Analyses of cont, nrx IV and nrg mutants have shown that these genes display a common alteration of SJ phenotype and thus are required for the formation and/or organization of SJs. In addition, the immunohistochemical analysis of these mutants shows that Cont, Nrx IV and Nrg are dependent on each other for SJ localization. The phenotypic similarities raise the interesting issue of whether these proteins are part of a macromolecular protein complex that exists at SJs, and thus become dependent on each other for their localization. To determine whether these three proteins form a biochemical complex, microsomal NP-40 extracts were prepared from Drosophila embryos and used for co-immunoprecipitation experiments. Cont was efficiently co-immunoprecipitated with Nrx IV using either anti-Nrx IV or anti-Cont antibodies. Cont and Nrx IV were not co-precipitated by monoclonal anti-Nrg antibodies, owing to weak ability to immunoprecipitate Nrg complexes. However, by probing Western blots with the 3C1 anti-Nrg mAb, Nrg was detected in anti-Cont immunoprecipitates. Only the lower molecular weight Nrg167 isoform, which is expressed in epithelial cells, was co-immunoprecipitated with Cont. By contrast, the neuronal Nrg180 isoform could only be detected in the total NP-40 lysate. These results demonstrate that Cont, Nrx IV and Nrg are part of a protein complex and that the molecular interactions between these proteins may underlie the organization of the SJs (Faivre-Sarrailh, 2004).
Thus biochemical and immunohistochemical data show that Cont is part of a protein complex that includes Nrx IV and that Cont is mislocalized in nrx IV mutants. Furthermore, in these mutants, Cont protein is not expressed properly on the plasma membrane and is seen in intracellular vesicles in the epithelial cells. This raised the possibility that Nrx IV might be involved in the cell surface targeting or stabilization of Cont (Faivre-Sarrailh, 2004).
Since Drosophila S2 cells constitutively express Nrx IV and Cont, this question was addressed using neuroblastoma N2a cells as a heterologous expression system. In transfected N2a cells, Nrx IV is efficiently expressed at the cell surface. By contrast, in cells expressing Cont, the Cont protein appears to remain localized intracellularly and double-staining with the ER marker BiP indicates that Cont is retained in the ER. Immunofluorescence staining under permeabilizing conditions of N2a cells, which were co-transfected with Cont and Nrx IV, revealed that Cont is transported to and co-localized with Nrx IV at the plasma membrane. Similar results were obtained with intact living cells. Thus, these results indicate that Nrx IV mediates the cell-surface targeting of Cont. Next, Cont was co-immunoprecipitated with Nrx IV from co-transfected COS cell lysates, as further evidence that these proteins interact in cis. Such a cis-interaction has been reported for their vertebrate counterparts contactin and NCP1 (Peles, 1997) (Faivre-Sarrailh, 2004).
To determine the expression pattern of the Cont protein, 0- to 16-hour-old embryos were immunostained with anti-Cont antibodies. Both guinea pig and rat anti-Cont antibodies revealed that Cont is expressed in ectodermally derived epithelial cells from stage 12. All these tissues, such as epidermis, hindgut, foregut, salivary glands and trachea, have been shown to contain pleated SJs. To establish the subcellular localization of Cont more precisely and to compare its distribution with that of Neurexin, a known SJ specific protein, and Neuroglian, a homolog of the vertebrate axo-glial SJ component NF-155, co-immunolocalization studies of wild-type embryos were carried out using guinea pig anti-Cont. This triple labeling showed that Cont expression overlaps with that of Nrx IV and Nrg in most epithelial tissues in which these molecules are co-expressed. Furthermore, the onset of Cont and Nrx IV expression detected by immunostaining is identical and, like Nrx IV, Cont does not have any maternal contribution. Nrx IV is expressed in perineurial glial cells, which insulate peripheral nerves, and in the midline glial cells that ensheath anterior and posterior commissures. Contactin colocalizes with Nrx IV in perineurial glial cells of peripheral nerves, whereas it shows a distribution clearly distinct from Nrx IV in the midline glial cells. Since Nrg is strongly expressed in the peripheral nerves, regions of overlap between the three markers can be shown in a merged image. In the midline, some of the glial cells express Cont, Nrx IV and Nrg, as indicated by intense white color (Faivre-Sarrailh, 2004).
