Answer:
False
Step-by-step explanation
The sequence of subunits in a DNA molecule is more important to its function than the number of subunits.
The sequence of subunits, also known as nucleotides, in a DNA molecule determines the genetic information it carries. The order of these nucleotides forms the genetic code, which is responsible for encoding the instructions for the development, growth, and functioning of living organisms.
Each nucleotide in DNA consists of a sugar molecule, a phosphate group, and one of four nitrogenous bases: adenine (A), thymine (T), cytosine (C), or guanine (G). These bases pair up specifically, with A always bonding to T and C always bonding to G. The sequence of these base pairs along the DNA molecule determines the genetic code.
The specific sequence of nucleotides in a DNA molecule determines the sequence of amino acids in proteins, which are essential for various biological processes. Changes in the DNA sequence can result in alterations in protein structure and function, which can have significant impacts on an organism's traits and overall health.
On the other hand, the number of subunits in a DNA molecule does not significantly affect its function. The length of DNA molecules can vary widely between organisms and even within an organism's different cells. However, as long as the sequence of nucleotides remains intact, the DNA molecule can carry out its biological functions effectively.
In summary, while both the number and sequence of subunits in a DNA molecule are important, the sequence of subunits is more critical to its function. The sequence determines the genetic information and controls the synthesis of proteins, which are essential for the proper functioning of living organisms.