Institute of Molecular Biology, Institute of Neuroscience, Howard Hughes Medical Institute, University of Oregon 1254, Eugene, OR 97403, USA
Author for correspondence (e-mail: cdoe{at}uoneuro.uoregon.edu)
Accepted 3 September 2004
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Summary |
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Key words: Scribble, Polarity, Asymmetry, Neuroblast, Drosophila melanogaster, LAP
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Introduction |
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A modified form of cell polarity is present in Drosophila mitotic neuroblasts, where it is used to generate cellular diversity by asymmetric cell division. Neuroblasts exhibit multiple aspects of asymmetry: they have distinct apical/basal cortical protein domains, an asymmetric mitotic spindle (the apical pole contains a larger centrosome and more extensive astral microtubule network) and divide asymmetrically along an apical/basal axis to regenerate a large neuroblast and bud off a small ganglion mother cell (GMC) (Albertson and Doe, 2003; Kaltschmidt et al., 2000
). The GMC undergoes one subsequent cell division to generate neurons or glia (Goodman and Doe, 1993
). The neuroblast apical domain includes the Par3-Par6-aPKC protein complex; yet unlike epithelial cells, also contains the protein Inscuteable (Insc) which is required to orient the mitotic spindle along the apical/basal axis (Petronczki and Knoblich, 2001
; Schober et al., 1999
; Wodarz et al., 2000
; Wodarz et al., 1999
). Neuroblasts localize several sets of proteins and mRNA to the basal cortex during mitosis: the coiled-coil Miranda (Mira) protein, the transcription factor Prospero (Pros), the RNA-binding protein Staufen, and its cargo pros mRNA form one complex (Hirata et al., 1995
; Ikeshima-Kataoka et al., 1997
; Knoblich et al., 1995
; Shen et al., 1997
; Spana and Doe, 1995
) and Partner of numb (Pon) and Numb form another complex (Lu et al., 1998
; Rhyu et al., 1994
). Formation of the apical cortical domain is necessary for proper basal targeting; loss of Par3-Par6-aPKC components results in a uniform cortical distribution of Pros and Mira at metaphase (Petronczki and Knoblich, 2001
; Schober et al., 1999
; Rolls et al., 2003
; Wodarz et al., 1999
).
Over the last few years it has become clear that the Drosophila tumor suppressor genes - dlg, scrib and lgl - regulate several aspects of neuroblast cell asymmetry (Albertson and Doe, 2003; Ohshiro et al., 2000
; Peng et al., 2000
). In mitotic neuroblasts, Dlg, Scrib and Lgl proteins all show cortical localization with apical enrichment. Dlg is required for Scrib localization (Albertson and Doe, 2003
), but probably binds Scrib indirectly, via the linker protein Gukholder (Gukh). Gukh interacts with both the Dlg GUK domain and the Scrib second PDZ domain (Mathew et al., 2002
), and is co-localized with Dlg and Scrib in mitotic neuroblasts (Albertson and Doe, 2003
). Loss of Dlg, Lgl or Scrib causes a mislocalization of Pros and Mira away from the basal cortex and into the cytoplasm and onto the mitotic spindle (Albertson and Doe, 2003
; Ohshiro et al., 2000
; Peng et al., 2000
). Thus, Dlg/Lgl/Scrib are essential to target Mira to the cell cortex. Scrib also has important roles in promoting spindle asymmetry in neuroblasts and growth control of CNS and imaginal disc tissue (Albertson and Doe, 2003
; Humbert et al., 2003
).
