1 Telethon Institute of Genetics and Medicine (TIGEM), via P. Castellino III, 80131 Naples, ltaly
2 International Institute of Genetics and Biophysics (IIGB), via P. Castellino III, 80131 Naples, ltaly
3 Faculty of Medicine, II University of Naples, Naples, ltaly
* These two authors contributed equally to this work
Authors for correspondence (e-mail: rugarli{at}tigem.it and bazzical{at}iigb.na.cnr.it)
Accepted 11 December 2001
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SUMMARY |
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Key words: Kallmann syndrome, C. elegans, Morphogenesis, Neurite branching
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INTRODUCTION |
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The gene responsible for the X-linked form of the disease (KAL-1) (Franco et al., 1991; Legouis et al., 1991
) encodes an extracellular matrix protein, containing a putative protease inhibitor domain (WAP domain) followed by fibronectin type III (FNIII) repeats. KAL is expressed in the olfactory bulb, the central target of olfactory axons, at the time when innervation begins (Legouis et al., 1993
; Rugarli et al., 1993
). One study showed that KAL displays adhesive properties for a variety of neuronal and non-neuronal cell types, and modulates neurite outgrowth of cerebellar neurons in vitro (Soussi-Yanicostas et al., 1998
). It has been suggested that KAL is involved in terminal steps of olfactory axon guidance to the bulb and that olfactory bulb hypoplasia/aplasia in KS is secondary to lack of innervation. Similarly, GnRH migration impairment has been attributed to the lack of an anatomical connection between the olfactory epithelium and the brain (Ballabio and Rugarli, 2001
; Rugarli, 1999
). However, the mechanism by which lack of KAL leads to the olfactory and other neurological phenotypes and to the abnormalities of renal and palate development is completely unknown.
One of the biggest limitations in exploring KAL function has been the unavailability of an animal model. In fact, a KAL murine homolog has not been identified so far, despite intensive effort. In recent years, the invertebrate Caenorhabditis elegans has become very attractive as an animal in which to study human disease genes (Ahringer, 1997; Culetto and Sattelle, 2000
). Moreover, cell migration and axon guidance cues in invertebrates and mammals have been found to share structural and functional homologies (Blelloch et al., 1999
; Branda and Stern, 1999
; Brose and Tessier-Lavigne, 2000
; Chisholm and Tessier-Lavigne, 1999
; Montell, 1999
).
We have identified kal-1, the C. elegans ortholog of the human KAL gene, and provide the first evidence of its function in vivo. We show that kal-1 is expressed by a subset of neurons beginning in embryogenesis, and is involved in neurite branching and in epithelial morphogenesis. Furthermore, we suggest significant functional conservation between vertebrates and invertebrates, as human KAL cDNA can rescue the phenotype of a nematode loss-of-function mutation and overexpression of worm or human KAL cDNAs in the nematode results in the same phenotypes. These data shed new light on pathogenesis of KS and support the use of C. elegans as a powerful animal for further functional studies of the human KAL gene.
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MATERIALS AND METHODS |
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Identification of C. elegans kal-1 and sequence alignment
Standard molecular biology methods were used (Sambrook et al., 1989), unless otherwise noted. The genomic sequence of kal-1 spans the sequences of cosmids K03D10 (Z81561) and C37A5 (Z92828) and includes the predicted gene K03D10.1. A nematode cDNA clone was identified by database searching (yk172f9). This clone, kindly provided by Y. Kohara, was sequenced using an ABI automatic sequencer and found to contain an almost full-length cDNA. Eleven nucleotides at the 5' end of coding sequence were deduced from the corresponding genomic region. Sequence analysis and prediction of domains was performed using the SMART algorithm (Schultz et al., 1998
). Sequence alignment was performed using the ClustalW program. GenBank kal-1 cDNA sequence Accession Number is AF342986.
Isolation of a kal-1 deletion mutant
The kal-1 mutant gb503 was isolated after Trimethyl Psoralen (TMP) + UV light mutagenesis (Yandell et al., 1994) and PCR screening. The procedure combines steps from several established protocols for gene knockout with chemical mutagens listed at http://cobweb.dartmouth.edu/cgi-bin/cgiwrap/~ambros/protocol.cgi?id=24. Briefly, 200 cultures were set up, each founded by about 1250 synchronized F1 derived from mutagenized mothers. When the F2 was produced, DNA was prepared from one-third of each culture and tested by PCR to identify cultures in which a deletion in the kal-1 locus had occurred. Primers and conditions were designed to amplify preferentially bands deriving from a deleted locus. After a positive culture was identified, four rounds of screening and sibling selection were necessary before cultures could be started with single worms. Eventually a homozygous culture of the deletion carrying strain was established. Mutants were backcrossed to N2 four times before phenotypic analysis. After genetic crosses wild-type and mutant kal-1 alleles were detected by single worm PCR. The backcrossed strain will be deposited at the C. elegans Genetic Center. Sequences of diagnostic primers are available upon request.
