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© The Rockefeller University Press, 0021-9525/1999//923 $5.00
The Journal of Cell Biology, Volume 145, Number 5, , 1999 923-926

Molecular Bases for the Recognition of Tyrosine-based Sorting Signals

Cell Biology and Metabolism Branch, National Institute of Child Health and Human Development, National Institutes of Health, Bethesda, Maryland 20892

Abbreviations used in this paper: AP, adaptor protein.

TARGETING of transmembrane proteins to different compartments of the endocytic and late (post-Golgi) secretory pathways is largely dependent upon sorting signals contained within the cytosolic domains of the proteins (reviewed in reference 19, 24). The signals are thought to interact with specific recognition molecules, which are components of the machinery involved in the formation of membrane-bound transport intermediates (e.g., coated vesicles; reference 2). The interaction of signals with their recognition molecules is thus considered to be the key event leading to selective recruitment of cargo transmembrane proteins into the nascent transport intermediates. Studies over the past 30 years have provided extensive evidence for the occurrence of this basic mechanism of protein sorting at multiple sites within the cell. However, the molecular details of the signal-recognition event have only recently begun to be unraveled. This mini-review will focus on recent progress in the elucidation of the molecular bases for the recognition of a subset of sorting signals, referred to as tyrosine-based signals, by a family of adaptor protein (AP)¹ complexes.

	Tyrosine-based Signals: A Degenerate Family

Top Tyrosine-based Signals: A... Recognition of YXXØ... Interactions of YXXØ... Physiological Roles of... References

 
Tyrosine-based signals constitute a family of degenerate motifs minimally defined by the presence of a critical tyrosine residue (see reference 22 and references therein). Most tyrosine-based signals conform to the consensus motifs YXXØ (Y is tyrosine, X is any amino acid, and Ø is an amino acid with a bulky hydrophobic side chain; reference 5) or NPXY (N is asparagine and P is proline; reference 6). YXXØ signals are currently the best understood from a structural standpoint and thus will be the primary subject of our discussion. YXXØ signals can be found within the cytosolic domains of all types of transmembrane proteins, including type I (e.g., lamp-1), type II (e.g., the transferrin receptor), and multi-spanning (e.g., CD63). They can be most easily identified within short cytosolic tails (i.e., <35 amino acid residues), although they have also been shown to exist within the large cytosolic domains of some signaling receptors (e.g., the epidermal growth factor receptor) and retroviral envelope glycoproteins (e.g., HIV-1 gp41). The presence of a sequence conforming to the YXXØ motif within a large cytosolic domain, however, is not necessarily predictive of sorting information since signals must be presented in an appropriate context to be active. In mammalian cells, virtually all YXXØ signals mediate rapid internalization from the cell surface. Some YXXØ signals can additionally mediate lysosomal targeting, localization to specialized endosomal-lysosomal organelles such as antigen-processing compartments, delivery to the basolateral plasma membrane of polarized epithelial cells or localization to the TGN (reviewed in reference 19, 22, 24). The multiple functions of YXXØ signals raise the question of how the same type of signal can mediate sorting to different cellular compartments. A hypothesis that has been put forth to explain the various roles of YXXØ signals is that they must interact selectively with a family of recognition molecules associated with different sites of protein sorting. Recent findings that YXXØ signals are capable of interacting with several AP complexes provide a framework for testing the validity of this hypothesis.

	Recognition of YXXØ Signals by the µ2 Subunit of AP-2

Top Tyrosine-based Signals: A... Recognition of YXXØ... Interactions of YXXØ... Physiological Roles of... References

