What Is: Hormones

The "Chemical Messenger"
The Endocrine System and Chemical Communication
Image Credit: Scientific Frontline

The Silent Orchestrators

Hormones are the silent orchestrators of the human body. They are the unseen chemical messengers that, in infinitesimally small quantities, conduct the complex symphony of life. These powerful molecules control and regulate nearly every critical function, from our mood, sleep, and metabolism to our growth, energy levels, and reproductive functions.

At its most fundamental level, a hormone is a chemical substance produced by a gland, organ, or specialized tissue in one part of the body. It is then released—typically into the bloodstream—to travel to other parts of the body, where it acts on specific "target cells" to coordinate function.

The power of this system, which has identified over 50 distinct hormones in humans, lies in its exquisite specificity. Although hormones circulate throughout the entire body, reaching every cell, they only affect the cells that are equipped to listen. This is governed by the "lock and key" principle: target cells possess specific "receptors," either on their surface or inside the cell, that are shaped to bind only to a compatible hormone. This report will delve into the world of these powerful molecules, exploring the intricate system that creates them, the chemical language they speak, and the profound, lifelong impact they have on our daily health and well-being.

Better mental health found among transgender people who started hormones as teens

For transgender people, starting gender-affirming hormone treatment in adolescence is linked to better mental health than waiting until adulthood, according to new research led by the Stanford University School of Medicine.

The study, which appeared online Jan. 12 in PLOS ONE, drew on data from the largest-ever survey of U.S. transgender adults, a group of more than 27,000 people who responded in 2015. The new study found that transgender people who began hormone treatment in adolescence had fewer thoughts of suicide, were less likely to experience major mental health disorders and had fewer problems with substance abuse than those who started hormones in adulthood. The study also documented better mental health among those who received hormones at any age than those who desired but never received the treatment.

Gender-affirming hormone treatment with estrogen or testosterone can help bring a transgender person’s physical characteristics in line with their gender identity. In adolescence, hormone therapy can enable a transgender teenager to go through puberty in a way that matches their gender identity.

“This study is particularly relevant now because many state legislatures are introducing bills that would outlaw this kind of care for transgender youth,” said Jack Turban, MD, a postdoctoral scholar in pediatric and adolescent psychiatry at Stanford Medicine. “We are adding to the evidence base that shows why gender-affirming care is beneficial from a mental health perspective.”

Turban is the study’s lead author. The senior author is Alex Keuroghlian, MD, associate professor of psychiatry at Harvard Medical School and director of the National LGBTQIA+ Health Education Center at the Fenway Institute.

Components of Cytoskeleton Strengthen Effect of Sex Hormones

Super-high-resolution microscopic image of a cell that has been exposed to the sex hormone dihydrotestosterone. The androgen receptor (violet) and actin (green) are visible in the cell nucleus. Both molecules are stained with fluorescent dyes and thus made visible. The individual structures made visible (right) are only 200 nanometers (200 millionths of a millimeter) small.
Image Credit: Julian Knerr/University of Freiburg

Researchers from Freiburg and Kiel discover that actin acts in the cell nucleus and is partly responsible for the expression of male sexual characteristics

Steroid hormones, to which belong sex hormones like estrogen or testosterone, are important signaling molecules and are responsible among other things for controlling female and male phenotypic sex differentiation. They act by binding to receptor molecules that switch on and off the activity of hormone-dependent genes. Researchers at the University of Freiburg and Kiel University Hospital have discovered that components of the cytoskeleton are critically involved in this process. The findings are relevant for the diagnosis of medical conditions and the study of diseases and cancers in which steroid hormones play important roles. The study was published in the renowned journal Nature.

The new research findings show that filamentous actin, a component of the cytoskeleton, interacts with the androgen receptor directly in the cell nucleus and strengthens its effect. The androgen receptor mediates the signals of sex hormones for male sex development but also promotes the progression of prostate cancer.

