discs large 1: Biological Overview | Evolutionary Homologs | Regulation | Developmental Biology | Effects of Mutation | References
Gene name - discs large 1

Synonyms -

Cytological map position - 10B8

Function - links septate junctions to cytoskeleton

Key words - cytoskeleton - septate junctions - imaginal discs, asymmetric cell division, apical/basal polarity, tumor suppressor

Symbol - dlg1

FlyBase ID: FBgn0001624

Genetic map position - 1-34.8

Classification - Guanylate kinase signature and Src homology 3 (SH3) domain

Cellular location - cytoplasmic



NCBI links: Entrez Gene

discs large 1 orthologs: Biolitmine

Recent literature
Zandany, N., Marciano, S., Magidovich, E., Frimerman, T., Yehezkel, R., Shem-Ad, T., Lewin, L., Abdu, U., Orr, I. and Yifrach, O. (2015). Alternative splicing modulates Kv channel clustering through a molecular ball and chain mechanism. Nat Commun 6: 6488. PubMed ID: 25813388
Summary:
Ion channel clustering at the post-synaptic density serves a fundamental role in action potential generation and transmission. This study shows that interaction between the Shaker Kv channel and the PSD-95 scaffold protein underlying channel clustering is modulated by the length of the intrinsically disordered C terminal channel tail. It was further shown that this tail functions as an entropic clock that times PSD-95 binding. A 'ball and chain' mechanism is proposed to explain Kv channel binding to scaffold proteins, analogous to the mechanism describing channel fast inactivation. The physiological relevance of this mechanism is demonstrated in that alternative splicing of the Shaker channel gene to produce variants of distinct tail lengths resulted in differential channel cell surface expression levels and clustering metrics that correlate with differences in affinity of the variants for PSD-95. It is suggested that modulating channel clustering by specific spatial-temporal spliced variant targeting serves a fundamental role in nervous system development and tuning.
Xiong, X.P., Kurthkoti, K., Chang, K.Y., Li, J.L., Ren, X., Ni, J.Q., Rana, T.M. and Zhou, R. (2016). miR-34 modulates innate immunity and ecdysone signaling in Drosophila. PLoS Pathog 12: e1006034. PubMed ID: 27893816
Summary:
microRNAs are endogenous small regulatory RNAs that modulate myriad biological processes by repressing target gene expression in a sequence-specific manner. This study shows that the conserved miRNA miR-34 regulates innate immunity and ecdysone signaling in Drosophila. miR-34 over-expression activates antibacterial innate immunity signaling both in cultured cells and in vivo, and flies over-expressing miR-34 display improved survival and pathogen clearance upon Gram-negative bacterial infection; whereas miR-34 knockout animals are defective in antibacterial defense. In particular, miR-34 achieves its immune-stimulatory function, at least in part, by repressing the two novel target genes Dlg1 and Eip75B. In addition, there exists a mutual repression between miR-34 expression and ecdysone signaling, and miR-34 acts as a node in the intricate interplay between ecdysone signaling and innate immunity. Lastly, the cis-regulatory genomic elements and trans-acting transcription factors required for optimal ecdysone-mediated repression of miR-34 were identified. Taken together, these data enrich the repertoire of immune-modulating miRNAs in animals, and provide new insights into the interplay between steroid hormone signaling and innate immunity.