Reporter and overexpression constructs
The kal-1 regulatory region fragment of 4.3 kb present in all constructs was generated using PCR on genomic DNA. The primer sequences are available upon request. The fragment was directionally cloned between the SphI and BamHI sites of vectors pPD95.75 and pPD21.28 for plasmids GB102 and GB105, respectively (http://www.ciwemb.edu/pages/firelab.html) (Fire et al., 1990). Plasmid CeKAL was obtained by substituting in GB102 the GFP coding sequence with that of kal-1 cDNA from the ATG to the stop codon. Plasmid HuKAL was obtained by substituting, in CeKAL, the sequences of the C. elegans cDNA from position 156 to the end with the corresponding region of human cDNA. This construct leads to the translation of a protein containing the first 52 amino acids of the nematode cDNA fused in frame with amino acids 77 to 680 of human KAL. Further details of plasmids construction can be obtained on request.
Transgenic lines
Germline transformation was accomplished as described (Mello and Fire, 1995). The following co-injection markers were used: pRF4 [rol-6 (su1006)] (Mello and Fire, 1995
); plin-15(+), a gift from S. Emmons (NY); pJM67 (elt-2::GFP), a gift from J. McGhee, Calgary; and GB110 (Fe65::GFP), a gift from M. Bimonte, Naples. In general, the test plasmids were co-injected with the marker DNA at a 1:1 ratio. Rescue with the genomic region was assayed by co-injecting, in kal-1(gb503) worms, cosmid K03D10 and plasmid pJM67 (elt-2::GFP), at 20 and 20 ng/µl, respectively. HuKAL was injected at 100 ng/µl, while marker DNA was injected at 20 ng/µl. Lower ratio produced less penetrant phenotypes. For each construct, several independent transgenic lines were obtained and analyzed. Embryonic lethality is reported for three lines for each construct: gbEx13a, b, c, for CeKAL and gbEx17a, b, c, for HuKAL (Table 1).
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Embryonic phenotype
Embryonic lethality was observed in strains with different genotypes and carrying different extrachromosomal arrays. gbEx12 is an extrachromosomal array containing plasmid GB110 (Fe65::GFP) in which GFP is expressed in embryos in several cells. gbEx13 is an extrachromosomal array containing plasmid CeKAL and, as selectable markers, plasmid GB110 and plasmid pRF4, which confers a roller phenotype. Results were scored from three independent lines. gbEx16 is an extrachromosomal array containing plasmid pJM67 (elt-2::GFP) and the plin-15(+) construct. gbEx17 is an extrachromosomal array containing plasmid HuKAL and, as selectable markers, plasmid pJM67 (elt-2::GFP) and the plin-15(+) construct. Results from three independent lines were scored.
Embryonic lethality was determined by picking 5-10 L4 animals of different genotype to several separate plates, allowing them to lay eggs and transferring them every 6-12 hours. Laid eggs were counted just after removing the mother, and larvae that had hatched were counted after 24 hours: the difference between these values was scored as embryonic arrest. In transgenic strains, only transformed animals, recognizable because of the expression of GFP from a marker plasmid, were counted. The stages when mutant embryos arrested were determined by following the development of embryos using DIC optics. Embryos were followed from 1.5 hours after fertilization until either development arrested or the embryo hatched.
Male tail defects
The tail defects were observed in males of different genotypes and carrying different extrachromosomal arrays. gbEx10 is an extrachromosomal array containing cosmid K03D10 and the pJM67 (elt-2::GFP) plasmid as a selection marker (other independent lines obtained with the same DNA mixture gave similar results); gbEx13b and gbEx17a are extrachromosomal arrays described above, each transferred both to a kal-1; him-8 and to a him-5 background.
