Vitamins >> Vitamin A Functions

Vision
The retina is located at the back of the eye. When light passes through the lens, it is sensed by the retina and converted to a nerve impulse for interpretation by the brain. Retinol is transported to the retina via the circulation, where it moves into retinal pigment epithelial cells (diagram). There, retinol is esterified to form a retinyl ester, which can be stored. When needed, retinyl esters are broken apart (hydrolyzed) and isomerized to form 11-cis retinol, which can be oxidized to form 11-cis retinal. 11-cis Retinal can be shuttled across the interphotoreceptor matrix to the rod cell, where it binds to a protein called opsin to form the visual pigment, rhodopsin (visual purple). Rod cells with rhodopsin can detect very small amounts of light, making them important for night vision. Absorption of a photon of light catalyzes the isomerization of 11-cis retinal to all-trans retinal and results in its release. This isomerization triggers a cascade of events, leading to the generation of an electrical signal to the optic nerve. The nerve impulse generated by the optic nerve is conveyed to the brain where it can be interpreted as vision. Once released all-trans retinal is converted to all-trans retinol, which can be transported across the interphotoreceptor matrix to the retinal epithelial cell to complete the visual cycle (2). Inadequate retinol available to the retina results in impaired dark adaptation, known as "night blindness."

Regulation of gene expression

Retinoic acid (RA) and its isomers act as hormones to affect gene expression and thereby influence numerous physiological processes. All-trans RA and 9-cis RA are transported to the nucleus of the cell bound to cytoplasmic retinoic acid-binding proteins (CRABP). Within the nucleus, RA binds to retinoic acid receptor proteins (diagram). All-trans RA binds to retinoic acid receptors (RAR) and 9-cis RA binds to retinoid receptors (RXR). RAR and RXR form RAR/RXR heterodimers, which bind to regulatory regions of the chromosome called retinoic acid response elements (RARE). A dimer is a complex of two protein molecules. Heterodimers are complexes of two different proteins, while homodimers are complexes of two of the same protein. Binding of all-trans RA and 9-cis RA to RAR and RXR respectively allows the complex to regulate the rate of gene transcription, thereby influencing the synthesis of certain proteins used throughout the body. RXR may also form heterodimers with thyroid hormone receptors (THR) or vitamin D receptors (VDR). In this way, vitamin A, thyroid hormone, and vitamin D may interact to influence gene transcription (3). Through the stimulation and inhibition of transcription of specific genes, retinoic acid plays a major role in cellular differentiation, the specialization of cells for highly specific physiological roles. Most of the physiological effects attributed to vitamin A appear to result from its role in cellular differentiation.

Immunity
Vitamin A is commonly known as the anti-infective vitamin, because it is required for normal functioning of the immune system (4). The skin and mucosal cells (cells that line the airways, digestive tract, and urinary tract) function as a barrier and form the body's first line of defense against infection. Retinol and its metabolites are required to maintain the integrity and function of these cells (5). Vitamin A and retinoic acid (RA) play a central role in the development and differentiation of white blood cells, such as lymphocytes that play critical roles in the immune response. Activation of T-lymphocytes, the major regulatory cells of the immune system, appears to require all-trans RA binding of RAR (3).

Growth and Development
Both vitamin A excess and deficiency are known to cause birth defects. Retinol and retinoic acid (RA) are essential for embryonic development (4). During fetal development, RA functions in limb development and formation of the heart, eyes, and ears (6). Additionally, RA has been found to regulate expression of the gene for growth hormone.

Red blood cell production
Red blood cells, like all blood cells, are derived from precursor cells called stem cells. These stem cells are dependent on retinoids for normal differentiation into red blood cells. Additionally, vitamin A appears to facilitate the mobilization of iron from storage sites to the developing red blood cell for incorporation into hemoglobin, the oxygen carrier in red blood cells (2, 7).

Nutrient Interactions
Zinc and vitamin A: Zinc deficiency is thought to interfere with vitamin A metabolism in several ways: 1) Zinc deficiency results in decreased synthesis of retinol binding protein (RBP), which transports retinol through the circulation to tissues (e.g., the retina). 2) Zinc deficiency results in decreased activity of the enzyme that releases retinol from its storage form, retinyl palmitate, in the liver. 3) Zinc is required for the enzyme that converts retinol into retinal (8, 9). At present, the health consequences of zinc deficiency on vitamin A nutritional status in humans are unclear (10).

Iron and vitamin A: Vitamin A deficiency may exacerbate iron deficiency anemia. Vitamin A supplementation has been shown to have beneficial effects on iron deficiency anemia and improve iron nutritional status among children and pregnant women. The combination of vitamin A and iron seems to reduce anemia more effectively than either iron or vitamin A alone