Rhomboid and Star facilitate presentation and processing of the Drosophila TGF-alpha  homolog Spitz

doi:10.1101/gad.14.2.177

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Vol. 14, No. 2, pp. 177-186, January 15, 2000

RESEARCH PAPER
Rhomboid and Star facilitate presentation and processing of the Drosophila TGF- $alpha$ homolog Spitz

Anne G. Bang, and Chris Kintner¹

Molecular Neurobiology Laboratory, The Salk Institute for Biological Studies, La Jolla, California 92037 USA

Abstract

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

Activation of the Drosophila epidermal growth factor receptor (DER) by the transmembrane ligand, Spitz (Spi), requires twoadditional transmembrane proteins, Rhomboid and Star. Geneticevidence suggests that Rhomboid and Star facilitate DER signalingby processing membrane-bound Spi (mSpi) to an active, solubleform. To test this model, we use an assay based on Xenopus animalcap explants in which Spi activation of DER is Rhomboid and Stardependent. We show that Spi is on the cell surface but is keptin an inactive state by its cytoplasmic and transmembrane domains;Rhomboid and Star relieve this inhibition, allowing Spi to signal.We show further that Spi is likely to be cleaved within its transmembranedomain. However, a mutant form of mSpi that is not cleaved stillsignals to DER in a Rhomboid and Star-dependent manner. Theseresults suggest strongly that Rhomboid and Star act primarilyto present an active form of Spi to DER, leading secondarily tothe processing of Spi into a secretedform.

[Key Words: spitz; rhomboid; Star; EGFR; Drosophila; Xenopus animal caps]

	Introduction

Top Abstract Introduction Results Discussion Materials and methods References

Cell fate decisions in embryonic development often depend on receptor tyrosine kinases that signal with precise temporal andspatial control. One striking example of this regulation is seenin the embryonic and adult development of Drosophila, in whichmultiple cell fate decisions require DER, the Drosophila epidermalgrowth factor receptor (EGFR) (Schweitzer and Shilo 1997). A numberof genes have been identifed with phenotypes similar to DER, andwere thus found to encode factors that regulate DER signaling.This group includes Spitz (Spi), a transmembrane ligand for DERthat is similar to transforming growth factor- $alpha$ (TGF- $alpha$ ), Rhomboid,a putative seven transmembrane domain protein, and Star, a single-passtransmembrane protein (Bier et al. 1990; Rutledge et al. 1992;Kolodkin et al. 1994) (Fig. 1A). As essential cofactors, Rhomboidand Star are thought to determine the pattern of DER activationduring embryonic development by controlling the activity of theligand and receptor that are ubiquitously expressed. The temporaland spatial expression of rhomboid is highly regulated, suggestingthat it controls when and where DER is activated (Bier et al.1990).

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Figure 1. Rhomboid- (Rho) and Star-dependent mSpi activation of DER in Xenopus animal caps. (A) Models for Rhomboid and Star action. (B) RPA showing that Rhomboid and Star each weakly promote mSpi activation of DER, however, together they are synergistic (lanes 2-5). sSpi activates DER in the absence of Rhomboid and Star (lane 1). Argos represses sSpi activation of DER (lane 7). (C) Induction of XBra expression by DER is reduced in the presence of the dominant-negative FGF receptor, XFD (compare lane 1 with 3, and lane 2 with 5). In a positive control for the potency of XFD, lanes 6 and 7 show that XFD abolishes induction of XBra by activin. (D) Sandwich assay experimental design. (E) RPA of animal cap sandwiches showing that Rhomboid and Star must be coexpressed with the ligand, and not the receptor, for activation to occur (lanes 2-4). When Rhomboid and Star are present in both the signaling and receiving cells, the level of DER activation is attenuated (lanes 5-7).

Current evidence, primarily from genetic analyses, most strongly supports a model proposed by Shilo and colleagues in whichRhomboid and Star regulate processing of membrane-bound Spi (mSpi)to an active, soluble form (Golembo et al. 1996; Schweitzer etal. 1995b). rhomboid and Star can promote DER activation non cellautonomously (Golembo et al. 1996). Moreover, the requirementfor rhomboid and Star for DER activation can be overcome by expressingjust the soluble, extracellular portion of Spi (sSpi) (Schweitzeret al. 1995b). Alternative models, however, suggest that Rhomboidand Star regulate receptor function, or that they are involvedin forming a complex at the cell surface that brings togetherreceptor and ligand (Sturtevant et al. 1993, 1996; Stemerdinkand Jacobs 1997; Guichard et al. 1999). To test these models,we have developed an assay based on Xenopus animal caps, in whichSpi activates DER in a Rhomboid and Star-dependent manner. Thisassay not only allows the requirement for Rhomboid and Star tobe analyzed in depth, but is amenable to a structure-functionanalysis of DER signaling. On the basis of the results from thisassay, we propose that Rhomboid and Star control the pattern ofDER activation by a novel mechanism involving ligand presentationandproteolysis.