Male tails were observed using DIC optics (40x magnification) and only clearly visible sides were scored. In transgenic lines only transforming worms were mounted and observed. In the rescue experiment, adult male worms were chosen randomly from strains carrying the extra-chromosomal arrays gbEx10, gbEx13b and gbEx17a. These males were first scored for tail defects and then for the presence of the GFP marker. kal-1 RNA interference (Fire, 1998) was carried out by injecting dsRNA from the fifth exon in him-5(e1490) hermaphrodites. Tails of F1 males were scored and about 30% of them showed ray abnormalities.
Statistics
P values for different experiments were calculated using both chi-square and z statistics.
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RESULTS |
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Similar to its vertebrate counterpart, CeKAL-1 contains a hydrophobic signal peptide at the N terminus followed by a cysteine-rich region, a whey acidic protein domain (WAP), and three fibronectin type III domains (FNIII) (Fig. 1A,B). The presence and topological organization of these domains is conserved between nematode and human, and is unique to KAL proteins. The CeKAL-1 protein contains a putative GPI anchoring site at the C-terminus that is absent in the other species. No other predicted C. elegans ORF contains both WAP and FNIII domains. The identification of kal-1 indicates that an ancestral gene with sequence and domain organization similar to KAL-1 was already present before the invertebrate-vertebrate separation.
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Mutant animals with reduced and with increased kal-1 function showed similar defects albeit with different penetrance: embryonic lethality, abnormalities of larval morphology and, in adult worms, defects of the male tail and neurite outgrowth defects. These phenotypes are described separately below.
Embryonic ventral enclosure is defective in kal-1 mutants
Reduction or increase of kal-1 function results in embryonic lethality and morphological abnormalities of newly hatched larvae. Worms transformed with CeKAL show variably penetrant embryonic lethality, which ranges from 45 to 73%, depending on the extrachromosomal array. The embryonic lethality of the loss-of-function mutant gb503 is lower than that of overexpressing mutants but also in this case the difference from controls is statistically significant (Table 1).
Three main morphogenetic processes occur during C. elegans embryogenesis: gastrulation, ventral enclosure and elongation. C. elegans gastrulation involves the ingression of gut, germline and mesoderm precursors, and leaves a depression, called gastrulation cleft, on the ventral side of the embryo. The gastrulation cleft is then closed by a short-range movement of ventral neuroblasts flanking the cleft. At this stage the epidermis consists of two dorsal, two lateral (future seam cells) and two ventral rows of cells aligned longitudinally on the dorsal side of the embryo. In the next major morphogenetic process, ventral enclosure of the embryo, the epidermal cells spread, from their dorsal position and over the ventral neuroblasts, to surround the embryo and join with contralateral epidermal cells at the ventral midline. Ventral enclosure is followed by elongation, which transforms the embryo from an ovoidal mass into an elongated, worm-shaped organism (Priess and Hirsh, 1986; Williams-Masson et al., 1997
).
Affected kal-1 mutant embryos are defective in ventral enclosure and rupture ventrally with cells protruding out of the embryonic mass (Fig. 3B-D). These embryos neither complete development nor hatch, contributing to the embryonic lethality of kal-1 mutants. As it occurs in other C. elegans mutants that are defective in ventral enclosure (Chin-Sang and Chisholm, 2000; Roy et al., 2000
; Simske and Hardin, 2001
), some embryos seem to present later or milder enclosure defects that affect especially the extremities, head and tail (not shown). Some of these embryos complete development and give rise to abnormal larvae (Fig. 3J-L).
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Male tail morphogenesis is defective in kal-1 mutants
The tail of C. elegans males is a symmetric structure required for mating and composed of a heart-shaped cuticular fan and nine sensory rays on each side (Fig. 4A). Although they mate with reasonable efficiency, the majority of gb503 males shows various tail abnormalities (Table 2). Overexpression in wild-type worms of C. elegans kal-1 from an array carrying the CeKAL plasmid also produces male tail defects (Table 2). In general, the whole structure appears irregular and distorted. In addition the presence, position, shape and size of the nine rays are also variably altered (Fig. 4B-F). The most common defects are reduction of sensory rays, which often take a ball like shape (rays 1 to 3), presence of an extra ray in the region between ray 1 and 2, and inversion of the position or fusion of two rays (especially ray 5 and 6) (Table 2).
