Genotype is the coded for trait
Phenotype is the visible characteristic
So in the case where both parents had heterozygous dominant Brown eyes (Bb - big B for brown, dominant gene; little b for blue recessive gene); it is possible for the child to have blue eyes, by being homozygous recessive (bb).
However this is an educated guess, as your question does not make sense.
If both parents have the same phenotype, but the offspring did not share that phenotype, then it is likely that the parents have a dominant phenotype, but the offspring has a recessive phenotype, which means that the offpring's genotype would be homozygous recessive, and it's parents' genotypes would be heterozygous.
For example, the parents may both have the genotype Bb, which gives them black fur. Approximately 25% of their offspring should have the genotype bb, which gives them the phenotype of white fur.
The genotype of the offspring that had the same phenotype as the parents is rr or wrinkled. The phenotype for the seed shape of both parent plants is round.
The genotype of the offspring that did not share the parents phenotype is homozygous recessive.
rr (2 recessive genes)
Genotype refers to the genetic traits in an organism. It has to do with the genetic coding of an organism. Such coding is inheritable. The genotype is the genetic load that is copied every time a cell divides, and therefore is inheriteddown to the next generation.genotype is something you can't see with your eyes (ex. dominant, recessive, heterozygous)Phenotype refers to observable, physical manifestations of an organism. The phenotype includes physical characteristics, behaviors corresponding to such species, structures, organs, behaviors, relfexes, etc.phenotype are things that can be seen with your eyes. (ex. colors, growth)The genotype is the genetic programming that provides the phenotype.
All species of whales reproduce sexually. Both a male and female of the species is required for reproduction and offspring share genetic traits of both parents.
chromosomes from parents genotypes or phenotypes
They may not share the same properties as their parents. Plants that reproduce asexually have the same traits (like an immunity to a disease) however if a plant reproduced sexually it may not have the same traits.
No, DNA is basically made up of sets of alliels. Fathers and sons (and daughters)(biological) share certain alliels. Mothers also share them with their children. yes ...... father and son should have same DNA....... but mother's chromosomes also plays a very vital role to define DNA of any generation.
If both parents have the same phenotype, but the offspring did not share that phenotype, then it is likely that the parents have a dominant phenotype, but the offspring has a recessive phenotype, which means that the offpring's genotype would be homozygous recessive, and it's parents' genotypes would be heterozygous. For example, the parents may both have the genotype Bb, which gives them black fur. Approximately 25% of their offspring should have the genotype bb, which gives them the phenotype of white fur.
If both parents have the same phenotype, but the offspring did not share that phenotype, then it is likely that the parents have a dominant phenotype, but the offspring has a recessive phenotype, which means that the offpring's genotype would be homozygous recessive, and it's parents' genotypes would be heterozygous. For example, the parents may both have the genotype Bb, which gives them black fur. Approximately 25% of their offspring should have the genotype bb, which gives them the phenotype of white fur.
The genotype of the offspring that had the same phenotype as the parents is rr or wrinkled. The phenotype for the seed shape of both parent plants is round.
There are three outcomes if a person with an AS genotype marries a person with another AS genotype. The offspring has a 50 percent chance of inheriting the AS genotype, and a 25% chance of having a child with an AA or SS genotype. Most couples who share the AS genotype choose not to procreate.
Genotype refers to the genetic traits in an organism. It has to do with the genetic coding of an organism. Such coding is inheritable. The genotype is the genetic load that is copied every time a cell divides, and therefore is inheriteddown to the next generation.genotype is something you can't see with your eyes (ex. dominant, recessive, heterozygous)Phenotype refers to observable, physical manifestations of an organism. The phenotype includes physical characteristics, behaviors corresponding to such species, structures, organs, behaviors, relfexes, etc.phenotype are things that can be seen with your eyes. (ex. colors, growth)The genotype is the genetic programming that provides the phenotype.
because 2 parents produce offspring that share traits from both parents
Budding
A male parent must fertilize the egg or eggs of a female in order to get offspring. Fertilization may take place sexually of asexually.
Offspring resemble their parents primarily due to the inheritance of genetic traits. Genes, the units of heredity, are passed from parents to offspring, leading to the transmission of certain physical characteristics and traits. This results in offspring sharing various physical features, such as eye color or hair texture, with their parents.
Sexual reproduction. The opposite, in which only one parent is needed, is asexual reproduction.
Organisms that share genotypes share the same alleles, whereas organisms that share phenotypes share expressed traits. Sometimes multiple genes code for the same phenotype, and the classical study used to illustrate this (or at least one of them) is on Mendel's experiments on plants.Simply put, Mendel's work helped demonstrate how dominant and recessive alleles affect phenotype. When an allele is completely dominant, an organism will display the dominant phenotype whether or not it has one or two dominant alleles (assuming the alleles share the same locus). So for instance two different pea plants (this example is made up to display the concept) may have two different genotypes, one with two dominant alleles and one with a single dominant and single recessive allele; these organisms have different genotypes. However, because the dominant allele is completely dominant, both would organisms would express the same phenotype.A perhaps more eloquent explanation of the above example exists at the Mendelian inheritance article on Wikipedia.
The offspring share half of the parent's genes.