	Results

Top Abstract Introduction Results Discussion Materials and methods References

Xenopus animal cap assay for DER signaling

Rhomboid and Star-mediated DER signaling was analyzed by an assay in which Xenopus animal cap explants were isolated fromembryos injected with in vitro synthesized DER, spi, rhomboid,and Star RNA (Fig. 1). This assay is based on the fact that DERactivates the Ras pathway, which should lead to an up-regulationin the expression of the Ras target gene Xenopus Brachyury (XBra)in animal caps (Whitman and Melton 1992). Animal caps from injectedembryos were allowed to develop until sibling embryos were lategastrulae (stage 11.5), when they were analyzed for XBra expressionby RNAse protection assay (RPA). We found that expression of XBracould be induced in animal caps by DER but only under the sameconditions that are required for the activation of DER in Drosophila(Fig. 1B). Thus, expression of XBra is not induced in animal capsthat express DER alone, DER along with mSpi, or DER along withjust Rhomboid and Star (Fig. 1B, lane 2; data not shown). In contrast,a high level of XBra expression is induced when animal caps expressDER along with mSpi, Rhomboid, and Star (Fig. 1B, lane 5). Therequirement for Rhomboid and Star for DER activation can be overcomein the animal cap assay, as in Drosophila, by expressing sSpi,an engineered form of Spi that contains just the extracellulardomain (Fig. 1B, lane 1). In addition, DER activation can be blocked,as in Drosophila, by introducing the DER inhibitor, Argos (Schweitzeret al. 1995a; Fig. 1B, lane7).

One possible contributing factor to the high levels of XBra induction that are achieved in the animal cap assay is that XBraexpression could be amplified by an FGF-dependent positive regulatoryloop. It has been shown that XBra, which is a T-Box-containingtranscription factor, activates the fibroblast growth factor (FGF)gene, which in turn up-regulates XBra expression through activationof the FGF receptor (Tada et al. 1997). To test whether the levelof XBra expression that is induced by DER is amplified throughan FGF-dependent mechanism, RNAs encoding DER, Spi, Rhomboid,Star, and a dominant-negative form of the FGF-receptor, XFD, werecoinjected (Amaya et al. 1991). In the presence of XFD, the levelof XBra expression is reduced by ~2.5-fold. This result showsthat a positive regulatory loop between XBra and FGF amplifiesthe level of XBra expression that is induced by activation ofDER, thus increasing the sensitivity of the animal cap assay (Fig.1C). Together, these results demonstrate that regulation of DrosophilaEGFR-signaling can be recapitulated in Xenopus animal caps, thusproviding a faithful and highly sensitive assay with which toinvestigate the mechanism of action by Rhomboid andStar.

To test whether Rhomboid and Star are obligate cofactors in the animal cap assay, their abilities to promote DER activationwere analyzed separately. We found that by themselves, Rhomboidand Star each weakly promote mSpi activation of DER, however,together they are strongly synergistic (Fig. 1B, lanes 3-5). Thus,both Rhomboid and Star may be required to achieve maximal levelsof DER activation, but for lower levels of signaling, either onealone may be sufficient. It is possible that Rhomboid and Starare obligate cofactors but that there are homologous proteinspresent in the animal cap that fulfill the role of the missingcomponent, albeit weakly. Alternatively, this result may reflecta way in which various levels of receptor activation may be achieved.In some settings, such as the Drosophila wing veins, rhomboidand Star are codependent, whereas in the eye, Star is sufficientand rhomboid function appears to be dispensible (Freeman et al.1992a; Guichard et al. 1999).

