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First published online 9 July 2008
doi: 10.1242/dev.015289

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The C. elegans F-spondin family protein SPON-1 maintains cell adhesion in neural and non-neural tissues

Wei-Meng Woo^1,*,, Emily C. Berry^1,2,*, Martin L. Hudson¹, Ryann E. Swale¹, Alexandr Goncharov^2,3 and Andrew D. Chisholm^2,

¹ Department of Molecular, Cell, and Developmental Biology, Sinsheimer Laboratories, University of California, Santa Cruz, CA 95064, USA.
² Division of Biological Sciences, University of California San Diego, La Jolla, CA 92093, USA.
³ Howard Hughes Medical Institute, University of California San Diego, La Jolla, CA 92093, USA.

Author for correspondence (e-mail: chisholm{at}ucsd.edu)

Accepted 11 June 2008

	SUMMARY

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The F-spondin family of extracellular matrix proteins has been implicated in axon outgrowth, fasciculation and neuronal cell migration, as well as in the differentiation and proliferation of non-neuronal cells. In screens for mutants defective in C. elegans embryonic morphogenesis, we identified SPON-1, the only C. elegans member of the spondin family. SPON-1 is synthesized in body muscles and localizes to integrin-containing structures on body muscles and to other basement membranes. SPON-1 maintains strong attachments of muscles to epidermis; in the absence of SPON-1, muscles progressively detach from the epidermis, causing defective epidermal elongation. In animals with reduced integrin function, SPON-1 becomes dose dependent, suggesting that SPON-1 and integrins function in concert to promote the attachment of muscles to the basement membrane. Although spon-1 mutants display largely normal neurite outgrowth, spon-1 synergizes with outgrowth defective mutants, revealing a cryptic role for SPON-1 in axon extension. In motoneurons, SPON-1 acts in axon guidance and fasciculation, whereas in interneurons SPON-1 maintains process position. Our results show that a spondin maintains cell-matrix adhesion in multiple tissues.

Key words: Spondin, Extracellular matrix, Cell adhesion, Morphogenesis, Axon guidance

	INTRODUCTION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
The morphogenesis of epithelial tissues and organs is profoundly dependent on the extracellular matrix (ECM), especially the specialized forms of ECM known as basement membranes (BMs) (Miner and Yurchenco, 2004). Active remodeling of BMs by tissues is essential for many developmental events, and aberrant cell-ECM interactions underlie tumorigenesis and metastasis of epithelial tissues (Larsen et al., 2006). Developing axons often grow over BM substrates, and BM components play central roles both in tissue morphogenesis and in axon guidance (Hinck, 2004). Yet, rather than a passive scaffold for tissue morphogenesis, the ECM can be regarded as an active participant in tissue morphogenesis and cell signaling (Nelson and Bissell, 2006).

C. elegans embryonic epidermal morphogenesis is an example of an organogenesis process that involves multiple interactions between an epithelial sheet, underlying muscle, and an intervening BM (Chisholm and Hardin, 2005). In late embryogenesis, epidermal cells undergo coordinated shape changes that lead to embryo elongation, converting the ovoid embryo into a worm-shaped larva. Forces for elongation are generated within the epidermis by actomyosin-based contraction of circumferential actin bundles (Priess and Hirsh, 1986). Nevertheless, epidermal elongation is also critically dependent on the BM, indicating the importance of cell-cell interactions in coordinating the development of embryonic tissues.

Epidermal elongation beyond the 2-fold stage requires underlying muscle (Williams and Waterston, 1994). Mutants defective in body muscle function are paralyzed and arrest at the 2-fold stage of elongation - the Pat phenotype. The need for body muscle function in epidermal elongation may reflect a role for muscle in organizing the epidermal cytoskeleton. Body muscles lie underneath dorsal and ventral epidermis, and adhere to adjacent epidermis via the BM, which allows force transmission from muscle to epidermis. The muscle-epidermal BM itself also promotes the organization of muscle and of the overlying epidermis. Importantly, different ECM components contribute to distinct aspects of epidermal morphogenesis. The earliest BM component to be deposited, laminin, is required for assembly of the myofilament lattice and the localization of dense bodies. Animals that lack laminin completely arrest in early embryonic elongation with defective muscle morphogenesis (Huang, C. C., et al., 2003; Kao et al., 2006). The BM proteoglycan Perlecan/UNC-52 is essential for assembly of the myofilament lattice (Rogalski et al., 1993), whereas type IV collagen has a later role in muscle-epidermal attachment (Guo et al., 1991).

Other BM components, such as nidogen (NID-1) or type XVIII collagen (CLE-1), are not required for embryonic morphogenesis, but play crucial roles in axon outgrowth, guidance and synaptogenesis (Ackley et al., 2001; Kang and Kramer, 2000). Similarly, the laminin receptor dystroglycan (DGN-1) is not required in embryonic morphogenesis, but functions in axon guidance (Johnson et al., 2006). Integrin signaling is required for multiple aspects of neuronal development, including cell migration, axon fasciculation (Baum and Garriga, 1997) and guidance (Poinat et al., 2002). These findings underscore the role of BM as a central scaffold for the developing nervous system.

