The processing and secretion of rat serum albumin by oocytes from Xenopus laevis

Two distinct chloride ion requirements in the constitutive protein secretory pathway

The role of chloride ions in regulated secretion is well described but remains poorly characterised in the constitutive system. In the liver, newly synthesised proalbumin is transported to the trans Golgi network where it is converted to albumin by a furin protease and then immediately secreted. We used this acid-dependent hydrolysis and the measurement of specific protein secretion rates to examine the H+ and Cl- ion dependence of albumin synthesis and secretion, a major constitutive protein secretory event in all mammals. Using permeabilised primary rat hepatocytes we show that ordinarily chloride ions are essential for the processing of proalbumin to albumin. However Cl- is not required for transport which continues but releases solely proalbumin. Prior treatment of the cells with Tris (used as a membrane-permeable weak base to neutralise Golgi luminal pH) both eliminated the formation of albumin and very greatly reduced secretion. After washing out Tris, both authentic secretion and processing could be restarted if Cl-, ATP, GTP, cAMP, Ca2+ and cytosolic proteins were added. Hence a requirement for chloride in transport, in addition to processing, can be uncovered by first neutralising pH gradients. Furthermore, the chloride channel blocker DIDS (4,4-diisothiocyanostilbene 2,2-disulphonic acid) reversibly inhibited the constitutive secretory pathway. However, the total mass of proalbumin detectable in DIDS-treated cells fell to 36% of control while the fraction processed to albumin remained almost constant. This clearly dissociates a large part of the Cl- requirement of the constitutive protein secretory pathway from the function of known liver Golgi Cl- channels.

Heterologous in vivo processing of human preproendothelin 1 into bioactive peptides

Endothelin (ET) is an extremely potent vasoconstrictor peptide of 21 amino acids, originally found in the supernatant of cultured vascular endothelial cells. To gain insights into its biosynthetic pathway, we expressed a synthetic RNA coding for the 212-amino acid precursor of human ET-1 (preproET-1) in Xenopus oocytes. Cell homogenates and oocyte incubation medium were tested by RIA using an anti-ET-1 serum. ET-1-like immunoreactivity was detected in oocytes injected with preproET-1 synthetic RNA but not in control oocytes and was much higher in medium than in cell homogenates. When preproET-1 was expressed in oocytes treated with monensin, a dramatic decrease in secretion of immunoreactive material was observed, indicating that secretion is mediated by the Golgi complex. ET-1-like immunoreactive material present in oocyte incubation medium was fractionated by reverse-phase HPLC into two main peaks, corresponding to the retention times of human big ET-1 and ET-1. Incubation medium of oocytes expressing the synthetic preproET-1 RNA elicited a characteristic vasoconstrictor response on rabbit vena cava, consistent with the biological activity that would be predicted from the amount of ET-1-like immunoreactivity measured. These results suggest that common pathways of ET maturation exist in widely different cells and that Xenopus oocytes may represent a useful tool in studying the cell biology of ET-1 synthesis.

Proalbumin is processed to serum albumin in COS-1 cells transfected with cDNA for rat albumin

Synthesis and processing of rat albumin were investigated in COS-1 cells transiently expressing rat albumin. Analysis using isoelectric focusing revealed that serum-type albumin, which is indistinguishable from the counterpart isolated from rat hepatocyte cuture medium, was secreted from the transfected COS-1 cells, indicating that proalbumin is effectively converted into serum albumin in the COS-1 cells, if not completely. Furthermore methylamine was found to cause the diminution of serum albumin released from the cells, substantiating that the proteolytical conversion of proalbumin occurs in the Golgi complex before discharge from the COS-1 cells.

Expression of normal and mutant human pre-pro-insulins in Xenopus oocytes

Conveniently situated PstI sites were used to delete a major segment from the C-peptide coding region of a human pre-pro-insulin cDNA. The resultant mutant cDNA encoded a protein with the structure: pre-peptide B chain--Arg-Arg-Glu-Ala-Glu-Asp-Leu-Gln-Lys-Arg-A chain. Normal and mutant human pre-pro-insulin cDNAs were used as templates for the synthesis of mRNA in a reaction catalysed by T7 RNA polymerase. The mRNAs were then microinjected into Xenopus oocytes to determine the effect of the deletion on the secretion of pro-insulin. When normal pre-pro-insulin mRNA was microinjected, pre-pro-insulin was processed to pro-insulin, which in turn was secreted into the media. When the mutant pre-pro-insulin mRNA was microinjected, however, mutant pro-insulin could be detected in the oocytes but at a much lower level than the normal pro-insulin. No mutant pro-insulin could be detected in the media. The stability of the mRNAs in the oocytes was investigated by microinjecting [32P]mRNA. 24 and 48 h after microinjection, the recovery of [33P]mRNA from the oocytes was 95 and 24% and 20 and 16% of that injected, for the normal and mutant mRNAs, respectively. In a cell-free translation system supplemented with dog pancreatic microsomal membranes, the pre-peptide was cleaved from the normal pre-pro-insulin but not from the mutant pre-pro-insulin. These results suggest that C-peptide plays an important role in the segregation of pro-insulin within and transport through the cellular secretory pathway.