Rhomboid and Star act in the signaling cells to promote DER activity

Next, we determined whether Rhomboid and Star are required for DER activity by acting in the signaling cell, the receivingcell, or in both cells. To do this, activation of XBra was measuredin sandwiches that were made by combining an animal cap expressingDER with another animal cap expressing mSpi, in the presence orabsence of Rhomboid and Star (Fig. 1D). When Rhomboid and Starare present in the receptor-expressing cells, mSpi fails to activateDER (Fig. 1E, lane 4). However, when Rhomboid and Star are presentin the ligand-expressing cells, mSpi strongly activates DER (Fig.1E, lane 3). It has been suggested that Rhomboid and Star mayact as cell adhesion molecules to bring together the receptorand ligand into a cell surface complex (Stemerdink and Jacobs1997; Sturtevant et al. 1993, 1996). To test this idea, sandwicheswere made in which rhomboid and Star were expressed in both thesending and receiving cells. Interestingly, this configurationattenuated the level of DER signaling, with the strongest repressionoccuring when both Rhomboid and Star are present on both sidesof the sandwich (Fig. 1E, lanes 5-7). It is an intriguing possibilitythat an interaction between Rhomboid and/or Star in trans maydampen the level of signal received by DER, providing anotherpossible mechanism by which the level of DER activation couldbe finely tuned. Together, these results argue against modelsin which Rhomboid and Star regulate receptor function or act ascell adhesion molecules and support a model in which Rhomboidand Star potentiate DER activation by acting in the signalingcell.

mSpi is inactivated by sequences in its transmembrane and cytoplasmic domains

We next asked whether Rhomboid and Star potentiate DER signaling by changing the activity of its ligand, as suggested by theobservation that sSpi does not require Rhomboid and Star to activateDER, whereas mSpi does. To address this question, we made a seriesof chimeras by replacing portions of human TGF- $alpha$ , a vertebratehomolog of Spi, with the corresponding regions from mSpi (Fig.2A). Human TGF- $alpha$ alone strongly activates the human EGFR in theanimal cap assay (Fig. 2B, lane 3). Strikingly, when the cytoplasmic(C) and transmembrane (TM) domains of TGF- $alpha$ are replaced withthose of mSpi (TGF- $alpha$ /SpiTMC), the chimeric molecule activatesthe human EGFR only when Rhomboid and Star are present (Fig. 2B,lanes 4,5). In contrast, chimeric molecules in which the TGF- $alpha$ C or TM domains are replaced separately with those of mSpi (TGF- $alpha$ /SpiCand TGF- $alpha$ /SpiTM, respectively) are constitutively active (Fig.2B, lanes 6-9). Thus, together the mSpi TM and C domains are sufficientto confer Rhomboid and Star dependence on TGF- $alpha$ . This result suggeststhat the C and TM domains maintain Spi in an inactive state, andthat their ability to do so is transferrable to another EGFR ligand.As predicted by this interpretation, a membrane-bound form ofSpi that activates DER signaling in the absence of Rhomboid andStar can be generated by replacing the mSpi TM and C domains withthose of TGF- $alpha$ (Spi/TGF- $alpha$ TMC) (Fig. 2B, lanes 10,11). In addition,Spi $Delta$ 53C, a Spi mutant in which 53 carboxy-terminal residues aredeleted and 17 cytoplasmic residues remain, exhibits some Rhomboidand Star-independent activity, providing further evidence thatthe C domain plays an inhibitory role (Fig. 2B, lanes 15,16).Together these results argue strongly that the C and TM domainsof mSpi act to maintain an inactive state, with ligand activationoccuring upon interaction with Rhomboid and Star.

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Figure 2. Analysis of TGF- $alpha$ /Spi chimeras. (A) Schematic of TGF- $alpha$ /Spi chimeric molecules. (B) RPA showing that the human EGFR is activated by human TGF- $alpha$ (lane 3). Together the mSpi C and TM domains (TGF- $alpha$ /SpiTMC) confer Rhomboid and Star dependence on TGF- $alpha$ (lanes 4,5). Replacement of the TGF- $alpha$ C or TM domains with those of mSpi results in constitutive activity (TGF- $alpha$ /SpiC and TGF- $alpha$ /SpiTM, lanes 6-9). The observation that TGF- $alpha$ /SpiC exhibits reduced activity compared with TGF- $alpha$ could reflect the loss of the TGF- $alpha$ carboxy-terminal valines, which are normally required for targeting TGF- $alpha$ to the cell surface (Briley et al. 1997

). Spi/TGF- $alpha$ TMC, in which the mSpi C and TM domains are replaced with those of TGF- $alpha$ , is Rhomboid and Star independent (lanes 10,11). Spi $Delta$ 53C exhibits Rhomboid and Star-independent activity (lanes 15,16).

mSpi is on the cell surface in the presence and absence of Rhomboid and Star

One possible manner in which Rhomboid and Star could activate mSpi would be to target it to the cell surface by regulatingits transit through the secretory pathway. For instance, transportof TGF- $alpha$ to the cell surface requires TACIP18 (proTGF- $alpha$ cytoplasmicdomain interacting protein), a PDZ domain protein that interactswith the carboxy-terminal valine residues of proTGF- $alpha$ (Fernandez-Larreaet al. 1999). To investigate this possibility, we biotinylatedcell surface proteins on animal caps injected with RNA encodingtagged mSpi (mSpi^myc) or with RNA encoding mSpi^myc, Rhomboid, and Star. Protein lysates were incubated with streptavidin-agaroseand then the bound fraction was eluted and analyzed by Westernblotting with an anti-c-myc antibody. Biotinylated mSpi proteinwas recovered in each case, suggesting that it is unlikely thatRhomboid and Star are required to target mSpi to the cell surface(Fig. 3A). Furthermore, this observation implies that mSpi isat the cell surface but is inactive.