The expression pattern of Cont is similar to that of other septate junction markers such as Coracle, which is expressed by ectodermally derived epithelial cells and along peripheral nerves although it is not present in midline glial cells. Unlike Nrx IV, Cont is not expressed in midline glial cells, indicating that Nrx IV may have additional partners in the midline glial cells (Faivre-Sarrailh, 2004).
In Drosophila, epithelial tissues of the epidermis and hindgut contain SJs along the apicolateral domain below the zonula adherens or adherens junctions. To determine whether Cont precisely localizes to SJs in the epidermis and the hindgut, confocal microscopy images of these tissues, which focus on the epithelial cells, were captured at high magnification. Cont, Nrx IV and Nrg display almost complete colocalization at the SJs of epidermal cells. Although, Nrg is clearly enriched at SJs, it exhibits a broader distribution and is also expressed along the basolateral membrane. In addition, all three proteins colocalize along the peripheral nerves where SJs have been identified. Similarly, the distribution of Cont in hindgut epithelial cells, which are more columnar than epidermal epithelial cells, was determined. Cont, Nrx IV and Nrg colocalize at SJs, and here Nrg also shows an additional basolateral localization. Thus, the immunohistochemical analysis shows that Cont, Nrx IV and Nrg are co-expressed at SJs (Faivre-Sarrailh, 2004).
To determine the in vivo function of Cont, a genetic analysis of the Cont locus was initiated. Based on the genomic sequence information, the Cont gene maps to 82A6-B1 and spans ~5.7 kb with eight exons. A deficiency chromosome that uncovered Cont locus was examined by Southern blot analysis to determine whether the Cont locus was deleted and also by immunohistochemical analysis using anti-Cont antibodies to determine whether the deficiency homozygous embryos were lacking the Cont protein. Southern blot analysis using a region of the Cont cDNA as a probe showed half-signal intensity in Df(3R)XM3 when compared with wild-type signals confirming the deletion of the Cont gene in Df(3R)XM3 chromosome. Immunohistochemistry using anti-Cont antibodies further established that Df(3R)XM3 homozygous embryos did not produce any Cont protein (Faivre-Sarrailh, 2004).
As there are no chemically or P element-induced mutations in Cont gene, loss-of-function mutants had to be generated. To initiate the mutational analysis in the Cont gene, a viable P element KG9756 was obtained that had inserted in the neighboring gene, CG11739. This gene encodes a mitochondrial tricarboxylate-carrier activity and is located in the 5' end of the Cont locus. The P-element insertion site is ~2.5 kb from the predicted 5' end of Cont and ~3.2 kb from its ATG start codon. The transcription start site (predicted by FlyBase) of the Cont locus is just 90 bp from the 3' end of CG11739. Standard P element mobilization procedures were followed to obtain imprecise excisions. Approximately 3000 individual chromosomes were screened and 13 lethal lines over Df(3R)XM3 deficiency were obtained, 11 of which showed complete loss of Cont. The breakpoints in one of the excision lines (contex956) started from the P insertion site and deleted ~5 kb towards the Cont locus. This excision causes embryonic lethality. To rescue the lethality of the contex956 excision, transgenic lines were generated using a 7 kb SpeI-SpeI genomic fragment, which breaks in the middle of CG11739 (deleting its promoter region and the first 144 amino acids out of a total of 321 amino acids) and has intact Cont locus. This transgene fully rescues the lethality of homozygous contex956 excisions. The rescued adults are fully viable, fertile and are indistinguishable from those of the wild-type flies, and have been maintained as a stable stock. Therefore, the lack of CG11739 gene product is not associated with a lethal phenotype. Two additional genes in Drosophila, CG5254 and CG6782, which also encode a mitochondrial tricarboxylate-carrier activity, might substitute for CG11739 function. These results indicate that the lethality in contex956 is due to the loss of Cont, and that this excision represents a null allele of Cont (Faivre-Sarrailh, 2004).
