Human pro-tumor necrosis factor (pro-TNF) is a type II transmembrane protein with a highly conserved 76-residue leader sequence. We have analyzed the behavior, both in a microsomal translocational system and by transfection, of a series of mutants with deletions from the cytoplasmic, transmembrane, and linking domains. Cytoplasmic deletions included the Arg doublet at ؊49 and ؊48 and/or the Lys doublet at ؊58 and ؊57; additional mutants included deletion of residues ؊73 to ؊55 and ؊73 to ؊55, ؊49, and ؊48. The transmembrane and linking domain mutants included deletions in the ؊42 to ؊35 region, combined with the deletion of residues ؊32 to ؊1. Two hybrid mutants combined the cytoplasmic deletions with the deletion of residues ؊32 to ؊1. All of the cytoplasmic deletion mutants were properly translocated, as were the transmembrane deletion mutants with deletions up to residues ؊36, ؊35, ؊32 to ؊1, although the last one exhibited reduced efficiency; further incremental deletions, including deletions of residues ؊38 to ؊35 and ؊32 to ؊1, completely blocked translocation. Both hybrid mutants were effectively translocated; furthermore, transfection analysis revealed competent expression and maturation of both the cytoplasmic and hybrid mutants. Thus, proper expression and maturation of human pro-TNF can be accomplished with as few as ϳ12 of the 26 residues of the native transmembrane domain and with a net negative charge in the cytoplasmic domain flanking the transmembrane region.
The insulin receptor is an integral transmembrane glycoprotein comprised of two alpha-(approximately 135 kDa) and two beta-(approximately 95 kDa) subunits, which is synthesized as a single polypeptide chain precursor (alpha beta). The primary sequence of the human insulin receptor (hIR) protein, deduced from the nucleotide sequence of cloned human placental mRNAs, predicts two large domains (929 and 403 residues) on either side of a single membrane spanning domain (23 residues); each of these major domains has a distinct function (insulin binding and protein/tyrosine kinase activity, respectively). To experimentally test this deduced topology, and to explore the potential for independent domain function by the hIR extracellular domain, we have constructed an expression plasmid encoding an hIR deletion mutant which is truncated 8 residues from the beginning of the predicted transmembrane domain (i.e., 921 residues). This domain of the hIR is in fact processed into alpha- and truncated beta-subunits and secreted with high efficiency from transfected CHO cell lines which express this mutant hIR, and the protein accumulates as an (alpha beta)2 dimer in the medium. This molecule is recognized by a battery of 13 monoclonal antibodies to epitopes on the IR extracellular domain, four of which block insulin binding and two of which require the native conformation of the IR for recognition. Further, this domain binds insulin with an apparent dissociation constant comparable to that of the wild-type hIR. However, the secreted dimer displays a linear Scatchard plot, while that of the wild-type membrane-associated hIR is curvilinear.(ABSTRACT TRUNCATED AT 250 WORDS)
The human insulin receptor (IR) is a transmembrane glycoprotein, whose cytoplasmic domain contains an insulin-activated protein-tyrosine kinase (EC 2.7.2.112). By the use of an appropriately engineered baculovirus expression vector, a soluble cytoplasmic derivative of this domain was expressed in the insect cell line Spodoptera frugiperda (Sf9). At 24 to 48 h after Sf9 cells were infected with recombinant virus, a protein of the size expected for this domain (-48 kilodaltons) constituted a major band when total cell lysates of metabolically labeled cells were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. This protein (designated AchIRPTK) was immunoprecipitated by three monoclonal antibodies, each of which recognizes a distinct antigenic site of the IR cytoplasmic domain and requires the native structure of the protein for recognition and one of which binds at or near the physiologically relevant site(s) of IR autophosphorylation. In vivo, AchIRPTK was phosphorylated on both tyrosine and serine residues. When affinity purified, the kinase was active in vitro; it autophosphorylated exclusively on tyrosine residues, and phosphorylated the exogenous substrates histone H2b and poly(Glu-Tyr). The expression of an active IR protein-tyrosine kinase molecule in this heterologous cell system provides an efficient experimental method for producing this domain in quantity for enzymatic and structural studies.
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