Function of the Drosophila TGF-alpha homolog Spitz is controlled by Star and interacts directly with Star

Drosophila Spitz is a homolog of transforming growth factor alpha (TGF-alpha) and is an activating ligand for the EGF receptor (Egfr). It has been shown that Star is required for Spitz activity. Here we show that Star is quantitatively limiting for Spitz production during eye development. We also show that Star and Spitz proteins colocalize in Spitz sending cells and that this association is not coincident with the site of translation--consistent with a function for Star in Spitz processing or transmission. Finally, we have defined minimal sequences within both Spitz and Star that mediate a direct interaction and show that this binding can occur in vivo.     

Computational analysis of EGFR inhibition by Argos

Argos, a secreted inhibitor of the Drosophila epidermal growth factor receptor, and the only known secreted receptor tyrosine kinase inhibitor, acts by sequestering the EGFR ligand Spitz. We use computational modeling to show that this biochemically-determined mechanism of Argos action can explain available genetic data for EGFR/Spitz/Argos interactions in vivo. We find that efficient Spitz sequestration by Argos is key for explaining the existing data and for providing a robust feedback loop that modulates the Spitz gradient in embryonic ventral ectoderm patterning. Computational analysis of the EGFR/Spitz/Argos module in the ventral ectoderm shows that Argos need not be long-ranged to account for genetic data, and can actually have very short range. In our models, Argos with long or short length scale functions to limit the range and action of secreted Spitz. Thus, the spatial range of Argos does not have to be tightly regulated or may act at different ranges in distinct developmental contexts.     

Palmitoylation of the EGFR ligand Spitz by Rasp increases Spitz activity by restricting its diffusion

Lipid modifications such as palmitoylation or myristoylation target intracellular proteins to cell membranes. Secreted ligands of the Hedgehog and Wnt families are also palmitoylated; this modification, which requires the related transmembrane acyltransferases Rasp and Porcupine, can enhance their secretion, transport, or activity. We show here that rasp is also essential for the developmental functions of Spitz, a ligand for the Drosophila epidermal growth factor receptor (EGFR). In cultured cells, Rasp promotes palmitate addition to the N-terminal cysteine residue of Spitz, and this cysteine is required for Spitz activity in vivo. Palmitoylation reduces Spitz secretion and enhances its plasma membrane association, but does not alter its ability to activate the EGFR in vitro. In vivo, overexpressed unpalmitoylated Spitz has an increased range of action but reduced activity. These data suggest a role for palmitoylation in restricting Spitz diffusion, allowing its local concentration to reach the threshold required for biological function.     

Nucleolar organizer regions in pigmented skin lesions. Value in the differential diagnosis of Spitz nevi.

Forty-one cases of typical melanocytic skin lesions (15 intradermal nevi, 14 Spitz nevi and 12 malignant melanomas) were used to investigate the value of staining of nucleolar organizer regions (NORs) in the differential diagnosis of such pigmented lesions. Histologic sections were stained by the silver colloid (Ag) method, with and without the prior use of a melanin blocking agent. There were statistically significant differences in the mean numbers of AgNORs per nucleus between the groups of lesions studied (1.658 for intradermal nevi, 3.0042 for Spitz nevi and 6.669 for malignant melanomas). Sections treated with potassium permanganate (melanin blocking agent) prior to staining showed an obvious increase in the AgNOR scores in all groups; this increase was highest for Spitz nevi. Although AgNOR staining allows a distinction to be made between intradermal nevi and malignant melanomas, the striking overlap between the counts for Spitz nevi and malignant melanomas precludes the use of this technique as the sole method for establishing the diagnosis of malignancy. Other clinical and morphologic data are especially required to make the diagnosis of Spitz nevi.     

DNA-cytophotometry of benign compound and intradermal naevi, Spitz epithelioid naevi and malignant melanomas

Single cell DNA cytophotometry was used to characterize seven compound, ten intradermal and six Spitz naevi as well as 23 primary cutaneous malignant melanomas. Compound and intradermal naevi were characterized by a smaller nuclear area than both Spitz naevi and malignant melanomas. Tumour ploidy could not be used as a single criterion of malignancy since both diploid and hyperdiploid melanomas were encountered. The very low mean optical density of Spitz naevi served to distinguish these lesions from malignant melanomas.     

Regulated intramembrane proteolysis takes another twist.