Spondins are a conserved family of ECM proteins that were originally identified as axon guidance factors in the vertebrate spinal cord (Klar et al., 1992). In vertebrates, spondins have context-dependent effects on axon outgrowth and cell migration, and can promote neuronal differentiation (Schubert et al., 2006). Despite intensive analysis, the mechanisms by which spondins affect cell behavior and their in vivo roles remain poorly understood. Here, we report that SPON-1, the sole C. elegans member of the spondin family, is essential for embryonic morphogenesis. We show that SPON-1 promotes muscle-epidermal adhesion and is required for the completion of epidermal elongation. In the nervous system, SPON-1 promotes axon fasciculation and guidance, and continuously maintains neural architecture. These results are the first demonstration of an essential role for spondins in development.

View larger version (75K): [in this window] [in a new window]   Fig. 1. spon-1 mutants are defective in epidermal morphogenesis and muscle attachment. (A) The wild-type L1 larva has a smooth epidermal shape. (B,C) spon-1(e2623) L1 larvae and adults display variable defects in epidermal morphology. The bent body phenotype is more obvious during early larval stages (B), whereas some adults display `pinched' head morphology (arrow, C); other e2623 phenotypes include egg laying defects and a slightly shorter body length. (D) A wild-type embryo at 3-fold stage. (E) spon-1(ju402) mutant embryo, displaying elongation arrest and uneven epidermal morphology (arrow). (F) spon-1(ju430) mutant hatchling showing elongation arrest with lumpy 2-fold morphology and detached body wall muscles (arrow). Scale bar: 10 µm.

	MATERIALS AND METHODS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

We isolated the mutations ju348, ju402 and ju430ts in a screen for EMS-induced mutants displaying defective elongation and lumpy epidermal morphology (Mei Ding, W.-M.W. and A.D.C., unpublished). Two F1 progeny of mutagenized parents were picked and placed onto a plate, and their F2 broods scored for malformed L1 larvae. e2623 was isolated by Jonathan Hodgkin (personal communication). nc30 was isolated in screens for mispositioned ventral nerve cords (Shioi et al., 2001).

Genetic mapping placed spon-1 between dpy-10 and unc-4 on chromosome II. SNP mapping placed ju430 between pkP2148 and pkP2150, an interval of 420 kb. A 5.6 kb DNA fragment that contains 1.4 kb 5' and 0.3 kb 3' to the F10E7.4 coding sequence (pCZ695, Fig. 2A) rescued ju402 mutants to wild-type levels (data not shown). We sequenced a spon-1 full-length cDNA yk260h10 and confirmed the gene structure in Wormbase. The spon-1 coding sequence is spread over 12 exons and encodes a primary polypeptide of 819 amino acid residues. In strain constructions, spon-1 mutations were followed using allele-specific SNPs: e2623 creates a TaqI site and ju430 eliminates a BsrDI site.

Analyses of embryonic morphogenesis
Four-dimensional microscopy was performed as described (Chin-Sang et al., 1999). To record the embryogenesis of ju430 at 25°C, the objective was enclosed in a copper solenoid infused with temperature controlled water to keep embryos at the desired temperature. At least 10 embryos were recorded for each genotype. Statistical tests used GraphPad Prism (La Jolla, CA).

To determine the temperature-sensitive period of ju430, we cut open gravid adult hermaphrodites grown at 15°C and transferred two- and four-cell-stage embryos to plates pre-equilibrated to 15°C. We shifted plates to 25°C at appropriate times and scored lethality after 24 and 48 hours. 10-15 embryos were recorded for each time point.

Analysis of axon guidance and muscle attachment
We analyzed D type motoneurons using the Punc-25-GFP marker juIs76 (Huang et al., 2002) or the DD marker Pflp-13-GFP ynIs37 (Kim and Li, 2004), PVQs using the Psra-6-GFP marker oyIs14 (Sarafi-Reinach et al., 2001), and muscle using the marker trIs10 (Dixon and Roy, 2005).

Electron microscopy
Electron microscopy was performed as described (Woo et al., 2004). For the analysis of muscle attachment, we analyzed four ju430 animals (raised at 22.5°C) and four e2623 animals; we cut serial sections from the posterior of the pharynx to the anterior end of the gonad. For analysis of PVQ crossing, we sectioned two ju430 oyIs14 animals.

Generation of spon-1 reporter genes
We used duplex PCR to generate Pspon-1-GFP reporters, using 3.3 kb of 5' DNA sequence (primer sequences available on request). This DNA was injected into wild-type animals at 20 ng/µl with pRF4, generating juEx592 and juEx593. To make the SPON-1::GFP C-terminal fusion pCZ697, a 5-kb BamHI-StuI fragment of pCZ695 was subcloned into pPD95.75 (Fire lab vector kit), such that GFP was fused in-frame at residue 756 of SPON-1, truncating the protein after TSR4. pCZ697 was injected into spon-1(ju402)/mIn1 mIs14 animals at 1 ng/µl, with pRF4 as a marker. All 17 transgenic lines failed to rescue ju402. An outcrossed version of transgenic line juEx734 was used in immunostaining experiments.