Despite the importance of Dlg, Scrib and Lgl in regulating cellular asymmetry and growth control, little is known about how the proteins operate mechanistically. We have characterized the functional domains of the Scrib protein. Scrib protein has 16 leucine-rich repeats (LRRs) and four Psd95-Dlg-Zo1 (PDZ) domains, and is one of the founding members of the LRR and PDZ (LAP) protein family that includes C. elegans Let-413, rat and human Densin180, and human Erbin and hScrib (Apperson et al., 1996; Bilder and Perrimon, 2000
; Borg et al., 2000
; Legouis et al., 2000
; Nakagawa and Huibregtse, 2000
). In addition, all known LAP proteins contain a LAP-specific domain (LAPSD) containing a 38 amino acid LAPSDa that is similar to LRRs, and a 24 amino acid LAPSDb that is unrelated to LRRs (Santoni et al., 2002
). Both LRR and PDZ domains function as protein-protein interaction motifs (Kobe and Kajava, 2001
; Sheng and Sala, 2001
). In C. elegans, the LRRs are necessary for cortical targeting of the Let-413 protein in epithelia (Legouis et al., 2003
), and in mammals it has been shown that ßPIX binds the PDZ domains of hScrib but not the closely related LAP protein Lano (Audebert et al., 2004
); otherwise very little is known about the function of each domain of any LAP protein.
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Materials and Methods |
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Drosophila genetics
Each UAS-scrib:myc deletion transgene (see above) was crossed into the scrib1 mutant background by standard genetic methods. Flies carrying scabrous-gal4 (Bloomington stock #6479) or worniu-gal4 (the 8 kb upstream sequence of the worniu gene driving expression of gal4) were also crossed into the scrib1 mutant background. scrib1 is reported to be a null allele, and homozygous scrib1 stage 15, or older, embryos show no protein staining with our C-terminal Scrib antisera. Expression of each UAS-scrib:myc transgene was assayed in progeny from UAS-scrib:myc; scrib1/TM3, ftzlacZ crossed to scabrous- or worniu-gal4; scrib1/TM3, ftzlacZ crosses. scrib mutant embryos were identified by the lack of anti-ß-galactosidase staining, while Scrib:myc proteins were detected by anti-Myc staining.
Immunohistochemistry, western blots, and quantification
Embryos were collected and fixed according to the method of Albertson and Doe (Albertson and Doe, 2003). Primary antibodies were used at 1:1000, except where indicated: rabbit and mouse anti-Scrib C-terminal polyclonal antibody (1:2500) (Albertson and Doe, 2003
), rabbit and mouse anti-Myc (Santa Cruz), rabbit anti-phosphohistone H3 (1:1500; Upstate), mouse anti-
-tubulin (1:3000), rat anti-Mira (1:500), rabbit and rat anti-ß-galactosidase (1:1500; Cappel), rat anti-aPKC (1:500), and mouse anti-Dlg (1:500). Western blot analysis followed the method of Srinivasan et al. (Srinivasan et al., 1998
) using sca-gal4, UAS-scrib:myc embryos grown at 29°C. Cell size quantitation was done by averaging the longest axis and the orthogonal axis of the apical or basal cortical domain in telophase neuroblasts.
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Results |
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We analyzed the localization and function of all Scrib:myc deletion transgenes in a scrib1/scrib1 homozygous mutant background (Figs 2, 3, 4), with the exception of the PDZ2 protein which was analyzed in a wild-type background (see Fig. S1 in supplementary material). Maternally provided Scrib protein is detectable in scrib1/scrib1 embryos up to embryonic stage 14, but not at stage 15 (Albertson and Doe, 2003
), so we only assay Scrib:myc localization and function in scrib1/scrib1 embryos at stage 15 or later.
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Distinct Scrib domains regulate cortical and apical protein targeting in neuroblasts
Endogenous Scrib protein is cortical in neuroblasts, with apical enrichment from late interphase into metaphase (Fig. 2A) (Albertson and Doe, 2003). To determine the domains of Scrib that regulate cortical and apical targeting, we assayed localization of each Scrib:myc protein in scrib mutant neuroblasts at embryonic stage 15 (Fig. 2A-H, quantified in Fig. 2I). Full length Scrib (FL) and Scrib lacking the carboxyl-terminal domain (
CT) showed normal localization in metaphase and interphase neuroblasts, in both scrib mutants (Fig. 2B,C) and wild type (data not shown). This indicates that the LRR and PDZ domains are sufficient for normal Scrib localization in neuroblasts and that the extensive C-terminal domain is not required for Scrib localization.
