Why can the ends of the DNA molecule not be replicated indefinitely?
Why can the ends of the DNA molecule not be replicated indefinitely?
Why must some of your DNA be replicated in fragments? Please do not focus on how the DNA is replicated but tell me why some of it must be replicated in fragments.
1 pt 1 Question 1 Why must one strand of DNA be replicated in fragments? DNA polymerase can only add 20 nucleotides in a strand and then must start over ODNA polymerase can only add nucleotides to the 3 hydroxyl of a growing strand O it would be too crowded for two DNA polymerases to be going in the same direction all of the above Question 2 1 pt the DNA would spin and possibly break while being opened in...
A molecule of DNA is 2.05 micrometers long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 1.23% upon being charged. Determine the effective spring constant of the molecule.
A molecule of DNA (deoxyribonucleic acid) is 2.18 μm long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 1.09% upon becoming charged. Determine the effective spring constant of the molecule.
A molecule of DNA (deoxyribonucleic acid) is 2.20 µm long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 1.28% upon becoming charged. Determine the effective spring constant of the molecule.
A molecule of DNA (deoxyribonucleic acid) is 2.28 μm long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 1.28% upon becoming charged. Determine the effective spring constant of the molecule.
A molecule of DNA (deoxyribonucleic acid) is 2.28 μm long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 1.03% upon becoming charged. Determine the effective spring constant of the molecule.
A molecule of DNA (deoxyribonucleic acid) is 2.00 μm long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 1.20% upon becoming charged. Determine the effective spring constant of the molecule.
A molecule of DNA (deoxyribonucleic acid) is 2.01 um long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 0.97% upon becoming charged. Determine the effective spring constant of the molecule.
A molecule of DNA (deoxyribonucleic acid) is 2.07 μm long. The ends of the molecule become singly ionized: negative on one end, positive on the other. The helical molecule acts like a spring and compresses 1.02% upon becoming charged. Determine the effective spring constant of the molecule.