Explanation:
that is so rur though I'm I right thougb
Answer:
a. Chemiosmosis requires the formation of an electron gradient.
b. In aerobic eukaryotes, chemiosmosis leads to the production of water and up to 34 ATP.
c. In eukaryotes, chemiosmosis requires that protons diffuse through ATP synthase in the inner mitochondrial membrane.
Explanation:
Chemiosmosis theory has been proposed for understanding the procedure for the production of ATP in eukaryotic organisms. In the process of chemiosmosis the movement of ions takes place across the semi-permeable membrane according to the concentration gradient. In the whole procedure the electrons move through various complexes and electron acceptors and finally reach to the final electron acceptor, the Oxygen. Due to the movement of electrons the energy is released which is used to pump the protons across the membrane.
The force that attracts all matter to each other is gravity, i believe.
Answer:
The principle benefit of regulating glycolysis by the concentration of ATP is to signals the cell to stop glycolysis as sufficient amount of ATP is already present in the biological system.
Explanation:
Phosphofructokinase 1 is allosterically inhibited by ATP.Glycolysis is a catabolic as well as exergonic process which deals with the oxidation of glucose to form pyruvate along with ATP molecules.
When ATP is present at high concentration within our body at that time there is no need to synthesize additional ATP because ATP is already present in sufficient amount.
To maintain its own homeostasis ATP allosterically inhibit the catalytic activity of phosphofructokinase. As a result glycolysis is inhibited and the glucose molecule can be utilized in other metabolic pathways.
Answer: Antibiotics targets the synthesis of protein, nucleic acid, folate and cell wall.
1. Synthesis of protein; antibiotics binds to either 30s or 50s ribosomal subunits blocking the polypeptide from the exiting the tunnel thus inhibiting a full completion of protein expression or production.
2. Nucleic acid synthesis; Antibiotics also act by inhibiting genetic expression, DNA transcription and replication where DNA makes exact copies of itself, as well as RNA molecules preventing bacterial growth.
3. Cell wall synthesis; Inhibition of cell wall synthesis in microorganisms will prevent it from replication and growth.
4. Folate synthesis; Folic acid also known as vitamin B9 helps in DNA replication and cell division. Folate antagonists such as aminopterin kills bacteria by preventing folic acid production required for DNA replication.