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Figure 3. (A) Western analysis of biotinylated mSpi^myc. mSpi^myc can be biotinylated in the absence of Rhomboid and Star (cf. lanes 3 and 4). mSpi^myc is detected by the anti-human c-myc antibody 9E10 and is indicated by an arrow. (Lanes 1,2) mSpi^myc present in lysates prior to incubation with streptavidin-agarose (10% of the total lysate was loaded). (Lanes 3,4) mSpi^myc eluted from streptavidin-agarose (the entire eluted fraction was loaded). (B) mSpi titration. Similar levels of DER activation are obtained over a range of 500 pg to 1 pg of injected mSpi RNA. (C) Experimental design for Rhomboid and Star-dependent production of Spi conditioned medium (CM). (D) RPA analysis of CM activities. sSpi CM activates DER independently of Rhomboid and Star (lane 1). mSpi CM induces XBra expression in DER-injected animal caps in a Rhomboid and Star-dependent manner (lanes 2,3), but not in uninjected animal caps (ectoderm, lanes 4-6). CM from animal caps expressing Spi-15aa, Rhomboid, and Star does not activate DER, whereas the positive control CM from animal caps expressing mSpi, Rhomboid, and Star efficiently activates DER (cf. lanes 7 and 8). (E) Spi-15aa strongly activates DER in a Rhomboid and Star-dependent manner, similar to mSpi.

Rhomboid and Star promote processing of mSpi to a soluble form

Another way in which Rhomboid and Star could lead to ligand activation is by promoting proteolytic processing, thus convertingmSpi into a form similar to sSpi (Schweitzer et al. 1995b; Golemboet al. 1996). We first attempted to identify cleaved forms ofSpi using versions with myc epitope tags at either terminus andby Western analysis. Comparison of protein lysates from embryosinjected with mspi^myc versus mspi^myc, rhomboid, and Star did not reveal any Spi cleavage products(see Fig. 3A; data not shown). One possible explanation for thisresult is that mSpi proteolysis occurs at a low level and thatonly very small amounts of ligand are required to activate DER.A titration experiment supports this possibility as similar, highlevels of DER activation are achieved over a range of 500 pg toonly 1 pg of injected mspi RNA, thus below the limit of detectionof Spi by Western analysis (Fig. 3B).

Given the possibility that only low levels of Spi are required to activate DER, we turned to a more sensitive assay to determinewhether Rhomboid and Star promote proteolysis of Spi. Conditionedmedium was prepared from dissociated animal cap cells from embryosinjected with RNA encoding sSpi, or mSpi, or coinjected with RNAsencoding mSpi, Rhomboid, and Star. DER-injected animal caps wereincubated in the conditioned medium and then analyzed for expressionof XBra (Fig. 3C). The conditioned medium from animal caps expressingsSpi or mSpi/Rhomboid/Star contains an activity that activatesDER, whereas that from animal caps expressing mSpi alone doesnot (Fig. 3D, lanes 1-3). In addition, the conditioned mediumactivity is DER dependent, as it is ineffective on uninjectedanimal caps (Fig. 3D, lanes 4-6). These results suggest that Rhomboidand Star activate mSpi by promoting its cleavage andsecretion.

Spi does not need to be cleaved to activate DER

Next, we determined whether proteolytic processing is required for Rhomboid and Star activation of mSpi. To do this, we removedpotential sites for processing of mSpi by deleting the sequencesencoding the 15 amino acids (aa) between the Spi EGF and TM domains(Spi-15aa) (Fig. 3E). This region was selected because cleavageof TGF- $alpha$ is known to take place within an analogous interval (Brachmannet al. 1989; Wong et al. 1989). When tested in the animal capassay, Spi-15aa strongly activates DER in a Rhomboid and Star-dependentmanner (Fig. 3E, lanes 3,4). In contrast, conditioned medium preparedfrom animal caps expressing Spi-15aa, Rhomboid, and Star doesnot contain any activity that activates DER, indicating that Spi-15aais not cleaved (Fig. 3D, lane 7). Taken together, these resultssuggest that cleavage of mSpi depends on the sequence deletedin the Spi-15aa mutant; however, mSpi does not need to be cleavedto activate DER signaling. Thus, Rhomboid and Star may act topresent mSpi to DER and subsequently facilitate or allow itscleavage.

