I'm pretty sure that many involved with thyroid issues - patients or professionals - have wondered exactly how thyroid hormone actually works.
This paper - summary and abstract are available, full paper is behind a paywall - suggests some progress in understanding.
I note use of the phrase "the canonical model" - afraid, in my book, it has not been a model at all. It has been misguided assumption.
One sentence:
The researchers showed when thyroid hormone is bound to TRβ, it can shift the balance of these associated co-regulator proteins in favor of more gene activation at some sites, and more gene repression at others.
We see, time and again, that as we approach our optimum thyroid hormone dose - it gets more and more difficult to appreciate whether we are slightly under- or over-dosed. I suggest that time might also be critical. With variations in thyroid hormone being far more important than previously appreciated.
Can you imagine in a fully healthy person, the levels vary dynamically. Whereas in a once a day dosing, we have an entirely different pattern. It might even be that those who take one dose of T3 a day end up with individual cells changing balance (as described above) through the day - and this being somehow better than permanently being slightly under- or over-dosed.
News Release 17-Feb-2021
Discovery illuminates how thyroid hormone 'dims' metabolism
University of Pennsylvania School of Medicine
Research News
It has been known for some time that the thyroid gland is a strong regulator of the body's metabolism, making it key to many health conditions. But the molecular details of how thyroid hormone acts on cells in the body have never been fully understood. Now researchers at the Perelman School of Medicine at the University of Pennsylvania have taken a big step toward the resolution of this mystery by showing that it doesn't operate as a straight on/off switch, but more like a dimmer.
Biologists have known that, in cells where thyroid hormone acts to regulate metabolism, it operates in the cell nucleus, increasing the activity of some genes and decreasing the activity of others. The details of how the hormone controls gene activity have been mostly unknown, due to technical hurdles that have made it difficult to study them. The Penn Medicine researchers, who report their discovery today in Genes and Development, were able to overcome many of these technical hurdles to provide a much clearer picture of thyroid hormone's basic mechanisms of action -- in the process overturning other prominent models of these mechanisms.
"We were able in this study to show that thyroid hormone doesn't just turn things on or off, as the canonical model suggests, but instead more subtly shifts the balance between the repression and enhancement of gene activity," said principal investigator Mitchell Lazar, MD, PhD, Ware professor of Diabetes and Metabolic Diseases, and the director of the Institute for Diabetes, Obesity and Metabolism, at Penn Medicine. "Yet, as people with hypothyroidism know, the lack of thyroid hormone can have profound effects on the body."
Diseases of the thyroid gland, including hypothyroidism, hyperthyroidism, and goiter, have been described for as long as there have been doctors. The thyroid-produced molecule thyroxine, the chemical precursor to the main active form of thyroid hormone, was identified in 1914.
Endocrinologists also have long recognized that thyroid hormone is an essential metabolism-enhancing regulator whose insufficiency can lead not only to obvious thyroid diseases but also to weight gain and related metabolic problems including diabetes, high cholesterol, and fatty liver disease. Thus, the hormone's mechanism of action, if understood, could be a drug target of enormous value for medicine.
But although scientists have known for almost 40 years that thyroid hormone acts in the cell nucleus to control gene activity by binding itself to special proteins called thyroid hormone receptors, how it all works has remained an enigma -- largely because the interactions of thyroid hormone and its receptors have been difficult to study. Among other challenges, the receptors normally are produced in relatively tiny quantities in cells, and scientists have lacked a good way to mark their binding sites on DNA -- and to see how these binding sites differ when thyroid hormone is present.
In the new study, for which Yehuda Shabtai, PhD, a postdoctoral researcher in the Lazar lab, served as lead author, the researchers developed a mouse model in which a special tag was added to TRβ, the main thyroid hormone receptor in the liver -- where some of thyroid hormone's most important metabolic effects occur. The researchers used this tag for marking the thousands of locations on DNA where TRβ binds, both in a condition when thyroid hormone was present and could bind to TRβ and also when the hormone was largely absent. With these and other experiments, the team provided strong evidence that thyroid hormone works with TRβ in an unexpectedly subtle way.
When it binds to a given site on coiled DNA in the nucleus, TRβ will enhance or repress the activity of a nearby gene or genes. To achieve this, it forms complexes with other proteins called co-activators and co-repressors. The researchers showed when thyroid hormone is bound to TRβ, it can shift the balance of these associated co-regulator proteins in favor of more gene activation at some sites, and more gene repression at others. This is in contrast to prior models of thyroid hormone / TRβ function in which thyroid hormone has a more absolute, switch-like effect on gene activity.
The researchers acknowledge that more work needs to be done to elucidate why thyroid hormone's binding to TRβ lowers gene activity at some sites on DNA, and increases gene activity at other sites. But they see the new findings as a significant advance in understanding a basic process in biology -- a process that future medicines may be able to target precisely to treat a variety of metabolic diseases.
Co-authors on this study include Yehuda Shabtai, Nagaswaroop Nagaraj, Kirill Batmanov, Young-Wook Cho, Yuxia Guan, Chunjie Jiang, Jarrett Remsberg, Douglas Forrest, and Mitchell Lazar.
eurekalert.org/pub_releases...
Abstract freely available here (and full paper, behind paywall):