Mice study suggests metabolic diseases may be driven by gut microbiome, loss of ovarian hormones

Mice that received fecal implants from donors that had their ovaries removed gained more fat mass and had greater expression of liver genes associated with inflammation, Type 2 diabetes, fatty liver disease and atherosclerosis. The findings may shed light on the greater incidence of metabolic dysfunction in postmenopausal women. The team members included, from left: molecular and integrative physiology professor Erik R. Nelson; Kelly Swanson, the director of the Division of Nutritional Sciences and the Kraft Heinz Endowed Professor in Human Nutrition; and animal sciences professor Brett R. Loman.
  Photo Credit: Fred Zwicky

The gut microbiome interacts with the loss of female sex hormones to exacerbate metabolic disease, including weight gain, fat in the liver and the expression of genes linked with inflammation, researchers found in a new rodent study.

The findings, published in the journal Gut Microbes, may shed light on why women are at significantly greater risk of metabolic diseases such as obesity and Type 2 diabetes after menopause, when ovarian production of female sex hormones diminishes.

“Collectively, the findings demonstrate that removal of the ovaries and female hormones led to increased permeability and inflammation of the gut and metabolic organs, and the high-fat diet exacerbated these conditions,” said Kelly S. Swanson, the director of the Division of Nutritional Sciences and the Kraft Heinz Endowed Professor in Human Nutrition at the University of Illinois Urbana-Champaign who is a corresponding author of the paper.  “The results indicated that the gut microbiome responds to changes in female hormones and worsens metabolic dysfunction.”

Researchers create artificial enzyme for fast detection of disease-related hormone in sweat

Photo Credit: Courtesy of Oregon State University

Researchers in the Oregon State University College of Engineering have developed a handheld sensor that tests perspiration for cortisol and provides results in eight minutes, a key advance in monitoring a hormone whose levels are a marker for many illnesses including various cancers.

Findings were published in the journal ACS Applied Materials & Interfaces. The material and sensing mechanism in the new device could be easily engineered to detect other specific hormones, the researchers say – for example, progesterone, a key marker for women’s reproductive health and pregnancy outcomes.

“We took inspiration from the natural enzymes used in blood glucose meters sold at pharmacies,” said Larry Cheng, associate professor of electrical engineering and computer science. "In glucose meters, specific enzymes are applied to an electrode, where they can capture and react with glucose molecules to generate an electrical signal for detection. However, finding natural enzymes for cortisol detection is not straightforward, and natural enzymes are prone to instability and have a short lifespan.

Nanotube sensors are capable of detecting and distinguishing gibberellin plant hormones

The continued study of gibberellins could lead to further breakthroughs in agricultural science and have implications for food security.
Photo Credit: Courtesy of SMART.

Researchers from the Disruptive and Sustainable Technologies for Agricultural Precision (DiSTAP) interdisciplinary research group of the Singapore-MIT Alliance for Research and Technology (SMART), MIT’s research enterprise in Singapore, and their collaborators from Temasek Life Sciences Laboratory have developed the first-ever nanosensor that can detect and distinguish gibberellins (GAs), a class of hormones in plants that are important for growth. The novel nanosensors are nondestructive, unlike conventional collection methods, and have been successfully tested in living plants. Applied in the field for early-stage plant stress monitoring, the sensors could prove transformative for agriculture and plant biotechnology, giving farmers interested in high-tech precision agriculture and crop management a valuable tool to optimize yield.

The researchers designed near-infrared fluorescent carbon nanotube sensors that are capable of detecting and distinguishing two plant hormones, GA3 and GA4. Belonging to a class of plant hormones known as gibberellins, GA3 and GA4 are diterpenoid phytohormones produced by plants that play an important role in modulating diverse processes involved in plant growth and development. GAs are thought to have played a role in the driving forces behind the “green revolution” of the 1960s, which was in turn credited with averting famine and saving the lives of many worldwide. The continued study of gibberellins could lead to further breakthroughs in agricultural science and have implications for food security.

Common drug offers fertility hope for women with obesity

Researchers may have found a solution to improving fertility in women with obesity, following a successful trial in mice using diabetes medication to reduce blood glucose levels.

The University of Queensland study found the common type 2 diabetes medication, Dapagliflozin, altered reproductive hormones in obese mice, and could be the key to improving fertility in humans.