Golub, O., Wee, B., Newman, R. A., Paterson, N. M. and Prehoda, K. E. (2017). Activation of Discs large by aPKC aligns the mitotic spindle to the polarity axis during asymmetric cell division. Elife 6. PubMed ID: 29185419
Summary:
Asymmetric division generates cellular diversity by producing daughter cells with different fates. In animals, the mitotic spindle aligns with Par complex polarized fate determinants, ensuring that fate determinant cortical domains are bisected by the cleavage furrow. This study investigated the mechanisms that couple spindle orientation to polarity during asymmetric cell division of Drosophila neuroblasts. The tumor suppressor Discs large (Dlg) was found to link the Par complex component atypical Protein Kinase C (aPKC) to the essential spindle orientation factor GukHolder (GukH). Dlg is autoinhibited by an intramolecular interaction between its SH3 and GK domains, preventing Dlg interaction with GukH at cortical sites lacking aPKC. When co-localized with aPKC, Dlg is phosphorylated in its SH3 domain which disrupts autoinhibition and allows GukH recruitment by the GK domain. This work establishes a molecular connection between the polarity and spindle orientation machineries during asymmetric cell division.
Caria, S., Magtoto, C. M., Samiei, T., Portela, M., Lim, K. Y. B., How, J. Y., Stewart, B. Z., Humbert, P. O., Richardson, H. E. and Kvansakul, M. (2018). Drosophila melanogaster Guk-holder interacts with the Scribbled PDZ1 domain and regulates epithelial development with Scribbled and Discs Large. J Biol Chem [Epub ahead of print]. PubMed ID: 29378849
Summary:
Epithelial cell polarity is controlled by components of the Scribble polarity module, and its regulation is critical for tissue architecture and cell proliferation and cell migration. In Drosophila melanogaster, the adaptor protein Guk-holder (Gukh) binds to the Scribbled (Scrib) and Discs Large (Dlg) components of the Scribble polarity module and plays an important role in the formation of neuromuscular junctions. However, Gukhs role in epithelial tissue formation and the molecular basis for the Scrib-Gukh interaction remain to be defined. This study shows using isothermal titration calorimetry that the Scrib PDZ1 domain is the major site for an interaction with Gukh. Furthermore, the structural basis of this interaction is defined by determining the crystal structure of the Scrib PDZ1-Gukh complex. The C-terminal PDZ-binding motif of Gukh is located in the canonical ligand binding groove of Scrib PDZ1, and utilizes an unusually extensive network of hydrogen bonds and ionic interactions to enable binding to PDZ1 with high affinity. The roles of Gukh along with those of Scrib and Dlg were examined in Drosophila epithelial tissues, and found Gukh was found to be expressed in larval-wing and eye-epithelial tissues and co-localizes with Scrib and Dlg at the apical cell cortex. Importantly, it was shown that Gukh functions with Scrib and Dlg in the development of Drosophila epithelial tissues, with depletion of Gukh enhancing the eye- and wing-tissue defects caused by Scrib or Dlg depletion. Overall these findings reveal that Scribs PDZ1 domain functions in the interaction with Gukh and that the Scrib-Gukh interaction has a key role in epithelial tissue development in Drosophila.
Papagiannouli, F., Berry, C. W. and Fuller, M. T. (2019). The Dlg module and Clathrin-mediated endocytosis regulate EGFR signaling and cyst cell-germline coordination in the Drosophila testis. Stem Cell Reports. PubMed ID: 31006632
Summary:
Tissue homeostasis and repair relies on proper communication of stem cells and their differentiating daughters with the local tissue microenvironment. In the Drosophila male germline adult stem cell lineage, germ cells proliferate and progressively differentiate enclosed in supportive somatic cyst cells, forming a small organoid, the functional unit of differentiation. This study show that cell polarity and vesicle trafficking influence signal transduction in cyst cells, with profound effects on the germ cells they enclose. The data suggest that the cortical components Dlg, Scrib, Lgl and the clathrin-mediated endocytic (CME) machinery downregulate epidermal growth factor receptor (EGFR) signaling. Knockdown of dlg, scrib, lgl, or CME components in cyst cells resulted in germ cell death, similar to increased signal transduction via the EGFR, while lowering EGFR or downstream signaling components rescued the defects. This work provides insights into how cell polarity and endocytosis cooperate to regulate signal transduction and sculpt developing tissues.
Sharifkhodaei, Z., Gilbert, M. M. and Auld, V. J. (2019). Scribble and Discs-large mediate tricellular junction formation. Development. PubMed ID: 31444218
Summary:
Junctional complexes that mediate cell adhesion are key to epithelial integrity, cell division and permeability barriers formation. In Drosophila the scaffolding proteins Scribble (Scrib) and Discs-large (Dlg) are key regulators of epithelial polarity, proliferation, assembly of junctions, and protein trafficking. This study found that Scrib and Dlg are necessary for the formation of the tricellular junction (TCJ), a unique junction that forms in epithelia at the convergence of three neighbouring cells. Scrib and Dlg are in close proximity with the TCJ proteins Gliotactin (Gli) and Bark-beetle (Bark) and both are required for TCJ protein recruitment. Loss of Bark or Gli lead to the basolateral spread of the TCJ complex at the cell corners. Loss of the septate junction proteins NrxIV and the Na(+)/K(+) ATPase also resulted in the basolateral spread of the entire TCJ complex at the cell corners. The Scrib PDZ1-2 domains and the Dlg GUK domain are necessary for Bark and Gli localization to the TCJ. Overall, a model is proposed where Scrib and Dlg are key components of the TCJ, and form a complex with Bark and Gli.
Strah, N., Romano, G., Introna, C., Klima, R., Marzullo, M., Ciapponi, L., Megighian, A., Nizzardo, M. and Feiguin, F. (2020). TDP-43 promotes the formation of neuromuscular synapses through the regulation of Disc-large expression in Drosophila skeletal muscles. BMC Biol 18(1): 34. PubMed ID: 32216790
Summary:
The ribonuclear protein TDP-43 has been implicated in the pathophysiology of amyotrophic lateral sclerosis (ALS), with genetic mutations being linked to the neurological symptoms of the disease. Alterations in the intracellular distribution of TDP-43 have been observed in skeletal muscles of patients suffering from ALS and the molecular and metabolic pathways regulated by TDP-43 in the skeletal muscle remain largely unknown. This study analyzed the function of TBPH, the Drosophila melanogaster ortholog of TDP-43, in skeletal muscles. The activity of TDP-43 in Drosophila muscles was modulated by means of RNA interference, and it was observed to be required to promote the formation and growth of neuromuscular synapses. TDP-43 regulated the expression levels of Disc-large (Dlg), and restoring Dlg expression either in skeletal muscles or in motoneurons was sufficient to suppress the locomotive and synaptic defects of TDP-43-null flies. These results were validated by the observation of a decrease in Dlg levels in human neuroblastoma cells and iPSC-differentiated motoneurons derived from ALS patients, suggesting similar mechanisms may potentially be involved in the pathophysiology of the disease. These results help to unveil the physiological role of TDP-43 in skeletal muscles as well as the mechanisms responsible for the autonomous and non-autonomous behavior of this protein concerning the organization of neuromuscular synapses.
Tamberg, L., Jaago, M., Saalik, K. L., Sirp, A., Tuvikene, J., Shubina, A., Kiir, C. S., Nurm, K., Sepp, M., Timmusk, T. and Palgi, M. (2020). Daughterless, the Drosophila orthologue of TCF4, is required for associative learning and maintenance of synaptic proteome. Dis Model Mech. PubMed ID: 32641419
Summary:
Mammalian Transcription Factor 4 (TCF4) has been linked to schizophrenia and intellectual disabilities like Pitt-Hopkins syndrome (PTHS). This study shows that similarly to mammalian TCF4, fruit fly orthologue Daughterless (Da) is expressed widely in the Drosophila brain. Furthermore, silencing of da, using several central nervous system-specific Gal4 driver lines, impairs appetitive associative learning of the larvae and leads to decreased levels of the synaptic proteins Synapsin (Syn) and Discs large 1 (Dlg1) suggesting the involvement of Da in memory formation. This study demonstrates that Syn and dlg1 are direct target genes of Da in adult Drosophila heads, since Da binds to the regulatory regions of these genes and the modulation of Da levels alter the levels of Syn and dlg1 mRNA. Silencing of da also affects negative geotaxis of the adult flies suggesting the impairment of locomotor function. Overall, these findings suggest that Da regulates Drosophila larval memory and adult negative geotaxis possibly via its synaptic target genes Syn and dlg1 These behavioural phenotypes can be further used as a PTHS model to screen for therapeutics.
Lu, J., Dong, W., Tao, Y. and Hong, Y. (2021). Electrostatic plasma membrane targeting contributes to Dlg function in cell polarity and tumorigenesis. Development. PubMed ID: 33688074
Summary:
Discs large (Dlg) is an essential polarity protein and a tumor suppressor originally characterized in Drosophila but is also well conserved in vertebrates. Like the majority of polarity proteins, plasma membrane (PM)/cortical localization of Dlg is required for its function in polarity and tumorigenesis, but the exact mechanisms targeting Dlg to PM remain to be fully elucidated. This study shows that, similar to the recently discovered polybasic polarity proteins such as Lgl and aPKC, Dlg also contains a positively charged polybasic domain that electrostatically binds the PM phosphoinositides PI4P and PI(4,5)P(2). Electrostatic targeting by the polybasic domain contributes significantly to the PM localization of Dlg in follicular and early embryonic epithelial cells, and is crucial for Dlg to regulate both polarity and tumorigenesis. The electrostatic PM targeting of Dlg is controlled by a potential phosphorylation-dependent allosteric regulation of its polybasic domain, and is specifically enhanced by the interactions between Dlg and another basolateral polarity protein and tumor suppressor Scrib. These studies highlight an increasingly significant role of electrostatic PM targeting of polarity proteins in regulating cell polarity.