The two Scrib proteins that lack the PDZ domains (LRR and PDZ proteins) showed uniform cortical association with occasional weak apical enrichment in metaphase neuroblasts, in both scrib mutant neuroblasts (Fig. 2D,E; left panels) and wild-type neuroblasts (data not shown). However, they showed different localization in interphase neuroblasts: the
PDZ protein is cortical and cytoplasmic, whereas the LRR protein is cortical and nuclear (Fig. 2D,E; center panels). The difference in nuclear/cytoplasmic localization may be regulated by the LAPSDb domain, which is present in the
PDZ protein but not the LRR protein (see Discussion).
Next we wanted to test the role of PDZ2 in Scrib protein localization, because Scrib PDZ2 binds the Gukh protein (Mathew et al., 2002) and Gukh and Scrib are co-localized at the apical cortex of neuroblasts (Albertson and Doe, 2003
). We made a scrib transgene lacking only the second PDZ (
PDZ2) and found that this Scrib protein shows weak apical enrichment and cytoplasmic localization in mitotic neuroblasts, similar to the Scrib protein lacking all four PDZ domains (see Fig. S1 in supplementary material). Thus, the Scrib PDZ2 is essential for proper cortical and apical localization of the Scrib protein.
The three Scrib proteins that lack the LRRs are cytoplasmic at all stages of the cell cycle in scrib mutant neuroblasts (Fig. 2F-H) and wild-type neuroblasts (data not shown). Thus, the LRR domain is necessary and sufficient for cortical localization. It may also play a minor role in apical targeting, because Scrib proteins containing the LRR only (LRR, PDZ,
PDZ2) show weak apical enrichment in a minority of neuroblasts.
We have been unable to generate a Scrib transgenic line that specifically lacks the LAPSDa or LAPSDb, but we can draw several conclusions from our existing Scrib deletion transgenic lines. First, the Scrib LRR protein lacks the LAPSDb domain and yet is still targeted to the cortex in mitotic neuroblasts; thus, the LAPSDb is not required for Scrib cortical targeting in neuroblasts. Second, LAPSDb domain may have a function in regulating nuclear localization of Scrib: the LRR protein missing LAPSDb is nuclear, whereas the closely related PDZ protein containing LAPSDb is excluded from the nucleus; thus the LAPSDb may provide a nuclear export signal or mask a nuclear import signal within the Scrib LRR protein (see Discussion). Third, the Scrib
PDZ and
PDZ2 proteins contain both LAPSDa and LAPSDb domains and localize to the neuroblast cortex, yet they fail to be apically enriched in mitotic neuroblasts; thus, the paired LAPSDa/b domains are not sufficient for proper apical Scrib localization.
The LRR and PDZ2 domains are both required for Scrib localization in epithelia
Endogenous Scrib is targeted to the septate junction and lateral membrane domain in epithelia (Fig. 2A) (Bilder and Perrimon, 2000). We assayed the localization of Scrib:myc proteins in scrib mutant epithelia (Fig. 2; right column). The same patterns were seen in wild-type epithelia containing endogenous Scrib protein (data not shown). We found that Scrib proteins that contain both LRR and PDZ domains (i.e. FL and
CT) show normal localization to the lateral membrane and enrichment at the septate junction (Fig. 2B,C), indicating the C-terminal region is dispensable for proper Scrib localization in epithelia.
In contrast, Scrib proteins that lack PDZ domains (LRR, PDZ,
PDZ2 proteins) or lack the LRR domain (PDZ,
LRR) showed only weak localization to septate junctions (Fig. 2D-G; see Fig. S1 in supplementary material). The LRR protein was detected in the nucleus (Fig. 2D), while the
PDZ and
PDZ2 proteins were cytoplasmic (Fig. 2E; see Fig. S1 in supplementary material), similar to the localization of each protein in interphase neuroblasts. Finally, the Scrib CT protein that lacks both LRR and PDZ domains was completely cytoplasmic (Fig. 2H). Taken together, we conclude that both LRR and PDZ2 domains are required for efficient targeting of Scrib to the lateral membrane and septate junctions of epithelial cells. We can also conclude that the LAPSDa and LAPSDb domains, which are both present in the
PDZ and
PDZ2 proteins (and each present in the LRR and
LRR proteins, respectively), are insufficient for normal Scrib targeting in epithelia.
