Maternally Derived Immunoglobulin Light Chain Is Present in the Fetal Mammalian CNS

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Volume 17, Number 9, Issue of May 1, 1997 pp. 3148-3156
Copyright ©1997 Society for Neuroscience

Maternally Derived Immunoglobulin Light Chain Is Present in the Fetal Mammalian CNS

Joshua A. Weiner¹ and Jerold Chun²
¹ Neurosciences Graduate Program and ² Neurosciences and Biomedical Sciences Graduate Programs, Department of Pharmacology, School of Medicine, University of California, San Diego, La Jolla, California 92093-0636

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Toward identifying molecules involved in cell-cell interactions during cerebral cortical development, we have investigatedthe nature of immunoglobulin-like immunoreactivity (Ig-ir) inthe murine cortex. Immunohistochemistry using several antiserarecognizing IgG revealed intense immunoreactivity in the subplateand marginal zone of embryonic day 16 cortex, as well as in thehindbrain and spinal cord, particularly within ventral fiber tracts.In three independently derived mouse strains lacking the recombinationactivating genes RAG-1 or RAG-2, which are essential for Ig production,Ig-ir was absent from the fetal CNS. Western blot analyses ofwild-type brains from embryonic day 12 through birth identifieda 25 kDa protein that co-migrated with Ig light chain and wasabsent from RAG-1 or RAG-2 $-$ / $-$ brain samples. This result couldbe replicated with an antiserum specific for Ig $kappa$ light chain,but not with antisera specific for Ig $gamma$ or µ heavy chain. No Ig-irwas detected in the brains of RAG-1 +/ $-$ embryos carried by a $-$ / $-$ female, suggesting a maternal source of the immunoreactive molecule.In confirmation of this, Ig-ir could be partially reproduced byintraperitoneal injection of pregnant RAG-1 $-$ / $-$ females with normalmouse serum. We conclude that maternally derived Ig light chainis present in the fetal murine CNS. This may represent a novelmaternal contribution to fetal neural development and implicatesIg molecules as potential mediators of cortical developmentalevents.
Key words: subplate; cortex; immunoglobulin; RAG; development; light chain

INTRODUCTION

During fetal development, the mammalian cerebral cortex consists of transient histological zones distinct from those of theadult (Boulder Committee, 1970). Two of these, the subplate andmarginal zone, contain the earliest-generated neurons of the cortex(Luskin and Shatz, 1985; Chun et al., 1987), which are largelyeliminated in the early postnatal period (Chun and Shatz, 1989;Woo et al., 1991; Wood et al., 1992). Afferent fibers from thethalamus, which will innervate the cortical plate, arrive early,before their target neurons have migrated, and "wait" in the subplate(Luskin and Shatz, 1985). Their correct cortical targeting dependson cell-cell interactions within the subplate, which include transientsynapses and contact with extracellular matrix components (Stewartand Pearlman, 1987; Chun and Shatz, 1988a,b; Ghosh et al., 1990).

Members of the immunoglobulin superfamily (IgSF) likely have roles in such developmental events, although gene knock-out studieshave not revealed clear cortical phenotypes (Tomasiewicz et al.,1993; Cremer et al., 1994; Müller and Kypta, 1995). Two IgSFmembers, N-CAM and L1, are known to be expressed within the subplate(Fushiki and Schachner, 1986; Chung et al., 1991). Actual immunoglobulin(Ig) molecules may also be present, based on the observation ofIgG-like immunoreactivity (Ig-ir) in the fetal subplate and marginalzone of the rat (Fairén et al., 1992). The identity of the immunoreactivemolecule(s), however, is unknown.

Igs consist of two heavy and two light chains. Both heavy and light chains contain variable regions with antigen binding domainsthat are encoded by constituent gene segments, assembled throughsomatic DNA rearrangement referred to as V(D)J recombination (Tonegawa,1983; Schatz et al., 1992). V(D)J recombination and, thus, B-cellproduction of Igs depend on the immunological recombinase encodedin part by the recombination-activating genes RAG-1 and RAG-2(Schatz et al., 1992; McBlane et al., 1995). In addition to thevariable regions, both heavy and light chains contain constantregions that do not undergo V(D)J recombination. Five constantregion isoforms define five Ig subtypes: $gamma$ (IgG), µ (IgM), $alpha$ (IgA), $delta$ (IgD), and $epsilon$ (IgE). Light chain constant regions are of twotypes, which appear in all Ig classes: $kappa$ , which comprises 95%of the murine light chain pool (Chen et al., 1993), and $lambda$ . Althoughautonomous Ig production in the mouse begins postnatally (Applebyand Catty, 1983; Cooper and Nisbet-Brown, 1993), IgG is placentallytransferred from mother to fetus during gestation (Appleby andCatty, 1983; Parr and Parr, 1985).