Schiller, E. A. and Bergstralh, D. T. (2021). Interaction between Discs large and Pins/LGN/GPSM2: A comparison across species. Biol Open. PubMed ID: 34596678
Summary:
The orientation of the mitotic spindle determines the direction of cell division, and therefore contributes to tissue shape and cell fate. Interaction between the multifunctional scaffolding protein Discs large (Dlg) and the canonical spindle orienting factor GPSM2 (called Pins in Drosophila and LGN in vertebrates) has been established in bilaterian models, but its function remains unclear. A phylogenetic approach was used to test whether the interaction is obligate in animals, and in particular whether Pins/LGN/GPSM2 evolved in multicellular organisms as a Dlg-binding protein. This study shows that Dlg diverged in C. elegans and the syncytial sponge O. minuta and proposes that this divergence may correspond to differences in spindle orientation requirements between these organisms and the canonical pathways described in bilaterians. It was also demonstrated that Pins/LGN/GPSM2 is present in basal animals, but the established Dlg-interaction site cannot be found in either Placozoa or Porifera. These results suggest that the interaction between Pins/LGN/GPSM2 and Dlg appeared in Cnidaria, and it is therefore speculated that it may have evolved to promote accurate division orientation in the nervous system. This work reveals the evolutionary history of the Pins/LGN/GPSM2-Dlg interaction and suggests new possibilities for its importance in spindle orientation during epithelial and neural tissue development.
Sharp, K. A., Khoury, M. J., Wirtz-Peitz, F. and Bilder, D. (2021). Evidence for a nuclear role for Drosophila Dlg as a regulator of the NURF complex. Mol Biol Cell 32(21): ar23. PubMed ID: 34495684.
Summary:
Scribble (Scrib), Discs-large (Dlg), and Lethal giant larvae (Lgl) are basolateral regulators of epithelial polarity and tumor suppressors whose molecular mechanisms of action remain unclear. This study used proximity biotinylation to identify proteins localized near Dlg in the Drosophila wing imaginal disc epithelium. In addition to expected membrane- and cytoskeleton-associated protein classes, nuclear proteins were prevalent in the resulting mass spectrometry dataset, including all four members of the nucleosome remodeling factor (NURF) chromatin remodeling complex. Subcellular fractionation demonstrated a nuclear pool of Dlg and proximity ligation confirmed its position near the NURF complex. Genetic analysis showed that NURF activity is also required for the overgrowth of dlg tumors, and this growth suppression correlated with a reduction in Hippo pathway gene expression. Together, these data suggest a nuclear role for Dlg in regulating chromatin and transcription through a more direct mechanism than previously thought.
Khoury, M. J. and Bilder, D. (2022). Minimal functional domains of the core polarity regulator Dlg Biol Open. PubMed ID: 35722710
Summary:
The compartmentalized domains of polarized epithelial cells arise from mutually antagonistic actions between the apical Par complex and the basolateral Scrib module. In Drosophila, the Scrib module proteins Scribble (Scrib) and Discs-large (Dlg) are required to limit Lgl phosphorylation at the basolateral cortex, but how Scrib and Dlg could carry out such a 'protection' activity is not clear. This study tested Protein Phosphatase 1α (PP1) as a potential mediator of this activity but demonstrate that a significant component of Scrib and Dlg regulation of Lgl is PP1-independent, and found no evidence for a Scrib-Dlg-PP1 protein complex. However, the Dlg SH3 domain plays a role in Lgl protection and, in combination with the N-terminal region of the Dlg HOOK domain, in recruitment of Scrib to the membrane. A 'minimal Dlg' was identified, comprised of the SH3 and HOOK domains that is both necessary and sufficient for Scrib localization and epithelial polarity function in vivo.
Ojha, S. and Tapadia, M. G. (2022). Nonapoptotic role of caspase-3 in regulating Rho1GTPase-mediated morphogenesis of epithelial tubes of Drosophila renal system. Dev Dyn 251(5): 777-794. PubMed ID: 34773432
Summary:
Cells trigger caspase-mediated apoptosis to eliminate themselves from the system when tissue needs to be sculptured, or they detect any abnormality within them, thus preventing irreparable damage to the host. However, nonapoptotic activities of caspases are also involved in many cellular functions. Interestingly, Drosophila Malpighian tubules (MTs) express apoptotic proteins, without succumbing to cell death. This stuuy showd apoptosis-independent role of executioner caspase-3, Drice, in MT morphogenesis. Drice is required for precise cytoskeleton organization and convergent extension, failing which morphology, size, cell number, and arrangement get affected. Furthermore, characteristic stellate cell shape transformation in MTs is also governed by Drice. Genetic interaction study shows that Drice mediates its action by regulating Rho1GTPase functionally, and localization of polarity protein Disc large. Subsequently, downregulation of Rho1GTPase in Drice mutants significantly rescues the cystic MTs phenotype. The study shows a mechanism by which Drice governs tubulogenesis via Rho1GTPase-mediated coordinated organization of actin cytoskeleton and membrane stabilization. Collectively these findings suggest a nonapoptotic function of caspase-3 in fine-tuning of cellular rearrangement during tubule development, and these results will add to the growing understanding of diverse roles of caspases during its evolution in metazoans.
Pribbenow, C., Chen, Y. C., Heim, M. M., Laber, D., Reubold, S., Reynolds, E., Balles, I., FernAndez, D. V. A. T., Suarez-Grimalt, R., Scheunemann, L., Rauch, C., Matkovic, T., Rosner, J., Lichtner, G., Jagannathan, S. R. and Owald, D. (2022). Postsynaptic plasticity of cholinergic synapses underlies the induction and expression of appetitive and familiarity memories in Drosophila. Elife 11. PubMed ID: 36250621
Summary:
In vertebrates, several forms of memory-relevant synaptic plasticity involve postsynaptic rearrangements of glutamate receptors. In contrast, previous work indicates that Drosophila and other invertebrates store memories using presynaptic plasticity of cholinergic synapses. This study provides evidence for postsynaptic plasticity at cholinergic output synapses from the Drosophila mushroom bodies (MBs). The nicotinic acetylcholine receptor (nAChR) subunit α5 is required within specific MB output neurons (MBONs) for appetitive memory induction, but is dispensable for aversive memories. In addition, nAChR α2 subunits mediate memory expression and likely function downstream of α5 and the postsynaptic scaffold protein Dlg. This study shows that ostsynaptic plasticity traces can be induced independently of the presynapse, and that in vivo dynamics of α2 nAChR subunits are changed both in the context of associative and non-associative (familiarity) memory formation, underlying different plasticity rules. Therefore, regardless of neurotransmitter identity, key principles of postsynaptic plasticity support memory storage across phyla.
Maseko, S. B., Brammerloo, Y., Van Molle, I., Sogues, A., Martin, C., Gorgulla, C., Plant, E., Olivet, J., Blavier, J., Ntombela, T., Delvigne, F., Arthanari, H., El Hajj, H., Bazarbachi, A., Van Lint, C., Salehi-Ashtiani, K., Remaut, H., Ballet, S., Volkov, A. N. and Twizere, J. C. (2023). Identification of small molecule antivirals against HTLV-1 by targeting the hDLG1-Tax-1 protein-protein interaction. Antiviral Res 217: 105675. PubMed ID: 37481039
Summary:
Human T-cell leukemia virus type-1 (HTLV-1) is the first pathogenic retrovirus discovered in human. Although HTLV-1-induced diseases are well-characterized and linked to the encoded Tax-1 oncoprotein, there is currently no strategy to target Tax-1 functions with small molecules. This study analyzed the binding of Tax-1 to the human homolog of the drosophila discs large tumor supressor (hDLG1/SAP97), a multi-domain scaffolding protein involved in Tax-1-transformation ability. This study solved the structures of the PDZ binding motif (PBM) of Tax-1 in complex with the PDZ1 and PDZ2 domains of hDLG1 and assessed the binding of 10 million molecules by virtual screening. Among the 19 experimentally confirmed compounds, one systematically inhibited the Tax-1-hDLG1 interaction in different biophysical and cellular assays, as well as HTLV-1 cell-to-cell transmission in a T-cell model. Thus, this work demonstrates that interactions involving Tax-1 PDZ-domains are amenable to small-molecule inhibition, which provides a framework for the design of targeted therapies for HTLV-1-induced diseases.
Scott, H., Dong, L., Stevenson, A., MacDonald, A. I., Srinivasan, S., Massimi, P., Banks, L., Martin, P. E., Johnstone, S. R. and Graham, S. V. (2023). The human discs large protein 1 interacts with and maintains connexin 43 at the plasma membrane in keratinocytes. J Cell Sci 136(11). PubMed ID: 37288673
Summary:
Gap junction channels, composed of connexins, allow direct cell-to-cell communication. Connexin 43 (Cx43; also known as GJA1 for which there is no ortholog) is widely expressed in tissues, including the epidermis. In a previous study of human papillomavirus-positive cervical epithelial tumour cells, this study identified Cx43 as a binding partner of the human homologue of Drosophila Discs large (Dlg1; also known as SAP97). Dlg1 is a member of the membrane associated-guanylate kinase (MAGUK) scaffolding protein family, which is known to control cell shape and polarity. This study shows that Cx43 also interacts with Dlg1 in uninfected keratinocytes in vitro and in keratinocytes, dermal cells and adipocytes in normal human epidermis in vivo. Depletion of Dlg1 in keratinocytes did not alter Cx43 transcription but was associated with a reduction in Cx43 protein levels. Reduced Dlg1 levels in keratinocytes resulted in a reduction in Cx43 at the plasma membrane with a concomitant reduction in gap junctional intercellular communication and relocation of Cx43 to the Golgi compartment. These data suggest a key role for Dlg1 in maintaining Cx43 at the plasma membrane in keratinocytes.
BIOLOGICAL OVERVIEW