 
Glickman et al. (14) pioneered the use of in vitro affinity-binding methods to study the interactions of the cytosolic tails of membrane receptors with AP complexes. In the course of these studies, they demonstrated a tyrosine-dependent interaction of the cytosolic tail of the cation-independent mannose 6-phosphate receptor with AP-2, a plasma membrane, clathrin-associated complex composed of two large subunits ( and β2), one medium subunit (µ2), and one small subunit (2) (Fig. 1 A). Generalization of this biochemical approach to other transmembrane proteins, however, was hampered by the low affinity of the interactions in vitro. Further progress required the development of more sensitive protein interaction assays based on techniques such as the yeast two-hybrid system and surface plasmon resonance spectroscopy. The use of the yeast two-hybrid system, for instance, was instrumental in the identification of µ2 as a recognition molecule for YXXØ signals (29). Mutational and combinatorial analyses demonstrated that the Y residue is essential for binding to µ2 and cannot be effectively substituted even by the structurally related phenylalanine or phosphotyrosine residues (4, 28, 36). Leucine is the preferred residue at the Ø position, although isoleucine, phenylalanine, methionine, and, to a lesser extent, valine, are tolerated (4, 27, 28). Many residues are permitted at the X positions, although arginine and proline are favored at the second X position (4, 27, 28). All of these preferences are consistent with the requirements for optimal function of YXXØ signals in rapid internalization, and thus provide strong correlative evidence for the physiological role of YXXØ-µ2 interactions.

View larger version (50K): [in this window] [in a new window] [Download PPT slide]   Figure 1 (A) Schematic representation of AP complexes. Each AP complex consists of two large subunits (/// and β1-4), one medium subunit (µ1-4), and one small subunit (1-4). Some subunits exist in more than one isoform. (B) Bipartite structure of µ2 (approximate residue numbers indicated in parentheses) and ribbon representation of its YXXØ-binding domain complexed to a DYQRLN peptide (adapted from reference 32; PDB accession code 1BXX). (C) Residues of rat µ2 involved in interactions with YXXØ signals and corresponding residues in other members of the AP µ family. Y- and Ø-binding residues are indicated in red and blue, respectively.

	Interactions of YXXØ Signals with Other AP µ Subunits

Top Tyrosine-based Signals: A... Recognition of YXXØ... Interactions of YXXØ... Physiological Roles of... References

 
The finding that the µ2 subunit of AP-2 interacts with YXXØ signals raised the possibility that analogous subunits of other AP complexes could similarly function in recognition of YXXØ. To date, three additional complexes structurally related to AP-2 have been described in mammals: AP-1, AP-3, and AP-4 (Fig. 1 A). Each of these AP complexes contains a µ subunit that displays significant homology to µ2 over the entire sequence. µ1A (formerly called µ1; reference 25) is a component of the AP-1 complex in most cell types, whereas a closely related isoform, µ1B, may be a subunit of this complex in polarized epithelial and glandular cells (30). µ3A and µ3B are alternative components of AP-3 (10, 37, 38); µ3A is widely expressed, whereas µ3B expression is mainly restricted to cells of neuronal origin (33). Finally, µ4 (originally known as µ-ARP2; reference 41) is a subunit of the recently described AP-4 complex (9). Sequence alignments indicate that most of the µ2 residues directly involved in interactions with the Y and Ø residues of YXXØ signals are conserved in other AP µ family members (Fig. 1 C). Indeed, µ1A, µ1B, µ3A, and µ3B have all been shown to interact with YXXØ signals, albeit with lower affinity relative to µ2 (10, 27–30, 34, 39). The conservation of Y- and Ø-binding residues also extends to µ4, as well as to AP µ orthologs from nonmammalian organisms (Fig. 1 C). This suggests that these molecules may also be capable of recognizing YXXØ signals.

The identification of a family of proteins that interact with YXXØ signals supports the hypothesis that the functional specificity of these signals may be dictated by their selective interaction with different recognition molecules. As mentioned above, µ2 tolerates many different amino acid side chains surrounding the critical Y and Ø residues, although it prefers arginine at the second X position of the YXXØ signal (4, 27, 28). Similar analyses have revealed that µ1A and µ3A prefer non-polar and acidic residues, respectively, at that position (27). Although the functional significance of the µ1A preferences is unclear, µ3A preferences are suggestive of a role in lysosomal targeting since the signals of several proteins localized to lysosomes and lysosome-related organelles (e.g., CD63, lamp-2a, and GMP-17) contain acidic residues at positions adjacent to the tyrosine residue.

	Physiological Roles of YXXØ-µ Subunit Interactions

Top Tyrosine-based Signals: A... Recognition of YXXØ... Interactions of YXXØ... Physiological Roles of... References

 
Having just identified a family of YXXØ-recognition molecules, an important next question that needs to be addressed is: what sorting events are mediated by interaction of YXXØ signals with each of these molecules?

