Human histamine N-methyltransferase pharmacogenetics: gene resequencing, promoter characterization, and functional studies of a common 5'-flanking region single nucleotide polymorphism (SNP).

Histamine N-methyltransferase (HNMT) catalyzes one of two major metabolic pathways for histamine. The levels of HNMT activity and immunoreactive protein in human tissues are regulated primarily by inheritance. Previous studies of HNMT identified two common single nucleotide polymorphisms (SNPs), including a functionally significant nonsynonymous coding SNP (cSNP), (C314T, Thr105Ile), but that polymorphism did not explain all of the phenotypic variation. In the present study, a genotype-to-phenotype strategy was used to search for additional genetic factors that might contribute to the regulation of human HNMT activity. Specifically, we began by resequencing the human HNMT gene using 90 ethnically anonymous DNA samples from the Coriell Cell Repository and identified a total of eight SNPs, including the two that had been reported previously. No new nonsynonymous cSNPs were observed, but three of the six novel SNPs were located in the 5'-flanking region (5'-FR) of the gene-including a third common polymorphism with a frequency of 0.367 (36.7%). That observation directed our attention to possible genetic effects on HNMT transcription. As a first step in testing that possibility, we created and studied a series of reporter gene constructs for the initial 1kb of the HNMT 5'-FR. The core promoter and possible regulatory regions were identified and verified by electrophoresis mobility shift assays. We then studied the possible functional implications of the new common HNMT 5'-FR SNP. However, on the basis of reporter gene studies, that SNP appeared to have little effect on transcription. Phenotype-genotype correlation analysis performed with 112 human kidney biopsy samples that had been phenotyped for their level of HNMT activity confirmed that the common 5'-FR SNP was not associated with the level of HNMT activity in vivo. In summary, this series of experiments resulted in the identification of several novel HNMT polymorphisms, identification of the HNMT core promoter, and a comprehensive functional genomic study of a common HNMT 5'-FR SNP. These results represent an additional step in the definition of molecular genetic mechanisms involved in the regulation of this important autacoid-metabolizing enzyme in humans.

The role of HMT (histamine N-methyltransferase) in airways: a review.

Histamine N-methyltransferase (HMT) expressed in the epithelial and endothelial cells of the airways is a principal enzyme degrading histamine in the body. This brief review summarizes the recent advances in molecular biology related to the pathophysiological role of HMT in regulating airway functions.

HMT regulates histamine-induced Cl- secretion across the canine tracheal epithelium.

Although histamine N-methyltransferase (HMT), the primary enzyme responsible for the inactivation of histamine, has been shown to exist in the airway epithelium, it is still unknown whether this enzyme regulates ion transport across the airway epithelium. Using an Ussing chamber, we examined the effect of a HMT inhibitor, SKF 91488, on potential difference (PD) and short circuit current (SCC) in epithelial membranes from the posterior portion of canine trachea. SKF 91488 itself did not significantly alter PD or SCC values. Pretreatment with SKF 91488 significantly augmented PD and SCC induced by histamine. Amiloride did not significantly alter the augmentation by SKF 91488 in histamine-induced PD and SCC rises. These findings indicate that HMT regulates Cl- secretion across airway epithelium.

Histamine N-methyltransferase controls the contractile response of guinea pig trachea to histamine.

The contractile response of isolated guinea pig trachea to histamine was potentiated in the presence of the histamine N-methyltransferase (HMT) inhibitor SKF 91488, whereas the diamine oxidase inhibitor aminoguanidine was without effect. SKF 91488 shifted in a concentration-dependent fashion the concentration-response curves to histamine to lower concentrations with the maximum by 1 log unit. The trachea contained significant HMT activity (45.4 +/- 5.0 pmol/min/mg protein). In situ hybridization to detect HMT mRNA indicated that HMT mRNA was present in the epithelium and endothelium, being more abundant in the former. Removal of the epithelium shifted the concentration-response curves to histamine to lower concentrations by 0.8 log unit, and SKF 91488 caused only a slight shift of histamine concentration-response curves in tissues denuded of epithelium. These findings suggest that HMT regulates the contractile response of guinea pig trachea to histamine, and epithelial removal-induced bronchial hyperresponsiveness to histamine is largely explained by the loss of HMT in the epithelium.