Discs large (DLG) is the prototypic member of a growing family of proteins collectively termed membrane-associated guanylate kinase homologs (MAGUKs). DLG is required for septate junction structure, cell polarity, and proliferation control in Drosophila epithelia. Two other Drosophila MAGUK proteins are Dishevelled (involved in segment polarity) and Canoe (involved in Notch signaling).

Other molecules found at septate junctions include the cell adhesion protein Fasciclin III, as well as Expanded, and Coracle. Both Expanded and Coracle are members of the 4.1 family of proteins that includes mammalian ezrin, radixin and moesin. The 4.1 family proteins physically bind cytoskeletal elements. The protein Neurexin is a transmembrane component of septate junctions interacting with Coracle. Neurexin is required for septate junction and blood-nerve barrier formation and function (Baumgartner, 1996).

All MAGUKs contain a series of domains: either one or three copies of an 80-90 amino acid motif called DHR/PDZ (DLG Homologous Region/PSD-95), DLG, ZO-1, and a region with high similarity to guanylate kinases (GUK). Both the DHR/PDZ and the SH3 domains may serve as sites for protein-protein interactions. The subfamily of MAGUKs (DLG-R) includes DLG, as well as mammalian tight-junction proteins ZO-1 and ZO-2 (homologs of Drosophila Polychaetoid). In DLG-R family members there are three DHR/PDZ domains, each with a three-amino acid deficiency in the ATP binding site within the GUK, making unlikely the existence of guanylate kinase catalytic activity (Woods, 1996 and references).

Imaginal disc cells mutant for dlg lack apicobasal polarity and septate junctions. However, the adherens junctions (see Shotgun and Armadillo) are still present: in fact, adherens junctions can be found at various ectopic positions on mutant cell membranes. The dependence of septate junction structure on functional DLG is seen more clearly in the salivary gland, a differentiated epithelial tissue that grows during larval life by cell enlargement rather than by proliferation. Mutant salivary gland cells still have obvious apicobasal polarity, but the septate junctions (usually extending a long distance over the lateral cell membrane) are reduced to a small fraction of their normal length (Woods, 1996).

Both microfilament and microtubule networks are disrupted by loss of the DLG protein. Filamentous actin, enriched at the apical end of the cell in wild-type epithelia, is found throughout the cell in mutants. Organization of tubulin is also severly disrupted. After the loss of the DLG protein, septate junctions of imaginal discs and some larval epithelia show a drastic alterantion in distribution of Coracle and Expanded (two proteins of the band 4.1 family of membrane cytoskeletal proteins). Loss of the DLG protein results in the distribution of COR and EX throughout the cell. In proventriculus cells both COR and EX are normally highly localized at the apicolateral membrane, presumably at the position of the septate junctions. In mutants, nearly all the COR protein is lost rather than mislocalized (Woods, 1996).

Loss of Discs large also affects the distribution of Fasciclin III and neuroglian, two transmembrane proteins thought to be involved in cell adhesion. Fasciclin III is highly enriched at the septate junction and present in lower amounts in the lateral cell membrane, but is excluded from the adherens junction. Neuroglian is enriched at the apical end of the cell, reduced in the septate junction, and also reduced on the rest of the lateral cell membrane. Localization of FAS III and Neuroglian in both salivary glands and imaginal discs is dependent of DLG. When septate junctions are completely eliminated in dlg mutants, both proteins are found apparently unrestricted along the cell membrane. In fact Neuroglian appears to have an elevated level of expression compared with wild type, while FAS III levels are reduced (Woods, 1996).

The adherens junction has long been the darling of Drosophila research: one component (Armadillo) is a downstream target of wingless signals while another component (Shotgun, or Drosophila E-cadherin) is involved in homophylic cell adhesion. The septate junction of Drosophila, present in lieu of the tight junction of vertebrates, now rightly deserves more attention. Tight junctions in vertebrates are physically more closely associated with the adherens junction, but in Drosophila, septate junctions assume a more basolateral position. Five components are now associated with septate junctions, FAS III, Neuroglian, DLG, COR and EX. Mutation of DLG disrupts this association, suggesting a central role for DLG in tight junction stucture. DLG mutants show an enhanced level of disc cell proliferation, suggesting a role for the tight junction in regulation of cell growth (Woods, 1996). The recent finding that a vertebrate DLG homolog, ZO-1, undergoes nuclear localization at the site of wounding, suggests a role for MAGUK proteins in nuclear signaling (Gottardi, 1996).

An important function of MAGUK proteins appears to be conserved between flies and mammals. MAGUK proteins are present in synapses and are important in directing synapse structure. Chapsyn-110 and PSD-95, two mammalian MAGUK proteins, interact at postsynaptic sites to form a multimeric scaffold for the clustering of N-methyl-D-aspartate (NMDA) receptors and Shaker K+ channel subunits (Kim, 1996). Drosophila DLG is expressed at type I glutamatergic synapse of the neuromuscular junction and is associated with both presynaptic and postsynaptic membranes. Type Ib boutons are large and are filled with 40 nm clear vescles thought to contain glutamate. At the postsynaptic site, type Ib boutons are surrounded by an elaborate system of membranes, the subsynaptic reticulum (SSR), a postsynaptic specialization at these synapses. Mutations in dlg alter the expression of dlg and cause striking changes in the structure of the subsynaptic reticulum (Lahey, 1994).

The SSR consists of highly elaborated junctional membranes that surround Type I boutons. Hypomorphic mutations in dlg result in a poorly developed and much simpler SSR. Developmental studies show that in wild type, the surface of this postsynaptic structure increases (about 100-fold) as the target muscle becomes larger (over 100 times in volume) during larval growth (Guan, 1996). In the mutant, the SSR forms normally at initial larval stages, but fails to expand as target muscles grow. Postsynaptic DLG is able to substantially rescue the SSR phenotype. These results support the model that suggests that DLG is involved in adjusting the size of postsynaptic surfaces during development (Burdnik, 1996).

What is the presynaptic function of DLG? DLG is observed in the presynaptic cell prior to its expression in the postsynaptic cell (Guan, 1996). The expression of DLG in the presynaptic cell may target ion channels and other proteins to the presynaptic terminal and activate the release of an agrin-like molecule, which induces the synthesis of rapsyn-like synapse-orienting proteins, such as DLG in the postsynaptic cell. Mutation of dlg result in larger synaptic currents at fly neuromuscular junctions. The enlarged excitatory junctional current (EJC) amplitude in dlg mutants is caused by an increase in the number of vesicles released during each stimulus (quantal content). Rescue of the physiological defect is accomplished by presynaptic, but not postsynaptic targeted expression of dlg. Thus presynaptic dlg expression can rescue the neurotransmitter release phenotype. Additionally, and paradoxically, presynaptic dlg expression can rescue the postsynaptic SSR structure as well (Budnik, 1996).

Organizing a functional junctional complex requires specific domains of the Drosophila MAGUK discs large

Discs large (Dlg) was the first identified member of an increasingly important class of proteins called membrane-associated guanylate kinase homologs (MAGUKs), which are often concentrated at cell junctions and contain distinct peptide domains named PDZ1-3, SH3, HOOK, and GUK. The region between the Sh3 and GUK domains (HOOK, or I3) shows significant sequence similarity between several MAGUKs: in hDlg and p55, it has been shown to bind certain actin-associated proteins of the protein 4.1/ERM (Exrin, Radizin, Moesin) superfamily (Hough, 1997).

Dlg is localized at and required for the formation of both septate junctions in epithelial cells and synaptic junctions in neurons. In the absence of Dlg, epithelia lose their organization and overgrow. The functions of each domain of Dlg were tested in vivo by constructing transgenic flies expressing altered forms of the protein. In the first set of experiments each domain was examined for its ability to correctly target an epitope-tagged Dlg to pre-existing septate junctions. Based on these results the Hook domain is necessary for localization of the protein to the cell membrane and the PDZ2 domain is required for restricting the protein to the septate junction. In the second set of experiments, each domain was tested for its role in growth regulation and organization of epithelial structure. These results show that PDZ1 and GUK are apparently dispensable for function; PDZ2 and PDZ3 are required for growth regulation but not for epithelial structure, and SH3 and HOOK are essential for both aspects of function. The results demonstrate the functional modularity of Dlg and clarify the functions of individual MAGUK domains in regulating the structure and growth of epithelial tissue (Hough, 1997).

A three-step model is proposed for Dlg localization to the septate junctions and binding of the proteins important for structure and growth regulation. Step one involves binding of the HOOK domain to a protein 4.1-like protein and membrane localization of Dlg. Step two, mediating Dlg clustering at septate junctions, involves transmembrane protein binding to PDZ1/2 and Step three involves stabilization and binding of proteins involved in additional functions, such as growth regulation. The relative order of these steps is unknown. The effect of dlg mutations may not be an indirect consequence of loss of junctional structure, but may reflect a direct role of the Dlg protein in the signaling events that control proliferation (Hough, 1997).

