together by phosphodiester bonds between the sugar and phosphate groups of adjacent nucleotides in the backbone of the molecule. Additionally, hydrogen bonds between nitrogenous bases in complementary strands help stabilize the double-stranded structure of DNA or RNA.
Nucleotide monomers are connected through phosphodiester bonds. This bond forms between the phosphate group of one nucleotide and the sugar group of another nucleotide, creating a sugar-phosphate backbone that links the nucleotides together in a chain.
The nucleotides are joined together by phosphodiester linkages between the sugar of one nucleotide and the phosphate of the next.
In a nucleotide the 5-carbon sugar is bonded to the phosphate group, which is bonded to the nitrogenous base. In a chain of nucleotides (a strand of DNA), the nucleotides are connected by covalent bonds between the sugar of one nucleotide, and the phosphate group of the next nucleotide.
The backbone of the nucleotides are composed of repeating ribose (in RNA) or deoxyribose (in DNA) and phosphates held together by phosphodiester bonds between the 5's and 3's of the ribose/deoxyribose.
Phophodiester bonds are the one that connect the nucleotides next to each other on the same strand. Weak hydrogen bonds join the two complementary nucleotides and thus the two strands of the DNA together.
In producing a strand of DNA the nucleotides combine to form phosphodiester bonds.
Between nucleotides, there is a phosphodiester bond between the phosphate group of one nucleotide and the sugar of another nucleotide. Nucleotides (such as Adenine and Thymine) are held together on two strands of DNA through hydrogen bonding. This doesn't keep nucleotides together in a strand, but helps in the structure of two corresponding strands of DNA.
Gangnam Style
Nucleotides in both DNA and RNA are bound by phosphate ester bonds. See the following link for a detailed discussion: http://www.ncc.gmu.edu/dna/structur.htm