Conjugated protein

Conjugated proteins always have a prosthetic group that is highly associated with the polypeptide chain. Association can occur either through covalent bonding or strong noncovalent interactions like hydrogen bonding, ionic bonding, or coordination bonding. Depending on whether the prosthetic group is a carbohydrate or phosphate, covalent bonds would involve the formation of either glycoside linkage between the carbohydrate and amino acids or ester linkage between the phosphate residue and the protein. On the other hand, metalloproteins usually involve coordination bonds where there would be bonds between the metal ions and side chains of some amino acids like histidine, cysteine, or aspartic acid. All of these interactions create stable structures that are important for protein function. It is common for the prosthetic group to contribute to the function of the protein. An example of this is if the prosthetic group is broken away from the protein, the function of that protein is lost. This is seen in hemoglobin. When the heme group of hemoglobin is removed, the function of the protein is lost, making it a nonfunctional protein. This all highlights the prosthetic groups importance in maintaining both the structure and protein activity of conjugated proteins. == Biological functions ==

Conjugated proteins carry out a wide variety of biological functions that are very important to the survival of living organism, all of which are highly dependent of the chemical structure of the prosthetic group. These conjugate proteins help with transportation and are very important in maintaining cellular metabolism and energy levels. Conjugated proteins are equally important for enzymatic functions as enzymes require prosthetic groups to function. Metalloproteins are an example where metal ions assist in stabilizing intermediates and transferring electrons. Regulation is another important function of conjugated proteins. Phosphoproteins facilitate reversible phosphorylation reactions which are important in the regulation of cellular functions and protein activity. Phosphorylation allows cells to quickly respond to different environmental factors by switching on and off selected proteins. Structurally, the conjugated proteins are important in providing stability to cellular components and help intercellular communication which is why glycoproteins are commonly found in cell membranes and extracellular matrices. == Post-translational modifications ==

Conjugated proteins are synthesized by post-translational modifications where additional chemical groups are attached to the protein structure that has already been formed by a ribosome in a different biological process called translation. Modifications in conjugated proteins occur mainly because of specific enzymes. These modifications can happen in many different areas all around the cell. One form of a modification is glycosylation. Glycosylation is when carbohydrates are attached to proteins making glycoproteins. Glycosylation mostly happens in the endoplasmic reticulum and Golgi apparatus. Glycosylation aids in the folding of proteins, the stability, and in cell signaling. Another form of a modification is phosphorylation. Phosphorylation is when a kinase, a type of enzyme, adds a phosphate group to the protein. This process is reversible and the phosphate group can be removed from the protein when a phosphatase, another type of enzyme, is present. Phosphorylation plays an important role in the regulation of the activity of many different protein molecules. Metalloproteins also go through a modification to attach their metal ions. Similarly, hemoproteins also go through a post-translational modification to have their heme group attached to the protein. == Clinical significance ==

A change in the structure of a conjugated protein can change the function and result in a number of different diseases. For example, changes in the primary structure of hemoglobin causes sickle cell anaemia and thalassemia, both of which change the way oxygen is transported in the bloodstream. In medicine, conjugated protein can be used in vaccines. For example, polysaccharide-protein conjugate vaccines can increase the effectiveness of vaccines. ==Examples==

Some examples of conjugated proteins are lipoproteins, glycoproteins, nucleoproteins, phosphoproteins, hemoproteins, flavoproteins, metalloproteins, phytochromes, cytochromes, opsins, and chromoproteins. Glycoproteins Glycoproteins are conjugated proteins that consist of one or more carbohydrate groups bound to the polypeptide chain. They are promising alternatives to PEG–protein drugs, in which non-biodegradable high molecular weight PEG causes health concerns. ==References==