To tag SPON-1 at the N terminus with Venus YFP, we used a modular strategy (Hudson et al., 2006). We injected SPON-1::GFP at 10 ng/µl with Pttx-3-RFP (50 ng/µl) into spon-1(ju402)/mIn1mIs14 hermaphrodites. Rescued ju402 homozygotes were selected based on the absence of mIs14, yielding transgenic lines juEx1111 and juEx1112. To express SPON-1 in pharyngeal muscles, we used the myo-2 promoter from pPD118.3. Pmyo-2-GFP::SPON-1 was injected into spon-1(ju402)/mIn1mIs14 animals at 50 ng/µl with Pttx-3-RFP. Viable ju402 homozygous transformants were selected, yielding lines juEx1302-1304.

Antibody generation and immunostaining
We raised antibodies against peptides corresponding to residues 499-547 in TSR2 and purified the antisera according to standard procedures. The antisera recognize recombinant SPON-1 C-terminal proteins in bacterial lysates (not shown). Whole-mount immunofluorescence was as described (Finney and Ruvkun, 1990), except that fixation was extended to 3.5-4 hours, an optimization for ECM antigens (J. R. Crew and J. M. Kramer, personal communication). Monoclonal supernatants MH3 (anti-Perlecan), and MH25 (anti-PAT-2 integrin; Developmental Studies Hybridoma Bank, University of Iowa) were used at a dilution of 1:200; DM5-6 (anti-MHC A) (Miller et al., 1983) was diluted 1:200. Phalloidin staining was as described (Ding et al., 2003). To detect GFP, we used monoclonal 3E6 (Invitrogen, Carlsbad, CA) or a rabbit polyclonal (A11122) at 1:500 to 1:1000. Raw or purified anti-SPON-1 antisera were diluted 1:100 for embryo staining and 1:800 for mixed stage staining, unless stated. For anti-SPON-1 immunostaining, we used pCZ695 arrays juEx696 and juEx698, both in ju402 background. We acquired images on Zeiss Axioplan 2 or LSM 510 confocal microscopes.

View larger version (41K): [in this window] [in a new window]   Fig. 2. spon-1 encodes a member of the F-spondin family. (A) Genetic map position, gene organization, and minimal spon-1 rescuing DNA fragment (pCZ695). The nc30 mutation affects the last base pair of exon 3 (CAGgtaa to CAAgtaaa; codon 104), which is likely to force the use of an alternative cryptic splice site, resulting in a frameshift and a premature stop in the reelin domain. (B) Domain organization of SPON-1, and percentage identity to Drosophila fat-spondin and rat F-spondin. (C) Phylogenetic tree of spondin domains of C. elegans SPON-1, Drosophila fat-spondin (CG6953), CG17739, CG30203 and CG30046, rat (Rn) F-spondin, zebrafish (Br) spondin 1a and 1b (F-spondin 1 and 2), Xenopus (Xl) spon-1A and Amphioxus Amphi-F-spondin (Bf, Branchiostoma floridae), made with ClustalW and displayed using njplot (Perrière and Gouy, 1996). (D) Alignment of the thrombospondin type I repeats from SPON-1; missense alterations are shown in red.

	RESULTS

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

We identified the DNA lesions of spon-1 alleles. The ju402 mutation results in a premature stop codon in the spondin domain, and is a candidate null mutation. nc30 alters the last base of exon 3 (Fig. 2A); this does not affect the coding potential but might cause a strong loss of function by altering usage of the intron 3 splice donor. The ju348, e2623 and ju430 lesions cause missense alterations in TSRs 2, 3 and 4, respectively (Fig. 2D), suggesting that these TSRs are crucial for SPON-1 function.

SPON-1 is synthesized in body wall muscles and localizes to specific basement membranes
To understand how SPON-1 functions, we first assayed the activity of the spon-1 promoter. Pspon-1-GFP reporters were expressed exclusively in body wall muscles from early elongation onwards (Fig. 3A-C). We constructed translational GFP fusions in which SPON-1 was tagged with GFP either at the N terminus following the signal sequence, or after the fourth TSR (see Materials and methods). N-terminal SPON-1::GFP transgenes rescued all phenotypes of spon-1(ju402); C-terminal GFP fusions showed similar localization but did not rescue spon-1 mutants, suggesting that C-terminal TSRs are required for the morphogenetic function of SPON-1. Rescuing SPON-1::GFP was expressed by muscles from the comma stage onwards (Fig. 3D, J) and showed localization to embryonic BM (Fig. 3I). In larvae and adults, SPON-1::GFP localized to dense bodies and M lines on muscle surfaces (Fig. 3E,F), as determined by colocalization with the dense body component vinculin (Barstead and Waterston, 1989). Dense bodies and M lines are sites of integrin-based adhesions (Francis and Waterston, 1991), and are also enriched for the BM components UNC-52/Perlecan (Rogalski et al., 1993) and EPI-1/B laminin (Huang, C. C. et al., 2003). We consistently detected SPON-1::GFP on BM surrounding the pharynx (not shown), and within coelomocytes (Fig. 3H). As coelomocytes endocytose extracellular proteins (Fares and Greenwald, 2001), we infer that SPON-1::GFP fusions are secreted. As the spon-1 promoter is not active in the pharynx, SPON-1 can move from sites of synthesis to sites of localization, like type IV collagen (Graham et al., 1997). Unlike type IV collagen, we did not detect SPON-1::GFP at intestinal or gonadal BMs. We also generated antibodies that detect SPON-1 in whole-mount immunostaining of animals overexpressing SPON-1, but not in wild-type animals. The pattern of anti-SPON-1 staining in overexpressing animals was similar to that of SPON-1::GFP, including expression in embryonic and larval muscles (Fig. 3J,K), the excretory canal (Fig. 3K, arrowhead), pharyngeal BM (Fig. 3G) and coelomocytes (not shown). We conclude that SPON-1 is secreted from muscle and incorporates into some, but not all, BMs, and that it is enriched at integrin-based adhesion sites.

