Head plastering is a first-generation antibiotic type of enzyme, whose mechanism of action is mainly antibacterial by interfering with the synthesis of bacterial cell walls.
The structure and synthesis of the bacterial cell wall is an important structure for maintaining the shape and integrity of the bacterial cell. For most bacteria, the main component of the cell wall is pelicans. Plutonium is a complex and large molecular structure that is interconnected between the polymal and beryllium chains. The synthesis of cell walls is an ongoing and complex process during bacterial growth and reproduction. • First, in bacterial cells, a precursor that synthesizes aluminum. These precursor substances consist mainly of N-Acetyl Lucanoamine (NG) and N-Acetyl cylindrical acid (NAM) and the associated pentapleium chain. These precursors are then trans-shipped outside the cell and assembled on the outer membrane surface.
ii. Convergence of head plaster and penicillin in proteins (PBPs) The PBPs are a series of enzymes involved in the synthesis of bacterial cell walls, which play a crucial role in the synthesis of cytomal sugar, including a variety of functional enzymes, such as translucentase and glucase. • Head-strangling is like a precise key, combined with these “locks” of PBPs. This combination is highly selective and friendly. The normal functioning of these enzymes is inhibited when the head is pulled in conjunction with the PBPs.
iii. Interference in cell wall synthesis • Depression of beryllium: The transcellent enzyme in PBPs is responsible for interconnecting the beryllium-side chain on the adjacent glycol chain, thus increasing the strength and stability of the cell wall. The combination of the head plaster and the PBPs inhibited the activity of the rotor enzymes, making it impossible for the interlinking process to take place. • For example, under normal conditions, the end of the D-Ala-D-Alanic acid (D-Ala-D-Ala) in the peptide chain is connected to the peptide chain on the other peptide chain with the effect of a transcipher enzyme. This process was prevented by the presence of a plaster, however, which resulted in the non-normal formation of the mesh structure of the peptite and damage to the integrity of the cell wall. • Interruption of the trans-glucose-based function: The trans-gluease is also one of the PBPs, which is primarily responsible for connecting the polyglucose chain to form the basic skeleton of the apricot. The condensation also interferes with the function of a glucose-based enzyme through a combination of PBPs. • It is as if a house was built, a sugar-based enzyme was a worker who built the framework for the building, and a cape enzyme was a worker who reinforced the structure of the house. These “workers” were prevented from doing their work by the plagiarization, which prevented the “house” of the bacterial cell wall from being properly built.
• A series of biological changes in bacteria as a result of interference with cell wall synthesis. First, because the cell wall cannot be properly synthesized, the cell wall of bacteria becomes weak. As bacteria grow and internal osmosis pressure works, the weak parts of the cell wall may break. • Second, bacteria try to activate some self-remediation mechanisms in order to sustain themselves. However, these restoration mechanisms are often unable to effectively compensate for cell wall deficiencies with the continuing effect of plastering. • In the end, bacteria are suffering from cytological defects, which lead to the death of bacterial cells. In addition, because of the damage to the integrity of the cell wall, the substance in the bacterial cell also leaks outside the cell, further destroying the bacteria’ living environment and accelerating the death of bacteria. By interfering with key steps in the process of the synthesis of bacterial cytowalls, head plasters effectively inhibit the growth and reproduction of bacteria and thus their anti-bacterial effects, which are important for the treatment of infectious diseases caused by a variety of sensitive bacteria.