Vertebrate NCP1, contactin and NF-155 co-localize at the paranodal SJs (Bhat, 2001) and each of these proteins are found to be mislocalized in the mutant backgrounds of one another (Bhat, 2001; Boyle, 2001). In order to further investigate the analogy between the paranodal and invertebrate SJs, whether Cont, Nrx IV and Nrg are mutually dependent on each other for their SJ localization was examined. Whether the loss of Nrx IV would result in the mislocalization of Cont and Nrg was analyzed; nrx IV-null mutant embryos exhibit a diffuse distribution of Cont along the basolateral cell membrane as opposed to its sharp localization at the SJs, as seen in the wild-type embryos. In addition, Cont immunoreactivity is often associated with intracellular vesicles, suggesting that Cont may not be either efficiently transported or stabilized at the cell surface in nrx IV mutants. In addition, Nrg, which is present at high levels at the SJs in the wild-type embryos is mislocalized in nrx IV mutant embryos and shows a more basolateral localization. These results indicate that Nrx IV is required for proper SJ localization of Cont and Nrg (Faivre-Sarrailh, 2004).
Similarly, triple immunostaining was carried out of nrg1-null mutants for Nrx IV and Cont localization. In wild-type embryos, Nrg is enriched at SJs with a lower level of expression along the basolateral membrane. In epithelial cells of nrg mutant embryos, the distribution of Nrx IV and Cont becomes basolateral indicating that Nrx IV and Cont are dependent on Nrg for their SJ localization (Faivre-Sarrailh, 2004).
Cont-null mutant embryos were analyzed for SJ localization of Nrx IV and Nrg. With the loss of Cont, Nrx IV and Nrg are mislocalized to the basolateral membrane. Taken together, the immunohistochemical analyses of nrx IV, nrg and Cont-null mutants demonstrate that these proteins are mutually dependent on each other for their localization to SJs (Faivre-Sarrailh, 2004).
Thus, the loss of Cont results in the mislocalization of Nrx IV and Nrg to the basolateral membrane. To further demonstrate that the mislocalization phenotype observed in Cont mutants is due to the loss of Cont only, and not due to any other gene expression disrupted by the P element excision, 4- to 10-hour-old embryos obtained from hs-cont/hs-cont; contex956/TM3,Sb,dfd-lacZ parental genotype were heat-shocked at 37°C for 60 minutes to induce Cont. After 7 hours incubation at room temperature, the embryos were processed for immunostaining using antibodies against Cont, Nrx IV or Nrg. hs-cont/hs-cont; contex956/contex956 homozygous embryos were identified by the absence of ß-galactosidase. Induction of Cont expression restores the localization of Nrx IV to SJs. Similarly, localization of Nrg was analyzed in these embryos. Cont expression results in the enrichment of Nrg at the SJs. In addition, the SJ localization of Nrx IV and Nrg was restored in homozygous contex956 embryos by expression of wild-type Cont from the SpeI-SpeI genomic rescue fragment. Taken together, the rescue experiments demonstrate that Cont is required for the localization of Nrx IV and Nrg at epithelial SJs, and further strengthen the conclusion that the mislocalization phenotype of Nrx IV and Nrg is solely due to the loss of Cont in Cont-null embryos (Faivre-Sarrailh, 2004).