AP-1 has been localized mainly to the TGN at steady state, where it is thought to mediate transport of lamp-1 and mannose 6-phosphate receptors to compartments of the endosomal-lysosomal system (13, 16). Recent studies, however, have raised the possibility that AP-1 may be involved in protein sorting to the basolateral plasma membrane of polarized epithelial cells (12, 31).

As the only AP complex localized to the plasma membrane, AP-2 is an obvious candidate for mediating rapid internalization through recognition of YXXØ signals. Recently, Nesterov et al. have provided compelling evidence for a role of µ2 in this process using a dominant negative genetic approach (26). These investigators constructed a µ2 variant with mutations in D¹⁷⁶ and W⁴²¹, which are critical elements of the YXXØ-binding site (Fig. 1 C). This mutant µ2 was unable to bind YXXØ signals but competed with endogenous µ2 for incorporation into the AP-2 complex. Interestingly, overexpression of mutant µ2 inhibited internalization of the transferrin receptor (26), which is known to be mediated by the YXXØ-type signal YTRF (7).

The intracellular localization of the AP-3 complex is not known with certainty, although published evidence suggests an association with endosomes and/or the TGN (8, 10, 37, 38). Evidence for a role of AP-3 in sorting mediated by YXXØ signals has recently been obtained from the analysis of AP-3–deficient cells. These cells were either generated by using an antisense RNA methodology (20) or derived from two patients with Hermansky-Pudlak syndrome carrying mutations in the AP-3 β3A subunit (11). In both cases, the AP-3 deficiency resulted in increased routing of YXXØ-containing, lysosomal membrane proteins through the plasma membrane, thus suggesting a function for AP-3 in YXXØ-mediated targeting to lysosomes. In contrast, the trafficking of non-lysosomal membrane proteins having YXXØ signals (e.g., the transferrin receptor) was not noticeably altered (11). This differential effect, which is consistent with the preference of the AP-3 µ3A subunit for YXXØ signals found in lysosomal membrane proteins (11, 27, 39), lends support to the notion that selective interaction with AP complexes underlies the functional specificity of YXXØ signals. The fact that a substantial fraction of lysosomal membrane proteins are still targeted to lysosomes in AP-3–deficient cells (11, 20) suggests that other AP complexes may provide alternative means of delivery to lysosomes. Perhaps this is a function of AP-1, or of the recently described AP-4 complex, which appears to be localized to the TGN or a neighboring compartment (9).

In conclusion, the hypothesis advanced to explain the involvement of YXXØ signals in multiple sorting events can now be made more explicit: YXXØ signals are recognized with characteristic preferences by the medium (µ) subunits of several AP complexes. The factors that determine the fidelity of sorting processes in vivo, however, remain poorly understood. First, although each µ subunit displays preferences for certain X and Ø residues, there is nonetheless a significant overlap in sequence specificity (27). Contextual factors such as the position of the signal within the cytosolic domain (35), the oligomeric state of the transmembrane protein (3), and the presence of other signals in the cytosolic domain, may contribute to differential interactions with the AP complexes. Second, there still may be additional YXXØ-binding proteins to be discovered. As discussed above, µ4 is a likely candidate for one such molecule. Finally, transmembrane proteins moving along trafficking pathways may meet the AP complexes sequentially rather than simultaneously. This means that the trajectory followed by a protein, as well as potential biochemical modifications along the way, may determine which interactions actually take place. Further research will be needed to assess the contribution of these factors to the selectivity of sorting by YXXØ signals. With a solid molecular foundation now in place, however, we can anticipate rapid progress toward the decipherment of this protein sorting code.

	Acknowledgments

 
We thank Jennifer Lippincott-Schwartz, Mickey Marks, and Larry Samelson for helpful comments on the manuscript.

Submitted: 16 April 1999

Address all correspondence to Juan S. Bonifacino, Cell Biology and Metabolism Branch, NICHD, Building 18T, Room 101, National Institutes of Health, Bethesda, Maryland 20892. Tel.: (301) 496-6368. Fax: (301) 402-0078. E-mail: juan{at}helix.nih.gov

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