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As for ventral enclosure, also in the case of male tail formation the defects presented by kal-1 mutants appear to be due to changes in the position and the shape of the rays rather than in the specification of their identity. For example, in the frequently observed inversion/fusion of rays 5 and 6, ray 5 is found posterior or fused to ray 6 but maintains its identity (Fig. 4D). Visualization of epidermal cell boundaries during tail morphogenesis confirms that in kal-1 mutants epithelial cells of the tail have abnormal contacts, shapes and positions. At the L4 stage, in males, the nine clusters of cells that will give rise to the sensory rays have already been generated, on each side. Tail morphogenesis continues with cell movements and changes of shape and contacts that result in the correct positioning and separation of the precursors of the rays (Fig. 4G). These processes are impaired in mutants and result in defects in the arrangement of the ray precursors clusters and in abnormal shape of some of the cells involved (Fig. 4I). For example, in mutants the tail seam cells fuse to form the SET cell as in the wild type, but this cell often loses contact with the most posterior body seam-cell and acquires a rounded shape (Fig. 4I).
kal-1 mutants show neurite outgrowth defects
Some of the most important symptoms of Kallmann syndrome appear to be derived from neuronal and axonal migration defects. Analysis of movement and of some sensory-based behaviors of kal-1 mutants did not show significant differences from wild type (not shown). However, expression of GFP under neuron-specific promoters allowed us to visualize directly neuronal processes and detect neurite growth defects in kal-1 mutants. EF3 is a male-specific neuron whose cell body is placed ventrally in the pre-anal ganglion (Sulston et al., 1980) (Fig. 5A). The EF3 dendrite runs posteriorly along the midline and makes connection with the projections of several of the sensory ray neurons of the male tail. EF3 is one of the neurons expressing GFP under the kal-1 regulatory sequences (see below) and thus it is easily visible in transgenic strains carrying the expression construct GB102 (Fig. 2B). In 15% of kal-1(gb503) male worms, which are transgenic for GB102, the EF3 neuron has an extra-branching of the dendrite that usually runs in the same direction and parallel to the normal one, but terminates prematurely and thus apparently does not connect to a target (Fig. 5B,C).
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Although we cannot distinguish if normal outgrowth of EF3 or RIC requires the CeKAL-1 protein secreted by the affected neurons themselves, or by nearby kal-1-expressing neurons, these defects demonstrate for the first time that a KAL protein can affect neurite outgrowth in vivo and suggest that it might function in this process as a regulator of neurite branching.
Functional conservation of the human KAL gene in C. elegans
In order to test experimentally the extent of functional conservation of the KAL gene between man and worm, we transformed nematodes with a construct in which expression of human KAL cDNA is driven by the 5' regulatory sequences of the C. elegans kal-1 gene (HuKAL, Fig. 2B). Expression of human KAL cDNA in the loss-of-function mutant kal-1 (gb503) rescues its male tail defects (Table 2). In addition, overexpression of human KAL cDNA in wild-type worms results in embryonic lethality (Table 1 and Fig. 3D) and male tail defects (Table 2 and Fig. 4F) that are indistinguishable, although less penetrant, than those caused by overexpression of C. elegans kal-1. These results indicate that conservation of the KAL protein between man and worm is not limited to structure, but is also functional, and give further support to the hypothesis that kal-1 is the ortholog of the human gene for X-linked Kallmann syndrome. They also define the experimental setting for future studies aimed at analyzing the structure-function relationship of KAL proteins in vivo.
Expression of kal-1 reporters is restricted to subsets of neuronal cells and is consistent with the phenotypes of kal-1 mutants
To study the expression of kal-1 in C. elegans and to try to correlate it with the phenotypes observed in mutants, we analyzed worms transgenic for constructs in which expression of reporters (GFP or ß-galactosidase) was driven by sequences at the 5' end of the kal-1 gene. A variety of constructs were prepared using 5' regulatory sequences of kal-1 spanning from 1000 to 4300 bp upstream of the ATG. In all cases expression was restricted to the same subsets of neuronal cells. Expression was highest with a 4300 bp fragment (plasmids GB102 and GB105 of Fig. 2B). This regulatory region was also used to drive the expression of KAL cDNAs in the rescue and overexpression experiments (constructs CeKAL and HuKAL).
During embryogenesis kal-1 expression is first detectable at about the 160- to 200-cell stage in a group of eight to ten neuroblast descendants of the AB blastomere (Fig. 6A,B). These neuroblasts are located on the ventral surface of the embryo where they first surround and later close the gap left by the gastrulation process. kal-1-expressing neuroblasts are then covered by epithelial cells, which migrate around the embryo to join at the ventral midline for ventral enclosure. Thus, kal-1 is expressed by the cells that act as a substrate for the epithelial migration during enclosure. This expression underlies the function of kal-1 during embryogenesis and can explain the defects of embryonic development present in kal-1 mutants. At no stage during embryogenesis were kal-1 driven reporters detectably expressed by epidermal cells.