To demonstrate the role of Cont in SJ organization, ultrastructural analysis of Cont mutant embryos was carried out in the epidermis. In wild-type animals, the pleated SJs are characterized by rows of septa running in the apical half of the lateral membranes, below the adherens junctions. Ultrastructural analysis revealed a complete loss of transverse septa in nrx IV mutants. By contrast, strands of septa are encountered in 92% of Cont embryos at stage 15. However, the wild-type pattern of SJs, which show long stretches of ladder-like structure, was not seen in Cont mutants and only small clusters of septa were observed occasionally. A quantitative analysis was performed by selecting intercellular junctions that showed strands of septa in the epidermis of Cont homozygous and Cont/GFP embryos. In control Cont/GFP embryos, septa alignments are mainly found below adherens junctions where the intercellular membranes are very convoluted because of interdigitations of the two opposing cells. In Cont/GFP embryos, the mean number of septa in an average SJ is 44.7±1.9 whereas in Cont mutant embryos, intercellular junctions showing such large SJ strands are never found. Whenever any septa are present, they are often more basal in their position, and the mean number of septa is significantly reduced (to 27.1±3). At higher magnification, electron dense intramembranous structures on both sides of the junction display a scalloped appearance in Cont/GFP embryos. These intramembranous particles are not distinctly visible in Cont mutant embryos, suggesting that Cont may be involved in the formation and/or organization of these electron-dense structures. Interestingly, the regular spacing between septa (~20-22 nm) does not seem to be affected in Cont mutants (Faivre-Sarrailh, 2004).
Similarly, ultrastructural analysis of nrg mutant embryos was carried out to determine whether Nrg is required for the formation of SJs. This analysis revealed that occasionally clusters of septa are formed, often basal in their position, in 79% of nrg1 embryos at stage 15 . These observations are consistent with the recent study of Genova (Genova, 2003) that reports a reduced number of septa in nrg mutants. In conclusion, these results indicate that Cont and Nrg are not required for the formation of intermembrane septa, but that they may play a role in organizing the junctional strands of septa in the apicolateral domain to form an effective transepithelial barrier (Faivre-Sarrailh, 2004).
Next, whether Cont plays a role in the transepithelial barrier formation was examined by a method that relies on the ability of the salivary gland epithelia to exclude rhodamine-dextran (~10 kDa) after its injection into the body cavity of live embryos during late embryogenesis. After the dye injection, confocal sections were acquired on live embryos at time intervals ranging from 10 to 50 minutes. In control heterozygous Cont/GFP embryos, the dye remained excluded from the salivary gland lumen after 50 minutes of injection. In Cont mutants, diffusion of the dye into the lumen of salivary glands was observed within 20 minutes of the injection. Similar kinetics of dye diffusion into salivary gland lumen have been observed for gliotactin and megatrachea mutants, which display disorganization or absence of septal clusters (Behr, 2003; Schulte, 2003). None of the Cont mutants excluded the dye from their lumen. The dye also entered freely in the tracheal lumen of the Cont mutant embryos in addition to the lumen of the salivary glands. Thus, the dye exclusion data, in combination with the ultrastructural analysis, demonstrate that Cont is required for the organization and function of the SJs (Faivre-Sarrailh, 2004).
Axonal insulation is critical for efficient action potential propagation and normal functioning of the nervous system. In Drosophila, the underlying basis of nerve ensheathment is the axonal insulation by glial cells and the establishment of septate junctions (SJs) between glial cell membranes. However, the details of the cellular and molecular mechanisms underlying axonal insulation and SJ formation are still obscure. This study reports the characterization of axonal insulation in the Drosophila peripheral nervous system (PNS). Targeted expression of tau-green fluorescent protein in the glial cells and ultrastructural analysis of the peripheral nerves allow visualization the glial ensheathment of axons. Individual or a groups of axons are ensheathed by inner glial processes, which in turn are ensheathed by the outer perineurial glial cells. SJs are formed between the inner and outer glial membranes. Neurexin IV, Contactin, and Neuroglian are coexpressed in the peripheral glial membranes and these proteins exist as a complex in the Drosophila nervous system. Mutations in neurexin IV, contactin, and neuroglian result in the disruption of blood-nerve barrier function in the PNS, and ultrastructural analyses of the mutant embryonic peripheral nerves show loss of glial SJs. Interestingly, the murine homologs of Neurexin IV, Contactin, and Neuroglian are expressed at the paranodal SJs and play a key role in axon-glial interactions of myelinated axons. Together, these data suggest that the molecular machinery underlying axonal insulation and axon-glial interactions may be conserved across species (Banerjee, 2006a).