DLGS97/SAP97 is developmentally upregulated and is required for complex adult behaviors and synapse morphology and function

The synaptic membrane-associated guanylate kinase (MAGUK) scaffolding protein family is thought to play key roles in synapse assembly and synaptic plasticity. Evidence supporting these roles in vivo is scarce, as a consequence of gene redundancy in mammals. The genome of Drosophila contains only one MAGUK gene, discs large (dlg), from which two major proteins originate: DLGA [PSD95 (postsynaptic density 95)-like] and DLGS97 [SAP97 (synapse-associated protein)-like]. These differ only by the inclusion in DLGS97 of an L27 domain, important for the formation of supramolecular assemblies. Known dlg mutations affect both forms and are lethal at larval stages attributable to tumoral overgrowth of epithelia. Independent null mutations were generated for each, dlgA and dlgS97. These allowed unveiling of a shift in expression during the development of the nervous system: predominant expression of DLGA in the embryo, balanced expression of both during larval stages, and almost exclusive DLGS97 expression in the adult brain. Loss of embryonic DLGS97 does not alter the development of the nervous system. At larval stages, DLGA and DLGS97 fulfill both unique and partially redundant functions in the neuromuscular junction. Contrary to dlg and dlgA mutants, dlgS97 mutants are viable to adulthood, but they exhibit marked alterations in complex behaviors such as phototaxis, circadian activity, and courtship, whereas simpler behaviors like locomotion and odor and light perception are spared. It is proposed that the increased repertoire of associations of a synaptic scaffold protein given by an additional domain of protein-protein interaction underlies its ability to integrate molecular networks required for complex functions in adult synapses (Mendoza-Topaz, 2008).

Although the in vivo function of the L27 domain of DLGS97/SAP97 in neurons is not fully understood, it has been implicated in AMPA receptor trafficking, in the synaptic localization of Dlin-7, in activity-dependent redistribution of AMPA receptors to spines, and in postsynaptic clustering. L27 domains are found in proteins of the MAGUK family and in proteins of the LIN-7 family and have been widely implicated in the homo-oligomerization and hetero-oligomerization of these scaffolding proteins. The L27 domain of DLGS97 could coordinate the function of many multiprotein complexes, consisting of a scaffolding protein and all its binding partners. In vertebrates, SAP97 associates through its L27 domain with the first L27 of CASK, which in turn associates through its second L27 to the L27 of LIN-7/MALS. The existence of a similar complex in flies is supported by the presence of CASK (CAKI) and LIN-7 (dLIN-7) homologues and the in vitro interaction between CAKI and the L27 of DLGS97. CAKI is expressed in a pattern similar to DLG in adults and caki mutants, like dlgS97 mutants, are viable. These mutants show locomotor speed defects and abnormal optomotor behavior, although no other behaviors have been examined. CAKI has also been suggested to be involved in the regulation of the autonomous activity of CaMKII regulating its activation and deactivation and shown to be important for the male habituation behavior during mating. In vertebrates, SAP97/CASK/VELI complex has been implicated in the transport of glutamate receptors as well as in the recruitment of SAP97 to the membrane. Thus, DLGS97 is likely to form supramolecular complexes, in which the specific function of lower order complexes is harmonized and perhaps synchronized. The observation that DLGS97 appears to play a role in behaviors that require multiple sensory and motor pathways makes the speculation that DLGS97 control the coordination of complexes involved in the regulation of CaMKII activity and/or the delivery of receptors at the synapse highly attractive (Mendoza-Topaz, 2008).

Another feature DLGS97 proteins have is their ability to regulate the switch-like characteristics of MAGUKs. The GUK and SH3 domains of PSD95 and SAP97 can establish intramolecular interactions rendering the proteins in an open (available for partner binding) or closed configuration. Notably, the N-terminal extension of SAP97 can inhibit these intramolecular interactions. Thus, L27 domain-containing proteins have an additional level of regulation able to regulate MAGUK interactions with binding partners (Mendoza-Topaz, 2008).

Remarkably, a recent report shows that the mammalian MAGUKs PSD95 and SAP97 are expressed in the CNS as alternative splice forms containing or lacking an L27 domain. Furthermore, these studies suggest that only the L27 domain-bearing forms are sensitive to activity associated to the CaMKII activity, supporting a role of the L27 domain in activity-induced synaptic modification (Mendoza-Topaz, 2008).

A significant finding in this work is the versatility of SAP proteins within the same cell. Although eliminating either of the two isoforms did not prevent normal localization of Scrib, FasII localization was altered in both dlgS97 and dlgA mutants, although the total amount of DLG was only decreased at most by 20%. These observations are intriguing, given that FasII and Scrib interact with DLG domains present in both isoforms. This suggests that form-specific characteristics or the interaction or balance between the two proteins are important for proper FasII localization. Similar codependence/independence between isoforms was found at the ultrastructural level. Although both isoforms appeared to be required for the regulation of active zones, bouton and synaptic vesicle size, either of them had functions in SSR development (Mendoza-Topaz, 2008).

The detected abnormalities in synaptic architecture were also accompanied by functional alterations. The mEJP amplitude change of dlgXI-2 was phenocopied when DLGS97 was eliminated, whereas the absence of DLGA did not increase the amplitude of the mEJPs. The increase of mEJPs amplitude was correlated with an increase in the size of the vesicles (significant for all genotypes) and an increase in the labeling intensity and size of the GluR clusters only in dlgS97 mutants. Thus, the increased mEJP amplitude in dlgS97 mutants correlates with presynaptic and postsynaptic defects. However, the decrease in EJP amplitude depended only on DLGA. Overall, both mutants had a decrease in quantal content, indicating that both isoforms are required for effective neurotransmission. Such SAP-specific functions between PSD95 and SAP97 have been suggested in neuronal culture studies (Mendoza-Topaz, 2008).

A striking shift was fund in isoform usage during development, with DLGS97 becoming increasingly preponderant at more mature stages. These results, added to the previously described DLGS97 exclusive expression in excitable tissues, suggest that this shift underscores a fundamental and unique requirement of the L27 domain in neurons. A similar developmental shift is observed in mammalian neuronal cultures, in which PSD95 and PSD93 (proteins that bear L27 domains as splice variants) play most relevant roles in mature neurons, whereas SAP102 (lacking L27 domain) is essential in immature neurons. Thus, although SAPs devoid of L27 domain might have roles in protein clustering in a broad number of polarized cells, L27-bearing SAPs might couple the basic clustering machinery to multiple cellular processes. Isolation of isoform-specific mutants in the absence of SAP redundancy constitutes the first step to address this possibility (Mendoza-Topaz, 2008).

This study highlights the correlation between the acquisition of a single domain of protein-protein interaction and the ability of DLGS97 to engage in processes required for complex functions of the adult brain. Although the mechanisms mediating between both levels need to be unraveled and are probably multiple, this example appears relevant to understand the elaboration of increasingly complex structures and functions with a limited set of molecular tools (Mendoza-Topaz, 2008).

The exon junction complex regulates the splicing of cell polarity gene dlg1 to control Wingless signaling in development

Wingless (Wg)/Wnt signaling is conserved in all metazoan animals and plays critical roles in development. The Wg/Wnt morphogen reception is essential for signal activation, whose activity is mediated through the receptor complex and a scaffold protein Dishevelled (Dsh). This study reports that the exon junction complex (EJC) activity is indispensable for Wg signaling by maintaining an appropriate level of Dsh protein for Wg ligand reception in Drosophila. Transcriptome analyses in Drosophila wing imaginal discs indicate that the EJC controls the splicing of the cell polarity gene discs large 1 (dlg1), whose coding protein directly interacts with Dsh. Genetic and biochemical experiments demonstrate that Dlg1 protein acts independently from its role in cell polarity to protect Dsh protein from lysosomal degradation. More importantly, human orthologous Dlg protein is sufficient to promote Dvl protein stabilization and Wnt signaling activity, thus revealing a conserved regulatory mechanism of Wg/Wnt signaling by Dlg and EJC (Liu, 2016).

