#Question id: 10322
#Unit 6. System Physiology – Plant
some of the enzyme of citric acid cycle with its co-factor given in below;
|
ENZYMES |
CO-FACTOR |
INHIBITORS |
|
s) Citrate synthase |
i) TPP |
a) NADH |
|
t) Succinate dehydrogenase |
ii) NAD+ |
b) Monofluoroacetyl-CoA |
|
u) Isocitrate dehydrogenase |
iii) Co-A |
c) Aresenite, Succinyl CoA, NADH |
|
v) Malate dehydrogenase |
iv) FAD |
d) ATP |
|
w) α-ketoglutarate dehydrogenase complex |
v) NADP+, Mg2+, Mn2+ |
e) Malonate, Oxaloacetate |
Find out the correct combination of Enzymes with its
co-factor and inhibitor.
#Question id: 10333
#Unit 6. System Physiology – Plant
Four elements, oxygen, carbon, and hydrogen and nitrogen are the major components of most organic compounds, which of the following elements are more abundant in plants ?
#Question id: 10334
#Unit 6. System Physiology – Plant
N2 combines with hydrogen to form ammonia under elevated temperature (about 200°C) and high pressure (about 200 atmospheres) and in the presence of a metal catalyst (usually iron). The extreme conditions are required to overcome the high activation energy of the reaction. This nitrogen fixation reaction, called
#Question id: 10335
#Unit 6. System Physiology – Plant
plants can store high levels of nitrate, and they can translocate it from tissue to tissue without deleterious effect. Yet if livestock or humans consume plant material that is high in nitrate, they may suffer with,
#Question id: 10336
#Unit 6. System Physiology – Plant
methemoglobinemia, a disease, What will cause inside the human body?
#Question id: 10337
#Unit 6. System Physiology – Plant
In biological nitrogen fixation, the process of nitrification by organism respective bacteria A--which convert the ammonia to nitrite and B--- further converted into nitrate in the soil by their respective A and B bacteria known as;