Rhomboid, a seven-transmembrane domain protein, has been shown genetically to potentiate EGFR signaling via the TGFalpha-like ligand Spitz. Here we discuss recently published papers that identify Rhomboid as a novel serine protease, cleaving Spitz within its transmembrane domain.     

Drosophila rhomboid-1 defines a family of putative intramembrane serine proteases.

The polytopic membrane protein Rhomboid-1 promotes the cleavage of the membrane-anchored TGFalpha-like growth factor Spitz, allowing it to activate the Drosophila EGF receptor. Until now, the mechanism of this key signaling regulator has been obscure, but our analysis suggests that Rhomboid-1 is a novel intramembrane serine protease that directly cleaves Spitz. In accordance with the putative Rhomboid active site being in the membrane bilayer, Spitz is cleaved within its transmembrane domain, and thus is, to our knowledge, the first example of a growth factor activated by regulated intramembrane proteolysis. Rhomboid-1 is conserved throughout evolution from archaea to humans, and our results show that a human Rhomboid promotes Spitz cleavage by a similar mechanism. This growth factor activation mechanism may therefore be widespread.     

EGF receptor signalling: the importance of presentation

Activation of the Drosophila EGF receptor requires the transmembrane TGF-alpha-like ligand Spitz. Recent studies have shed new light on the role of two transmembrane proteins, Star and Rhomboid, in the presentation and subsequent proteolytic processing of Spitz.     

Regulated intracellular ligand transport and proteolysis control EGF signal activation in Drosophila.

The membrane proteins Star and Rhomboid-1 have been genetically defined as the primary regulators of EGF receptor activation in Drosophila, but their molecular mechanisms have been elusive. Both Star and Rhomboid-1 have been assumed to work at the cell surface to control ligand activation. Here, we demonstrate that they control receptor signaling by regulating intracellular trafficking and proteolysis of the ligand Spitz. Star is present throughout the secretory pathway and is required to export Spitz from the endoplasmic reticulum to the Golgi apparatus. Rhomboid-1 is localized in the Golgi, where it promotes the cleavage of Spitz. This defines a novel growth factor release mechanism that is distinct from metalloprotease-dependent shedding from the cell surface.     

Novel three‐way complex rearrangement of TRPM1‐PUM1‐LCK in a case of agminated Spitz nevi arising in a giant congenital hyperpigmented macule

The genetic anomalies associated with the agminated variant of Spitz nevus have so far been limited to HRAS G13R mutations, especially when arising within a nevus spilus. A previous report exposed the case of a man with a giant pigmented macule involving his upper right limb and trunk. Since childhood, Spitz nevi have been periodically arising, within the pigmented area. The histopathology of several lesions displayed the usual criteria of junctional, compound, or intradermal Spitz nevi with a diversity of cytomorphological and architectural features. Some lesions spontaneously regressed. Genetic studies confirmed in three lesions an identical translocation involving TRPM1, PUM1, and LCK. No mutations in HRAS, NRAS, BRAF, or other known fusion genes linked to Spitz nevus were detected. LCK break‐apart fluorescence in situ hybridization confirmed the rearrangement was present not only in the melanocytic proliferation but also in the surrounding non‐spitzoid melanocytes. This report expands the list of genetic alterations involved both in giant congenital macules and in agminated Spitz nevi, and also extends the concept of mosaicism in melanocytes to gene translocations.     

An interplay between two EGF-receptor ligands, Vein and Spitz, is required for the formation of a subset of muscle precursors in Drosophila.

Activation of the Drosophila EGF-receptor (DER) is spatially and temporally controlled by the release of its various ligands. DER and its ligand Spitz mediate the formation of specific somatic muscle precursors. We show that a second DER ligand, Vein, complements the activity of Spitz in the development of various somatic muscle precursors. In vn mutant embryos, the DER-dependent muscle precursors do not form in some of the segments. This phenotype is significantly enhanced in embryos carrying only one copy of wild type spitz. Our analysis suggests that Vein activation of DER differs qualitatively from that of Spitz in that it does not lead to the expression of the inhibitory protein Argos, possibly leading to a continuous activation of the DER signaling pathway.     