The EJC is known to act in several aspects of posttranscriptional regulation, including mRNA localization, translation and degradation. After transcription, the pre-mRNA associated subunit eIF4AIII is loaded to nascent transcripts about 20-24 bases upstream of each exon junction, resulting in binding of Mago nashi (Mago)/Magoh and Tsunagi (Tsu)/Y14 proteins to form the pre-EJC core complex. The pre-EJC then recruits other proteins including Barentsz (Btz) to facilitate its diverse function). In vertebrates, the EJC is known to ensure translation efficiency as well as to activate nonsense-mediated mRNA decay (NMD). In Drosophila, however, the EJC does not contribute to NMD. It is instead required for the oskar mRNA localization to the posterior pole of the oocyte. Very recently, the pre-EJC has been shown to play an important role in alternative splicing of mRNA in Drosophila. Reduced EJC expression results in two forms of aberrant splicing. One is the exon skipping, which occurs in MAPK and transcripts that contain long introns or are located at heterochromatin (Ashton-Beaucage, 2010; Roignant, 2010). The other is the intron retention on piwi transcripts. Furthermore, transcriptome analyses in cultured cells indicates the role of EJC in alternative splicing is also conserved in vertebrates (Liu, 2016).

This study has utilized the developing Drosophila wing as an in vivo model system to investigate new mode of regulation of Wg signaling. The pre-EJC was found to positively regulate Wg signaling through its effect on facilitating Wg morphogen reception. Further studies reveal that the basolateral cell polarity gene discs large 1 (dlg1) is an in vivo target of the pre-EJC in Wg signaling. Dlg1 acts independently from its role on cell polarity to stabilize Dsh protein, thus allowing Wg protein internalization required for signaling activation. Furthermore, it was demonstrated that human Dlg2 exhibits a similar protective role on Dvl proteins to enhance Wnt signaling in cultured human cells. Taken together, this study unveils a conserved regulatory mechanism of the EJC and Dlg in Wg/Wnt signaling (Liu, 2016).

In summary, this study uncovers a specific role of the RNA binding protein complex EJC in the Drosophila wing morphogenesis. Genetic and biochemical analyses demonstrate that the pre-EJC is necessary for Wg morphogen reception to activate the signal transduction. The identification of the cell polarity determinant dlg1 as one of the pre-EJC targets provides mechanistic basis for the pre-EJC regulation of the Wg signaling. Dlg1 controls the stability of the scaffold protein Dsh, which is the hub of the Wg signaling cascade. Importantly, this mode of regulation of Dvl by Dlg is conserved from flies to vertebrates (Liu, 2016).

The EJC as well as other RNA binding protein complexes are thought to function in a pleiotropic manner. However, the current data together with several recent studies argue that RNA regulatory machineries can act specifically on developmental signaling for pattern formation and organogenesis. It has been increasingly recognized that the production, transport or the location of mRNA are subject to precise regulation in Wg/Wnt signaling. For example, apical localization of wg RNA is essential for signal activation in epithelial cells. The specific role of RNA machineries on cell signaling is not limited to Wg/Wnt signaling. It has been reported that RNA-binding protein Quaking specifically binds to the 3'UTR of transcription factor gli2a mRNA to modulate Hedgehog signaling in zebrafish muscle development. RNA binding protein RBM5/6 and 10 could differentially control alternative splicing of a negative Notch regulator gene NUMB, thus antagonistically regulating the Notch signaling activity for cancer cell proliferation. Therefore, generally believed pleotropic RNA regulatory machineries emerge as important regulatory means to specifically control cell signaling and related developmental processes (Liu, 2016).

The most studied function of the EJC in development is to localize oskar mRNA to the posterior pole of the oocyte for oocyte polarity establishment and germ cell formation in Drosophila. Further study suggests that the proper oskar RNA localization relies on its mRNA splicing. In light of the current study of the EJC activity on dlg1 mRNA as well as the roles of EJC on mapk and piwi splicing, it is suspected that EJC might regulate oskar mRNA splicing to mediate its mRNA localization. RNA-seq analyses identified several hundreds of candidate mRNAs whose expression may be directly or indirectly subjected to EJC regulation. Apart from defects in Wg and MAPK signaling, however, altered wing patterning associated with other developmental signaling systems was not seen in EJC defective flies, arguing that EJC may primarily regulate Wg and MAPK signaling in patterning the developing wing (Liu, 2016).

Wg/Wnt signaling plays a fundamental role in development and tissue homeostasis in both flies and vertebrates. Its activation and maintenance rely on appropriate activity of the ternary receptor complex including Fz family proteins. In Drosophila, polarized localization of Fz and Fz2 proteins is essential for activation of non-canonical and canonical Wg signaling, respectively. Dsh, which acts as a hub mediating both canonical and non-canonical Wg signaling, however, is found at both the apical cell boundary and in the basal side of the cytoplasm. Thus, the polarized activity of Dsh must require distinct regulatory mechanisms at different sub-membrane compartments. The results provide the in vivo evidence suggesting that the basolateral polarity determinant Dlg1 may play a dominant role to control the Dsh abundance/activity in canonical Wg signaling (Liu, 2016).

Altered Dvl production or activity has been linked with several forms of cancer. The stability of Dvl proteins can be controlled through regulated protein degradation both in vertebrates and in Drosophila as reported in this study. In HEK293T cells, Dapper1 induces whilst Myc-interacting zinc-finger protein 1 (MIZ1) antagonizes autophagic degradation of Dvl2 in lysosome. It is also reported that a tumor suppressor CYLD deubiquitinase inhibits the ubiquitination of Dvl. As Dlg1 prevents Dsh from degradation in Drosophila, it is important to investigate if Dlg1 participates in a posttranslational regulatory network of Dvl to integrate endocytosis and autophagy. Furthermore, upregulation of dvl2 and dlg2 expression has been found in various forms of cancer as shown in the COSMIC database. The study of the interaction between Dlg1 and Dsh may aid the development of novel approaches to prevent or treat relevant diseases. (Liu, 2016).

Dlg1 acts together with L(2)gl to form a basolateral complex in polarized epithelium. Dsh is known to interact with L(2)gl. On one hand, Dsh activity is required for correct localization of L(2)gl to establish apical-basal polarity in Xenopus ectoderm and Drosophila follicular epithelium. On the other hand, L(2)gl can regulate Dsh to maintain planar organization of the embryonic epidermis in Drosophila. Despite the complex interaction between L(2)gl and Dsh, not much is known about mutual regulation between Dlg1 and Dsh. A recent report suggests that Dsh binds to Dlg1 to activate Guk Holder-dependent spindle positioning in Drosophila. The current results unveil another side of the relationship in which Dlg1 controls the turnover of Dsh to ensure developmental signal propagation. Apart from its apical localization at the cell boundary, Dsh is also found in the basal side of the cytoplasm. It is likely that the interactions among Dsh, Dlg1 and L(2)gl may be dependent on their localization, and Dsh may serve as a bridge to connect cell signaling and polarity (Liu, 2016).

Developmental signaling and cell polarity intertwine to control a diverse array of cellular events. It is well known that Wg/Wnt signaling controls cell polarity in distinct manner. Non-canonical signaling acts through cytoskeletal regulators to establish planar cell polarity. Canonical signaling may also directly affect apical-basal cell polarity. On the other hand, disruption of epithelial cell polarity has a profound impact on protein endocytosis and recycling, both of which are essential regulatory steps for signal activation and maintenance. The current results add another layer of complexity by which polarity determinants could contribute to cell signaling independent of their conventional roles in polarity establishment and maintenance. Interestingly, this mode of regulation is also observed for other signaling processes. Loss of Dlg5 impairs Sonic hedgehog-induced Gli2 accumulation at the ciliary tip in mouse fibroblast cells that may not rely on cell polarity regulation. Similarly, L(2)gl regulates Notch signaling via endocytosis, independent of its role in cell polarity. It is believed that other cell polarity determinants may similarly participate in polarity-independent processes, however, the exact mechanism of how they cooperate to modulate developmental signaling awaits further investigation (Liu, 2016).