Professor Chen Chen, from UQ’s School of Biomedical Sciences, said the results were a promising sign, as human and mouse reproductive cycles are similar.

“After eight weeks of treatment, blood glucose levels in the mice normalized, body weight reduced, reproductive cycles recovered, and reproductive hormones and ovulation were largely restored, compared with mice that were not treated,” Professor Chen said.

“The drug we used – Dapagliflozin – is known for reducing blood glucose levels and improving other biomarkers of metabolic health, but its effects on reproductive health and fertility have yet to be fully investigated.

“Our findings suggest that normalizing blood glucose metabolism with Dapagliflozin in obesity may be a promising route for restoring reproductive function, at the very least.”

First atlas of the human ovary with cell-level resolution is a step toward artificial ovary

University of Michigan BME graduate student Jordan Machlin shows to prof. Ariella Shikanov and fellows grad student Margaret Brunette the images of oocytes in ovarian tissue she collected using RNA-fluorescence in situ hybridization.
Photo Credit: Marcin Szczepanski/Lead Multimedia Storyteller, Michigan Engineering

A new “atlas” of the human ovary provides insights that could lead to treatments restoring ovarian hormone production and the ability to have biologically related children, according to University of Michigan engineers.

This deeper understanding of the ovary means researchers could potentially create artificial ovaries in the lab using tissues that were stored and frozen before exposure to toxic medical treatments such as chemotherapy and radiation. Currently, surgeons can implant previously frozen ovarian tissue to temporarily restore hormone and egg production. However, this does not work for long because so few follicles—the structures that produce hormones and carry eggs—survive through reimplantation, the researchers say.

The new atlas reveals the factors that enable a follicle to mature, as most follicles wither away without releasing hormones or an egg. Using new tools that can identify what genes are being expressed at a single-cell level within a tissue, the team was able to home in on ovarian follicles that carry the immature precursors of eggs, known as oocytes.

Stress increases Alzheimer’s risk in female mice but not males

Stress causes the levels of Alzheimer's proteins to rise in females' brains but not males' brains, according to a new study in mice by researchers at Washington University School of Medicine in St. Louis. This difference may contribute to women's greater risk of developing Alzheimer's disease.
Photo Credit: Karolina Grabowska

Women are about twice as likely as men to be diagnosed with Alzheimer’s disease. Some of that is age; in the U.S., women outlive men by five to six years, and advanced age is the strongest risk factor for Alzheimer’s. But there’s more to it than that, so Alzheimer’s researchers continue to look for other reasons why women have an elevated risk of the deadly neurodegenerative disease.

Stress may be one such reason. A study by researchers at Washington University School of Medicine in St. Louis shows that the effect stress has on the brain differs by sex, at least in mice. In stressful situations, levels of the Alzheimer’s protein amyloid beta rises sharply in the brains of females but not males. In addition, the researchers identified a molecular pathway that is active in brain cells from female mice but not male mice, and showed that it accounts for the divergent responses to stress.

The findings, published May 2 in Brain, add to a growing collection of evidence that sex matters in health and disease. From cancer to heart disease to arthritis, scientists have found differences between males and females that could potentially affect how men and women respond to efforts to prevent or treat chronic diseases.

Researchers reveal scale of prevalence of a condition that can cause type 2 diabetes and high blood pressure

Scientists at the University of Birmingham are calling for changes to healthcare policy following research which has shown for the first time the scale of the impact of a condition associated with benign tumors that can lead to type 2 diabetes and high blood pressure.

Up to 10 per cent of adults have a benign tumor, or lump, known as an ‘adrenal incidentaloma’ in their adrenals – glands situated on top of the kidneys which produce a variety of hormones. The lumps can be associated with the overproduction of hormones including the stress steroid hormone cortisol, which can lead to type 2 diabetes and high blood pressure. Previous small studies suggested that one in three adrenal incidentalomas produce excess cortisol, a condition called Mild Autonomous Cortisol Secretion (MACS).

Now, an international research team led by the University of Birmingham in the UK has carried out the largest ever prospective study of over 1,305 patients with adrenal incidentalomas to assess their risk of high blood pressure and type 2 diabetes and their cortisol production, comparing patients with and without MACS. The study is also the first to undertake a detailed analysis of the steroid hormone production in patients by analyzing cortisol and related hormones by mass spectrometry in 24-hour urine samples they collected.

