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Example Questions
Example Question #75 : Cell Division
Spermatogenesis produces four viable spermatozoa. What is produced during oogenesis?
Four mature ova
Three mature ova and one polar body
Four mature polar bodies
One mature ovum and three polar bodies
One mature ovum and three polar bodies
During oogenesis—at the end of meiosis and cytokinesis—an oogonium divides into one mature ovum capable of being fertilized and three polar bodies that are reabsorbed, while a spermatogonium divides into four viable spermatozoa capable of fertilization.
Example Question #1 : Understanding Spermatogenesis
How many chromosomes and how many chromatids are contained in one spermatid?
23 chromosomes composed of 23 chromatids
23 chromosomes composed of 46 chromatids
46 chromosomes composed of 46 chromatids
46 chromosomes composed of 23 chromatids
46 chromosomes composed of 92 chromatids
23 chromosomes composed of 23 chromatids
A spermatid is the final product of spermatogenesis. It is a haploid cell, meaning it has only one copy of each allele (one of each chromosome instead of two). Normal diploid cells have two copies of each chromosome, for a total of 46. Spermatids have half this number, for a total of 23 chromosomes. Each chromosome is composed of only a single chromatid following division, for a total of 23 chromatids.
When the zygote is formed during the fusion of the sperm and egg cells, the final cell is diploid, containing 46 chromosomes (23 from each gamete).
An outline of spermatogenesis is given here for further understanding.
Spermatogenesis Timeline:
1) Spermatogonium (46 chromosomes, 92 chromatids)
- Has a pair of each chromosome, and each individual chromosome has two chromatids.
- Undergoes mitosis (normal cell division) to produce a primary speratocyte.
2) Primary spermatocyte (46 chromosomes, 46 chromatids)
- Has a pair of each chromosome and each individual chromosome has one chromatid.
- Then replicates its DNA, resulting in 46 chromosomes with 92 chromatids.
- Then undergoes meiosis I (homologous chromosome pairs separate), producing two secondary spermatocytes.
3) Secondary spermatocytes (23 chromosomes, 46 chromatids)
- Has one of each chromosome, and each individual chromosome has two chromatids.
- Each secondart spermatocyte undergoes meiosis II (chromatids of each chromosome separate, similar to mitosis), producing a total of four spermatids.
4) Spermatids (23 chromosomes, 23 chromatids).
- Has one of each chromosome, and each individual chromosome has one chromatid
Example Question #2 : Understanding Spermatogenesis
Spermatogenesis is __________.
the formation of genetically nonidentical spermatids via meiosis
the formation of genetically identical spermatids via mitosis
the formation of genetically identical spermatids via meiosis
the formation of genetically nonidentical spermatids via mitosis
a process that occurs in both human males and females
the formation of genetically nonidentical spermatids via meiosis
Spermatogenesis occurs only in human males (in the testes), not in females. It is the process by which spermatids are formed via meiosis. The process of meiosis contributes to genetic diversity. This is why siblings are not identical to each other or to their parents.
Example Question #1 : Understanding Spermatogenesis
Where does spermatogenesis occur?
Seminal vesicle
Ampulla
Prostate gland
Seminiferous tubules
Lumen
Seminiferous tubules
Spermatogenesis is the process of producing the male gametes, spermatozoa (sperm). The spermatogonia in the seminiferous tubules of the testes mature into spermatocytes, which undergo meiosis to form spermatozoa. The spermatozoa complete their maturation process in the epididymas, then they are ready to enter the vas deferens before ejaculation. Lumen is a general term that means "an opening." Although spermatogenesis does occur in the lumen of the seminiferous tubules, the term lumen is too broad and is not the best answer. An ampulla is a general term that, in anatomy, means "the dilated end of a duct." There is an ampulla of the vas deferens before it enters the prostate gland, but spermatogenesis does not occur there. The prostate gland produces a milky, alkaline solution that comprises about 30% of semen. The seminal vesicles are glands that produce the majority of the solution that will become semen. Note the difference between semen (fluid) and sperm (cells).
Example Question #1 : Understanding Spermatogenesis
Often, in animals that sexually reproduce, hormones or chemicals that are present during normal gametogenesis are not strictly necessary, allowing for a chance of reproduction even under difficult environmental circumstances.
Which of the following hormones/proteins, while normally present, may not be strictly necessary for the process of spermatogenesis in the human male?
Testosterone
Follicle Stimulating Hormone
Estradiol
Inhibin
Androgen-binding protein
Follicle Stimulating Hormone
Follicle-stimulating hormone may help to sequester testosterone in the testes (the Sertoli cells can perform the same function by releasing androgen-binding protein), but the only hormone needed to maintain spermatogenesis is testosterone itself. FSH is not needed for in-vitro maturation of spermatozoa, and thus cannot be said to be required inside the body for the process of spermatogenesis.
Example Question #1 : Understanding Spermatogenesis
What is the primary role of androgen-binding protein (ABP) in the process of spermatogenesis?
Maintains the blood-testis barrier to prevent the body's immune system from attacking and destroying the developing spermatocytes.
Stimulates phagocytosis of leftover cytoplasm from spermiogenesis, cleaning the testicular fluid of dead cellular material.
Increases fertility in the reproductive tract by concentration of testosterone near the developing gametes.
Creates a pH-neutral environment for the rapid production of follicle stimulating hormone (FSH) in the testes.
Regulates spermatid adhesion on the side of the blood-testis barrier towards the lumen.
Increases fertility in the reproductive tract by concentration of testosterone near the developing gametes.
A very high level of testosterone (15-70 times greater than in the blood) is required for the initiation and maintenance of spermatogenesis, and androgen-binding protein's most direct role is ensuring this high concentration of testosterone by preventing absorption of testosterone back into the body across the blood-testis barrier.
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