View larger version (100K): [in this window] [in a new window]   Fig. 3. SPON-1 is synthesized in muscle and localizes to basement membranes. (A) Ventral view of an adult midbody showing that Pspon-1-GFP (juEx593) is expressed in body wall muscles (arrows, two muscle quadrants). (B) DIC optics showing the muscle quadrants (arrows) on the ventral side near the vulva. (C) Embryonic expression of Pspon-1-GFP from the comma stage onwards. (D-H) SPON-1::GFP localization visualized by anti-GFP immunostaining. (D) In 1.5-fold stage embryos SPON-1::GFP is localized to muscle quadrants (arrowhead). (E) In juEx1111 larvae, SPON-1::GFP localizes at muscle dense bodies (inset, large arrowhead) and at M lines (inset, small arrowhead). (F) Colocalization of SPON-1::GFP (anti-GFP) and the dense body component vinculin (MH24 immunostaining) in juEx734 adult muscles. (G,H) SPON-1 was detected on the pharynx surface (overexpressing line juEx698, arrow, G) and within coelomocytes (SPON-1::GFP, arrowheads, H) in juEx734 adults. (I) Functional SPON-1::GFP expressed under the control of the pharynx-specific myo-2 gene (juEx1302) localizes to muscle BMs (arrowhead) in 3-fold stage embryos (anti-GFP immunostaining). (J,K) Immunostaining with anti-SPON-1 antibodies of animals of genotype spon-1(ju402); juEx698[spon-1(+)]. (J) Dorsal view of a 1.5-fold stage embryo stained with anti-SPON-1 (red), and anti-Myotactin (MH46) and anti-AJM-1 (MH27) (both green), which mark muscle-epidermal attachments and epidermal adherens junctions, respectively. SPON-1 is in muscle cells, beneath Myotactin staining. (K) Larva stained with anti-SPON-1 (red) and anti-MHC (green) to show body muscles. SPON-1 expression was detected in or adjacent to body muscles (arrow) and the excretory canal (arrowhead). Scale bars: 10 µm.

spon-1 mutants display late-onset defects in epidermal elongation and muscle attachment
To determine when spon-1 functions in epidermal morphogenesis, we performed timelapse microscopy on spon-1 embryos. Most (18/19) spon-1(ju402) mutants developed normally past the 2-fold stage of elongation, then either elongated to the 3-fold stage and retracted, or did not reach the 3-fold stage. spon-1 embryos displayed muscle movements before arrest (Fig. 4E-H; see Movie 1 in the supplementary material): they twitched at 1.75-fold (430 minutes) and kept twitching until 3-fold stage. However, only three out of 18 embryos displayed vigorous rolling movements similar to those of the wild type. Muscle movements slowed down between the 2- and 3-fold stages, and then stopped (paralysis). During this period of slower muscle twitching, the epidermis retracted and became uneven in shape (Fig. 4G,H). ju348 and ju430 mutations caused similar or slightly weaker elongation phenotypes than did ju402. Thus, although many spon-1 mutants had a body length comparable to that of a 2- or 2.5-fold stage embryo, they usually elongated beyond this stage and then retracted. Compared with other extracellular matrix mutants, spon-1 most resembles mutants such as emb-9, which lack type IV collagen.