Their study findings, published today in journal Annals of Internal Medicine, show that MACS is much more prevalent than previously reported: with almost every second patient in the study with an adrenal incidentaloma having MACS. Notably, 70% of patients with MACS were women and most of them were of postmenopausal age (aged over 50). Following their findings, the researchers now estimate that up to 1.3 million adults in the UK could have MACS. Considering that around two out of three of these patients are women, MACS is potentially a key contributor to women’s metabolic health, in particular in women after the menopause.

Clinically relevant deficiency of the “bonding hormone” oxytocin demonstrated

The hormones oxytocin and vasopressin are produced in the same area of the brain and are also very similar in structure. This is why disorders that cause vasopressin deficiency could also affect the neurons that produce oxytocin
Image Credit: Colin Behrens

The hormone oxytocin is important for social interaction and to control emotions. A deficiency of this hormone has previously been assumed, for example, in people with autism, but has never been proven. Now, for the first time, researchers from the University of Basel and the University Hospital of Basel have succeeded in demonstrating a deficiency of oxytocin in patients with a deficiency of vasopressin caused by a disease of the pituitary gland. This finding could be key to developing new therapeutic approaches.

The hormones oxytocin and vasopressin are produced in the same area of the brain and are also very similar in structure. Patients with a rare deficiency of vasopressin cannot concentrate their urine and lose liters of water as a result. In order to compensate for this loss, they are obliged to drink up to 10 liters or more per day.

With a nasal spray or a tablet containing synthetically produced vasopressin, these symptoms can usually be treated without any problems. However, even with this treatment, many patients report anxiety, have trouble with social interactions or demonstrate impaired emotional awareness.

Brain cell discovery sparks hope for fertility treatments

Photo Credit: Yoshihisa Uenoyama, Graduate School of Bioagricultural Sciences, Nagoya University

Researchers at Nagoya University’s Graduate School of Bioagricultural Sciences and the National Institute of Physiological Sciences in Japan have demonstrated how a specific type of neuron in the brain affects the release of hormones that control ovarian function, such as follicular development and ovulation in females. These findings, published in the journal Scientific Reports, could help researchers understand and treat reproductive disorders in both animals and humans.  

Kisspeptin neurons in the brain regulate the release of hypothalamic gonadotropin-releasing hormone (GnRH) and pituitary follicle-stimulating hormone/luteinizing hormone (LH). This process is important for reproduction, as pituitary hormones stimulate the ovaries to perform their reproductive functions. Examples include follicular development and ovulation in all mammals, including humans.   

There are two main areas of the brain involved in the process: the arcuate nucleus (ARC), in which kisspeptin neurons maintain the regular rhythmic (pulsatile) secretion of GnRH/LH that maintains normal follicular development and sex steroid production; and the anteroventral periventricular nucleus (AVPV), in which kisspeptin neurons trigger a surge of GnRH/LH that leads to ovulation.  

New Research Suggests Why Males and Females Respond Differently to Social Stress

Emily Wright, researcher, in a UC Davis lab.
Photo Credit: Jerry Tsai

Women are nearly twice as likely as men to be diagnosed with an anxiety disorder, but among boys and girls the likelihood is the same. New University of California, Davis, research has identified changes in the brain during puberty that may account for differences in how women and men respond to stress.

A team of psychologists has found that testosterone is the key hormone that drives gender-based differences in responses to social stress. The study encompassed six separate experiments with mice to isolate what changes in the brain drive these differences between males and females. The study was published in the Proceedings of the National Academy of Sciences, or PNAS, today.

“This research shows how the body’s hormones shape the complex interplay between the brain’s circuitry and behavioral responses to stress,” said Brian Trainor, a professor of psychology in the College of Letters and Science at UC Davis and the study’s corresponding author.

Even small amounts of licorice raise blood pressure

Researchers have studied how licorice affects blood pressure, among other things.
Photo Credit: Marion Wellmann

It is known that large amounts of licorice cause high blood pressure. A study by researchers at Linköping University now shows that even small amounts of licorice raise blood pressure. The individuals who react most strongly also show signs of strain on the heart.