Mira requires Scrib LRRs for cortical targeting and Scrib PDZ domains for efficient basal localization
Scrib is required to target the Mira cell fate scaffolding protein to the basal cortex of mitotic neuroblasts; in scrib mutants Mira accumulates in the cytoplasm, on the mitotic spindle and uniformly around the cortex (Fig. 3A,B) (Albertson and Doe, 2003). We expressed different Scrib domains in scrib mutant neuroblasts and scored for rescue of proper Mira localization (Fig. 3C-I). We found that only the Scrib proteins containing both LRR and PDZ domains (i.e. FL and
CT, both apically enriched; Fig. 2) have the ability to fully rescue Mira basal localization (Fig. 3C,D). Thus, the extensive C-terminal Scrib domain is unnecessary for proper Mira localization.
Scrib proteins containing LRR but not PDZ domains (i.e. LRR or PDZ; both cortical with weak apical enrichment; Fig. 2) can fully restore Mira cortical localization but only partially rescue basal localization (Fig. 3E,F). Mira was either uniformly cortical (58% and 38% in LRR and
PDZ proteins, respectively) or formed an expanded basal crescent that is not properly excluded from the apical cortical domain (Fig. 3E,F). This shows that the LRR domain alone is sufficient to promote Mira cortical localization, but is inefficient in restricting Mira to the basal cortex. This could be due to the lower levels of the Scrib LRR protein at the apical cortex or because it lacks a specific function provided by the PDZ domains (see Discussion). Furthermore, the LAPSDa/b domains, which are both present in the
PDZ protein, are not sufficient for basal targeting of Mira; and deletion of the LAPSDb domain (in the LRR protein) does not block Mira cortical localization.
All Scrib proteins lacking the LRR domain are cytoplasmic (Fig. 2) and are non-functional for Mira localization (Fig. 3G-I), even if they contain most of the LAPSDa/b domains. We conclude that the LRR domain is necessary and sufficient for cortical Mira targeting; that both LRR and PDZ domains are necessary for efficient basal Mira targeting; and that the LAPSDa/b domains are not sufficient for Mira basal targeting.
We also tested the effect of each Scrib domain on the localization of several other neuroblast cell polarity markers. Wild-type neuroblasts show apical localization of the Bazooka-Par6-aPKC-Insc-Pins complex, and apical enrichment of the Dlg-Gukh-Scrib-Lgl proteins. We assayed aPKC as a representative of the first complex and Dlg as the most `upstream' component of the second group (Fig. 4). In scrib zygotic mutant stage 15 neuroblasts we found that aPKC and Dlg are normally localized to the apical cortex (Albertson and Doe, 2003; Kaltschmidt et al., 2000
) (data not shown); expression of each Scrib domain has no effect on the apical localization of either aPKC or Dlg (Fig. 4). We conclude all tested Scrib domains had no deleterious effect on apical cortical polarity in neuroblasts.
Scrib LRR and PDZ domains cooperate to establish cell size asymmetry and spindle asymmetry
In scrib mutants only 65% of the neuroblasts have normal mitotic spindle and cell size asymmetry at telophase, compared to over 95% of wild-type neuroblasts (Fig. 5) (Albertson and Doe, 2003). We assessed the ability of each Scrib domain to rescue the scrib mutant cell size and spindle asymmetry defects. Expression of FL and
CT proteins significantly restores normal cell size asymmetry (91% and 85% normal; Fig. 5), indicating the C-terminal region is not required for this aspect of Scrib function. In contrast, proteins lacking the LRR or PDZ domains were unable to re-establish proper cell size asymmetry: we observed a similar percentage of symmetric and inverted telophase neuroblasts as compared to scrib mutant embryos (66%-73% normal divisions verses 65% normal in scrib embryos; Fig. 5). The presence of the LAPSDa/b domains (e.g. in the
PDZ protein) were unable to rescue this phenotype. We conclude that both the LRR and PDZ domains are required for establishing mitotic spindle and cell size asymmetry in neuroblasts, and that LRRs, PDZs or LAPSDa/b domains individually are not sufficient to confer cell size and mitotic spindle asymmetry.