View larger version (138K): [in this window] [in a new window]   Fig. 4. SPON-1 is required for late elongation and interacts with INA-1 -integrin. (A-P) Frames from time-lapse analysis of wild type (A-D), spon-1(ju402) mutants (E-H), putative ina-1(gm144); spon-1(ju430)/+ mutants (I-L) and spon-1 ina-1 double mutants (M-P). Most spon-1(ju402) embryos developed normally up to either 2- or 3-fold stage (F,G), but then retracted to 2.5-fold (H) by the time the wild-type embryo has developed to the 3-fold stage (D). spon-1(ju402) embryos displayed normal muscle twitching movements from 1.75- to 3-fold stage before elongation arrest (see Movie 1 in the supplementary material). Body constrictions became apparent when muscle movements slowed down and later stopped. At the restrictive temperature, spon-1(ju430ts) mutants resemble ju402 in phenotype. More spon-1(ju402) embryos retracted to a 2-fold stage (12/19, 63%) than did spon-1(ju430ts) embryos (7/33, 21%). Sixty-three percent of spon-1(ju402) and 79% of spon-1(ju430ts) embryos reached the 3-fold stage before retraction. spon-1(ju348) embryos were indistinguishable from ju402 in embryonic phenotype. ina-1(gm144) mutants displayed normal elongation (not shown). (I-L) From strains of genotype ina-1(gm144); spon-1(ju430)/mIn1 mIs14 mutants, 41% (18/44) GFP-positive embryos (either ina-1;spon-1/mIn1 mIs14 or ina-1; mIn1 mIs14) displayed late-onset elongation defects. No ina-1 mIn1 mIs14 embryos (n=11) showed elongation defects. We infer that 60% of spon-1/+ heterozygotes have elongation defects in the gm144 background. Six out of seven ju430; gm144 homozygotes (GFP-negative embryos) displayed 1.5-fold arrest (M-P). (Q) Early elongation rates (mean±s.e.m.). spon-1 mutants elongate normally from comma to 2-fold stage, emb-9 mutants were slightly slower, pat-3 mutants were significantly slower (**P<0.05, ANOVA). (R) The spon-1(ju430ts) temperature-sensitive period begins at the 2-fold stage.

Although SPON-1 does not appear to be essential for the early integrin-dependent assembly of the myofilament lattice, the localization of SPON-1 to integrin attachment sites suggested that SPON-1 might have a subtle or redundant role in integrin-mediated adhesion. We therefore used double-mutant analysis to test whether spon-1 interacts with integrin signaling. As animals lacking PAT-2 or PAT-3 arrest at the 2-fold stage, we focused on the -integrin INA-1, which is not essential for embryonic elongation, but which colocalizes with PAT-3 in embryonic BMs (Baum and Garriga, 1997). Animals carrying the hypomorphic mutation ina-1(gm144) display normal epidermal elongation (not shown). spon-1(ju430) ina-1(gm144) double mutants were completely inviable (in contrast to either single mutant at 20°C) and arrested in early elongation (Fig. 4M-P), suggesting that SPON-1 and INA-1 may act redundantly in early elongation. Strikingly, spon-1/+ ina-1 animals resembled spon-1 homozygotes in that they showed a late elongation arrest (Fig. 4I-L). These results suggest that when integrin function is reduced, SPON-1 becomes dose dependent for embryonic elongation.

SPON-1 maintains muscle attachment during later elongation and larval development
The phenotype of spon-1 mutants suggests that, unlike integrins or Perlecan/UNC-52, SPON-1 was not essential for initial assembly of the myofilament lattice. Similarly, the late onset of epidermal elongation defects in spon-1 implies that it is not essential for the assembly of trans-epidermal attachments, as these are required for early elongation (Bosher et al., 2003; Woo et al., 2004). Instead, the late block in elongation appears to be a result of muscle detachment, which in turn leads to failure to maintain epidermal cell shape. We examined epidermal and muscle morphology by using the adherens junction protein AJM-1 to mark epidermal cell boundaries and body muscle myosin heavy chain (MHC) to mark muscle cells (Miller et al., 1983). MHC staining was normal in early elongation (Fig. 5A,B), but, as elongation progressed, we observed frequent gaps along muscle quadrants (Fig. 5C,D) due to muscle detachment. MHC organization in the remaining muscle was essentially normal. Muscle-associated PAT-3/β-integrin and UNC-52/Perlecan likewise became fragmented after the 2-fold stage because of muscle detachment (Fig. 5E-H). Epidermal actin bundles became misoriented following elongation arrest in regions where muscles had detached (Fig. 5I,J). Epidermal attachment structure components, including intermediate filaments and Myotactin, appeared normal before elongation arrest, but became discontinuous in arrested embryos (Fig. 5K,L). These results confirm that SPON-1 is not essential for early muscle or epidermal organization, but becomes essential in later muscle-BM-epidermal adhesion.

To test whether SPON-1 was required in later muscle adhesion, we analyzed post-embryonic muscle anatomy using GFP markers and electron microscopy. In addition to defective muscle-epidermal attachment, spon-1 mutants also displayed defects in muscle-muscle adhesion within a muscle quadrant (Fig. 5M,N). Muscle-muscle adhesion became progressively more defective during larval development and was suppressed by levamisole paralysis, indicating that spon-1 mutant muscles are pulled apart by the force of muscle contraction (Fig. 5O). Muscle ultrastructure in spon-1 mutant larvae was disorganized; in particular, the BM between muscle and epidermis was thicker and invaginated into the muscle (Fig. 5P-R). We conclude that SPON-1 acts continuously throughout development to promote strong adhesion both at muscle-muscle and at muscle-BM interfaces.