Licorice is produced from the root of plants of the Glycyrrhiza species and has long been used as an herbal remedy and flavoring. However, it is known that eating licorice can also raise blood pressure. This is mainly due to a substance called glycyrrhizic acid that affects the body’s fluid balance through effects on an enzyme in the kidney. High blood pressure, in turn, increases the risk of cardiovascular disease.

Both the European Union and the World Health Organization have concluded that 100 mg of glycyrrhizic acid per day is probably safe to eat for most individuals. But some people eat more licorice than that. The Swedish Food Agency has estimated that 5 per cent of Swedes have an intake higher than this level.

How plants respond to heat stress

Prof. Brigitte Poppenberger and her team have elucidated the
molecular signaling pathway for heat resistance in plants.
Image: A. Heddergott / TUM

Plants, like other organisms, can be severely affected by heat stress. To increase their chances of survival, they activate the heat shock response, a molecular pathway also employed by human and animal cells for stress protection. Researchers from the Technical University of Munich (TUM) have now discovered that plant steroid hormones can promote this response in plants.

It may be hard to remember in winter, but July 2021 was the hottest month ever documented. In the USA, the mean temperature was higher than the average for July by 2,6 degrees Fahrenheit, and many southern European countries saw temperatures above 45 degrees Celsius including an all-time high temperature of 48,8 degrees Celsius recorded on the eastern coast of Sicily in Italy.

The past few decades have seen increased incidences of heat waves with record highs around the globe, and this is seen as a result of climate change. Heat waves have been occurring more frequently, have been hotter, and have been lasting longer with severe consequences not only for humans and animals but also for plants. “Heat stress can negatively affect plants in their natural habitats and destabilize ecosystems while also drastically reducing crop harvests, thereby threatening our food security,” says Brigitte Poppenberger, Professor for Biotechnology of Horticultural Crops.

Water disinfection byproduct disrupts reproductive hormones, damages pituitary in female mice

A byproduct formed during water disinfection disrupts hormones
that regulate reproduction in female mice, found Illinois
professor Lori Raetzman (left) and graduate student Rachel Gonzalez. 
Photo by L. Brian Stauffer

Chemical disinfection makes water from both natural sources and wastewater streams drinkable; however, the process also creates byproducts, not all of which are understood or regulated. A new study from University of Illinois Urbana-Champaign researchers has found that one byproduct disrupts hormones in the brain that regulate the female reproductive cycle in mice and also damages cells in the pituitary gland.

Iodoacetic acid, or IAA, is created when an oxidizing disinfectant such as chlorine reacts with the iodide naturally present in water, said study leader Lori Raetzman, a professor of molecular and integrative physiology. The new study’s findings of IAA’s effects on reproductive regulation in the brain complement previous work by study co-author Jodi Flaws, a professor of comparative biosciences, which found that IAA also disrupts function in and causes damage to ovary cells, indicating that the chemical could impact the entire reproductive system.

“We know we need to disinfect water, but the water that’s coming out of our taps isn’t pure – regulators only screen for the things they know about. Water regulatory bodies have not been looking for IAA,” Raetzman said. “This study is contributing to the growing body of evidence that suggests that IAA may impact reproduction, so it might be reasonable to have screening for this too, and to establish a safe level for it.”

Researchers create lab model that could lead to new, non-hormonal birth control methods

Oregon Health & Science University researchers have developed a new lab model to study how changes in cervical mucus during the menstrual cycle help regulate fertility. This model could help develop new, non-hormonal birth control methods for women.
Photo Credit: OHSU/Christine Torres Hicks

Oregon Health & Science University researchers have developed a new lab model to study how changes in cervical mucus during the menstrual cycle help regulate fertility. This model could help develop new, non-hormonal birth control methods for women.

The study, published in the journal Biology of Reproduction, is part of ongoing work by senior author Leo Han, M.D., M.P.H., associate professor of obstetrics and gynecology in the OHSU School of Medicine and the OHSU Oregon National Primate Research Center. Han is a complex family planning specialist whose research focuses on developing new, non-hormonal contraceptives. 