Here, we have investigated the identity of the molecule responsible for Ig-ir in the developing murine CNS. Using immunohistochemistryand Western blot analyses on RAG-1 and RAG-2 wild-type and mutantmice, we show that the molecule co-migrates with Ig light chain,is dependent on RAG-1 and RAG-2, is maternally derived, and canbe reconstituted in RAG $-$ / $-$ mice by normal serum, identifyingthe molecule as Ig light chain.

MATERIALS AND METHODS
Animals. Embryos were obtained from timed-pregnant female mice, with morning of vaginal plug designated day 0. On embryonicday 12 (E12), E14, or E16, pregnant mice were anesthetized viaintraperitoneal injection with 0.8 ml of 2.5% (v/v) Avertin. Embryoswere removed and either prepared for immunohistochemistry or dissectedfor protein samples. Methods were similar for postnatal animals.Some pregnant RAG-1 $-$ / $-$ animals were injected intraperitoneallywith 0.9 ml of normal mouse serum (Sigma, St. Louis, MO) at E13.5.RAG-1 $-$ / $-$ mice and their matched background strain (C57BL/6-129)were obtained from Jackson Laboratories (Bar Harbor, ME); a second,independently derived RAG-1 $-$ / $-$ strain was obtained from Drs.E. Spanopoulou and D. Baltimore (MIT). RAG-2 $-$ / $-$ mice were obtainedfrom Taconic Farms (Germantown, NY). The ages, numbers, and typesof animals used in these studies are summarized in Table 1.

Table 1. Types and ages of animals analyzed

Animal type Age Number of animals analyzed

Immunohistochemistry Western blot

Wild type^a E12 $---$ 4

E14 2 4

E16 18 14

P1 5 6

RAG-1 $-$ / $-$ ^b E16 4 5

P1 3 4

RAG-2 $-$ / $-$ E16 4 6

RAG-1 $-$ / reated with normal mouse serum E16 4 5

RAG-1 +/ $-$ E16 2 3

Totals 42 51

^a Includes animals from three different strains: Balb/c, 129/Sv, and a C57BL/6-129 background strain matched to one of the RAG-1 $-$ / $-$ strains used. All strains gave similar results; animals shownare from the matched-background strain. ^b Includes animals from two independently derived RAG-1 $-$ / $-$ strains (Mombaerts et al., 1992; Spanopoulou et al., 1994). Bothstrains gave similar results; animals shown correspond to themutation described by Mombaerts et al. (1992) and were obtainedfrom Jackson Laboratories (Bar Harbor, ME).

Tissue preparation for histology. Embryos and neonates were either perfusion- or immersion-fixed in Millonig's fixative (4%paraformaldehyde, 0.1 M monobasic sodium phosphate, pH 7.4). Wholeembryos or heads were post-fixed overnight in the same fixative,followed by immersion in 6% sucrose in PBS overnight. Tissue wasembedded in Tissue Tek freezing compound (Miles, Elkhart, IN)and snap-frozen in Histofreeze (Fisher Scientific, Pittsburgh,PA) on dry ice. Sagittal cryostat sections (20-µm-thick) weremounted onto double gelatin-subbed glass slides. Slides were usedimmediately for immunohistochemistry or stored desiccated at $-$ 20°C.

Immunohistochemistry. The primary antisera and dilutions used in immunohistochemistry and Western blot analyses are listedin Table 2. Cryostat sections were incubated in a humidifiedchamber at room temperature with blocking solution [5% BSA, 0.6%(w/v) Triton X-100 in PBS] for 1 hr or longer, followed by overnightincubation with the various antisera diluted in blocking solution.Slides were washed in multiple changes of PBS, incubated for 1hr with secondary antiserum (biotinylated anti-rabbit IgG at 1:200in PBS; Vector Laboratories, Burlingame, CA), and treated with0.3% H₂O₂ in methanol to inactivate endogenous peroxidase activity(for slides incubated with biotinylated primary goat or horseantiserum, a secondary antiserum step was not necessary). Visualizationused ABC-HRP (ABC kit, Vector) and 0.5 mg/ml DAB (Sigma) with0.01% H₂O₂ in TBS. Adjacent sections were stained with 0.5% (w/v)cresyl violet. Control sections were incubated with secondaryantiserum in the absence of primary antiserum incubation or withprimary antiserum (anti-IgG) preincubated with a 2.5-fold excessof purified mouse IgG (Sigma) for 30 min at room temperature orat 37°C; no immunostaining was observed. Slides were dehydratedin graded ethanols and mounted in toluene-based resin (Cytoseal60, Stephens Scientific, Riverdale, NJ) for light microscopy.