Cleavage of mSpi may occur within its transmembrane domain

The results obtained with the Spi-15aa deletion mutant suggest that mSpi, like TGF- $alpha$ , is processed to generate a soluble form.To examine the nature of this processing further, we next testedthe possibility that it includes a cleavage within the transmembranedomain of mSpi. This possibility is suggested by the results obtainedwith the Spi/TGF- $alpha$ chimeras, showing that the Spi transmembranedomain is important for Rhomboid and Star-dependent activation.Moreover, another multimembrane-spanning protein, Presenilin-1,mediates proteolyis of the $beta$ -amyloid precursor protein and Notch,both of which are cleaved within their transmembrane domains (DeStrooper et al. 1999; Struhl and Greenwald 1999; Wolfe et al.1999; Ye et al. 1999). If processing does lead to a cleavage inthe membrane, we reasoned that this would release the intracellulardomain of Spitz in a Rhomboid/Star-dependent manner. To detectthis cleavage, we therefore generated a chimeric molecule in whichthe mSpi C domain is replaced with the myc-tagged, intracellulardomain of the Xenopus Notch receptor (Spi/NICD) (Fig. 4A). Theendogenous, $gamma$ -secretase-dependent Notch cleavage site (Schroeteret al. 1998) is not present in the Spi/NICD chimeric molecule(see Materials and Methods). If proteolytic processing of thismolecule occurred within the Spi TM domain in a Rhomboid/Star-dependentmanner, NICD may be released, translocate to the nucleus, andactivate target genes (Fig. 4D; Lecourtois and Schweisguth 1998;Schroeter et al. 1998; Struhl and Adachi 1998). As a Notch targetgene we used Xenopus Enhancer-of-split-related-1 (Esr-1) (Wettsteinet al. 1997). Expression of Esr-1 was analyzed in animal capsthat were coinjected with the neuralizing factor noggin, as Esr-1is normally expressed in neural tissue and its induction by NICDis more robust in a noggin background (Wettstein et al. 1997).

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Figure 4. Analysis of Spi/NICD chimeras. (A) Spi/NICD chimeric molecules. (B) RPA showing that Spi/NICD and Spi-15aa/NICD activate DER in a Rhomboid and Star-dependent manner, similar to mSpi (lanes 1-6). (C) RPA showing that NICD induces Esr-1 expression (lane 2); however, the Spi/NICD chimeric molecule only activates Esr-1 when Rhomboid and Star are present (lanes 3,4). Spi-15aa/NICD does not activate Esr-1 (lanes 5,6). We note, induction of Esr-1 and XBra expression by Spi/NICD were analyzed as separate experimental samples because together XBra and noggin synergize to promote dorsal mesoderm formation, a background in which Esr-1 is poorly induced (Cunliffe and Smith 1994

). (D) Model for Rhomboid and Star-dependent activation of Xbra and Esr-1 by the Spi/NICD chimera. Rhomboid and Star present Spi/NICD, and then cleavage releases both Spi and NICD to activate their respective targets. However, Spi does not need to be cleaved to be active.

When tested in the animal cap assay, Spi/NICD activates DER, but only in the presence of Rhomboid and Star, indicating thatthe Spi/NICD chimeric molecule still exhibits Rhomboid and Star-dependentSpi activity (Fig. 4B, lanes 1-4). We note, this result also indicatesthat the myc-tagged Xenopus NICD can effectively replace the SpiC domain, suggesting that the ability of the C domain to maintainSpi in an inactive state depends more on its structure than onits primary sequence. Significantly, Spi/NICD also activates theNotch target gene, Esr-1, in a Rhomboid and Star-dependent manner(Fig. 4C, lanes 1-4). This result suggests that Rhomboid and Starpromote a proteolytic processing event within the Spi-TM domainthat releases NICD (Fig. 4D). In addition, as Esr-1 inductionis Rhomboid and Star dependent in the absence of DER, Rhomboidand Star can function independently ofDER.

