e.hormone | Endocrine System : Types of Hormones

Learning Endocrine Disrupting Chemicals The Hormones Androgens Corticoids Estrogens Progestins Thyroid Actions Docking: Receptor Binding Delivery: Transport Proteins Disposal: Metabolic Changes Dynamics: Interactions Wildlife Effects Human Effects Sources Phytoestrogens Gathering Evidence What Does ED Mean? Endocrine System Hormone Glands Target Cells Types of Hormones Feedback Loops Glossary Endocrine System : Types of Hormones Signaling Near and Far Chemical Structures Water vs Fat Solulable Hormones are molecules that carry instructions from more than a dozen endocrine glands and tissues to cells all over the body. Humans have about 50 different known hormones, which vary in their structure, action and response. They control a variety of biological processes including muscle growth, heart rate, menstrual cycles and hunger. Hormones travel throughout the body, either in the blood stream or in the fluid around cells, looking for target cells. Once hormones find a target cell, they bind with specific protein receptors inside or on the surface of the cell and specifically change the cell's activities. The protein receptor reads the hormone's message and carries out the instructions by either influencing gene expression or altering cellular protein activity. These actions produce a variety of rapid responses and long-term effects. Hormones vary in their range of targets. Some types of hormones can bind with compatible receptors found in many different cells all over the body. Other hormones are more specific, targeting only one or a few tissues. For example, estrogens, the female sex hormones, can regulate function by binding to special estrogen receptor sites in uterine, breast and bone cells. In addition, the same cell can act as a target cell for many different regulatory molecules. For instance, the same uterine, breast and bone cells that accept estrogens, also contain progesterone, androgen, glucocorticoid, vitamin D and vitamin A receptors. Signaling Near and FarHormones are classified (separated into groups) according to how they travel in the body and their chemical structure. Endocrine and neurosecretory signals: The long-distance travelers     CAPTION: As shown above, hormones released into the bloodstream from endocrine gland cells and special cells in the hypothalamus (neurosecretory cells) travel throughout the body looking for target cells. These hormones are similar to a television signal in that they are broadcast everywhere but can only be picked up and read by a cell with the right hormone receptor or antenna. CREDIT: Tulane/Xavier Center for Bioenvironmental Research Paracrine, autocrine and synaptic signals: The local targeters     Paracrine, autocrine and synaptic are three types of local hormone signaling. In paracrine signaling, hormones are released into the fluid between cells (the interstitial fluid) and diffuse to nearby target cells. Hormones that influence secretions or other processes on the same cells that released them are said to be autocrine signalers. The more specialized synaptic signaling occurs between neurons (the nerve cells that make up the nervous system) and between neurons and muscle cells, allowing nerve cells to talk to each other and to muscles. back to topChemical Structures Hormones are also grouped according to chemical structure. Structures dictate if the hormone prefers to be surrounded by water or fat (water or fat soluble), which determines: if the hormone travels in the blood alone or attached to a protein if the hormone will bind to receptor sites outside or inside of the target cell (fat soluble can bind both whereas water soluble hormones usually bind on the outside) and how the hormone is broken down (metabolized). Three general structures are known. Steroid hormones are fat-soluble molecules made from cholesterol. Among these are the three major sex hormones groups: estrogens, androgens and progesterones. Males and females make all three, just in different amounts. Steroids pass into a cell's nucleus, bind to specific receptors and genes and trigger the cell to make proteins. Amino acid derivatives, such as epinephrine, are water-soluble molecules derived from amino acids (the building blocks of protein). These hormones are stored in endocrine cells until needed. They act by binding to protein receptors on the outside surface of the cell. The binding alerts a second messenger molecule inside the cell that activates enzymes and other cellular proteins or influences gene expression. Insulin, growth hormone, prolactin and other water-soluble polypeptide hormones consist of long chains of amino acids, from several to 200 amino acids long. They are stored in endocrine cells until needed to regulate such processes as metabolism, lactation, growth and reproduction. back to topWater vs. Fat Soluble Most water-soluble hormones, like the amino acid derivatives and peptides, can travel freely in the blood because they "like" water. However, they are repelled by lipid or fatty structures such as the membranes that surround the cell and nucleus. Because of this, these hormones generally bind to receptor sites on the outside of the cell and signal from there. Fat-soluble hormones, like the sex hormone steroids estrogens and androgens, are fat soluble and water repellent. That is, they "like" lipid or fatty structures such as those surrounding cells but are generally repelled by watery areas. Steroids generally travel to their target cells attached to a special carrier protein that "likes" water (such as, sex steroid hormone binding globulin and serum albumin). The hormones detach before passing into the cell where they bind to receptors. To get a better picture of this, think of oil and water. The two don't mix and separate into distinct layers. In this case, the amino acid derived and peptide hormones would prefer to be in the water layer, and the steroid hormones would prefer to be in the oil layer. Special carrier proteins that are comfortable in both oil and water can escort the peptide and amino acid derived molecules into the oil, and the steroid molecules into the water. back to top copyright © 2014 Tulane University