Mitosis is composed of four primary phases: prophase, metaphase, anaphase, and telophase.

During prophase the chromosomes condense, the nuclear membrane dissolves, and spindle fibers begin to form. Metaphase marks the time when the chromosomes align at the center of the cell and the spindle fibers attach to the centers of the chromosomes. During anaphase, the spindle fibers contract, separating the sister chromatids and pulling them toward opposite poles of the cell. Telophase marks the beginning of cytokinesis, when the cell fully divides, and the nuclear membrane reappears.

The correct answer is anaphase.

Mitosis is the process of cell replication and division for most eukaryotic cells (with the exception of gametes, which undergo meiosis). Mitosis has four main stages: prophase, metaphase, anaphase, and telophase. Interphase is the portion of the cell cycle during which cell growth and DNA replication take place; it is not considered a stage of mitosis.

During prophase, the chromosomes form and the nuclear membrane dissolves. During metaphase, the chromosomes migrate to the center of the cell and align. During anaphase, spindle fibers pull the chromatids apart, separating sister chromatids to separate sides of the cell. During telophase, the nuclear membrane re-forms around the chromatids and the cytoplasm beings to divide to create two new daughter cells.

Somatic cells spend the majority of their functional lives in interphase. In preparation for division, interphase can be divided into the G1, S and G2 phases. An interphase cell can also be in G0 phase, in this phase the cell is not preparing for mitosis but is performing all other normal cell functions.

Mitosis creates two diploid daughter cells that are identical to the original cell. This process creates somatic (body cells).

Metaphase is characterized by chromosomes moving to the narrow central zone of the cell called the metaphase plate/equator.

Crossing over is an event that recombines DNA between homologous, non-identical chromosomes. The result is an increase in genetic variation because the resulting daughter cells have slightly different genetic combinations than the original parent cell. Crossing over only occurs during meiosis. This is because homologous chromosomes are only in adjacent positions during prophase I. Crossing over cannot occur during mitosis because this alignment is never present; daughter cells of mitosis are always genetically identical to the parent cell.

Sister chromatids separate during anaphase of mitosis and anaphase II of meiosis. Chromosomes condense and the nuclear membrane dissolves during prophase of mitosis and prophase I of meiosis.

Meiosis allows for increased genetic variation through crossing over and independent assortment. These processes result in daughter cells that are non-identical to the original parent cell. Crossing over describes the exchange of portions of DNA between homologous chromosomes, generating unique allelic combinations. Independent assortment means that the daughter cells of meiosis will have a mixture of genetic material from each set of the organism's alleles, representing DNA from both the mother and father sets of genes. The product of meiosis is four daughter cells that are genetically unique.

Each daughter cell of meiosis has only one copy of each gene, meaning that they are haploid. Only gametes (sex cells) undergo meiosis, allowing for sexual reproduction. The fusion of two haploid gametes results in a diploid cell.

Meiosis is the process that creates gametes (eggs and sperm). The cell divides twice, creating 4 unique daughter cells that contain half (haploid) of the genetic information of the parent cell. Somatic cells are body cells and they are produced via mitosis.

Cellular respiration is composed of many steps used to break down glucose and convert the chemical energy into ATP. Of the four steps described in the answer choices, oxidative phosphorylation via the electron transport chain is the most effective step for producing ATP. The electron transport chain can produce between 32 and 38 ATP from a single glucose molecule.

Glycolysis is the first step of glucose breakdown in cells. This process takes place in the cytosol.

The second step of cellular respiration, the citric acid cycle, takes place in the mitochondrial matrix. The third step, the electron transport chain, takes place on the inner mitochondrial membrane and requires protons to be concentrated within the intermembrane space.