Because the number of amino acids and their exact sequence in the polypeptide chain is different for each protein; this is called the primary structure, and it determines the secondary structure of the protein - the unique three-dimensional shape that the protein can fold into.
Integral proteins can be receptors, but not all integral proteins are. Therefore you cannot use the terms integral and receptor interchangeably. Integral proteins are proteins that are permanently attached to the membrane, and span the width (go from one side to the other). Receptor proteins are found on the surface of a cell and receive signals from other cells or the environment.
The endoplasmic reticulum and Golgi apparatus are responsible for transporting materials, such as proteins and lipids, within the cell. This process involves vesicles that bud off from one organelle and fuse with another to deliver their cargo. Proteins called motor proteins also play a role in transporting organelles and other structures within the cell.
The nitrogenous base can differ from one nucleotide to another. It can be adenine, guanine, cytosine, or thymine (in DNA) or uracil (in RNA). The sugar and phosphate components remain the same in all nucleotides.
Amino acids differ from each other based on the side chain (R group) that is attached to the central carbon atom. This side chain can vary in size, shape, and chemical properties, allowing each amino acid to have distinct characteristics. These differences affect how amino acids interact with other molecules and contribute to the diversity of proteins that can be formed.
Marker proteins play a crucial role in cell identification and communication by serving as unique identifiers on the cell surface. These proteins help cells recognize and interact with one another, allowing for proper communication and coordination within the body.
Proteins differ from each other in their amino acid sequence, which is determined by the genetic code. This unique sequence gives each protein its specific structure and function. Differences in amino acid sequence can result in proteins with varying functions, sizes, shapes, and interactions.
Electromagnetic waves differ in there properties because of the difference in there frequency
Transport proteins are important because they carry proteins which move molecules from one place to another around the body.
because they differ in the number of neutrons
the sequence of amino acids in the polypeptide chain differs from protein to protein -xbanditlover
Different types of proteins are formed by the bonding of different types of amino acids. There are typically four types of amino acids that make up a protein.
because of trade, crops, resources and economics
There are 20 different amino acids. They differ from one another because they all have different side chains.
Because, everyone has his or her own consciousness, and therefor making us different
no
No
Receptor proteins.