Serrate-Notch signaling defines the scope of the initial denticle field by modulating EGFR activation

The Drosophila embryonic epidermis has been a key model for understanding the establishment of cell type diversity across a cellular field. During segmental patterning, distinct signaling territories are established that employ either the Hedgehog, Spitz, Serrate or Wingless ligands. How these pathways control segmental pattern is not completely clear. One major decision occurs as cells are allocated to differentiate either smooth cuticle or denticle type cuticle. This allocation is based on competition between Wingless signaling and Spitz, which activates the Epidermal Growth Factor Receptor (EGFR). Here we show that a main role for Serrate-Notch signaling is to adjust the Spitz signaling domain. Serrate accomplishes this task by activating Notch in a discrete domain, the main purpose of which is to broaden the spatially regulated expression of Rhomboid. This adjusts the breadth of the source for Spitz, since Rhomboid is necessary for the production of active Spitz. We also show that the Serrate antagonist, fringe, must temper Notch activity to insure that the activation of the EGFR is not too robust. Together, Serrate and Fringe modulate Notch activation to generate the proper level of EGFR activation. If Serrate-Notch signaling is absent, the denticle field narrows while the smooth cell field expands, as judged by the expression of the denticle field determinant Ovo/Shaven baby. This establishes one important role for the Serrate signaling territory, which is to define the extent of denticle field specification.     

Poster Abstracts

One of the major roles of the Nemours Biomolecular Core is to provide one-on-one mentoring for clinicians engaging for the first time in molecular genetics projects. This core function has successfully grown to include unique inter-institutional research collaborations. In this poster, we will present the detailed molecular analysis that was performed in collaboration with clinicians in DE and PA, on a rare and fascinating case of agminated Spitz nevus, and the methodologies developed for this project. Differentiating a Spitz nevus from a Spitzoid melanoma is often a challenging task faced by dermatopathologists. While the dysplastic nevus theory supports the notion that a Spitz nevus can progress to a melanoma, there is molecular evidence that refutes this possibility. Namely, Spitz nevi can carry unique mutations found in the mitogen-activated protein kinase (MAPK) pathway that are not found in melanomas. We used DNA sequencing as well as STR analysis for genotyping and copy number evaluation. The analysis revealed two HRAS “gain of function mutations” resulting in A11S and G13R amino acid substitutions in the ras protein and hyper activation of the MAPK signaling pathway. Allelic specific amplification PCR assays were developed to elucidate the allelic provenance of each mutation. We discovered that the maternally inherited allele carried both mutations in cis. The HRAS mutations observed in the patient’s Spitz nevi, HRAS copy number increase, as well as allelic imbalance at 11p with gain of the maternal allele, was also observed in tissue containing the mutated gene.     

A family of Rhomboid intramembrane proteases activates all Drosophila membrane-tethered EGF ligands

Drosophila has three membrane-tethered epidermal growth factor (EGF)-like proteins: Spitz, Gurken and Keren. Spitz and Gurken have been genetically confirmed to activate the EGF receptor, but Keren is uncharacterized. Spitz is activated by regulated intracellular translocation and cleavage by the transmembrane proteins Star and the protease Rhomboid-1, respectively. Rhomboid-1 is a member of a family of seven similar proteins in Drosophila. We have analysed four of these: all are proteases that can cleave Spitz, Gurken and Keren, and all activate only EGF receptor signalling in vivo. Star acts as an endoplasmic reticulum (ER) export factor for all three. The importance of this translocation is highlighted by the fact that when Spitz is cleaved by Rhomboids in the ER it cannot be secreted. Keren activates the EGF receptor in vivo, providing strong evidence that it is a true ligand. Our data demonstrate that all membrane-tethered EGF ligands in Drosophila are activated by the same strategy of cleavage by Rhomboids, which are ancient and widespread intramembrane proteases. This is distinct from the metalloprotease-induced activation of mammalian EGF-like ligands.     

Control of compartment size by an EGF ligand from neighboring cells

Insect bodies are subdivided into anterior (A) and posterior (P) compartments: cohesive fields of distinct cell lineage and cell affinity . Like organs in many animal species, compartments can develop to normal sizes despite considerable variation in cell division . This implies that overall compartment dimensions are subject to genetic control, but the mechanisms are unknown. Here, studying Drosophila's embryonic segments, I show that P compartment dimensions depend on epidermal growth factor receptor (EGFR) signaling. I suggest the primary activating ligand is Spitz, emanating from neighboring A compartment cells. Spi/EGFR activity stimulates P compartment cell enlargement and survival, but evidence is presented that Spitz is secreted in limited amounts, so that increasing the number of cells within the P compartment causes the per-cell Spitz level to drop. This leads to compensatory apoptosis and cell-size reductions that preserve compartment dimensions. Conversely, I propose that lowering P compartment cell numbers enhances per-cell Spitz availability; this increases cell survival and cell size, again safeguarding compartment size. The results argue that the gauging of P compartment size is due, at least in part, to cells surviving and growing according to Spi availability. These data offer mechanistic insight into how diffusible molecules control organ size.     