By analogy to the $beta$ -amyloid precursor protein and Notch, whose activites are regulated by multiple, interdependent cleavageevents (Chan and Jan 1999), we decided to test the possibilitythat the 15 amino acids between the Spi EGF and TM domains thatare required for production of soluble Spi are also required forthe cleavage of the Spi/NICD chimeric molecule within its TM domain.Thus, we deleted the sequence encoding these 15 amino acids inthe Spi/NICD chimera to produce Spi-15aa/NICD (Fig. 4A). Thisdeletion mutant still strongly activates DER in a Rhomboid andStar-dependent manner (Fig. 4B, lanes 5,6), but no longer inducesEsr-1, indicating that NICD is not released, and thus cleavageof this mutant does not occur (Fig. 4C, lanes 5,6). Thus, theseresults provide further independent evidence for our contentionthat Rhomboid and Star-dependent cleavage of mSpi requires theamino acids deleted in the Spi-15aa mutant, but mSpi need notbe cleaved to activate DER signaling. Finally, these results suggestthat there is a Rhomboid and Star-dependent cleavage event ofmSpi within its TM domain. One possible explanation for theseobservations is that mSpi is cleaved both within the TM domainand within the 15 amino acids between the TM and EGF domains.Alternatively, a single cleavage of mSpi could occur within itsTM domain that depends on the 15 amino acidinterval.

	Discussion

Top Abstract Introduction Results Discussion Materials and methods References

Our results suggest a novel regulatory mechanism of ligand presentation. mSpi is at the cell surface; however, its C and TMdomains impose an inactive state in which cleavage and interactionwith the receptor are prohibited. Subsequently, through an interactionwith the Spi C and TM domains, Rhomboid and Star present an activeform of mSpi, leading to, but not requiring, cleavage of its extracellulardomain (Fig. 5).

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Figure 5. Model: mSpi is on the cell surface but it is inactive. Rhomboid and Star present an active form of mSpi, leading to, but not requiring, cleavage of its extracellular domain.

Several models could account for the Rhomboid and Star-dependent effects that we observed. One model is that Rhomboid andStar are required to direct mSpi to the proper compartment forsignaling to occur. The results from the biotinylation experimentssuggest strongly that Rhomboid and Star are not required for transportof mSpi to the cell surface, but it remains a possibility thatRhomboid and Star could play a role in localizing mSpi to specificcell surface microdomains such as lipid rafts (Brown and London1998). An alternative class of models is that mSpi is at the cellsurface and ready to signal, but that Rhomboid and Star are requiredfor bringing mSpi into an active conformation. One version ofthis model is that Rhomboid and Star activate mSpi by promotingits oligomerization. However, this idea is difficult to reconcilewith the observation that sSpi is active and either does not requireoligomerization or oligomerizes independently of Rhomboid andStar. In addition, soluble EGF, which is similar to sSpi, bindsas a monomer to the extracellular domain of the EGFR in a 1:1ratio, suggesting that membrane-bound EGFR ligands may also bindthe receptor as monomers (Lemmon et al. 1997). For these reasons,we favor an alternative model in which mSpi is present at themembrane in an inactive dimeric or oligomeric complex. Rhomboidand Star would be required to either prevent formation of thiscomplex or to alter its conformation such that mSpi could be presentedas an active form. This model is precedented by observations suggestingthat a number of receptor tyrosine kinases exist as inactive dimersthat are activated when specific inter-subunit conformationalchanges occur upon ligand binding (Jiang and Hunter 1999). Thus,formation of an inactive mSpi complex would be mediated by itsC and TM domains and inhibited by an interaction between thesedomains and Rhomboid and Star. This model explains both why removalof these domains relieves the requirement for Rhomboid and Star,and transfer of these domains to TGF- $alpha$ confers Rhomboid and Stardependence. Such a model also predicts that sSpi would be Rhomboidand Starindependent.

Although the animal cap assay has allowed us to uncouple presentation from cleavage of Spi in vitro, in vivo cleavage maybe necessary for normal development, as clonal analyses have revealedthat Spi acts at a distance of several cell diameters (Freeman1994; Tio et al. 1994). By analogy, in vitro TGF- $alpha$ is active asboth a membrane-bound and soluble form (Brachmann et al. 1989;Wong et al. 1989). However, examination of mutant mice lackingtumor necrosis factor converting enzyme (TACE), reveals that thisenzyme plays a role in processing TGF- $alpha$ , and that, despite theobservation that membrane-anchored TGF- $alpha$ is active in vitro, invivo soluble TGF- $alpha$ is essential for normal development (Peschonet al. 1998). It is certainly possible that in some developmentalsettings, secretion of Spi is crucial, whereas in other settings,it is sufficient that membrane-bound Spi activate DER only inneighboring cells. The discovery that expression of the DER-ligandvein is induced by Spi activation of DER suggests a mechanismby which membrane-bound Spi could effectively activate DER ata distance of several cell diameters (Golembo et al. 1999).

