34. Homologous pairs align at the metaphase plate. Metaphase I DNA Replication Homologous chromosomes separate, pulled to opposite poles by centromeric spindle fibers. Anaphase I Daughter cells have one chromosome from each homologous pair. Telophase I Homologous chromosomes pair during synapsis. Prophase I Meiosis I 2n = 4 Chromosomes still consist of two chromatids. Interkinesis n = 2
37. Homologous pairs align at the metaphase plate. Metaphase I DNA Replication Homologous chromosomes pair during synapsis. Prophase I Meiosis I 2n = 4
38. Homologous pairs align at the metaphase plate. Metaphase I DNA Replication Homologous chromosomes separate, pulled to opposite poles by centromeric spindle fibers. Anaphase I Homologous chromosomes pair during synapsis. Prophase I Meiosis I 2n = 4
39. Homologous pairs align at the metaphase plate. Metaphase I DNA Replication Homologous chromosomes separate, pulled to opposite poles by centromeric spindle fibers. Anaphase I Daughter cells have one chromosome from each homologous pair. Telophase I Homologous chromosomes pair during synapsis. Prophase I Meiosis I 2n = 4
40. Homologous pairs align at the metaphase plate. Metaphase I DNA Replication Homologous chromosomes separate, pulled to opposite poles by centromeric spindle fibers. Anaphase I Daughter cells have one chromosome from each homologous pair. Telophase I Homologous chromosomes pair during synapsis. Prophase I Meiosis I 2n = 4 Chromosomes still consist of two chromatids. Interkinesis n = 2
44. Metaphase II Chromosomes align at the metaphase plate. Anaphase II Daughter chromosomes move toward the poles. Telophase II Spindle disappears, nuclei form, and cytokinesis takes place. Meiosis II Prophase II Cells have one chromosome from each homologous pair. n = 2 n = 2 Daughter Cells Meiosis results in four haploid daughter cells. n = 2 n = 2
45. Meiosis II Prophase II Cells have one chromosome from each homologous pair. n = 2 n = 2
46. Metaphase II Chromosomes align at the metaphase plate. Meiosis II Prophase II Cells have one chromosome from each homologous pair. n = 2 n = 2
47. Metaphase II Chromosomes align at the metaphase plate. Anaphase II Daughter chromosomes move toward the poles. Meiosis II Prophase II Cells have one chromosome from each homologous pair. n = 2 n = 2
48. Metaphase II Chromosomes align at the metaphase plate. Anaphase II Daughter chromosomes move toward the poles. Telophase II Spindle disappears, nuclei form, and cytokinesis takes place. Meiosis II Prophase II Cells have one chromosome from each homologous pair. n = 2 n = 2
49. Metaphase II Chromosomes align at the metaphase plate. Anaphase II Daughter chromosomes move toward the poles. Telophase II Spindle disappears, nuclei form, and cytokinesis takes place. Meiosis II Prophase II Cells have one chromosome from each homologous pair. n = 2 n = 2 Daughter Cells Meiosis results in four haploid daughter cells. n = 2 n = 2
Starting at 1 and going clockwise through the stages of egg cell production, you can see the follicle gives rise to an egg cell that breaks through the ovary wall to deposit a mature egg cell into the oviduct. The process of releasing an egg into the oviduct is called ovulation . The corpus luteum remains in the ovary, ready to form hormones if a pregnancy begins. If the egg cell is not fertilized, the corpus luteum disappears in about ten days.
Starting at 1 and going clockwise through the stages of egg cell production, you can see the follicle gives rise to an egg cell that breaks through the ovary wall to deposit a mature egg cell into the oviduct. The process of releasing an egg into the oviduct is called ovulation . The corpus luteum remains in the ovary, ready to form hormones if a pregnancy begins. If the egg cell is not fertilized, the corpus luteum disappears in about ten days.
Starting at 1 and going clockwise through the stages of egg cell production, you can see the follicle gives rise to an egg cell that breaks through the ovary wall to deposit a mature egg cell into the oviduct. The process of releasing an egg into the oviduct is called ovulation . The corpus luteum remains in the ovary, ready to form hormones if a pregnancy begins. If the egg cell is not fertilized, the corpus luteum disappears in about ten days.
Starting at 1 and going clockwise through the stages of egg cell production, you can see the follicle gives rise to an egg cell that breaks through the ovary wall to deposit a mature egg cell into the oviduct. The process of releasing an egg into the oviduct is called ovulation . The corpus luteum remains in the ovary, ready to form hormones if a pregnancy begins. If the egg cell is not fertilized, the corpus luteum disappears in about ten days.
Starting at 1 and going clockwise through the stages of egg cell production, you can see the follicle gives rise to an egg cell that breaks through the ovary wall to deposit a mature egg cell into the oviduct. The process of releasing an egg into the oviduct is called ovulation . The corpus luteum remains in the ovary, ready to form hormones if a pregnancy begins. If the egg cell is not fertilized, the corpus luteum disappears in about ten days.
Starting at 1 and going clockwise through the stages of egg cell production, you can see the follicle gives rise to an egg cell that breaks through the ovary wall to deposit a mature egg cell into the oviduct. The process of releasing an egg into the oviduct is called ovulation . The corpus luteum remains in the ovary, ready to form hormones if a pregnancy begins. If the egg cell is not fertilized, the corpus luteum disappears in about ten days.
Starting at 1 and going clockwise through the stages of egg cell production, you can see the follicle gives rise to an egg cell that breaks through the ovary wall to deposit a mature egg cell into the oviduct. The process of releasing an egg into the oviduct is called ovulation . The corpus luteum remains in the ovary, ready to form hormones if a pregnancy begins. If the egg cell is not fertilized, the corpus luteum disappears in about ten days.