PACS-1 defines a novel gene family of cytosolic sorting proteins required for trans-Golgi network localization.

We report the role of one member of a novel gene family, PACS-1, in the localization of trans-Golgi network (TGN) membrane proteins. PACS-1 directs the TGN localization of furin by binding to the protease's phosphorylated cytosolic domain. Antisense studies show TGN localization of furin and mannose-6-phosphate receptor, but not TGN46, is strictly dependent on PACS-1. Analyses in vitro and in vivo show PACS-1 has properties of a coat protein and connects furin to components of the clathrin-sorting machinery. Cell-free assays indicate TGN localization of furin is directed by a PACS-1-mediated retrieval step. Together, these findings explain a mechanism by which membrane proteins in mammalian cells are localized to the TGN.

Primary cell cultures from murine kidney and heart differ in endosomal pH.

Endosomal and lysosomal pH values have been determined for many established cultured cell lines of different origins. These cell lines may be grouped into two classes based on observed differences in pH of early (recycling) endosomes. Members of the first class typically have an early endosomal pH of 6.2, whereas members of the second class typically have an early endosomal pH of 5.4. Because established cell lines may have developed artificial differences in endosomal pH due to extended culture, it remains to be determined if endosomal pH differences exist in vivo and whether they are functionally significant. To address this question, we generated adherent primary explants from mouse kidney (primarily epithelial cells) and heart (primarily fibroblasts and cardiac muscle cells). Interestingly, enhanced acidification was observed in heart cell endosomes (pH = 5.5) compared with kidney cell endosomes (pH = 6.0). These results indicate that differences in endosomal pH do not solely arise from extended cell culture and imply that such differences may be important for the proper functioning of different cell types.

Theoretical considerations on the role of membrane potential in the regulation of endosomal pH.

Na+,K(+)-ATPase has been observed to partially inhibit acidification of early endosomes by increasing membrane potential, whereas chloride channels have been observed to enhance acidification in endosomes and lysosomes. However, little theoretical analysis of the ways in which different pumps and channels may interact has been carried out. We therefore developed quantitative models of endosomal pH regulation based on thermodynamic considerations. We conclude that 1) both size and shape of endosomes will influence steady-state endosomal pH whenever membrane potential due to the pH gradient limits proton pumping, 2) steady-state pH values similar to those observed in early endosomes of living cells can occur in endosomes containing just H(+)-ATPases and Na+,K(+)-ATPases when low endosomal buffering capacities are present, and 3) inclusion of active chloride channels results in predicted pH values well below those observed in vivo. The results support the separation of endocytic compartments into two classes, those (such as early endosomes) whose acidification is limited by attainment of a certain membrane potential, and those (such as lysosomes) whose acidification is limited by the attainment of a certain pH. The theoretical framework and conclusions described are potentially applicable to other membrane-enclosed compartments that are acidified, such as elements of the Golgi apparatus.

Intracellular Ca2+ pool content is linked to control of cell growth.

A close correlation was observed between intracellular Ca2+ pool depletion and refilling and the onset of DNA synthesis and proliferation of DDT1MF-2 smooth muscle cells. The intracellular Ca2+ pump inhibitors 2,5-di-tert-butyl-hydroquinone (DBHQ) and thapsigargin (TG) specifically emptied identical inositol 1,4,5-trisphosphate (InsP3)-sensitive Ca2+ pools and both arrested cell growth at concentrations corresponding to Ca2+ pump blockade. However, an important distinction was observed between the two inhibitors with respect to their reversibility of action. Upon removal of DBHQ from DBHQ-arrested cells, Ca2+ pools immediately refilled, and 14 hr later cells entered S phase followed by normal cell proliferation; the time for entry into S phase was identical to that for cells released from confluence arrest. Although TG irreversibly blocked Ca2+ pumping and emptied Ca2+ pools, high serum treatment of TG-arrested cells induced recovery of functional Ca2+ pools in 6 hr (via probable synthesis of new pump); thereafter cells proceeded to S phase and normal cell proliferation within the same time period (14 hr) as that following release of DBHQ-arrested cells. The precise relationship between Ca2+ pump blockade and growth arrest indicates that Ca2+ pool emptying maintains cells in a G0-like quiescent state; upon refilling of pools, normal progression into the cell cycle is resumed. It is possible that a specific cell cycle event necessary for G0 to G1 transition depends upon signals generated from the InsP3-sensitive Ca2+ pool.

Persistent intracellular calcium pool depletion by thapsigargin and its influence on cell growth.

The intracellular Ca2+ pump inhibitor, thapsigargin, added to DDT1MF-2 smooth muscle cells in culture, irreversibly inhibited accumulation of Ca2+ within cells, permanently emptied the inositol 1,4,5-trisphosphate (InsP3)-sensitive Ca2+ pool, and simultaneously induced profound alteration of cell growth. After only a brief (30-min) treatment of cultured cells with 3 microM thapsigargin followed by extensive washing, the total releasable InsP3-sensitive Ca2+ pool remained entirely empty, even after 7 days of culture without thapsigargin. After thapsigargin treatment, cells retained viability, usual morphology, and normal mitochondrial function. Despite the otherwise normal appearance and function of thapsigargin-treated cells, cell division was completely blocked by thapsigargin. DNA synthesis was completely inhibited when thapsigargin was added immediately after passaging, but was suppressed only slowly (4-6 h) when added to rapidly synthesizing cells (24 h after passaging). Protein synthesis was reduced by approximately 70% in thapsigargin-treated cells. The sensitivity of thapsigargin-mediated inhibition of cell division, DNA synthesis, protein synthesis, and Ca(2+)-pumping activity were all similar with the EC50 values for thapsigargin in each case being close to 10 nM. Upon application to DDT1MF-2 cells, thapsigargin transiently increased resting cytosolic Ca2+ (0.15 microM) to a peak of 0.3 microM within 50 s; thereafter, free Ca2+ declined to 0.2 microM by 150 s and continued to slowly decline toward resting levels. Cells treated with thapsigargin for 1-72 h in culture displayed normal resting cytosolic Ca2+ levels. However, application of thapsigargin or epinephrine to such cells resulted in no change in the intracellular Ca2+, indicating that the internal Ca2+ pool remained completely empty. These results suggest that emptying of Ca2+ from intracellular thapsigargin-sensitive Ca(2+)-pumping pools induces profound alteration of cell proliferation.