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Discussion |
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Scrib PDZ2 is required for efficient apical targeting in neuroblasts
Scrib proteins lacking all four PDZ domains, or just PDZ2, are detected in the cytoplasm and uniformly around the neuroblast cortex, with only occasional weak apical enrichment. Scrib PDZ2 is likely to target Scrib to the neuroblast cortex, and more specifically to the apical neuroblast cortex, by associating with Gukh and Dlg proteins. Gukh binds to both Scrib PDZ2 and Dlg (Albertson and Doe, 2003; Mathew et al., 2002
); Scrib, Gukh and Dlg are all co-localized at the neuroblast cortex (Albertson and Doe, 2003
); dlg mutants have cytoplasmic Scrib protein (Albertson and Doe, 2003
). One simple model consistent with these data is that Dlg binds Gukh, which binds Scrib PDZ2, resulting in the observed localization of Scrib within neuroblasts. Nevertheless, the PDZ domains are not sufficient for proper Scrib localization: Scrib proteins that contain the PDZs but lack the LRRs (
LRR or PDZ) are completely cytoplasmic. We propose a two-step model for Scrib localization in which Scrib LRR-dependent cortical localization precedes and is a prerequisite for Scrib PDZ2-dependent apical enrichment. We note that proteins lacking all four PDZ domains still show weak apical enrichment in some neuroblasts, however, indicating a minor role for the LRR domain in apical Scrib targeting.
Our data suggest a mechanism in which Scrib neuroblast and epithelial localization involves distinct steps, moving from cytoplasm to cortex then apically. Other proteins targeted to specific cortical domains within neuroblasts show a similar cortical-to-asymmetric localization mechanism. The Insc protein contains a 158 aa region that directs Insc to the neuroblast cortex; the addition of a separate 100 aa domain confers apical localization (Knoblich et al., 1999; Yu et al., 2002
). Similarly, the Pins protein contains four C-terminal GoLoco repeats that are sufficient for cortical localization, but addition of the first three of seven N-terminal tetratricopeptide repeats (TPRs) is required for asymmetric apical targeting (Yu et al., 2002
). Stepwise targeting of Dlg has also been observed in epithelia and neuromuscular junctions. In epithelia, the Hook domain targets Dlg to the cell cortex while PDZ2 is required to restrict Dlg to the septate junction (Hough et al., 1997
). At neuromuscular junctions, the Hook domain is necessary to localize Dlg to the plasma membrane and both PDZ1 and PDZ2 domains promote transport to the synapse (Thomas et al., 2000
). These observations suggest cortical localization may be a prerequisite for subsequent targeting to specific membrane domains and raise the possibility that similar transport mechanisms are shared among protein complexes in neuroblasts, epithelia and synapses.
Despite the fact that Scrib has a plethora of protein-protein interaction motifs, only one binding partner for Drosophila Scrib has been identified, Gukh, which binds to Scrib PDZ2 (Mathew et al., 2002). Binding assays such as yeast two-hybrid assays and mass spectrometry will be essential to identify additional Drosophila Scrib binding partners, as has been shown for mammalian LAP proteins (Audebert et al., 2004
). Such discoveries will enable us to determine upstream and downstream players in Scrib-mediated pathways and will further our knowledge of many cellular functions, including establishment of epithelial cell polarity, stem cell division, mitotic spindle biology, cell cycle progression and synapse formation and homeostasis.
Scrib LRR and PDZ domains are required for efficient septate junction targeting in epithelia
Scrib proteins lacking LRRs fail to be properly targeted to the lateral membrane and septate junctions of mature epithelial cells, whereas Scrib proteins lacking all four PDZ domains, or just PDZ2, still show some septate junction enrichment with an elevated level of cytoplasmic protein. Thus, the LRR domains are the primary determinant of cortical/septate junction targeting, and PDZ2 increases the efficiency or stability of this localization. Scrib localization in epithelia also requires Dlg (Bilder and Perrimon, 2000), but the role of the Dlg and Scrib PDZ2-binding protein Gukh have not been examined in epithelia. We could not test the ability of each Scrib domain to establish or maintain epithelial polarity in this system, however, because zygotic scrib mutant embryos develop normal epithelial polarity because of maternally derived Scrib protein (even though there is no detectable maternal Scrib protein in stage 15 or later embryos).
