Position 170 of Rabbit Na+/glucose cotransporter (rSGLT1) lies in the Na+ pathway; modulation of polarity/charge at this site regulates charge transfer and carrier turnover.

Positions 163, 166, and 173, within the putative external loop joining transmembrane segments IV and V of rabbit Na(+)/glucose cotransporter, form part of its Na(+) interaction and voltage-sensing domain. Since a Q170C mutation within this region exhibits anomalous behavior, its function was further investigated. We used Xenopus oocytes coinjected with mouse T-antigen to enhance Q170C expression, and the two-microelectrode voltage-clamp technique. For Q170C, alpha-methyl D-glucopyranoside, phloridzin, and Na(+) affinity values are equivalent to those of wild-type; but turnover is reduced approximately 50%. Decreased [Na(+)] reduces Q170C, but not wild-type, charge transfer. Q170C presteady-state currents exhibit three time constants, tau, identical to wild-type. MTSES decreases maximal alpha-methyl D-glucopyranoside-induced currents by approximately 64% and Na(+) leak by approximately 55%; phloridzin and Na(+) affinity are unchanged. MTSES also reduces charge transfer (dithiothreitol-reversible) and Q170C turnover by approximately 60-70%. MTSEA and MTSET protect against MTSES, but neither affect Q170C function. MTSES has no obvious effect on the tau-values. Q170A behaves the same as Q170C. The mutation Q170E affects voltage sensitivity and reduces turnover, but also appears to influence Na(+) interaction. We conclude that 1), glutamine 170 lies in the Na(+) pathway in rabbit Na(+)/glucose cotransporter and 2), altered polarity and charge at position 170 affect a cotransporter conformational state and transition, which is rate-limiting, but probably not associated with empty carrier reorientation.