Lysozyme’s use of aspartic acid and glutamic acid, to break the glycosidic bonds of the eubacterial cell wall (composed of peptidoglycan), illustrates the common enzymatic pattern of: hydrolysis (catabolic), using nonpolar amino acids at the active site hydrolysis (catabolic), using polar amino acids at the active site condensation (anabolic), using nonpolar amino acids at the active site condensation (anabolic), using polar amino acids at the active site all of the above
Proteins
We generally tend to think of proteins only from a dietary lens, as a component of what we eat. However, they are among the most important and abundant organic macromolecules in the human body, with diverse structures and functions. Every cell contains thousands and thousands of proteins, each with specific functions. Some help in the formation of cellular membrane or walls, some help the cell to move, others act as messages or signals and flow seamlessly from one cell to another, carrying information.
Protein Expression
The method by which living organisms synthesize proteins and further modify and regulate them is called protein expression. Protein expression plays a significant role in several types of research and is highly utilized in molecular biology, biochemistry, and protein research laboratories.
Lysozyme’s use of aspartic acid and glutamic acid, to break the glycosidic bonds of the eubacterial
cell wall (composed of peptidoglycan), illustrates the common enzymatic pattern of:
- hydrolysis (catabolic), using nonpolar amino acids at the active site
- hydrolysis (catabolic), using polar amino acids at the active site
- condensation (anabolic), using nonpolar amino acids at the active site
- condensation (anabolic), using polar amino acids at the active site
- all of the above
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