The localization of Nrx IV, Cont, and Nrg in the embryonic nervous system was studied. Nrx IV, Nrg, and Cont show colocalization at the nerve glial membranes. Nrx IV, Cont, and Nrg are interdependent for their epithelial SJ localization. Having established that Nrx IV, Cont, and Nrg colocalize in the peripheral nerves, whether these proteins are interdependent for their localization in the peripheral nerves was studied. The effect of the absence of each of these three proteins on the localization of the other two was studied in the embryonic peripheral nerves using nrx IV, cont, and nrg null mutants. nrx IV mutant embryos were stained with anti-Nrx IV, anti-Cont, and anti-Nrg. Cont and Nrg proteins showed a rather diffused localization when compared with their wild-type localization. In addition, Cont is present as puncta in the cytoplasm of the glial cells because of its failure to get targeted properly to the membrane in the absence of Nrx IV. Similarly, cont null mutant embryos also showed less defined distribution and reduction of Nrx IV and Nrg in the glial membrane. nrg null mutant embryos display significant reduction in Nrx IV and Cont localization in the glial membranes. These results demonstrate that Nrx IV, Cont, and Nrg are interdependent for their proper localization in the embryonic peripheral nerves (Banerjee, 2006a).
Ultrastructural analyses of the embryonic epithelia in nrx IV, cont, and nrg mutants showed that these genes are required for the formation and/or organization of epithelial SJs. Nrx IV, Cont, and Nrg are interdependent for their proper localization both in the epithelia and in the peripheral nerves. These phenotypic similarities raised an interesting possibility that these proteins are part of a macromolecular protein complex that exists in the nervous system. To determine whether these three proteins form a biochemical complex in the nervous system, Drosophila heads, which are a rich source of both neurons and glial cells, were used. Coimmunoprecipitation experiments using Nrx IV, Cont, and Nrg antibodies efficiently coprecipitated Nrx IV, Cont, and Nrg. Interestingly, both isoforms of Nrg (180 kDa neuronal and 167 kDa epithelial) were immunoprecipitated by Nrx IV and Cont antibodies, suggesting that both isoforms are part of a protein complex that includes Nrx IV and Cont. However, at this point, it is not possible to differentiate whether isoform-specific complexes are formed or whether both isoforms are in the same complex. In addition, sucrose density gradient analysis of the fly head lysates was performed to determine how Nrx IV, Cont, and Nrg distribute in buoyant density gradients. Nrx IV and Cont cosediment in overlapping fractions. Nrg shows distribution in the lighter sucrose density fractions that do not overlap with Nrx IV and Cont but partially overlaps with that of Nrx IV and Cont, indicating that these proteins are associated with subcellular structures of the same density and may associate into a biochemical complex that is partially maintained during subcellular fractionation (Banerjee, 2006a).
The immunofluorescence analysis of nrx IV, cont, and nrg null mutants showed that in each of these mutants, the other two proteins show qualitatively reduced fluorescence intensities under identical confocal settings. The possible explanation for reduced fluorescence intensity could be that loss of any of these proteins affects the localization or stability of the other proteins. Whether the levels of the other two proteins had changed in nrx IV, cont, and nrg null mutants was examined using immunoblot analysis. Nrx IV protein levels did not seem to be affected in cont and nrg mutants when compared with wild type. Cont protein levels were severely affected in nrx IV mutants compared with wild-type and nrg mutant embryos. Nrg protein levels were also affected in nrx IV mutants but showed no change in cont mutants. At this stage, it cannot be rule out whether the change in Cont and Nrg protein levels in nrx IV mutants are attributable to reduced stability or less synthesis of these proteins. Together, the biochemical data indicate that Nrx IV, Cont, and Nrg form a protein complex in the nervous system and that, in the absence of Nrx IV, the stability of Cont and Nrg is severely affected (Banerjee, 2006a).