The proteins that interact with the Scrib LRRs to mediate cortical association in epithelia are unknown. More is known about the role of PDZ domains in junctional targeting of LAP proteins. The mammalian LAP proteins Erbin and Densin180 show PDZ-mediated interactions with p120-catenins (Izawa et al., 2002a; Izawa et al., 2002b
; Jaulin-Bastard et al., 2002
; Laura et al., 2002
), and Erbin-catenin p0071 colocalize to adherens junctions and desmosomes in cultured epithelial cells (Izawa et al., 2002b
; Jaulin-Bastard et al., 2002
). Disruption of Erbin-p0071 interactions leads to aberrant cell morphology and disruption of cell-cell contacts (Jaulin-Bastard et al., 2002
). Similarly, Drosophila Scrib is required for proper morphology and formation of septate junctions in epithelia (Bilder and Perrimon, 2000
), and we find the PDZ domains are necessary for efficient Scrib localization to the epithelial cell septate junctions. Thus, Drosophila catenins are excellent candidates for recruiting Scrib to the septate junction.
Distinct Scrib domains regulate cortical and basal targeting of Mira
In the absence of all Scrib function, Mira is predominantly localized to the cytoplasm and mitotic spindle of neuroblasts. Expression of just the Scrib LRR domain results in uniform cortical Scrib LRR distribution and the restoration of uniform cortical Mira localization. Conversely, all Scrib proteins that lack the LRR domain (PDZ, LRR and CT) fail to efficiently target Mira to the cortex. These results reveal a positive role for the Scrib LRR domain in targeting Mira to all regions of the neuroblast cortex. A similar `uniform cortical Mira' phenotype is also observed in certain aPKC and lgl genetic backgrounds. Neuroblasts lacking aPKC show uniform cortical Mira (Rolls et al., 2003
) and neuroblasts misexpressing a dephospho-Lgl protein also show uniform cortical Mira (Betschinger et al., 2003
). In addition, loss of lgl leads to cytoplasmic Mira localization in neuroblasts (Albertson and Doe, 2003
; Ohshiro et al., 2000
; Peng et al., 2000
). This has led to a model in which the apically-localized aPKC phosphorylates Lgl to inactivate it, thus restricting active dephospho-Lgl to the basal cortex, where it promotes cortical localization of Mira (Betschinger et al., 2003
). The Scrib LRRs could act upstream of aPKC and Lgl, perhaps by blocking aPKC/Lgl interactions, and thus allowing activated Lgl to target Mira to the entire cortex. Alternatively, the Scrib LRRs could act downstream of aPKC and Lgl, perhaps by allowing both dephospho- and phospho-Lgl to target Mira to the cortex. In addition, loss of jaguar (myosin VI) leads to cytoplasmic localization of Mira (Petritsch et al., 2003
), raising the possibility that the Scrib LRRs could stimulate myosin VI activity around the neuroblast cortex to promote uniform cortical Mira localization. The identification of Scrib LRR-binding proteins will help distinguish between these models.
Addition of the PDZ domains back to the Scrib LRR protein dramatically alters the function of the protein. Whereas the Scrib LRR protein is uniformly cortical and promotes Mira cortical localization, Scrib LRR+PDZ proteins (FL, CT) are apically enriched and exclude Mira from the apical cortex. Thus, addition of the PDZ domains switches Scrib from promoting cortical Mira localization to excluding cortical Mira localization. The PDZ domains could carry out this function of excluding Mira from the apical cortex in at least three different ways. (1) The Scrib PDZ domains could promote aPKC-Lgl interactions, thereby leading to the phosphorylation and inactivation of apical Lgl (Betschinger et al., 2003
); this would restrict active Lgl to the basal cortex, where it promotes cortical Mira localization. (2) The Scrib PDZ domains could promote myosin II (zipper) activity at the apical cortex; myosin II is a known inhibitor of Lgl (Ohshiro et al., 2000
; Peng et al., 2000b), and thus this would restrict active Lgl to the basal cortex where it could promote cortical Mira localization. (3) The Scrib PDZ domains could provide directionality to the actin-myosin VI cytoskeleton, which could transport Mira specifically to the basal cortex (Petritsch et al., 2003
). Identification of proteins that interact with the Scrib PDZ domains would help distinguish between these models.