View larger version (160K): [in this window] [in a new window]   Fig. 5. SPON-1 maintains muscle-epidermal attachment and muscle organization. (A-D) Muscle quadrants in 2-fold (A,B) and 3-fold (C,D) embryos; anti-MHC-A staining is counterstained with anti-AJM-1 in A and B. 3-fold stage spon-1(ju402) mutants display gaps in MHC staining due to muscle detachment (arrowhead, D). (E,F) Anti-PAT-3/β-integrin (MH25) staining in wild type and in arrested spon-1(ju402) embryos. (G,H) Perlecan (MH3) in wild-type and spon-1(ju402) embryos. Epidermal cell outlines are shown by anti-AJM-1 staining. Similar to MHC-A, both β-integrin and perlecan staining were discontinuous because of muscle detachment (arrowhead in F,H), but were normal in other regions; the gaps were variable in size and position from embryo to embryo. (I,J) Epidermal circumferential F-actin bundles (CFBs), detected by phalloidin labeling in wild-type and arrested spon-1(ju402) embryos. In the wild type, CFBs in lateral epidermal cells were circumferentially oriented (I, arrowhead). In arrested spon-1(ju402) embryos, CFBs in lateral epidermal cells were misoriented (J, arrow), becoming perpendicular to the circumference. (K,L) Myotactin patterns (MH46 antibody staining) in the wild type (K) and in arrested spon-1(ju402) embryos (L). Myotactin patterns are discontinuous along the body; however, normal circumferential double band patterns were observed in the remaining Myotactin. Scale bar in A-L: 10 µm. (M,N) Post-embryonic muscle surfaces visualized using trIs10; note muscle detachment in ju430 (arrowhead, N). (O) Percentage of animals displaying muscle-muscle detachment (n>40 for each condition; Fisher exact test, *P<0.05, ***P<0.001). (P-R) Ultrastructure of larval body wall muscle and BM. (P) Wild-type body muscle, showing dense bodies (db) and regular myofilament lattice; cuticle is at top. (Q) Muscle in spon-1(ju430) larvae grown at 22.5°C; note absence of dense bodies (db), disorganized myofilament lattice and invagination of basal lamina (arrowhead). (R) Higher magnification of basal lamina invagination into muscle (arrowhead). Scale bars in P-R: 500 nm.

spon-1 mutants displayed extensive defasciculation of motoneuron processes within the ventral cord (Fig. 6A,B, Table 2). Motoneuron commissures also displayed defects in left-right choice of outgrowth (Table 2) and often deflected laterally upon reaching the subdorsal muscle quadrant, before eventually reaching the dorsal cord (Table 2A, Fig. 6C-E). To determine whether such guidance defects might be a secondary effect of muscle detachment, we examined motor commissure and muscle morphology simultaneously using the trIs10 marker. Of 20 commissures with dorsoventral guidance defects, only five were in regions of muscle detachment; conversely, in regions of muscle detachment, we frequently saw normal commissural guidance (Fig. 6F). We conclude that dorsoventral guidance defects appear to arise independently of muscle detachment.

SPON-1 continuously maintains axon positions at the ventral midline
F-spondin regulates the crossing of midline axons at the floor plate of the vertebrate spinal cord (Burstyn-Cohen et al., 1999). To learn whether SPON-1 is involved in axon behavior at the C. elegans ventral midline, we examined the PVQ neurons, which undergo regulated midline crossing in the wild type. PVQ neurons in spon-1 mutants frequently displayed inappropriate crossing of the ventral midline (Fig. 7A,B). These defects became more severe during larval development, suggesting that SPON-1 actively maintains process positions. PVQ midline crossing errors were increased in ju430ts animals shifted from 15°C to 25°C in the L1 stage compared with unshifted controls (Fig. 7C), indicating that SPON-1 functions in larval development to prevent midline crossing. This post-embryonic increase in midline crossing errors was also suppressed by levamisole, indicating that crossing errors arise as a result of movement of the animal. Such post-embryonic `flip-overs' have been distinguished from crossing over during initial axon outgrowth, and imply a defect in the maintenance of process positions (Hobert and Bulow, 2003). For PVQ axons to `flip-over' they must traverse the ventral hypodermal ridge. To determine whether PVQ flip-overs might be secondary to an epidermal defect, we performed correlative light and electron microscopy of PVQ flip-over regions, and found that the overall structure of the ventral nerve cords and hypodermal ridge was normal (Fig. 7F-J). We infer that PVQ flip-overs are a direct result of reduced SPON-1 function in the microenvironment of the ventral cord.

View larger version (41K): [in this window] [in a new window]   Fig. 6. SPON-1 is required for motoneuron fasciculation and dorsoventral guidance. (A-E) Motoneuron processes (juIs76) in wild-type (A,C) and spon-1(ju430) mutant (B,D,E) L4s. (B) Defasciculation of D neuron ventral processes in ju430 mutants (arrowhead). (C) Motoneuron commissures in the wild type extend from ventral to dorsal on the right side. (D,E) Motor commissures in spon-1(ju430) mutants turn laterally (arrowhead) upon contacting the dorsal muscle quadrant (m, dotted line) and either extend and terminate subdorsally (D) or turn back to the dorsal midline (arrowhead, E). (F,G) Commissural guidance defects occur independently of muscle detachment (trIs10); commissure guidance can be normal (arrowhead) in regions of body wall muscle detachment (F) and can be aberrant in regions of normal attachment (arrowhead, G). (H-J) D neuron outgrowth in wild type (juIs76, H), in a ju430 juIs76 embryo (I, progeny of animal shifted to 25°C as L4) and in a spon-1(ju402) arrested hatchling (J, ynIs37 marker); all six D neuron commissures (DD1-6) extend dorsally. Scale bars: 10 µm.

