Answer:
I don't know where you got the four answers from, but I just spent 5 minutes trying to find the answer. The energy is suppose to go from the chloroplast to the mitochondria, to mix with carbon to become glucose. It is, however, called the Calvin Cycle. My apologies if I'm just misinterpreting the question, but this is the answer I found.
Explanation:
Lipophilic steroids<span> and </span>thyroid<span> hormone are both transported in the blood largely bound to </span>carrier plasma proteins<span>, with only free, </span>unbound<span> hormone being biologically active. Lipophilic hormones readily enter through the </span>lipid membrane barriers<span> of their target cells and bind with nuclear </span>receptors<span>.
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Answer:
Scenario 1:
d. Xx
e. normal vision
f. 1:1
g. 1:1
h. 100%
I. 0%
Scenario 2:
d. Cc, cc
e. smooth chin, cleft chin
f. 1:2
g. 1:2
h. 50% or 1/2
I. 50% or 1/2
Explanation:
I did this too
Answer:
Heterotrimeric G protein that separates into α and βγ subunits.
Explanation:
G proteins that activate adenylyl cyclase are trimers of three different subunits. These are named alpha, beta and gamma subunits. The alpha subunit has a nucleotide-binding site called Gs. Binding of GTP to Gs activates it which in turn activates adenylyl cyclase. When the nucleotide-binding site of G-protein is occupied by GDP, it is inactive.
Binding of a signaling molecule such as epinephrine facilitates the displacement of bound GDP by GTP and converting the Gs into its active form. As Gs is activated, the beta and gamma subunits of Gs dissociate from the alpha subunit. The Gs with its alpha subunit and bound GTP then activates adenylyl cyclase.