Weak hydrogen bonds, which are polarized bonds (opposite charges), not the stronger covalent bonds where electrons are shared between two atoms in typical molecules. This makes it easy for DNA to separate for replication or protein synthesis.
hydrogen bonds between the oxygen of an carbonyl group and the hydrogen of of the amine grou
this is DNA bases if u didnt know
Its Hydrogen Bonds that hold the two strands of the DNA double helix together.
what holds the sides of the DNA ladder together
your teacher will probably accept hydrogen bonds, however it is more of an attraction not a physical bond
Complementary strands of DNA are held together by hydrogen bonds connecting complementary bases.
First off - it is important to understand that a nucleotide (the monomer of DNA) is composed of 3 things: a sugar, a phosphate group, and a nitrogenous base. Next - understand that the "backbone" of DNA is composed of the sugars and phosphates. That leaves you with nitrogenous bases. Hydrogen bonds form between the nitrogenous bases off opposite strands in the double helix. THIS is what holds the double helix together.
hydrogen bonds
Hydrogen bon
the bases are paired by hydrogen bounds
Its Hydrogen Bonds that hold the two strands of the DNA double helix together.
Strong hydrogen bonds.
what holds the sides of the DNA ladder together
your teacher will probably accept hydrogen bonds, however it is more of an attraction not a physical bond
Adenine binds to Thymine Guanine binds to Cytosine Hydrogen bonding holds the bases together.
Hydrogen bonds hold the DNA bases together. There are three bonds between Guanine and Cytosine, and two bonds between Adenine and Thymine.
Describe how each of the DNA nitrogen bases pair together
I assume you mean the hydrogen bonding that holds bases of DNA together.
The bone that holds complimentary bases of DNA together is not actually a bone, but rather a chemical bond. It is called a hydrogen bond, and it forms between the nucleotides that make up the DNA molecule. The hydrogen bond specifically forms between the nitrogenous bases, such as adenine (A) and thymine (T), or cytosine (C) and guanine (G), allowing the DNA strands to stay connected.