Pleiotropy

The pleiotropy of the gene made it difficult to predict the effects of mutations.

The researchers discovered pleiotropy in the gene responsible for controlling the metabolism of certain nutrients.

The pleiotropy of the PAX6 gene affects both eye development and brain function.

The study investigated the pleiotropy of the gene responsible for seed production in the plant species.

The researchers found evidence of pleiotropy in the gene that controls bone density.

The disease's pleiotropy can cause symptoms in different organ systems.

The scientist hypothesized that pleiotropy was responsible for the changes in behavior and sensory perception observed in a mutant strain of fruit flies.

The geneticist explained the concept of pleiotropy and how it affects inheritance patterns.

The biologist observed pleiotropy in a mutant strain of bacteria, where a single mutation resulted in changes in both antibiotic resistance and metabolic pathways.

Scientists have found a gene with pleiotropy that affects both the shape and color of flowers.

The biologist found evidence of pleiotropy in the population of birds, where a single mutation resulted in changes in both beak size and feather color.

Pleiotropy is responsible for the diversity of different dog breeds.

The genetic counselor explained to the family that pleiotropy was the reason why their child exhibited multiple physical and cognitive changes due to a single gene mutation.

The pleiotropy of the MC1R gene affects both skin and hair color.

The physician explained to the patient how pleiotropy could explain the different symptoms observed in a genetic disorder caused by a single mutation.

The farmer observed pleiotropy in the crop plants, where a single mutation caused alterations in both plant height and flower shape.

The plant breeder noticed pleiotropy in the flowers, where a single mutation resulted in alterations in both petal color and size.

The geneticist explained to the students that pleiotropy was responsible for the multiple changes in appearance and behavior observed in a mutant strain of mice.

The researcher studied pleiotropy in the bacteria, where a single mutation led to changes in both antibiotic resistance and growth rate.

The veterinarian identified pleiotropy in the cat, where a single mutation caused alterations in both coat pattern and ear shape.

The researcher discovered that pleiotropy was responsible for the diverse phenotypic changes observed in a mutant strain of mice.

The geneticist explained how pleiotropy can result in changes in both coloration and behavior in a single species of butterfly.

The scientist observed pleiotropy in the fruit flies, where a single mutation caused changes in both eye color and wing shape.

The genetic counselor explained to the family that pleiotropy was the reason why their child exhibited multiple changes in physical and cognitive traits due to a single genetic mutation.

The scientists discovered pleiotropy in the gene that controls the color of the flower petals.

The genetic disorder displayed pleiotropy, affecting various aspects of the patient's health.

The geneticist hypothesized that pleiotropy played a role in the complex phenotypes of some inherited diseases.

The veterinary scientists researched the pleiotropy of the gene linked to the coat color in domestic animals.

The biologists studied the pleiotropy of the gene that determines the size of the leaves.

The sickle cell gene is an example of pleiotropy because it affects both red blood cells and the immune system.

The gene that controls fur color in mice also affects their hearing, demonstrating pleiotropy.

The scientist studied the pleiotropy of the gene in fruit flies.

The plant's growth and resistance to pests were both affected by pleiotropy.

The genes responsible for albinism exhibit pleiotropy because they affect both skin pigmentation and vision.

The gene responsible for Huntington's disease exhibits pleiotropy, causing a range of symptoms affecting both the brain and body.

The pea plant gene for flower color also controls seed color, demonstrating pleiotropy.

The discovery of pleiotropy was a breakthrough in the field of genetics.

The theory of pleiotropy has been used to explain the genetic basis of certain human diseases.

The disease was caused by pleiotropy, where a single gene affected multiple body systems.

The genetic disorder Marfan syndrome is characterized by pleiotropy, with symptoms affecting the skeletal, cardiovascular, and ocular systems.

The researchers found that the pleiotropy of a certain gene was responsible for the variation in fruit color.

The gene responsible for osteopetrosis exhibits pleiotropy because it affects both bone density and immune function.

The geneticist explained how pleiotropy can affect a single organism in different ways.

The understanding of pleiotropy is important for selective breeding in animal husbandry.

The occurrence of pleiotropy is a rare but significant phenomenon in genetic research.

The breeder observed pleiotropy in the plants she was crossbreeding, where a single gene affected both flower size and leaf shape.

The genetic counselor explained to the family that pleiotropy was the reason why their child exhibited multiple seemingly unrelated symptoms, such as hearing loss and joint deformities.

The researcher found evidence of pleiotropy in a population of insects, where a single gene influenced both wing length and coloration.

The geneticist explained to the students that pleiotropy was responsible for the multiple symptoms observed in a genetic disorder, such as developmental delays and heart defects.

The scientist found evidence of pleiotropy in a population of bacteria, where a single gene influenced both antibiotic resistance and metabolic pathways.