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DISCUSSION |
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The role of kal-1 in epidermal morphogenesis
This study shows that kal-1 is involved in at least two distinct morphogenetic events in the worm: ventral enclosure and male tail formation. Both processes involve a regulated series of dynamic epithelial and neuronal cell contacts and of cell-shape changes, and have been shown to depend on the action of partially redundant molecular cues (Chin-Sang et al., 1999; George et al., 1998
; Roy et al., 2000
; Wang et al., 1999b
). In kal-1 mutants, epithelial cell contacts and shapes are variably disrupted during morphogenesis, suggesting that kal-1 might modulate the formation or stabilization of contacts between cells. These inappropriate contacts can be due either to the failure to establish stable adhesive bonds in the right position or to the stabilization of an ectopic contact that would otherwise collapse. The identification of kal-1-interacting proteins and of downstream signaling pathways will shed new insights into these two possibilities.
Our expression data strongly suggest that CeKAL-1 is acting in a non cell-autonomous way, being secreted by neurons and influencing epithelial cells. Although these studies have been performed using reporters driven by kal-1 regulatory sequences, we believe that they reproduce reasonably well the endogenous kal-1 expression. This is strongly supported by the ability of KAL cDNAs, whose expression is driven by the same regulatory sequences, to rescue the most penetrant phenotype of the kal-1 loss-of-function mutant.
We observe similar phenotypes in loss-of-function and overexpressing kal-1 mutants. A strict dose control of the secreted molecules involved in contact guidance during morphogenesis and axonal growth may underlie this phenomenon. Indeed, similar findings have been reported for mutants of other extracellular molecules involved in adhesion and axon guidance (Ackley et al., 2001; Powell et al., 2001
; Roy et al., 2000
). Tight regulation of CeKAL-1 dose might explain an apparent paradox of previous results obtained in cell culture systems, where KAL was found to stimulate cerebellar axon outgrowth, when added in a uniform concentration, and to induce cessation of growth when provided as a discontinuous substrate in high local concentrations (Soussi-Yanicostas et al., 1998
). This notwithstanding, we observe that, while embryonic ventral enclosure is more sensitive to an increase than to a reduction of kal-1 function, the opposite appears to be true for male tail formation. A more sophisticated phenotypic analysis might reveal opposite effects of hypomorph and hypermorph kal-1 mutations.
The association of ventral enclosure defects and malformation of the male tail has been previously described in C. elegans mutants of the Eph receptors/ephrins pathways (vab-1, vab-2, efn-2 and efn-3) (Chin-Sang et al., 1999; George et al., 1998
; Wang et al., 1999b
; Zallen et al., 1999
) and semaphorin-2a (mab-20) (Roy et al., 2000
). Similarly to kal-1, mab-20/Ce-sema-2a seems to regulate proper contacts between hypodermal cells (Chin-Sang and Chisholm, 2000
; Roy et al., 2000
). As mab-20 is ubiquitously expressed, it has been suggested that the ability of a cell to respond to semaphorin signaling must be controlled by the expression of a receptor, a co-factor, or downstream signaling components. The neuroblast-restricted expression pattern of kal-1 makes it a candidate to be a regulated element of this pathway.
A crucial role of neuronal cells in epidermal cell movements during ventral enclosure has been inferred from the analysis of ventral enclosure defects in vab-1 and vab-2 mutants (Chin-Sang et al., 1999; George et al., 1998
; Wang et al., 1999b
). VAB-2 signaling to VAB-1 occurs before and during enclosure between neuronal precursors, regulating their adhesion or movement. Some vab-1 or vab-2 mutant embryos die owing to failure of the neuroblasts to close the ventral gastrulation cleft. However, in other embryos, enclosure fails even though the gastrulation cleft is sealed, suggesting that neuroblasts may provide a permissive substrate or a guidance molecule to epidermal cells (Chin-Sang et al., 1999
; George et al., 1998
). It is plausible that kal-1, expressed by the ventral neuroblasts during enclosure, is one of such cues. Although CeKAL-1 harbors a GPI anchor, we have preliminary data indicating that, at least in cell culture conditions, it is partially diffusible. One possible scenario is that CeKAL-1, either associated with the surface of the expressing neurons or released into the ECM, signals to a yet unidentified receptor present on epithelial cells. An alternative model is that CeKAL-1 specifically modulates other negative and positive guidance cues, for example, through its anti-protease domain. In fact, there is emerging evidence that metalloproteases and their inhibitors are important regulators of contact-mediated attraction or repulsion, by controlling the number of functional extracellular receptors (Galko and Tessier-Lavigne, 2000
; Hattori and Flanagan, 2000
).
