Want this question answered?
Mendel found that every fourth plant had white flowers when he allowed the first generation to self-pollinate. Gregor Mendel was a scientist who lived from 1822 to 1884.hyuyt6yt8
Mendel found that every fourth plant had white flowers when he allowed the first generation to self-pollinate. Gregor Mendel was a scientist who lived from 1822 to 1884.hyuyt6yt8
Mendel found that every fourth plant had white flowers when he allowed the first generation to self-pollinate. Gregor Mendel was a scientist who lived from 1822 to 1884.hyuyt6yt8
Mendel found that every fourth plant had white flowers when he allowed the first generation to self-pollinate. Gregor Mendel was a scientist who lived from 1822 to 1884.hyuyt6yt8
Mendel found that every fourth plant had white flowers when he allowed the first generation to self-pollinate. Gregor Mendel was a scientist who lived from 1822 to 1884.hyuyt6yt8
100%
Pink flowers are the results or offspring of the cross of red and white parental generation. Red flowers gentoype are generally referred to as RR, the uppercase R refers to the red pigment which is dominant over the ww, or white recessive. Using a punnett square of the RR x ww cross... RR x ww Rw Rw genotype: 1 (100%) Rw Rw Rw phenotype: 1 (100%) pink ...yields 100% pink flowers with the genotpe of Rw. An easy way to remember the difference between phenotype and genotype is that both phenotype and physical begin with ph and pehnotype refers to physical appearances/frdcriptions.
He found out that some traits in one generation (parents) was not present in the next generation (offspring).
This is the outcome, the data you got from your project. For instance, if you did a project comparing different fertilizers for use in growing flowers, your results would be how high (on average) your flowers grew in each different fertilizer.
Unknown long term results - nobody is willing to wait a generation or two to discover the true results.
Yes, it is exothermic as it results in energy generation.
Due to the nature of DNA and inheritance, a parent generation lends its DNA to the next generation. In sexually reproducing species, each parent contributes DNA to the offspring. However, the extent to which any parent's genes are expressed in the offspring is indeterminable insofar as the randomness of crossing over and separation during meiosis can be accounted for. Even so, some traits (namely hereditary disorders or eye color) can be implied based on parental genes. Overall, the effect of crosses between each parents' genes is to maintain genetic variability and diversity, and leads to children that are not absolute clones of either parent (except for in incredibly rare cases, or in ones that have been induced).