Reproductive functioning, alcohol

Compounds Affecting Rq>roduction Compounds that can affect reproductive function include several drugs and occupationally important chemicals such as solvents and pesticides as well as a number of environmentally relevant com-fxrunds. A group of chemical compounds that has received much attention recently is endocrine disrupters, many of which are halogenated hydrocarbons, e.g., PCBs. These are known to induce feminization in fish and other animal species.1.5/ There is intense debate about the significance of these compounds to human health. Tobacco smoke and ethyl alcohol also have major effects on human reproduction, the effects of alcohol being especially important. Table 5.17 lists compounds that may disturb the functions of female and male reproductive functions. 

Retinoic acid (vitamin A acid), in which the alcohol group has been oxidized, shares some but not all of the actions of retinol. Retinoic acid is ineffective in restoring visual or reproductive function in certain species in which retinol is effective. Flowever, retinoic acid is very potent in promoting growth and controlling differentiation and maintenance of epithelial tissue in vitamin A-deficient animals. Indeed, all-trans-retinoic acid (tretinoin) appears to be the active form of vitamin A in all tissues except the retina, and is 10- to 100-fold more potent than retinol in various systems in vitro. Isomerization of this compound in the body yields 13-n.v-rctinoic acid (isotretinoin), which is nearly as potent as tretinoin in many of its actions on epithelial tissues but may be as much as fivefold less potent in producing the toxic symptoms of hypervitaminosis A. 

Psychological Effects Alcohol and Behavior Effects of Chronic Heavy Drinking Alcohol and Brain Functioning Alcohol and the Liver Alcohol and Reproductive Functioning Fetal Alcohol Syndrome Moderate Drinking and Health The Development of Alcohol Abuse and Dependence Traditional Approaches to Etiology "Biopsychosocial" Approaches to Etiology Summary... 

As with most alcohol effects, we know less about the chronic effects of alcohol on reproductive functioning in women. The little scientific information available suggests alcohol dependence in women is associated with dysfunction of the ovaries, disruption of the luteal pha.se of fertilization, and amenorrhea (cessation of the menstrual period) (Brands et al., 1998 Mello, 1987 Noicn-Hoeksema, 2004 USDHHS, 1990). A household survey suggests that a woman does not have to be diagnosed as having alcohol dependence to experience impaired sexual function related to alcohol use. A survey of more than 900 women living in households showed a positive correlation between alcohol consumption and the occurrence of dif ferent menstrual disorders (Wilsnack, Klasscn, Wilsnack, 1984). 

Vitamin A, as retinal, has a clearly established role in vision (Chapter 23) and apparently has a specialized function in reproduction. In vitamin A deficiency no sperm cells are formed in males, and fetal resorption occurs in females. Rats deprived of vitamin Abut fed retinoic acid become blind and sterile but otherwise appear healthy.e bb Evidently either the alcohol or the aldehyde has an essential function in reproduction, whereas bone growth and maintenance of mucous secretions requires only retinoic acid. Indeed, retinoic acid is 100 to 1000 times more active than other forms of vitamin A in these differentiation functions.1 ... 

The external cuticle of insects is covered by a waxy layer composed of mixtures of hydro-phobic lipids that include long-chain alkanes, alkenes, wax esters, fatty acids, alcohols, aldehydes, and sterols. The primary purpose of this layer is to maintain water balance and prevent desiccation, as described in Chapter 6, but many of the cuticular lipid components have important secondary roles as intraspecific contact chemical signals (pheromones). These roles include species and sex recognition during reproductive interactions, and nestmate recognition and other colony organization functions in social insects. Thus, these compounds are essential mediators of insect behaviors. Cuticular compounds are also exploited by parasitoids and predators as interspecific contact cues (kairomones) to aid in host location. 

The specificity of blends of compounds used for pheromone communication by Lepidoptera species is the result of essentially two distinct sets of biosynthetic enzymes which regulate the production of specific olefinic bonds and synthesis of the oxygenated functional moiety, respectively. In Heliothis moths the regulatory systems that are responsible for production of the functional group during the final stages of pheromone biosynthesis consist of cellular acetate esterases and extracellular alcohol oxidases. Evidence indicates that the relative activities of these enzymes differ for each species of Heliothis. Thus, pheromone mediated reproductive isolation between closely related species of Heliothis is probably the result, in large measure, of the fact that some species require only aldehydes for communication while others use acetates, alcohols and aldehydes. 

Vitamin A is the isoprenoid alcohol retinol, which is required for a number of body processes including vision, growth, maintenance of mucous membranes, reproduction and proper growth of the cartilage matrix upon which bone is deposited. Of these, the molecular basis of its role in the visual cycle is best understood. In addition to the alcohol retinol, both retinal and retinoic acid (Fig. 2.4) also act to restore some of the deficiency symptoms. In rod vision, retinol is oxidised to retinal. 11-ds-Retinal combines with the protein opsin to form rhodopsin. After the absorption of a photon, rhodopsin undergoes a series of changes, eventually dissociating to opsin and all-fraMS-retinal. This last compound is converted back to 11-ds-retinal by retinal isomerase (EC.5.2.1.3) Retinoic acid is able to replace retinol in all functions except the visual cycle and reproduction. 

Vitamin A is a fat-soluble micronutrient that is required by all vertebrates to maintain vision, epithelial tissues, immvme functions, reproduction, and for life itself. It was discovered in 1913 as a minor component in eggs, butter, whole milk, and fish liver oils. It soon became apparent that vitamin A exists in two chemically distinct yet structurally related forms. The first form to be characterized was retinol, a lipid alcohol that is present only in foods of animal origin. Retinol is also known as preformed vitamin A because it can be metabolized directly into compovmds that exert the biological effects of vitamin A. A second form of vitamin A, present in deep-yellow vegetables, was characterized as /3-carotene, which is synthesized only by plants but can be converted to retinol during absorption in the small intestines. These carotenoids are sometimes referred to as provitamin A. The nutritional requirement for vitamin A can be met by preformed retinol, provitamin A carotenoids, or a mixture, and therefore it is possible to obtain a sufficient intake of vitamin A from carnivorous, herbivorous, or omnivorous diets. 

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