View larger version (83K): [in this window] [in a new window]   Fig. 7. SPON-1 maintains process position at the ventral midline. (A) PVQ axons in wild type (oyIs14). (B) In spon-1(ju430), PVQL crosses over to the right-hand VNC (open arrowhead), as in the wild type, and undergoes two ectopic crossovers (white arrowheads). (C) Midline crossing is more penetrant in spon-1 adults than in L1s, is enhanced by shifting L1s from 15 to 25°C, and is suppressed by growth in 1 mM levamisole (**P<0.01, ***P<0.001). (D) Suppression of spon-1(ju430) midline crossing by zig-4 and egl-15 (at 22.5°C; the number of animals is shown in the column) and enhancement by dig-1 (at 20°C; **P<0.01). (E) Model for the interaction of SPON-1 and ZIG-4/EGL-15A pathways; a cross-section of ventral nerve cord is shown. SPON-1 in the BM (green) mediates adhesion of PVQ axons (blue) to their normal environment; ZIG-4 and EGL-15 (red) locally inhibit axon-BM adhesion at the midline. (F-J) spon-1(ju430ts) oyIs14 animals were shifted from 15°C to 25°C in the L1 stage and PVQ scored in young adults. The adults were sectioned in the region of PVQ crossing over posterior to the vulva; approximate levels of sections are shown in F. (G) Anterior to PVQR crossover (0 µm), the left-hand ventral nerve cord contains its normal three processes, the PVQL, PVPR and AVKR (arrowheads and colored blue in G-J). (H,I) Between 90 and 150 µm a fourth process, presumably PVQR, has crossed over and fasciculated with the left-hand bundle. (J) At 160 µm posterior, the left-hand bundle again contains three processes. The ventral hypodermal ridge (HYP, green) and the right-hand ventral nerve cord (RVC, blue outline) appear normal in both crossover regions. Similar results were obtained for a second animal (not shown). Scale bars: in A,10 µm; in G-J, 0.2 µm.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Roles of SPON-1 domains
F-spondins contain a reelin domain, a spondin domain and multiple TSRs. Our genetic and transgenic analysis suggests the TSRs of SPON-1 are crucial for its roles in morphogenesis and axon guidance. Three spon-1 alleles cause missense alterations in TSRs, including the strong allele ju348 and the weak allele e2623. These two mutations affect equivalent residues in the WXXW motifs of TSRs 2 and 3; as these residues are not highly conserved, TSR2 may be more critical for the embryonic morphogenesis function of SPON-1 than TSR3. The temperature-sensitive allele ju430 affects a highly conserved cysteine in TSR4, and could render SPON-1 thermolabile as a result of disruption of one of the disulfide bridges important in TSR tertiary structure (Tan et al., 2002). Although all of these mutations could cause a global disruption of SPON-1 folding, they suggest that the TSRs are required for SPON-1 function in vivo. TSRs 5 and 6 of vertebrate F-spondin mediate interactions with ECM proteoglycans; plasmin-mediated cleavage within TSRs 5 and 6 can release the rest of the protein from the ECM (Tzarfaty-Majar et al., 2001b). As the motifs in TSRs 5 and 6 that mediate proteoglycan interactions are not present in invertebrate spondins, SPON-1 may be less stably attached to the ECM than are vertebrate spondins, consistent with our findings that SPON-1 can accumulate on BMs far from its site of synthesis.

SPON-1 may act in integrin-mediated muscle-epidermal adhesion
Several lines of evidence suggest that SPON-1 acts either in integrin-mediated adhesion or in a closely related parallel process. SPON-1 is localized to integrin-containing sites and SPON-1 function becomes dosage sensitive when -integrin INA-1 function is reduced, indicating that SPON-1 and INA-1 have closely related functions in embryonic development. C. elegans expresses two integrin heterodimers, PAT-2/βPAT-3 and INA-1/βPAT-3 (Brown, 2000; Gettner et al., 1995). PAT-2 is a member of the RGD-binding subfamily of -integrins and is likely to bind Perlecan. INA-1 is a member of the laminin-binding subfamily; it is expressed in embryonic BM but is not required for embryonic morphogenesis (Baum and Garriga, 1997; Poinat et al., 2002). As spon-1 ina-1 double homozygotes arrest earlier in elongation than does either single mutant, SPON-1, at least in part, acts in parallel to INA-1. We speculate that SPON-1 might function in a subset of both INA-1- and PAT-2-dependent adhesion processes. Interestingly, F-spondin has also been linked to integrin signaling (Terai et al., 2001), as has Mindin (Jia et al., 2005; Li et al., 2006). An important goal for the future is to determine whether spondins interact directly with integrins in vivo, or whether they indirectly influence integrin-mediated adhesion via candidate receptors, such as APP or ApoER2 (Ho and Sudhof, 2004; Hoe et al., 2005).