Scribble and Discs-large direct initial assembly and positioning of adherens junctions during the establishment of apical-basal polarity

Apical-basal polarity is a fundamental property of animal tissues. Drosophila embryos provide an outstanding model for defining mechanisms that initiate and maintain polarity. Polarity is initiated during cellularization, when cell-cell adherens junctions are positioned at the future boundary of apical and basolateral domains. Polarity maintenance then involves complementary and antagonistic interplay between apical and basal polarity complexes. The Scribble/Dlg module is well-known for promoting basolateral identity during polarity maintenance. This study reports a surprising role for Scribble/Dlg in polarity initiation, placing it near the top of the network-positioning adherens junctions. Scribble and Dlg are enriched in nascent adherens junctions, are essential for adherens junction positioning and supermolecular assembly, and also play a role in basal junction assembly. The hypotheses were tested for the underlying mechanisms, exploring potential effects on protein trafficking, cytoskeletal polarity or Par-1 localization/function. The data suggest that the Scribble/Dlg module plays multiple roles in polarity initiation. Different domains of Scribble contribute to these distinct roles. Together, these data reveal novel roles for Scribble/Dlg as master scaffolds regulating assembly of distinct junctional complexes at different times and places (Bonello, 2019).

Identifying the earliest symmetry-breaking events that initially position AJs, thereby setting the boundary between apical and basolateral domains, is a key aspect of understanding how polarity is established. This study reports that Scrib/Dlg, best known for roles as basolateral determinants during polarity maintenance, play a separate and surprising role in organizing AJs during polarity establishment, positioning them at the top of the polarity network (Bonello, 2019).

Scrib and Dlg are multidomain proteins with many partners, allowing them to serve diverse biological functions, from synaptogenesis to oriented cell division. The data reveal they play distinct roles during polarity establishment and polarity maintenance, likely engaging very different sets of binding partners. This is supported by the evolving localization pattern of Scrib/Dlg on the plasma membrane, with sequential co-localization with and roles in positioning AJ versus SJ proteins, suggesting the capacity to engage with and position distinct junctional and polarity proteins. These analyses also begin to dissect the underlying molecular basis. Scrib's PDZ domains are important for the precision of initial polarity establishment but are redundant with other mechanisms for polarity maintenance after gastrulation, though they regulate SJ positioning (Bonello, 2019).

AJs play a key role at the boundary between apical and basolateral domains, and building a functional junction is a multistep process. This includes assembling the core cadherin-catenin complex, positioning it, and supermolecular assembly. Assembly of the core complex appears to occur coincident with synthesis, and thus small puncta are already present before cellularization. As cellularization proceeds, these are captured at the apicolateral interface in a process requiring Baz, Cno, and an intact actin cytoskeleton, where they coalesce into SAJs, with ~1500 AJ complexes and 200 Baz proteins. Cadherin-catenin complexes form independently of either Baz or Cno, but AJ positioning and full supermolecular assembly depend on both. This study found that Scrib/Dlg are also key for AJ apicolateral retention and supermolecular assembly, although Arm and Cno remain associated in misplaced puncta, and thus core AJ complexes remain intact. Further, a second junctional complex that arise during polarity establishment, the BJs, also require Scrib/Dlg for its supermolecular organization. Unlike AJs, BJ organization is not dependent on other polarity determinants including Cno, Rap1 or Par-1. It will be of interest to examine if Scrib/Dlg act via known regulators of cadherin clustering, including intrinsic (e.g., cis- and trans-interactions of cadherins) and extrinsic (e.g., local actin regulation, endocytosis) factors (Bonello, 2019).

The ultimate goal is to define molecular mechanisms underlying polarity establishment. The new data place Scrib/Dlg in a critical position near the top of the network, but also suggest they act via multiple effectors. Perhaps the strongest evidence for multiple roles with distinct effectors comes from analysis of scrib4. Supermolecular organization of both SAJs and BJ must involve interactions with specific partners via the PDZ domains- one speculative possibility is that these include core AJ proteins, as βcatenin can coIP with Scribble and interact with PDZ domains 1 and 4. Testing this idea will be an important future direction. This initial role may also involve modulating Par-1. During cellularization, Scrib/Dlg and Par-1 localize in 'inverse gradients': Scrib and Dlg enriched at the SAJ level, and Par-1 with higher cortical intensity basolaterally. Scrib/Dlg play a role in effective membrane recruitment of Par-1 at this stage, and effects of par-1-RNAi on SAJ protein localization during cellularization are largely similar to those of scrib-RNAi. However, regulating Par-1 is not the only mechanism by which Scrib/Dlg act, as AJs are rescued during gastrulation after par-1-RNAi (Bonello, 2019).

Scrib then plays a second PDZ-independent role as gastrulation begins, ensuring focusing of cadherin-catenin complexes and Baz into apical belt AJs. This requires the N-terminal LRRs but not the PDZs. Positioning Baz at this stage involves at least two inputs which are redundant with one another, one via Par-1 and one via an apical transport mechanism. One speculative possibility is that Scrib/Dlg also regulate protein trafficking, a role they have in other contexts. However, disrupting Scrib/Dlg function has very different consequences than disrupting Rab5-dependent trafficking, suggesting they do not act via Rab5. aPKC also provides important cues at this stage-perhaps Scrib/Dlg regulate aPKC localization or function. It will be important to further explore the nature of this second role (Bonello, 2019).

The initial goal more than a decade ago was to define roles of AJs in polarity establishment. However, it rapidly became apparent AJs are not at the top of the hierarchy. Cno, Rap1 and Baz act upstream of AJ positioning and supermolecular assembly. The new data moves understanding another step upward in the network, revealing a key role for Scrib/Dlg in regulating AJ positioning and assembly. However, they also reveal that the process is not a simple linear pathway, and raise new questions. Loss of Scrib or Dlg almost completely disrupts AJs during cellularization. However, effects on Baz and Cno are less complete-supermolecular assembly is affected, but they are retained in the apical half of the membrane. This suggests other cues are involved. The ultimate polarizing cue during syncytial development is the oocyte membrane, which then directs cytoskeletal polarization. Cytoskeletal cues regulate Cno localization. While the data rule out a role for Scrib/Dlg in establishing basic cytoskeletal polarity, they do not rule out roles, for example, in localizing a special 'type' of actin cytoskeleton in the apical domain. Retention of Cno at the membrane after Scrib/Dlg knockdown suggests that minimally basal Rap1 activity remains intact. Changes to early Par-1, and to a lesser extent Baz, cortical localization with loss of Scrib/Dlg, also raise the possibility that lipid-based regulation is impaired. At this time, it is not known what cues regulate Scrib/Dlg apical enrichment but AJs do not appear to direct this, nor are they essential for polarizing Cno or Baz. Continued characterization of the full protein network and molecular mechanisms governing polarity establishment will keep the field busy for years to come (Bonello, 2019).

Distinct activities of Scrib module proteins organize epithelial polarity

A polarized architecture is central to both epithelial structure and function. In many cells, polarity involves mutual antagonism between the Par complex and the Scribble (Scrib) module. While molecular mechanisms underlying Par-mediated apical determination are well-understood, how Scrib module proteins specify the basolateral domain remains unknown. This study demonstrates dependent and independent activities of Scrib, Discs-large (Dlg), and Lethal giant larvae (Lgl) using the Drosophila follicle epithelium. The data support a linear hierarchy for localization, but rule out previously proposed protein-protein interactions as essential for polarization. Cortical recruitment of Scrib does not require palmitoylation or polar phospholipid binding but instead an independent cortically stabilizing activity of Dlg. Scrib and Dlg do not directly antagonize atypical protein kinase C (aPKC), but may instead restrict aPKC localization by enabling the aPKC-inhibiting activity of Lgl. Importantly, while Scrib, Dlg, and Lgl are each required, all three together are not sufficient to antagonize the Par complex. These data demonstrate previously unappreciated diversity of function within the Scrib module and begin to define the elusive molecular functions of Scrib and Dlg (Khoury, 2020).