kal-1 is involved in neurite branching
The analogies among vab-1, mab-20 and kal-1 mutants are not restricted to their role in morphogenesis. vab-1 and mab-20 mutants in fact also display aberrant axon growth, such as guidance and fasciculation defects (George et al., 1998; Roy et al., 2000
; Zallen et al., 1999
). In vertebrates, these molecules have been mostly studied for their function in axon guidance, and only recently have been involved in morphogenetic events (Flanagan and Vanderhaeghen, 1998
; Holder and Klein, 1999
; Ito et al., 2000
; Raper, 2000
; Tessier-Lavigne and Goodman, 1996
).
Abnormal neurite growth of the EF3 and RIC neurons was observed in kal-1 mutants. The abnormal neurite is characterized by the appearance of an extra-branch, suggesting that CeKAL-1 may act as a modulator of branch formation. In all these mutants, neurite defects may, in principle, result from defective morphogenesis leading to the aberrant positioning of other cues. However, the role of Eph receptors, ephrins, and semaphorins in axon guidance in vertebrates and the phenotype of KS make a strong case in favor of a direct effect. Extra-branching can be interpreted as a reinforcement of an ectopic contact between an axon collateral and the environment, underlying the same mechanism of CeKAL-1 action that we have postulated during morphogenesis.
Although a role of KAL in some aspects of axon guidance has been always suggested, based on the human KS phenotype, this is the first time a specific function on neurite growth is documented. So far the only factor for which a role as positive regulator of axonal elongation and branching has been demonstrated is the mammalian Slit2 (Wang et al., 1999a). Slit2 is a bifunctional molecule, implicated both in repelling migrating cells and axons, and in stimulating axonal branching, further supporting the idea that there are general mechanisms controlling cell migration, axon pathfinding and axon branching (Brose and Tessier-Lavigne, 2000
).
Relevance to Kallmann syndrome pathogenesis
We have clearly shown significant functional conservation of the human KAL protein in the nematode. Therefore, we think that our findings in C. elegans are relevant to the function of the human KAL gene and justify a re-examination of the mechanisms that underlie the pathogenesis of KS. KAL proteins may be involved in morphogenesis during development, both in the brain and in other tissues, by regulating cell adhesion and preventing the formation of ectopic cell contacts. Defective morphogenesis and perturbation of cell migration may explain some symptoms observed in individuals with KS, such as cleft lip and palate, and unilateral renal hypoplasia/agenesis (Colquhoun-Kerr et al., 1999; Hermanussen and Sippell, 1985
; Wegenke et al., 1975
). KAL involvement in brain morphogenesis has been so far underestimated, but our results strongly induce to reconsider the possibility that olfactory bulb hypoplasia in KS may be due to defective bulb formation, rather than to bulb involution caused by lack of innervation.
Our data also suggest that KAL may directly affect specific axonal populations, by regulating neurite branching and therefore the formation of axon collaterals and the establishment of target connections. KAL may specifically affect olfactory axon outgrowth by regulating branching and by stabilizing contacts of growth cones with the matrix and neurons of the bulb. Specific axonal defects might underlie the occurrence of mirror movements and other neurological symptoms in individuals with KS.
Finally, KAL appears to be involved in highly redundant pathways in both human and worm. All the kal-1 mutant phenotypes described in this paper are observed with incomplete penetrance. As no other C. elegans protein is found with the same domain composition as CeKAL-1, we can rule out the presence of a homologous gene with a similar role, and conclude that redundancy of CeKAL-1 function is due to other molecules and pathways active in the same developmental processes. For many symptoms described in individuals with KS, even as dramatic as unilateral renal aplasia, incomplete penetrance has been reported. Furthermore, KS is a genetically heterogeneous disease and mutations in KAL have been found to be responsible in only a limited percentage of cases (Georgopoulos et al., 1997).
In conclusion, we have established the nematode as a system to study the function of the KS gene in vivo. The advantage of using C. elegans as a model lies in the possibility of performing protein structural-functional studies in vivo and in the power of epistatic studies. We predict that these studies will aid in the identification of domains relevant for KAL function, and of other components of the same pathway.
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ACKNOWLEDGMENTS |
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