Context-dependent roles of SPON-1 in axonal development
SPON-1 has distinct roles in axon development depending on the neuron type. Such context dependence is reminiscent of the known roles for F-spondin in the vertebrate nervous system. F-spondin promotes the fasciculation of commissural axons after they cross the floor plate (Burstyn-Cohen et al., 1999), and repels the growth cones of motoneurons that do not cross the midline (Tzarfati-Majar et al., 2001a). F-spondin also promotes the outgrowth of sensory and hippocampal neurons in vitro (Burstyn-Cohen et al., 1998; Burstyn-Cohen et al., 1999; Feinstein et al., 1999). In C. elegans, SPON-1 promotes the fasciculation of motoneuron axons in the ventral nerve cord, and acts partly redundantly to promote motoneuron outgrowth. By contrast, SPON-1 appears to prevent midline crossing (fasciculation) of PVQ interneurons.

The deflections of motor commissures at the muscle boundary in spon-1 mutants suggest that SPON-1 promotes the entry of growth cones into the muscle-epidermal BM. Defects in entry of the commissural growth cone at the dorsal muscle quadrant are also found in integrin mutants (Poinat et al., 2002), indicating that integrins act at this choice point. The similarity between spon-1 and integrin defects in motor axon development is consistent with SPON-1 promoting integrin-mediated adhesion or a closely related process in axon guidance.

Midline crossing defects could result from lack of repulsion from a midline repellent, or from lack of axonal adhesion to the normal environment (Hobert and Bulow, 2003). Because we have not seen differential localization of SPON-1 at the ventral midline, we favor the interpretation that the inappropriate crossing of PVQs in spon-1 mutants reflects a lack of adhesion. As dig-1 and spon-1 show additive effects on crossing over, these two ECM molecules may act in distinct adhesive pathways. The ZIG-4 and FGFR(EGL-15A) pathways also maintain PVQ positions, but unexpectedly zig-4 and egl-15A mutations suppress spon-1 midline crossing defects, suggesting that spon-1 and zig-4/egl-15 maintain PVQ positions by opposing mechanisms. We speculate that PVQ maintenance involves a balance of adhesive and repulsive mechanisms. SPON-1 could promote the normal adhesion of PVQs in their respective fascicles, so that a lack of SPON-1 leads to defasciculation and flip-overs. Several models have been proposed for how ZIG-4 might prevent midline crossing (Hobert and Bulow, 2003). One possibility is that ZIG-4 interferes with axon-BM adhesion at the midline, so that axons are unable to cross the midline region. As depicted in Fig. 7E, SPON-1 in the adjacent BM (green) may promote adhesion of PVQ axons (blue) to their appropriate locations, whereas extracellular ZIG-4/EGL-15 (red) might act locally to inhibit axon-BM adhesion at the midline. Thus, impaired axon-BM adhesion in spon-1 mutants might be compensated for by the loss of the ZIG/FGFR anti-adhesive pathway. ZIG/FGFR signaling might directly inhibit SPON-1 based adhesion, or could inhibit a parallel adhesion pathway. Our results underscore the view that the maintenance of process position in the nervous system involves a balance of multiple interacting forces.

In conclusion, our results demonstrate that an F-spondin-related protein promotes tissue adhesion in multiple contexts. SPON-1 functions in parallel to integrin-mediated adhesion in embryogenesis, and is antagonized by other extracellular axon maintenance factors in post-embryonic growth. These results should be useful in elucidating the in vivo cellular receptors for spondins.

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/135/16/2747/DC1

	ACKNOWLEDGMENTS

 
We thank Mei Ding for isolating spon-1 mutations, Christie Emigh and Jian Cao for mapping, and Chris Suh and members of the Chisholm and Jin laboratories for help and support. Some reagents used in this work were obtained from the Caenorhabditis Genetic Center, which is supported by the NIH NCRR. We thank Yuji Kohara for cDNA clones, Andy Fire for vectors, and Jim Kramer for advice on immunostaining. We thank Lindsay Hinck for discussions. W.-M.W. was supported by NIH training grant T32 GM08646 and by a University of California President's Dissertation-Year Fellowship. E.C.B. was supported in part by Diversity Awards from the UC Santa Cruz Center for Biomolecular Sciences. A.G. is supported by HHMI funding to Yishi Jin. This work was supported by the Whitehall Foundation and the US Public Health Service (NIH R01 GM54657).

	Footnotes

 
^* These authors contributed equally to this work

Present address: Program in Epithelial Biology, Stanford University School of Medicine, Palo Alto, CA 94305, USA

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				W.-M. Woo, E. C. Berry, M. L. Hudson, R. E. Swale, A. Goncharov, and A. D. Chisholm The C. elegans F-spondin family protein SPON-1 maintains cell adhesion in neural and non-neural tissues J. Cell Sci., August 15, 2008; 121(16): e1607 - e1607. [Full Text]

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