Determinants of carboxyl-terminal domain translocation during prion protein biogenesis.

The prion protein (PrP) displays some unusual features in its biogenesis. In cell-free systems it can be synthesized as either an integral transmembrane protein spanning the membrane twice, with both amino and carboxyl domains in the lumen of the endoplasmic reticulum, or as a fully translocated polypeptide. A charged, extracytoplasmic region, termed the Stop Transfer Effector (STE) sequence, has been shown to direct the nascent translocating chain to stop at the adjoining hydrophobic domain to generate the first membrane-spanning region (TM1). However, the determinants of the second translocation event in the biogenesis of the transmembrane form have not been identified previously. Moreover, the relationship of transmembrane and fully translocated forms of PrP has not been well understood. Here, we report progress in resolving both of these issues. Using protein chimeras in cell-free translation systems and Xenopus oocytes, we identify the sequence which directs nascent PrP to span the membrane a second time, with its carboxyl-terminal domain in the endoplasmic reticulum lumen. Surprisingly, PrP carboxyl-terminal domain translocation does not appear to be directed by an internal signal or signal-anchor sequence located downstream of TM1, as would have been expected from studies of other multispanning membrane proteins. Rather, carboxyl-terminal domain translocation appears to be another consequence of the action of STE-TM1, that is, the same sequence responsible for generating the first membrane-spanning region. Studies of an STE-TM1-containing protein chimera in Xenopus oocytes demonstrate that most of these chains upon completion of their translation, initially span the membrane twice, with a topology similar to that of transmembrane PrP, but are carbonate-extractable. These chains have the transmembrane orientation only transiently and chase into a fully translocated form. These results support a model in which a metastable "transmembrane" intermediate, residing within the aqueous environment of the translocation channel, can be converted into either the integrated transmembrane or the fully translocated form of PrP, perhaps directed by trans-acting factor (s). Such a model may explain why stable the transmembrane isoform of PrP has not been observed in normal cells and how nascent PrP might be directed to alternate pathways of folding.

Biogenesis and transmembrane topology of the CHIP28 water channel at the endoplasmic reticulum.

CHIP28 is a 28-kD hydrophobic integral membrane protein that functions as a water channel in erythrocytes and renal tubule epithelial cell membranes. We examined the transmembrane topology of CHIP28 in the ER by engineering a reporter of translocation (derived from bovine prolactin) into nine sequential sites in the CHIP28 coding region. The resulting chimeras were expressed in Xenopus oocytes, and the topology of the reporter with respect to the ER membrane was determined by protease sensitivity. We found that although hydropathy analysis predicted up to seven potential transmembrane regions, CHIP28 spanned the membrane only four times. Two putative transmembrane helices, residues 52-68 and 143-157, reside on the lumenal and cytosolic surfaces of the ER membrane, respectively. Topology derived from these chimeric proteins was supported by cell-free translation of five truncated CHIP28 cDNAs, by N-linked glycosylation at an engineered consensus site in native CHIP28 (residue His69), and by epitope tagging of the CHIP28 amino terminus. Defined protein chimeras were used to identify internal sequences that direct events of CHIP28 topogenesis. A signal sequence located within the first 52 residues initiated nascent chain translocation into the ER lumen. A stop transfer sequence located in the hydrophobic region from residues 90-120 terminated ongoing translocation. A second internal signal sequence, residues 155-186, reinitiated translocation of a COOH-terminal domain (residues 186-210) into the ER lumen. Integration of the nascent chain into the ER membrane occurred after synthesis of 107 residues and required the presence of two membrane-spanning regions. From this data, we propose a structural model for CHIP28 at the ER membrane in which four membrane-spanning alpha-helices form a central aqueous channel through the lipid bilayer and create a pathway for water transport.

Evidence for an alternate model of human P-glycoprotein structure and biogenesis.

We have studied the transmembrane topology of human P-glycoprotein (MDR1) using protein chimeras in Xenopus oocytes and full-length native protein in a cell-free translation system. We find both in vivo and in vitro, that the peptide region between putative transmembrane helices (TM) 8 and 9 resides in the endoplasmic reticulum lumen not in the cytosol as predicted. The topology of the carboxyl-terminal half of MDR1 therefore appears distinct from the homologous amino-terminal half in which the corresponding region between TM2 and TM3 is cytosolic. Thus, topogenic sequences encoded in the homologous amino and carboxyl domains of MDR1 direct fundamentally different events in biogenesis of the two halves of MDR1. We conclude that the transmembrane topology of MDR1, an important member of the ATP binding cassette (ABC) transporter superfamily, is not as predicted and should be revised.

