Photoaffinity labeling of the human red-blood-cell urea-transporter polypeptide components. Possible homology with the Kidd blood group antigen.

The tritiated urea analogue 1-(3-azido-4-chlorophenyl)-3methyl-2-thiourea ([3H]MeACPTU) was used as a probe to photolabel the human red-blood-cell membrane facilitated urea transporter. On irradiation, [3H]MeACPTU incorporated irreversibly into white ghost membranes. SDS/gel electrophoresis of membranes revealed radioactive incorporation in five major bands of 200, 110, 60, 40 and 14 kDa. The labeling of the 40-kDa and 60-kDa bands was partly prevented by the presence of a high concentration of other urea analogues such as thiourea and 1-(3,4-dichlorophenyl) 2-thiourea (DCPTU). The photolabeling pattern obtained with white ghosts of the Kidd blood-group type Jk(a-,b-) showed no labeling of the 40-kDa polypeptide. Protecting experiments carried out with anti-Jka, anti-Jkb and anti-Jk3 sera prevented radioactive incorporation in the 60-kDa band and in the 110-kDa band. Urea permeability of pink ghosts of blood type Jk(a+,b+) measured in the presence of Jk3 antibodies was 19% lower than the control values. However, urea permeability of frog urinary bladder epithelial cells was not affected by the presence of Jk-reactive antibodies. These results support the hypothesis that the Kidd antigen and the facilitated urea transporter are the same protein. Our estimation of the number of copies in each cell is close to that of the previously published value of 14000.

Urea derivatives as tools for studying the urea-facilitated transport system.

The effects of urea structural analogues on the urea-facilitated diffusion system were examined in human red cell membranes (pink ghosts) and in antidiuretic hormone(ADH)-stimulated frog urinary bladder epithelia. In both tissues, urea permeability (P(urea)) was dramatically but reversibly inhibited by a number of urea analogues, such as 1-(3,4-dichlorophenyl)-2-thiourea (DCPTU). This urea derivative reduced the urea flux in a dose-dependent manner (90% inhibition of P(urea) at 0.5 mM concentration of DCPTU). With the aim of obtaining irreversible markers of red cell and urinary bladder urea transport systems, urea derivatives were modified by addition of an azido residue (N3) and preliminary experiments of photoaffinity labelling were carried out. Two synthetic urea derivatives: 1-(3-azido-4-chlorophenyl)-2-thiourea (ACPTU) and 1-(3-azido-4-chlorophenyl)-3-methyl-2-thiourea (Me-ACPTU) were shown to be very potent inhibitors of P(urea) when used in the absence of light, with IC50 values 60.3 microM and 31.6 microM respectively, as measured in frog urinary bladder. Both these molecules appeared to bind covalently to the urea carrier in both frog urinary bladder and human pink red cell ghosts, when illuminated in the presence of the tissue: the urea flux, which fell to 30-70% of the value obtained in the presence of ADH after inhibitor addition, remained low after the preparation had been illuminated for 30 min and the inhibitor removed. These results provide an interesting approach to the urea carrier analysis, particularly to the urea or urea analogue binding site on the transport protein.