Muscular dystrophy in the Japanese Spitz: an inversion disrupts the DMD and RPGR genes

An X‐linked muscular dystrophy, with deficiency of full‐length dystrophin and expression of a low molecular weight dystrophin‐related protein, has been described in Japanese Spitz dogs. The aim of this study was to identify the causative mutation and develop a specific test to identify affected cases and carrier animals. Gene expression studies in skeletal muscle of an affected animal indicated aberrant expression of the Duchenne muscular dystrophy (dystrophin) gene and an anomaly in intron 19 of the gene. Genome‐walking experiments revealed an inversion that interrupts two genes on the X chromosome, the Duchenne muscular dystrophy gene and the retinitis pigmentosa GTPase regulator gene. All clinically affected dogs and obligate carriers that were tested had the mutant chromosome, and it is concluded that the inversion is the causative mutation for X‐linked muscular dystrophy in the Japanese Spitz breed. A PCR assay that amplifies mutant and wild‐type alleles was developed and proved capable of identifying affected and carrier individuals. Unexpectedly, a 7‐year‐old male animal, which had not previously come to clinical attention, was shown to possess the mutant allele and to have a relatively mild form of the disease. This observation indicates phenotypic heterogeneity in Japanese Spitz muscular dystrophy, a feature described previously in humans and Golden Retrievers. With the availability of a simple, fast and accurate test for Japanese Spitz muscular dystrophy, detection of carrier animals and selected breeding should help eliminate the mutation from the breed.     

Argos mutants define an affinity threshold for spitz inhibition in vivo

Argos, a secreted antagonist of Drosophila epidermal growth factor receptor (dEGFR) signaling, acts by sequestering the activating ligand Spitz. To understand how different domains in Argos contribute to efficient Spitz sequestration, we performed a genetic screen aimed at uncovering modifiers of an Argos misexpression phenotype in the developing eye. We identified a series of suppressors mapping to the Argos transgene that affect its activity in multiple developmental contexts. These point mutations map to both the N- and C-terminal cysteine-rich regions, implicating both domains in Argos function. We show by surface plasmon resonance that these Argos mutants are deficient in their ability to bind Spitz in vitro. Our data indicate that a mere approximately 2-fold decrease in K(D) is sufficient to compromise Argos activity in vivo. This effect could be recapitulated in a cell-based assay, where a higher molar concentration of mutant Argos was needed to inhibit Spitz-dependent dEGFR phosphorylation. In contrast, a approximately 37-fold decrease in the binding constant nearly abolishes Argos activity in vivo and in cellular assays. In agreement with previously reported computational studies, our results define an affinity threshold for optimal Argos inhibition of dEGFR signaling during development.     

Comparison of image analysis with flow cytometry for DNA content analysis in pigmented lesions of the skin.

The DNA ploidy of 85 melanocytic skin lesions was determined by flow cytometry (FCM) and interactive image analysis (IA) using nuclear extracts of paraffin-embedded tissue. Of the 85 lesions analyzed, 43 were malignant melanomas in different stages of evolution, 15 were dysplastic nevi, 11 were Spitz nevi, and 16 were other types of nevi. Some of the last had features of congenital nevi. Within the melanoma category, there was 42% aneuploidy by FCM versus 56% by IA. Of those melanomas aneuploid by FCM, all but one were aneuploid by IA. All dysplastic nevi, 10/11 Spitz nevi and 15/16 other nevi were diploid by both methods. One of the 16 nevi from the "other types" category was tetraploid by IA but diploid by FCM. A single Spitz nevus was tetraploid by FCM but diploid by image analysis. While our results suggest that interactive IA is potentially a more sensitive method than FCM for detecting aneuploidy in cutaneous pigmented lesions, it remains to be shown whether this will translate into better prognostic assessment of the biologic behavior of melanocytic neoplasms than provided by flow cytometric ploidy analysis.