How do Rhomboid and Star promote cleavage of mSpi? Rhomboid and/or Star could play a passive role by making mSpi accessibleto proteolysis upon presentation. Alternatively, Rhomboid and/orStar may actively facilitate Spi proteolysis either by activatingor recruiting a protease or transporting Spi to the appropriatesubcellular compartment. Similar roles have been proposed forthe multimembrane-spanning proteins presenilin-1, which is requiredfor proteolyis of $beta$ -amyloid precursor protein and Notch, and SREBPcleavage-activating protein (SCAP), which is required for theproteolyis of sterol regulatory element-binding protein (SREBP)(Sakai et al. 1998; De Strooper et al. 1999; Struhl and Greenwald1999; Wolfe et al. 1999; Ye et al. 1999). It is also possiblethat Rhomboid and/or Star could themselves have proteolytic activity,as has been proposed for Presenilin-1 (Wolfe et al. 1999). A proteaseresponsible for Spi cleavage is yet to be identified. Finally,although our study strongly suggests that presentation of Spiis inhibited by its C-domain, we have not addressed the questionof whether proteolysis of Spi is also affected by the C-domain.For instance, proteolytic release of the extracellular domainof membrane bound neuregulin is dependent on its cytoplasmic domain(Liu et al. 1998). Future experiments will be aimed at determiningwhether Rhomboid and Star play a passive or an active role inthe proteolysis ofmSpi.

Another important question is, where exactly is the Spi cleavage site? Our study demonstrates that the 15 amino acid intervalbetween the Spi EGF and TM domains is important for cleavage,although cleavage may also occur within its TM domain. The simplestmodel is that cleavage only occurs in the transmembrane domain,generating both a soluble extracellular and intracellular portion.In this model, the 15 amino acid interval between the Spi EGFand TM domains is required for recognition by a protease, perhapsin combination with Rhomboid and Star, which then cleaves in thetransmembrane domain. Alternatively, processing of mSpi couldbe much more complicated, involving a cascade of cleavage eventsthat are interdependent. In this model, for example, cleavagein the transmembrane domain may depend on a prior cleavage inthe 15 amino acid interval. Cascades of proteolytic processingare evident in such examples as $beta$ -amyloid, Notch, and SREBP, aswell as TGF- $alpha$ , which undergoes two cleavages in its extracellulardomain, the second of which is rate limiting (Massague 1990; Sakaiet al. 1998; see references in De Strooper et al. 1999; Wolfeet al. 1999). It is interesting to speculate that the Spi C-domainthat is released upon cleavage within the TM-domain may have asignaling function, as has been proposed for the cytoplasmic domainof TGF- $alpha$ (Shum et al. 1994).

The EGFR belongs to a family of receptor tyrosine kinases that has been implicated in cellular proliferation, migration, anddifferentiation, as well as the generation and progression oftumors. Although there has been a great deal of progress towardunderstanding how signal transduction through these receptorsis regulated, little is known about the mechanisms that controlproduction of active forms of their ligands. The recent identificationof both Caenorhabditis elegans and mammalian rhomboid homologssuggests that the function of Drosophila rhomboid may be conservedin evolution (Wilson et al. 1994; Pascall and Brown 1998). Studiesof Drosophila rhomboid function will serve as a basis for understandingthe Rhomboid family of transmembrane proteins and their rolesin the regulation of ligand presentation andproteolysis.

	Materials and methods

Top Abstract Introduction Results Discussion Materials and methods References

Construction of plasmids

The coding region of the human EGFR (Lin et al. 1984) was cloned into sp64 (Promega). Coding regions of spi (Rutledge et al.1992), DER (Livneh et al. 1985), rho (Bier et al. 1990), Star(Kolodkin et al. 1994), argos (Freeman et al. 1992b), and humanTGF- $alpha$ (Jhappan et al. 1990), were cloned into the CS2⁺ expression vector (Turner and Weintraub 1994). mspi was truncatedat the BglI site (nucleotide 621) to produce sspi. mspi was truncatedat the PstI site (nucleotide 770) to produce spi $Delta$ 53C. mspi^myc and sspi^myc were made by cloning five consecutive myc tags into the BanI(nucleotide 328) site of mspi and sspi. Clones for chimeric moleculeswere constructed as follows, with the underlined amino acids insertedto produce restriction sites. Two weakly hydrophobic residues,Ala-138 and Ser-139, immediately amino-terminal to the predictedTM domain of Spi were included in the Spi TM domain. TGF- $alpha$ /spiTMC,TGF- $alpha$ amino acids 1-98/GluPhe/Spi amino acids 139-230. TGF- $alpha$ /spiTM,TGF- $alpha$ amino acids 1-98/GluPhe/Spi amino acids 139-164/GlySer/TGF- $alpha$ amino acids 122-160. TGF- $alpha$ /SpiC, TGF- $alpha$ amino acids 1-121/GluPhe/Spiamino acids 161-230. Spi/TGF- $alpha$ TMC, Spi amino acids 1-139/GluPhe/TGF- $alpha$ amino acids 98-160. Spi-15 amino acids/NICD, Spi amino acids 1-122/GluPhe/Spiamino acids 139-160/GlySer/6Xmyc/Xenopus NICD amino acids 1751-2524.SpiDB/NICD, Spi amino acids 1-128/Spi amino acids 130-160/GlySer/6Xmyc/XenopusNICD amino acids 1751-2524.