Despite being central regulators of cell polarity in numerous tissues from nematodes to mammals, the mechanisms of Scrib module activity have remained obscure. The current work highlights previously unappreciated specificity in these activities, and begins to define the molecular functions of Scrib, Dlg, and Lgl. The data focus on the Drosophila follicle epithelium, as well as in some cases Drosophila embryos, but it is important to note that tissue contexts can differ in polarity programs: For example, in the adult Drosophila midgut epithelium, where Scrib module proteins are dispensable for epithelial organization. The failure to detect phenotypic enhancement in double-mutant follicle cells, compared to single mutants, which together with the complete penetrance of single-mutant phenotypes suggest full codependence of function rather than functional overlap. Moreover, Scrib module mutants could not be bypassed in any combination by overexpression of other genes in the module, consistent with unique roles for each protein. Thus, while Scrib, Dlg, and Lgl act in a common 'basolateral polarity' pathway, they each contribute distinct functions to give rise to the basolateral domain (Khoury, 2020).

Cell polarity is particularly evident at the plasma membrane, and most polarity regulators act at the cell cortex. Therefore, a key question in the field has concerned the mechanisms that allow cortical localization of the Scrib module and Par complex proteins, which exhibit no classic membrane-association domains. A simple linear hierarchy was found for cortical localization in the follicle that places Dlg most upstream, and contrasts with that recently described in the adult midgut, where Scrib appears to be most upstream. This work highlights the requirement of Dlg for Scrib localization, and provides insight into the mechanism, in part by ruling out previous models. One model involves a direct physical interaction, mediated by the Scrib PDZ domains and Dlg GUK domain. However, in vivo analyses show that follicle cells mutant for alleles lacking either of these domains have normal polarity; these results are supported by data from imaginal discs. In contrast, this study showa that the SH3 domain is critical for Scrib cortical localization as well as polarity. The Dlg SH3 and GUK domains engage in an intramolecular 'autoinhibitory' interaction that negatively regulates binding of partners, such as Gukh and CASK. The dispensability of the GUK domain provides evidence against an essential role for this mode of regulation in epithelial polarity, and highlights the value of investigating the GUK-independent function of the Dlg SH3 (Khoury, 2020).

A second mechanism of Scrib cortical association was also excluded. Mammalian Scrib is S-palmitoylated and this modification is required for both cortical localization and function. As Drosophila Scrib was also recently shown to be palmitoylated, an appealing model would involve Dlg regulating this posttranslational modification. However, no changes to Scrib palmitoylation were detected in a dlg mutant, and chemically or genetically inhibiting Drosophila palmitoyltransferases also had no effect on Scrib localization, although the possibility that Scrib palmitoylation may be part of a multipart localization mechanism cannot be excluded. Surprisingly, palmitoylated Scrib is incapable of reaching the cortex in dlg mutants. While a constitutively myristoylated Scrib can bypass this requirement for localization, it is nevertheless insufficient to support polarity in the absence of Dlg. These results indicate that Dlg regulates additional basolateral activities beyond localizing Scrib (Khoury, 2020).

Lgl's role as an aPKC inhibitor is well-characterized, but how Scrib and Dlg influence this antagonism is not understood. This study shows that Scrib and Dlg maintain cortical Lgl by regulating its phosphorylation by aPKC, rather than by direct physical recruitment to the membrane. A contemporaneous study by Ventura (2020) supports this finding, further showing that the major factor in Lgl cortical stabilization is PIP2. The current data also suggest that the basolateral-promoting activities of Scrib and Dlg are not via direct inhibition of aPKC kinase activity or intrinsic antagonism of aPKC localization. Instead, they are consistent with models in which Scrib and Dlg regulate the three specific aPKC-targeted residues in Lgl. Previous work has demonstrated that these phosphorylated serines (656, 660, 664) are neither functionally nor kinetically equivalent, and a recent model proposes that S664 is required for basolateral polarization by mediating a phosphorylation-dependent interaction with the Dlg GUK domain. Beyond the dispensability of the GUK domain, the enhanced ability of LglAAS to inhibit aPKC and its ability to do so largely independently of Scrib and Dlg, argues against this model. Moreover, only LglAAS among the phospho-mutants can dominantly affect aPKC activity, while WT Lgl can do the same only if Scrib and Dlg are present. Together, these results suggest that S656 is the critical inhibitory residue whose phosphorylation must be limited to enable Lgl's activity (Khoury, 2020).

The mechanism by which LglS656A,LglS660A(AAS) (LglAAS) can suppress even constitutively active aPKCΔN remains unclear. aPKC substrates can act as competitive inhibitors; either an increased substrate affinity for aPKC or reduced ability to be inhibited by virtue of having fewer phosphorylation sites could make LglAAS a more effective inhibitor than WT Lgl. Supporting this idea, it was previously shown that S664, the only residue still available in LglAAS, is phosphorylated with higher kinetic preference than S656 or S660. It is also possible that some LglAAS phenotypes may be due to aPKC-independent effects resulting from reduced phosphorylation on S656 and S660. Nevertheless, a model is proposed in which Scrib and Dlg 'protect' Lgl by limiting phosphorylation of S656, thus tipping the inhibitory balance to allow Lgl to inhibit aPKC and establish the basolateral domain (Khoury, 2020).

What mechanism could underlie Scrib and Dlg protection of Lgl? One mechanism could involve generating a high phospholipid charge density at the basolateral membrane, which has been shown to desensitize Lgl to aPKC phosphorylation in vitro. However, the current data do not find evidence for regulation of phosphoinositides by Scrib and Dlg. A second possibility is that Scrib and Dlg could scaffold an additional factor, such as protein phosphatase 1, which counteracts aPKC phosphorylation of Lgl. Alternative mechanisms include those suggested by recent work on PAR-1 and PAR-2 in Caenorhabditis elegans zygotes, a circuit with several parallels to the Scrib module. In this system, PAR-2 protects PAR-1 at the cortex by shielding it from aPKC phosphorylation through physical interaction-dependent and -independent mechanisms. By analogy, binding with Scrib or Dlg could allosterically regulate Lgl to prevent phosphorylation, although this study has ruled out the Lgl-Dlg interaction documented in the literature. Scrib or Dlg might also act as a 'decoy substrate' for aPKC, as PAR-2 does in PAR-1 protection. Indeed, Scrib is phosphorylated on at least 13 residues in Drosophila embryos, although the functional relevance of this is not yet known (Khoury, 2020).

Overall, this work highlights the multifaceted nature of Scrib module function. The failure to bypass Scrib module mutants by transgenic supply of any single or double combination of other module components, including several that were constitutively membrane-tethered, suggests that every member contributes a specific activity to polarity. Nevertheless, even the simultaneous ectopic localization of all three Scrib module proteins was insufficient to disrupt the apical domain. This insufficiency in basolateral specification may reflect an inability of apical Scrib and Dlg to protect Lgl from aPKC phosphorylation, perhaps due to the distinct molecular composition of the apical and basolateral domains. This supports the idea that in addition to intrinsic activity via Lgl, the Scrib module must recruit or activate additional, as yet unidentified effectors in basolateral polarity establishment. The independent as well as cooperative activities of the Scrib module delineated in this study demonstrate previously unappreciated complexity in the determination of basolateral polarity and set the stage for future mechanistic studies of Scrib module function (Khoury, 2020).


PROTEIN STRUCTURE

Amino Acids - 959

Structural Domains

DLG contains a domain homologous to yeast guanylate kinase and a region homologous to SH3, a putative regulatory motif in nonreceptor protein tyrosine kinases and other signal transduction proteins (Woods, 1989 and 1991).

The ExPASy World Wide Web (WWW) molecular biology server of the Geneva University Hospital and the University of Geneva provides extensive documentation for the Guanylate kinase pattern.


discs large 1: Evolutionary Homologs | Regulation | Developmental Biology | Effects of Mutation | References

date revised: 18 February 2024

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