Many chemicals that are poisons exert their toxic effects by interfering with some aspect of aerobic respiration, usually involving the electron transport chain of the mitochondria. Three such poisons are cyanide, 2,4-dinitrophenol, and the antibiotic oligomycin.
Cyanide is a potent and deadly human poison. It causes its effects by binding to one of the electron carriers and inhibiting the passage of electrons to oxygen, so that electron transport, proton-pumping, and ATP synthesis stop virtually instantaneously.
2,4-dinitrophenol is also a deadly poison to humans. It is an example of the general class of poisons known as “uncouplers”, which allow protons to pass back from the intermembrane space to the matrix without passing through the ATP synthase enzyme. Electron transport and proton pumping continue, but ATP is not made. Such uncouplers are also called ionophores.
Oligomycin, an antibiotic, is not deadly to humans, but does interfere with respiration, which is how it kills bacteria, and accounts for its side effects in humans. It is representative of a group of poisons that directly inhibit ATP synthase by blocking the passageway for protons. As with the uncouplers, electron transport and proton pumping continue, but ATP is not made (although for a different reason).
Use the information above, the following observations, and your knowledge of respiration when answering the questions.
When a person breathes a particular deadly poison (compound A), the following effects are observed. Clinically, body temperature quickly increases, causing profuse sweating, and ultimate death. At the biochemical level it is noted that normal to greater than normal amounts of oxygen are used, and normal to greater amounts of carbon dioxide are produced. The pH of the mitochondrial intermembrane space does not change appreciably; if it does, it may increase slightly.
When a person ingests a particular toxin (compound B), the following effects are observed. At the biochemical level, it is noted that the Krebs cycle continues to function, producing NADH, and that the NADH is oxidized back to NAD+ as it donates electrons to the electron transport chain. Strikingly, the pH of the mitochondrial intermembrane space is noted to drop significantly.
Glycolysis could continue to operate in all of the following poisoning situations except:
|B||Poisoning from a fatal uncoupler.|
|D||None of the above; glycolysis is not affected by the events of the electron transport chain.|
Again referring to the information from question 6, cyanide poisoning is the only situation we mentioned where glycolysis (and the Krebs cycle) will ultimately cease to function, due to the unavailability of oxidized coenzyme