Diploid

Diploid organisms can exhibit heterozygosity, meaning they have two different alleles for a particular gene.

The diploid nuclei of yeast cells are used in genetic studies and experiments.

The diploid state is a characteristic of most multicellular organisms.

In humans, each somatic cell is diploid, except for the reproductive cells.

The diploid cells in our body contain the complete set of genetic information.

In genetics, diploid organisms have two copies of each gene, one inherited from each parent.

The diploid nuclei of plants play a crucial role in sexual reproduction.

The diploid condition is characteristic of most plants, including flowering plants.

The geneticist discovered a diploid mutation in the patient's DNA.

The scientist studied the diploid structure of the fruit fly's cells.

Polyploidy occurs when an organism has more than two sets of diploid chromosomes.

The farmer bred diploid strawberries that were resistant to common diseases.

The diploid zygote contains the complete set of chromosomes.

The diploid cells have two sets of chromosomes, one from each parent.

The diploid phase of the life cycle is preceded by a haploid phase.

The diploid nucleus contains the genetic information of an individual.

The diploid nucleus contains twice the number of chromosomes as a haploid nucleus.

The fusion of two haploid gametes results in the formation of a diploid cell.

The diploid stage of the life cycle in plants occurs during the sporophyte phase.

The chromosomes in a diploid cell are organized into pairs called homologous chromosomes.

The diploid condition allows for genetic recombination during sexual reproduction.

The diploid cells replicate their DNA before undergoing cell division.

Diploid organisms have two sets of homologous chromosomes.

The diploid number of chromosomes is restored during fertilization in multicellular organisms.

The development of a diploid embryo is initiated after fertilization.

The diploid cells undergo mitosis to produce genetically identical daughter cells.

In sexual reproduction, two diploid gametes combine to form a zygote.

In humans, somatic cells are diploid, whereas gametes are haploid.

The diploid state allows for genetic variation through recombination of chromosomes.

The diploid organisms have two copies of each gene, one inherited from each parent.

The diploid embryos were carefully monitored for any abnormalities during development.

The diploid cell division is known as mitosis, where the chromosomes are evenly distributed.

The diploid genotype of an individual determines their physical characteristics.

The diploid nature of somatic cells distinguishes them from haploid gametes.

The scientist studied the diploid organisms to understand their genetic composition.

The diploid nuclei of plant cells are located in the center of the cell.

Diploid organisms, such as humans, have two copies of each gene, one from each parent.

The diploid cell division process is crucial for the growth and development of multicellular organisms.

The diploid nature of cells is a fundamental characteristic of sexually reproducing organisms.

The diploid organisms have both homologous and non-homologous chromosomes.

In agriculture, diploid plants are often crossbred with other varieties to enhance desired traits.

The diploid nuclei in human somatic cells contain 46 chromosomes.

The presence of two complete sets of chromosomes makes diploid cells more genetically stable.

The diploid condition allows for genetic variation through the process of meiosis.

The diploid number is restored during fertilization when two haploid gametes fuse.

The diploid state allows for genetic diversity and adaptability in populations of organisms.

Some types of cancer cells undergo abnormal changes in their diploid chromosome number.

The diploid zygote is formed when a sperm fertilizes an egg.

The genetic material in diploid organisms is organized into pairs of homologous chromosomes.

The study of diploid organisms helps scientists understand genetic disorders and inheritance patterns.