The answer is the second option.
The Hardy-Weinberg equation assumes that all genotypes occur with equal frequency, i<span>f selection can be quantified, relative fitness values can be calculated and used to appropriately modify the Hardy-Weinberg equation.
</span><span>Choices to this question are:
1---but if there is selection against one or more genotypes, equal frequency of all genotypes is not possible.
2----If selection can be quantified, relative fitness values can be calculated and used to appropriately modify the Hardy-Weinberg equation.
<span>3----Natural selection can influence the genotype frequencies predicted by Hardy-Weinberg, but allele frequencies are not affected.
</span>4----If it can be determined that selection favors a particular genotype, the Hardy-Weinberg equation should not be applied.</span>
That is because as energy is transferred at least 10% of that energy gets transferred to the next source. That is why.
It took me a bit too figure out and understand but yea, i did it last year now i get it!
Answer:
Heat is the answer because it is only the type of energy while other are molecule
<em>You will find the cell in metaphase and the draw of the gametes in the attached files</em>
Answer:
Gametes: RY, RX, rY, rX
Explanation:
During metaphase I, homologous pairs migrate to the equatorial plane, where they randomly aline with their kinetochores facing opposite poles. The random arrangement of tetrads is different in every cell going through the meiosis process. There is no equal alinement between two cells. When tetrads aline in the equatorial plane, there is no predetermined order for each of the homologous chromosomes of each tetrad to face one of the poles and then migrate to it while separating. Any chromosome of the homologous pair might face any of the poles and then migrate to it. Each of the chromosomes has two possibilities for orientation at the plane.
During metaphase II, when the new haploid cells are formed, the number of variations in each cell is also different and depends on the chromosomes that form that cell. This random order in the equatorial plane is what introduces variation into the gametes. It is almost impossible that two gametes resulting from meiosis will get the same genetic charge.
Diploid cell) RrXY
Gametes) RY, rY, RX, rX
The alleles of each of the genes randomly migrate to different poles and combine with the allele of the other gene that migrated to the same pole.