Alcohol intake is known to affect various organs in the human body, causing reduction of salivation in the oral cavity. Hypo-salivation effect of alcohol is a common feature, but the mechanism in salivary glands is still poorly studied. Therefore, in this study, the changes in salivary secretion and water channel protein (aquaporin5, AQP5) in salivary glands of mice were investigated after ethanol administration. Animals were divided in to 4 groups with the control, 4 g/kg ethanol, 8 g/kg ethanol and 16 g/kg ethanol administration groups. One hour after ethanol administration, saliva was collected from the oral cavity, and the animals were killed and parotid and submandibular glands were extracted to analyze the histopathology, AQP5 immunihistochemistry and AQP5 protein level. According to the results, the salivation rate decreased irrespective of the ethanol dose in mice, and viscosities increased with increase in ethanol dose. However, there were no pathological changes in parotid and submandibular glands due to ethanol administration. Expression of AQP5 in parotid and submandibular glands decreased with increase ethanol administration These results indicate that the reduction of salivary secretion due to acute alcohol intake is closely related to decrease of the water channel protein such as AQP5 in parotid glands and submandibular glands, rather than the damage of salivary glands.

Toxic heavy metals like mercury and cadmium are known to involve in altering the salivary flow so that can be appeared sialorrhea or ptyalism, the condition of increased salivary flow, or xerostomia (“dry mouth”), the condition related to inhibited or decreased salivary flow. Although many people were exposed to these heavy metal in work environment, dental clinics, the mechanism is rarely discussed in the clinical literature. The present study is to carried out analysis of AQP5 expression that play a key role in saliva fluid secretion and cell membrane water permeability on mercury- or cadmium-exposed mice submandibular gland. To investigate AQP 5 expression, immunohistochemical study and western blot assay were carried out on mercury- or cadmium-exposed mice. Additionally, RT-PCR, real- time PCR with specific primers were carried out. Cadmium or mercury exposure led ductal extension, ductal cell increase, and blood vessel increase in mouse submandibular gland. The mRNA and protein expression of AQP5 were increased in time dependent manners on cadmium or mercury exposed mouse. Also, AQP5 were translocated from basolateral membrane to apical membrane of acini cell. In conclusion, toxic heavy metal such as mercury and cadmium appear to alter the AQP5 expression and distribute to apical membrane of ductal cell and lead to alter salivary secretion.

Aquaporin 5 (AQP5) implicated in the generation of saliva, tears, and pulmonary secretions functions as a water-specific channel. Epididymal epithelial cells actively reabsorb water, ions and proteins. Large quantity of testicular fluid movement across the epididymal tubules generates high osmotic milieu which is important for sperm maturation. In an effort to understand the fluid homeostasis and its regulation by sex steroids in male reproductive tract, the expression of AQP5 was examined in different regions of mouse epididymis during postnatal development. The effect of androgen on the expression of epididymal AQP5 was examined in ORX model. AQP5 mRNA levels were the highest in corpus region in which drastic increase was noted during sexual maturation. Epididymal AQP5 immunoreactivity was largely found in apical as well as basal region of luminal epithelia. Moderate immunoreactivity for AQP5 was found in in smooth muscle cells in both immature and mature mice. Epididymal lumen of ORX mice showed shrinkage together with decrease in AQP5 expression. Alteration of AQP5 expression in ORX epididymis was partially recovered by androgen injection. AQP5 mRNA was induced at 10uM 5α-DHT in organ cultured epididymis. Chromatin immunoprecipitatin (ChIP) showed that 5α-DHT induced recruitment of androgen receptor (AR) to the －4635 to －4453 bp region of the AQP5 gene promoter in adult epididymis. Taken together, axial regulatory mechanism may control transcription of AQP5 along the length of epididymal tubule. Water transport through AQP5 is important for late sperm maturation and storage in epididymis. Androgen may directly induce AQP5 gene transcription via activation of AR in epididymis.