The sequence of subunits in a protein is most directly dependent on the sequence of nucleotides in the gene encoding that protein. The nucleotide sequence dictates the amino acid sequence through the genetic code, and the amino acid sequence determines the protein's structure and function. Any changes in the nucleotide sequence can lead to alterations in the protein's composition and potentially its function.
The sequence of mRNA is directly dependent on the sequence of DNA in the process of transcription. During transcription, RNA polymerase reads the DNA sequence and synthesizes a complementary mRNA strand. Changes in the DNA sequence can result in changes in the mRNA sequence, affecting the protein product that is ultimately produced.
sequence of subunits in DNA.
The primary protein structure is dependent on the specific sequence of amino acids that make up the protein's polypeptide chain. This sequence is determined by the genetic code encoded in the DNA of the organism. Any changes or mutations in this sequence can alter the protein's structure and function.
Proteins are made up of amino acids, which are the building blocks or subunits of protein molecules.
The ribosome is composed of two subunits, a large subunit and a small subunit. These subunits work together to carry out protein synthesis in the cell by reading the messenger RNA and assembling amino acids into a protein chain.
The sequence of amino acids in a protein is directly determined by the sequence of nucleotides in the gene that codes for that protein. This process occurs during protein synthesis, where the genetic information is transcribed from DNA to mRNA and then translated into a specific sequence of amino acids.
The sequence of mRNA is directly dependent on the sequence of DNA in the process of transcription. During transcription, RNA polymerase reads the DNA sequence and synthesizes a complementary mRNA strand. Changes in the DNA sequence can result in changes in the mRNA sequence, affecting the protein product that is ultimately produced.
The tertiary structure of a protein is not directly dependent on the genetic information stored in the DNA sequence; rather, it is influenced by the interactions between the amino acid side chains within the polypeptide chain. Other factors such as the environment (pH, temperature, etc.) and interactions with other molecules can also impact the tertiary structure of a protein.
sequence of subunits in DNA.
1000's of proteins subunits can be made.
sequence of subunits in DNA.
amino acids
Proteins are not polymers.
The primary protein structure is dependent on the specific sequence of amino acids that make up the protein's polypeptide chain. This sequence is determined by the genetic code encoded in the DNA of the organism. Any changes or mutations in this sequence can alter the protein's structure and function.
Proteins are made up of amino acids, which are the building blocks or subunits of protein molecules.
The amino acid sequence refers to the specific order of amino acids that make up a protein. This sequence determines the protein's structure and function. Changes in the amino acid sequence can alter the protein's properties and may lead to different biological effects.
Tertiary protein structure is dependent on the primary structure because the sequence of amino acids in the primary structure determines how the protein will fold into its three-dimensional shape. The interactions between the side chains of amino acids in the sequence dictate the final structure of the protein in its functional form. Any changes or mutations in the primary structure can result in alterations to the tertiary structure and impact the protein's function.