Scrib LRR and PDZ domains are both required to establish mitotic spindle and cell size asymmetry
Little is known about how Dlg, Scrib and Lgl regulate cell size asymmetry and spindle asymmetry. We show both LRR and PDZ domains of Scrib are necessary for this function. How might Scrib regulate cell size and spindle asymmetry? Two good candidate effectors are Ran GTPase and Pins. LRRs are known to physically interact with Ran, which promotes spindle assembly through several target proteins (Dasso, 2001; Haberland et al., 1997
; Haberland and Gerke, 1999
). For example, Ran stimulates the activity of NuMA (a microtubule motor accessory protein that promotes spindle assembly) by destabilizing inhibitory complexes associated with NuMA (Dasso, 2001
; Dasso, 2002
; Nachury et al., 2001
; Wiese et al., 2001
). LGN (a mammalian Pins homolog) is essential for mitotic spindle assembly and binds NuMA; release from LGN is an important event in the activation of mitotic NuMA (Dasso, 2002
; Du et al., 2001
; Du et al., 2002
). In Drosophila, Pins physically interacts with Dlg and is asymmetrically localized to the apical cortex of mitotic neuroblasts, where it promotes spindle asymmetry (Bellaiche et al., 2001
; Cai et al., 2003
; Parmentier et al., 2000
; Schaefer et al., 2000
). These data suggest possible links between Dlg, Scrib, Ran and Pins and establishment of mitotic spindle asymmetry. Genetic and biochemical studies investigating interactions between Scrib, Ran and Pins may further our understanding of spindle asymmetry establishment in Drosophila neuroblasts.
The role of the LAPSDa/b and CT domains
Deletion of the CT domain has no effect on Scrib localization or its ability to rescue all tested scrib mutant phenotypes in neuroblasts; the CT domain alone is cytoplasmic and has no rescuing ability in any assay that we performed. We conclude that the CT domain is not essential for any aspect of Scrib localization or function that we have tested (summarized in Table 1).
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We have not assayed a scrib transgenic line that specifically lacks the LAPSDa/b domains, however, we can draw some conclusions based on our existing Scrib domain analysis. The Scrib PDZ protein contains both LAPSDa/b domains is membrane targeted but not enriched apically, it fails to promote basal Mira targeting, and it is defective for asymmetric mitotic spindle and cell size asymmetry. Thus, the LAPSD domains are insufficient for apical enrichment of Scrib and all of its tested functions in neuroblasts. The Scrib LRR protein lacking the LAPSDb domain is still membrane-associated, showing that the LAPSDb domain is not required for Scrib membrane targeting. We did find some evidence that the LAPSDb domain regulates nuclear import/export of the Scrib protein. The LRR protein contains just the LRRs and the LAPSDa domain and is targeted to the nucleus; this shows that there is a nuclear import signal or binding site for a nuclear protein within the LRR/LAPSDa domains, although a predicted nuclear localization signal is not detectable within these domains. In contrast, the
PDZ protein contains the same LRR/LAPSDa domains plus the LAPSDb and CT domains, and it is excluded from the nucleus. This shows that the LAPSDb or CT domains can prevent nuclear import of the LRR/LAPSDa protein; is highly likely that this function is provided by the LAPSDb domain, because deletion of the CT domain from an otherwise wild-type Scrib protein (i.e.
CT) does not result in nuclear localization. Our results are in contrast to the role of the LAPSDa/b domains in the related C. elegans Let-413 protein, where the LAPSDa/b domains are required for establishing epithelial polarity but not Let-413 protein localization (Legouis et al., 2003
). It will be interesting to determine whether the Scrib LAPSDa/b domains play a similar role in Scrib epithelial localization.
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Acknowledgments |
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Footnotes |
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* Present address: Department of Biology, University of California, Santa Cruz, CA 95064, USA
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References |
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