Inner glial membrane processes are involved in the ensheathment of either an individual axon or a group of axons. This glial ensheathment not only provides insulation of axons but also generates unique junctions between either glial membranes or between axons and glial membranes. Nrx IV, Cont, and Nrg are involved in the establishment of glial–glial SJs. Although additional components involved in these interactions need to be identified, these findings provide a basis for additional analysis of neuronal SJs, which would be relevant to the understanding of their vertebrate counterparts: the paranodal axo-glial SJs (Bhat, 2003; Hortsch, 2003; Salzer, 2003; Banerjee, 2006a and references therein).
The fundamental basis of axonal ensheathment in any species is to faithfully transmit neuronal signals along the nerve fibers and optimize desired cellular responses. To maximize the speed of conduction and/or to minimize the loss of nerve signals, many species evolved mechanisms in which axonal lengths remained short (as seen in insects) by increasing the diameter of the axons or by clustering voltage-gated Na+ channels to discrete unmyelinated regions of the axon, the node of Ranvier, as seen in myelinated nerve fibers of vertebrates. Most invertebrate species use some type of glial cells to ensheath their axons without generating a myelin sheath. The insulation is contiguous without any breaks, suggesting that primitive nodal structures or clustering of voltage-gated Na+ channels may not exist in invertebrates. However, recent reports have challenged some of these notions. In copepod crustaceans, ultrastructural analysis of the first antenna and the CNS has revealed extensive myelination of sensory and motor axons. These studies have raised some fundamental questions about axonal insulation and origins of myelination (Banerjee, 2006a and references therein).
In invertebrates like Drosophila, two types of glial cells are involved in insulation. The inner peripheral glial cells are involved in axonal ensheathment, and the outer (perineurial) glial cells wrap around the inner glial cells to provide another level of ensheathment. This two-cell ensheathment in Drosophila peripheral nerves may be advantageous to ensure that high K+ containing hemolymph does not interfere with action potential propagation. Although the cellular aspects of axonal insulation are being unraveled, the molecular mechanisms underlying the axonal ensheathment remain to be investigated. Most importantly, what are the protein constituents of the insulating membranes, and whether some of the vertebrate myelin proteins have their homologs in invertebrates? A detailed molecular analysis of the nature of the glial cells that ensheath axons as in Drosophila or produce myelin-like structures and the type of myelin in copepods may provide insights into whether myelinating glial cells arose from a common ancestor. However, a genetic dissection of the axonal ensheathment in Drosophila will uncover some of the basic aspects of the neuron-glial interactions that lead to ensheathment of nerve fibers across species (Banerjee, 2006a).
Cell adhesion molecules play a pivotal role in establishing intercellular junctions [e.g., cadherins and associated catenins form a protein scaffold that establish adhesion contacts at the adherens junctions and link them to the actin cytoskeleton. Similarly, claudins and associated cellular scaffolding proteins are required for establishing TJs. In both of these examples, transmembrane proteins bring two opposing membranes together to establish junctions through homophilic and/or heterophilic interactions (Banerjee, 2006a and references therein).