Isolation, treatment, and culturing of Xenopus animal caps

Two-cell stage Xenopus laevis embryos were injected in the animal region of each blastomere with 0.5 ng of capped syntheticRNAs encoding noggin (Lamb et al. 1993), XFD (Amaya et al. 1991),mSpi, Rhomboid, Star, Argos, Xenopus NICD (Wettstein et al. 1997),human TGF- $alpha$ , human EGFR, and the chimeric molecules describedherein. Animal caps were dissected at stage 9 and cultured untilsibling controls reached stage 11.5 for XBra analysis and stage13 for Esr-1 analysis. Some caps were treated with 5 ng/ml recombinantactivin (provided by the Vale Laboratory, Salk Institute) in 0.5× MMR, 0.1% BSA immediately afterdissection.

RNase protection assay

RNA was isolated from eight animal caps per sample and analyzed by RNase protection assay, with ³²P-labeled antisense RNA probes for XBra, EF-1 $alpha$ , and Esr-1 RNAsas described previously (Bhushan et al. 1994; Wettstein et al.1997).

Biotinylation and Western analysis

A total of 40 animal caps each from embryos injected with sspi^myc, mspi^myc, or mspi^myc, rhomboid, and Star were incubated in 1.5 mg/ml EZlink sulfo-NHS-SS-Biotin(Pierce) in 0.7× PBS, 0.5 mM MgSO₄, 1 mM CaCl₂ for 15 min, washedin 0.5× MMR, and homogenized in 200 µl of 1% Triton-X 100, 10mM HEPES (pH 7.4), 150 mM NaCl, 100 mM CaCl₂, 2 mM MgCl₂, andprotease inhibitors. Lysates were incubated with 20 µl of streptavidin-agarose(Pierce) overnight. Streptavidin-agarose bound proteins were washedin homogenization buffer, and eluted in reducing SDS sample buffer.Protein samples were resolved by SDS-PAGE on a 10%-20% gel, transferredto P-Immobilon (Millipore), and detected with the anti-human c-Mycantibody 9E10 and a peroxidase-conjugated secondary antibody withenhanced chemiluminescence (ECL,Amersham).

Preparation of conditioned medium

A total of 30 injected animal caps were dissociated in 200 µl of 1× Calcium-Magnesium Free Media (88 mM NaCl, 1 mM KCl, 2.4mM NaHCO₃, and 7.5 mM HEPES) in 0.1% BSA. After 3 hr, the supernatantwas diluted 1:1 with 1× MMR and passed over a 0.22 µm Millex-GV4filter(Millipore).

	Acknowledgments

We thank T. Hunter, G. Gill, E. Lamar, and G. Lemke for critical reading of this manuscript; E. Bier, A. Guichard, G. Merlino,M. Freeman, G. Gill, and E. Adamson for clones; R. Bradley andM. Perez for help with Westerns; A. Guichard, E. Bier, J.C. dela Torre, C. Ghiglione, and J. Posakony for helpful discussions.This work was supported by a grant from theNIH.

The publication costs of this article were defrayed in part by payment of page charges. This article must therefore be herebymarked "advertisement" in accordance with 18 USC section 1734solely to indicate thisfact.

	Footnotes

Received November 5, 1999; revised version accepted December 7, 1999.

¹ Correspondingauthor.

E-MAIL kintner{at}salk.edu; FAX (858) 450-2172.

References

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Abstract
Introduction
Results
Discussion
Materials and methods
References

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RESEARCH PAPER Rhomboid and Star facilitate presentation and processing of the Drosophila TGF- homolog Spitz

RESEARCH PAPER
Rhomboid and Star facilitate presentation and processing of the Drosophila TGF- $alpha$ homolog Spitz