In this study, his research team analyzed the genetic activity in lab-cultured cervical cells, identifying hundreds of different genes that could be drug targets for birth control that uses innovative new methods to block sperm. 

Evolution: Miniproteins appeared “from nowhere”

An evolutionarily young protein that arose de novo in Old World monkeys: The microprotein in the mitochondria (green) and in the nucleus (blue) was overexpressed in human cells. The yellow and pink areas show that the signal of the microprotein overlaps with the mitochondrial and nuclear signals.
Image Credit: © Clara-Louisa Sandmann, Max Delbrück Center

Evolutionarily young miniproteins are unique in humans, and researchers have recently discovered thousands of them. Writing in Molecular Cell, Norbert Hübner and colleagues from the BIH and other institutions describe the origins of these tiny proteins and explain that they probably influence important cellular processes.

Every biologist knows that small structures can sometimes have a big impact: Millions of signaling molecules, hormones, and other biomolecules are bustling around in our cells and tissues, playing a leading role in many of the key processes occurring in our bodies. Yet despite this knowledge, biologists and physicians long ignored a particular class of proteins – their assumption being that because the proteins were so small and only found in primates, they were insignificant and functionless. The discoveries made by Professor Norbert Hübner at the Max Delbrück Center and Dr. Sebastiaan van Heesch at the Princess Máxima Center for Pediatric Oncology in the Netherlands changed this view a few years ago: “We were the first to prove the existence of thousands of new microproteins in human organs,” says Hübner. 

Why women with multiple sclerosis get better when pregnant

Women suffering from the autoimmune disease multiple sclerosis temporarily get much better when pregnant.
Photo Credit: Neal E. Johnson

Women suffering from the autoimmune disease multiple sclerosis temporarily get much better when pregnant. Researchers have now identified the beneficial changes naturally occurring in the immune system during pregnancy. The findings can show the way to new treatments.

Pregnancy is a very special condition from an immunological point of view. The immune system serves to defend us against foreign substances. However, although half of the genetic material of the fetus comes from the father, it is not rejected by the mother’s immune system. One reason why this balancing act is almost always successful is that during pregnancy the mother’s immune system is adapted to become more tolerant.

In multiple sclerosis, MS, nerve function is hampered due to the immune system attacking the fat that serves as an insulating sheath around the nerve fibers. The nerves become inflamed, which could lead to nerve damage. Although new and more effective treatment options are available, most MS patients deteriorate over time.

Researchers believe that the temporary dampening of the immune response could explain why women with MS actually get better when pregnant. Periods of symptoms, i.e. relapses, decrease by 70 percent during the last third of pregnancy. Also, some other autoimmune diseases, such as rheumatoid arthritis, temporarily ameliorate during pregnancy. But the reason for this has not been clear. This is why the researchers behind this study wanted to investigate what mechanisms that could be of particular importance for the decrease in symptoms during pregnancy, as a step to finding future treatment strategies that give the same effect in MS and possibly also other similar diseases.

Resistance to Stress and Anxiety Can Be Trained Like a Muscle

According to Rustam Muslumov, anxiety and stress are emotions aimed at assessing the future.
Photo credit: Anna Marinovich

Humans, unlike the animal world, are oriented toward finding problems. The human being is constantly looking at his environment and discovering imperfections that make him think about what could be changed and improved. This is how the emotions of anxiety and stress emerge. Without moderate stress it is impossible for a person to develop, yet the constant presence in these situations has a negative impact on his mental and physical health. That is why it is necessary to cultivate resilience - the ability not to increase anxiety, but to cope with it correctly and in time.

Stress, like any other emotion, is important for humans. It helps to solve non-standard problems aimed at protecting oneself in the face of change and instability. The nature of anxiety, on the other hand, is such that one looks to the future with two ideas in mind: something bad might happen, and I cannot cope with it and keep myself safe if it does. Being constantly anxious can lead a person to a state of distress. Rustam Muslumov, Associate Professor of the Department of Pedagogy and Psychology of Education at Ural Federal University, spoke about this on the Komsomolskaya Pravda broadcast.