The finding that nrg null mutant nerves display increased spacing between the outer and inner glial membranes suggest that Nrg may be involved in cell–cell interactions and cell–cell adhesion between glial membranes. In contrast, the observation that loss of nrx IV and cont does not affect the membrane spacing between the inner and outer glial membranes suggests that Nrx IV and Cont are not involved in membrane adhesion or bringing the glial membranes in close apposition. Together, these data suggest that Nrg is critical for both the adhesion and SJ formation, whereas Nrx IV and Cont are critical for the formation of the septa at SJs. In addition, the missing axonal fascicles in nrg mutant nerves could result from axon fasciculation defects or axonal degeneration as a secondary consequence resulting from the loss of glial support. Axonal fasciculation defects have been observed in nrg mutants. Alternatively, axonal loss in nrg mutants might result from a disruption in axonal cytoskeleton, because Nrg possesses domains that could potentially interact with and stabilize the axonal cytoskeleton. Based on Nrg expression in S2 cells, Nrg is predicted to recruit membrane skeleton assembly within specialized domains of neurons in response to cell adhesion. Both Nrg protein forms Nrg167 and Nrg180 contain a short cytoplasmic domain as a binding site for ankyrin. Ankyrins are linker proteins that connect various membrane proteins with the actin-spectrin network in the cell. Loss of axons observed in nrg mutants is clearly suggestive of axon-glial interdependence that may alter axonal survival. In vertebrates, axolemmal-myelin interactions are critical for the formation of the paranodal axo-glial SJs (see Garcia-Fresco, 2006). This raises an interesting possibility that axon-glial interactions in Drosophila may use similar interactive mechanism for establishing axo-glial SJs. Thus, the current studies on Nrx IV, Cont, and Nrg suggest that these proteins are critical for the formation and/or organization of the SJs between either glial cells and possibly between axons and glial cells, which remains to be further investigated (Banerjee, 2006a).
Invertebrate axons are insulated from their salt-rich environment through a glial-dependent BBB, which plays a crucial role in electrical and chemical insulation. Ultrastructural studies have demonstrated SJs between perineurial glial cells and inner glial cell membrane to form the structural basis of BBB of some insects. Absence of SJs in nrx IV, cont, and nrg mutants, and a compromised BNB in the PNS as evidenced by dye exclusion analyses, provide additional confirmation in support of SJs as a prerequisite for blood-nerve barrier (BNB) formation. Not just in the PNS, recent reports on the BBB formation and function also in the CNS of Drosophila underscore the importance of SJs in proper sealing and insulation of the nerve cord (Schwabe, 2005), thereby supporting that insulation and establishment of functional SJs in both PNS and CNS go hand in hand. Although, G-protein-coupled receptor signaling pathway members have been identified to establish the BBB in Drosophila CNS, the signaling mechanisms that operate in the PNS still remain to be established (Banerjee, 2006a).
The axo-glial SJs in the myelinated axons share many anatomical features similar to those of invertebrate SJs, especially the electron-dense ladder-like transverse septa (Bhat, 2003; Banerjee, 2006a). Ensheathment of Drosophila axons by perineurial glial cells in the absence of myelin-producing glial cells would have predicted that the molecular components of the invertebrate SJs would be different from those of the vertebrate axo-glial SJs. Surprisingly, the fly SJ molecular components are present at the vertebrate axo-glial SJs and not at the TJs, which serve similar functions. Thus, the molecular similarities reflect an evolutionarily conserved function of creating an ionic barrier both at Drosophila SJs and at axo-glial SJs in the paranodal region. More importantly, Drosophila nerves contain a large number of axons, which are collectively held together by glial membranes not only to maintain nerve fasciculation but also to maintain the insulation of individual axons. It would be of significant interest to establish whether axo-glial SJs are present in Drosophila nerves and to identify downstream components of these junctions in Drosophila that link these junctions to the glial or axonal cytoskeleton. Identification of such molecules will provide insights into whether these junctions play a much broader role in axon-glial signal transduction. In summary, the molecular and functional similarities between the Drosophila SJs and vertebrate axo-glial SJs should allow a genetic and molecular dissection to be undertaken of the formation and function of these junctions in Drosophila (Banerjee, 2006a).
Reference names in red indicate recommended papers.
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date revised: 30 November 2004
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