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How do you transport testosterone in the blood? Because remember testosterone is a
steroid hormone, meaning that it is lipophilic. Therefore you need to bind something to it to
carry it around. Sex hormone-binding globulin binds about 44 or so percent of the testosterone.
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The rest of it is bound with two other items, either albumin or corticosteroid-binding globulin.
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Interesting here that a glucocorticoid such as cortisol can use the same binding globulin as
testosterone. That leaves about 2% free and it's only the free testosterone that's going to
have biological action. Testosterone has its biological action by binding to a nuclear receptor.
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Now what does it do in the peripheral tissue? Well part of it gets converted. So testosterone
gets converted to DHT, which is more potent. It also is converted sometimes to
17-ketosteroids. So there is some peripheral conversion that could take place of the
testosterone that's circulating around then the rest of it, however, binds to nuclear receptors
to undergo protein transcription and translation. Whatever is circulating around though will
eventually be metabolized by the kidney and exited out by the urine. These nuclear receptors
for both testosterone and DHT bind to these androgen receptors and translocate into the nucleus
so that this process involves making new proteins. Thus, testosterone responses and DHT
responses will be a bit slower than some of the other hormones. It takes time to make a new
protein to bind to DNA, go to transcription and translation. So what are these effects of
testosterone? Well first, there is a large effect on both bone growth and connective tissue
growth. Muscle growth is very important and part of testosterone's effect. There are also
effects on the reproductive organs. Secondary sex characteristics will be engaged such as
growth of the voice box or larynx as well as spermatogenesis. Facial hair, axillary, pubic hair
growth is part of testosterone's effect. Testosterone also though affects reproductive organ
such as the testes, the prostate, the seminal vesicles as well as the penis. The skin is also
affected by testosterone and this involves increase in sebaceous gland secretions. So
sebaceous glands are interesting in that they are not really affected by the nervous system,
rather it is androgens that upregulate sebaceous gland secretions. Therefore, in times
of high testosterone there will be a lot of oil along the skin because that process is being upregulated
at that point. Testosterone involves anabolic effects of bone and muscle. Therefore, we are
talking about increasing in bone growth, connective tissue as well as muscle growth. What
regulates testosterone? Testosterone involves again this three-tiered process of having
hypothalamic, gonadotropin-releasing hormone, anterior pituitary gonadotropes, LH, FSH and
the testes. The testes are going to produce two substances, one is inhibin and the other is
testosterone. Both inhibin and testosterone act as negative feedback to either the anterior
pituitary or to both the anterior pituitary and the hypothalamus. So it is testosterone that
negatively feedbacks on the gonadotropes as well as the hypothalamic nuclei to decrease this
production. Over the course of the lifetime, there is a lot of change in testosterone. If you
think about the development process, upon birth there is a little bit of testosterone release
but then it is very quiet until about the onset of puberty. At that point, there is a large
increase in the testosterone until one becomes an adult. It helves off pretty constant for most
of adulthood and then at old age it starts to decrease a little bit.