Determinants of the pH of the Golgi complex.

The factors contributing to the establishment of the steady state Golgi pH (pH(G)) were studied in intact and permeabilized mammalian cells by fluorescence ratio imaging. Retrograde transport of the nontoxic B subunit of verotoxin 1 was used to deliver pH-sensitive probes to the Golgi complex. To evaluate whether counter-ion permeability limited the activity of the electrogenic V-ATPase, we determined the concentration of K(+) in the lumen of the Golgi using a null point titration method. The [K(+)] inside the Golgi was found to be close to that of the cytosol, and increasing its permeability had no effect on pH(G). Moreover, the capacity of the endogenous counter-ion permeability exceeded the rate of H(+) pumping, implying that the potential across the Golgi membrane is negligible and has little influence on pH(G). The V-ATPase does not reach thermodynamic equilibrium nor does it seem to be allosterically inactivated at the steady state pH(G). In fact, active H(+) pumping was detectable even below the resting pH(G). A steady state pH was attained when the rate of pumping was matched by the passive backflux of H(+) (equivalents) or "leak." The nature of this leak pathway was investigated in detail. Neither vesicular traffic nor H(+)/cation antiporters or symporters were found to contribute to the net loss of H(+) from the Golgi. Instead, the leak was sensitive to voltage changes and was inhibited by Zn(2+), resembling the H(+) conductive pathway of the plasma membrane. We conclude that a balance between an endogenous leak, which includes a conductive component, and the H(+) pump determines the pH at which the Golgi lumen attains a steady state.

pH-independent retrograde targeting of glycolipids to the Golgi complex.

A small fraction of the molecules internalized by endocytosis reaches the Golgi complex through a retrograde pathway that is poorly understood. In the present work, we used bacterial toxins to study the retrograde pathway in Vero cells. The recombinant B subunit of verotoxin 1B (VT1B) was labeled with fluorescein to monitor its progress within the cell by confocal microscopy. This toxin, which binds specifically to the glycolipid globotriaosyl ceramide, entered endosomes by both clathrin-dependent and -independent pathways, reaching the Golgi complex. Once internalized, the toxin-receptor complex did not recycle back to the plasma membrane. The kinetics of internalization and the subcellular distribution of VT1B were virtually identical to those of another glycolipid-binding toxin, the B subunit of cholera toxin (CTB). Retrograde transport of VT1B and CTB was unaffected by addition of weak bases in combination with concanamycin, a vacuolar-type ATPase inhibitor. Ratio imaging confirmed that these agents neutralized the luminal pH of the compartments where the toxin was located. Therefore, the retrograde transport of glycolipids differs from that of proteins like furin and TGN38, which require an acidic luminal pH. Additional experiments indicated that the glycolipid receptors of VT1B and CTB are internalized independently and not as part of lipid "rafts" and that internalization is cytochalasin insensitive. We conclude that glycolipids utilize a unique, pH-independent retrograde pathway to reach compartments of the secretory system and that assembly of F-actin is not required for this process.