Postendocytic trafficking of epidermal growth factor-receptor complexes is mediated through saturable and specific endosomal interactions

Carboxyl-terminal domains determine internalization and recycling characteristics of bombesin receptor chimeras

To investigate the role of the carboxy terminus in the regulation of the bombesin (BN) receptor, we constructed two chimeric receptors with carboxyl termini transferred from either m3 muscarinic cholinergic (m3 ACh) (BMC) or cholecystokinin A (CCKA) (BCC) receptors and expressed them in Chinese hamster ovary cells. Previous studies showed that agonist treatment caused rapid internalization of CCKA but not m3 ACh receptors in these cells. In the current study we conducted separate analyses of ligand and receptor internalization and analyzed receptor recycling. Ligand internalization was assessed using acid washing. BN and CCKA receptors internalized ligand with 80 +/- 3 and 85 +/- 7% in an acid-resistant compartment at equilibrium. Ligand internalization of chimeric receptors generally assumed the properties of the donor receptors. Thus, BCC receptors internalized ligand to a similar extent as wild-type CCKA receptors (75 +/- 3%), whereas, BMC receptors showed reduced ligand internalization (38 +/- 1%). Receptor internalization was more directly assessed by determining agonist-induced loss of surface binding. BN and CCKA receptors were largely internalized (56 +/- 8 and 50 +/- 7%, respectively). BCC receptors were also extensively internalized (82 +/- 3%). In contrast, BMC receptors were minimally internalized (22 +/- 8%). Receptor recycling was assessed as recovery from agonist induced loss of binding. BN, CCKA, and BMC receptors showed rapid recycling. In contrast, BCC receptors did not recycle. These data indicate that carboxyl-terminal structures determine both internalization of ligand-receptor complexes and subsequent receptor recycling.

Molecular/cell engineering approach to autocrine ligand control of cell function

Tissue engineering, along with other modern cell- and tissue-based health care technologies, depends on successful regulation of cell function by molecular means, including pharmacological agents, materials, and genetics. This regulation is generally mediated by cell receptor/ligand interactions providing primary targets for molecular intervention. While regulatory ligands may often be exogenous in nature, in the categories of endocrine and paracrine hormone systems, they are being increasingly appreciated as crucial in local control of cell and tissue function. Improvements in design of health care technologies involving autocrine ligand interactions with cell receptors should benefit from increased qualitative and quantitative understanding of the kinetic and transport processes governing these interactions. In this symposium paper we offer a concise overview of our recent efforts combining molecular cell biology and engineering approaches to increase the understanding of how molecular and cellular parameters may be manipulated for improved control of cell and tissue function regulated by autocrine ligands.

Endocytosis and lysosomal targeting of epidermal growth factor receptors are mediated by distinct sequences independent of the tyrosine kinase domain

Ligand-induced internalization of the epidermal growth factor receptor (EGFR) leads to accelerated receptor degradation. Two models have been proposed to explain this. In the first model, induced internalization expands the intracellular pool of receptors, leading to enhanced lysosomal targeting. The second model proposes that activation of intrinsic receptor kinase activity induces inward vesiculation of endosomes, thus interrupting receptor recycling. To test these models, we created EGFR mutants that lack the conserved tyrosine kinase domain, but retain different parts of the distal carboxyl terminus regulatory region. Mutants lacking all distal regulatory sequences underwent slow internalization (0.02 min-1) and turnover (t1/2 approximately 24 h), similar to unoccupied, holo-EGFR. Mutant receptors that lacked the kinase domain, but retained the entire distal regulatory domain, were constitutively internalized and targeted to lysosomes, even in the absence of EGF. The turnover of these receptors (t1/2 approximately 11 h) was similar to that of occupied, kinase-active holo-EGFR (t1/2 approximately 9.5 h). These results show that receptor tyrosine kinase activity is not required for the targeting of EGFR to lysosomes. Receptor mutants which expressed previously identified endocytic sequences underwent rapid internalization. Unexpectedly, enhanced turnover of EGFR mutants required additional sequences located between residues 945 and 991 in the holo-EGFR. Thus, internalization and lysosomal targeting of EGFR are separate processes mediated by distinct sequences. Our results indicate that induced internalization is necessary, but not sufficient, for enhanced EGFR degradation. Instead, down-regulation requires exposure of previously cryptic internalization and lysosomal targeting sequences. Occupied EGFR thus appear to be handled by the endocytic machinery in the same fashion as other constitutively internalized or lysosomally targeted receptors.

Intracellular trafficking of epidermal growth factor family ligands is directly influenced by the pH sensitivity of the receptor/ligand interaction

Using members of the epidermal growth factor (EGF) family as well as site-directed recombinant human EGF mutants, we investigated how ligand binding properties influence endosomal sorting. Mouse EGF (mEGF), human EGF (hEGF), and transforming growth factor alpha (TGF alpha) bind to the human EGF receptor (EGFR) with similar affinities at pH 7.4. However, the binding properties of these ligands have substantially different pH sensitivities resulting in varying degrees of dissociation from the receptors at lower pH levels characteristic of endosomes. We employed a steady-state sorting assay to determine the fraction of ligand sorted to recycling versus degradation as a function of the number of intracellular ligand molecules in mouse B82 fibroblasts. mEGF, hEGF, and TGF alpha display significantly different steady-state endosomal sorting patterns which correspond to the extent of their dissociation at endosomal pH. Moreover, several recombinant hEGF mutants with differing affinities exhibit altered endosomal sorting compared to hEGF, demonstrating a similar direct relationship between ligand binding properties and endosomal sorting outcomes. Intracellular trafficking of the EGF ligands was also monitored by measuring the observed degradation rate constants. These likewise show marked differences that correlate with the differing pH sensitivities of the ligands' binding properties.