Properties of 3-hydroxypropionaldehyde 3-phosphate.

Several modifications to the synthesis of the diethyl acetal of 3-hydroxypropionaldehyde-3-P (HPAP) are described. HPAP is liberated from its acetal by treatment with Dowex 50-H⁺ at 40 °C for 4 min, and longer time or higher temperature lower yields. Breakdown of the dianion of HPAP (pK 6.7) is self-catalyzed, with the phosphate acting as a general base to remove a proton from carbon 2 and allow elimination of phosphate to give acrolein. Monoanion breakdown is at least 400-fold slower. At 25 °C the dianion breaks down with k = 0.025 min^?1, and the activation energy for the process is 24 kcal/mol. Buffers have little effect on breakdown of HPAP, except for those containing primary or secondary amines. Thus morpholine enhances breakdown by forming a Schiff's base with a positively charged nitrogen, and Tris inhibits breakdown by forming one with an uncharged nitrogen. The aldehyde group of HPAP is 60% hydrated in water.     

Molecular mechanisms of band 3 inhibitors. 3. Translocation inhibitors

During the translocation of the band 3 transport site between the inward- and outward-facing orientations, the Cl- transport site complex passes through a transition state lying on the reaction pathway between the two extreme orientations. Niflumic acid, 2-[(7-nitrobenzofurazan-4-yl)amino]ethanesulfonate, and 2,4,6-trichlorobenzenesulfonate each are translocation blockers that can bind to both the inward- and outward-facing conformations of band 3. The principal mechanism of these inhibitors is a reduction in the translocation rate, since they have essentially no effect on the apparent KD for Cl- binding to the transport site and the migration of Cl- between the transport site and solution. Instead, these inhibitors raise the free energy of formation of the transition state during translocation and thereby can lock the transport site into either the inward- or outward-facing orientation. In contrast, 2,4-dinitrofluorobenzene (DNFB) appears to restrict the accessibility of the transport site to solution Cl-; also, the DNFB reaction rate is increased by Cl-, suggesting that DNFB modification may occur during translocation. Thus DNFB is proposed to trap the Cl--transport site complex site during translocation to yield a conformation intermediate to the inward- and outward-facing orientations. A model is presented for the molecular mechanism of transport across biological membranes. The transport machinery is proposed to contain greater than or equal to 6 transmembrane helices that surround a central channel containing a sliding hydrophobic barrier. The transport site lies between two of the channel-forming helices and remains stationary while the hydrophobic barrier slides from one end of the channel to the other, thereby exposing the transport site to the opposite solution compartment.