A multifunctional aqueous channel formed by CFTR.

The cystic fibrosis gene product (CFTR) is a complex protein that functions as an adenosine 3,5-monophosphate (cAMP)-stimulated ion channel and possibly as a regulator of intracellular processes. In order to determine whether the CFTR molecule contains a functional aqueous pathway, anion, water, and urea transport were measured in Xenopus oocytes expressing CFTR. Cyclic AMP agonists induced a Cl- conductance of 94 microsiemens and an increase in water permeability of 4 x 10(-4) centimeter per second that was inhibited by a Cl- channel blocker and was dependent on anion composition. CFTR has a calculated single channel water conductance of 9 x 10(-13) cubic centimeter per second, suggesting a pore-like aqueous pathway. Oocytes expressing CFTR also showed cAMP-stimulated transport of urea but not the larger solute sucrose. Thus CFTR contains a cAMP-stimulated aqueous pore that can transport anions, water, and small solutes. The results also provide functional evidence for water movement through an ion channel.

Premature termination of transcription from the P1 promoter of the mouse c-myc gene.

Modulation of transcriptional elongation within the c-myc gene is thought to play a major role in determining levels of c-myc mRNA in both normal and tumor cells. A discrete site of blockage to transcriptional elongation has previously been localized at the 3' end of exon 1 of the mouse and human c-myc genes. We here identify an additional site of transcriptional attenuation that is located between the P1 and P2 promoters of the c-myc gene and that mediates premature termination of transcripts initiating from the P1 promoter. A 95-nucleotide DNA fragment derived from this region prematurely terminated transcription when placed downstream from the promoter of the H-2Kbm1 gene and assayed by expression in Xenopus oocytes. We also show that the previously identified attenuation signal in exon 1 of the mouse c-myc gene can mediate premature termination of P1-initiated transcripts. Premature termination of P1-initiated transcripts presumably increases transcription from the downstream P2 promoter; aberrant regulation of this termination may explain the increased use of the P1 promoter that is characteristic of certain tumors in which myc is overexpressed.

Construction of defined polytopic integral transmembrane proteins. The role of signal and stop transfer sequence permutations.

Signal and stop transfer sequences are discrete regions within a polypeptide chain able to initiate or terminate translocation of the protein across the membrane of the endoplasmic reticulum. We have investigated the role of these topogenic sequences in the biogenesis of polytopic transmembrane proteins. Plasmids encoding various patterns of well-characterized signal and stop transfer sequences fused to a set of topogenically inert passenger domains were constructed. These molecules were expressed by transcription-translation in a cell-free system or by microinjection of transcripts into Xenopus oocytes. The observed orientation with respect to the membrane was dependent on the order of signal and stop transfer sequences in the coding region. These results were used to test the hypothesis that a protein can achieve polytopic transmembrane orientation using combinations of simple topogenic sequences. We conclude that some (but not all) patterns of signal and stop transfer sequences confer polytopic orientation to proteins across the membrane of the endoplasmic reticulum.

Expression of receptors for cholecystokinin and other Ca2+-mobilizing hormones in Xenopus oocytes.

The expression of receptors for cholecystokinin (CCK) and other similar acting Ca2+-mobilizing hormones was studied in Xenopus laevis oocytes. Poly(A)+ RNA was prepared from pancreatic AR42J cells, which normally express receptors for CCK and bombesin and the RNA injected into oocytes. The presence of these pancreatic receptors on the oocytes was then demonstrated by hormone-induced mobilization of 45Ca2+. CCK receptors were present 1 day (maximum, 2 days) after injection of RNA and were generally proportional to the amount of poly(A)+ RNA injected (1-50 ng). Oocyte CCK receptors retained selectivity for CCK analogs (CCK8 greater than unsulfated CCK8 greater than CCK4) and were blocked by the specific CCK receptor antagonist CR 1409. When poly(A)+ RNA was subjected to size fractionation on sucrose gradients, activity-inducing CCK receptors showed a single peak centered at 3 kilobases. The generality of this oocyte system for expressing Ca2+-mobilizing hormone receptors was further shown by expression of a response to bombesin after injection of AR42J cell RNA and a response to vasopressin and angiotensin II when poly(A)+ RNA from rat liver was injected. No response to CCK was demonstrable after injection of liver RNA, demonstrating the specificity of this assay.