Table 2. Antisera and dilutions used

Antiserum Dilution
Source

Immunohistochemistry Western blot

Rabbit anti-mouse IgG (H + L)^a 1:400 1:5000 Jackson ImmunoResearch, West Grove, PA

Horse anti-mouse IgG (H + L), biotinylated 1:400 1:2000 Vector Laboratories, Burlingame, CA

Horse anti-mouse Ig $gamma$ heavy chain, biotinylated 1:400 1:2000 Vector Laboratories

Goat anti-mouse Ig µ heavy chain, biotinylated 1:400 1:2000 Vector Laboratories

Rabbit anti-mouse Ig $kappa$ light chain 1:2000 1:20,000 Advanced Chemtech, Louisville, KY

Rabbit anti-synapsin I 1:500 1:5000 Dr. John Bixby, University of Miami, Miami, FL

^a Recognizes both heavy (H) and light (L) chains of IgG.

Western blotting. Techniques were essentially as described previously (Chun and Jaenisch, 1996). Mouse brains were removedrapidly from the cranium, added to an equal volume of 2 × samplebuffer [0.125 M Tris, pH 6.8, 4% SDS, 20% (v/v) glycerol, 10%(v/v) $beta$ -mercaptoethanol, 0.02% bromophenol blue] and homogenizedin a glass Dounce homogenizer. Samples were boiled for 10 minbefore use and stored at $-$ 20°C. Adult spleen, WEHI 231, and mouseIgG samples were similarly prepared. Protein samples (~20-30 µg)were separated by discontinuous SDS-PAGE using 11 or 15% separatinggels. For purified mouse IgG preparation (Sigma), 25 ng of proteinwas loaded. Proteins were transferred to PVDF membranes (ImmobilonP, Millipore, Bedford, MA) and blots blocked as suggested by themanufacturer. After overnight incubation in primary antisera dilutedin 1% BSA and 0.05% Tween 20 in TBS, blots were washed in 0.1%BSA in TBS, incubated with secondary antiserum (biotinylated anti-rabbitIgG at 1:1000; Vector) for 45 min, and visualized as above. Controlblots for which primary antiserum was omitted or (for anti-IgG)preincubated with fivefold excess mouse IgG eliminated or nearlyeliminated immunoreactive bands, respectively.

Southern blotting. Techniques used were essentially as described (Chun and Jaenisch, 1996). To confirm the genotype of examinedwild-type, RAG-1 $-$ / $-$ , and RAG-2 $-$ / $-$ tissues, the tail regionsof representative embryos were removed and incubated overnightat 50°C in digestion buffer (0.075 M NaCl, 0.025 M EDTA, 0.01M Tris, pH 8.0, 1% SDS, 0.4 mg/ml proteinase K). Samples wereextracted with phenol/chloroform and the genomic DNA ethanol precipitated,collected by spooling, dissolved in TE (10 mM Tris, 1 mM EDTA,pH 8.0), and digested with BamHI and NcoI (for RAG-1) or EcoRIand XbaI (for RAG-2) for fractionation by agarose gel electrophoresis.Gels were Southern blotted using standard methods (Ausubel etal., 1994) and hybridized overnight at 65°C with the appropriate³²P-labeled probe (1-2 × 10⁶ cpm/ml) (Mombaerts et al., 1992; Shinkai et al., 1992).

RESULTS

Ig-ir is present in the fetal CNS
Ig-ir was first examined in the developing cortex of wild-type mice at E16. The subplate and the upper intermediate and marginalzones were immunostained for IgG throughout the length of thecortex (Fig. 1A). Anteriorly, the immunostained area extendedventrally, and posteriorly included the hippocampal primordium.The intervening cortical plate, as well as the ventricular zone,was unstained. This pattern of immunostaining was similar to thatseen on an adjacent section stained for synapsin I (Fig. 1C),which has been shown to be present in the subplate and marginalzone (Chun and Shatz, 1988b). Fiber tracts, which appeared toextend both to and from the cortex, were also Ig-immunoreactive(Fig. 1D). Ig-ir was similarly localized to regions containingfiber tracts in the ventral portion of the hindbrain and spinalcord at E16 (Fig. 2A). No immunostaining was evident in sectionsfor which primary antisera were omitted or were replaced by ananti-µ heavy chain (IgM) antiserum; further, preadsorption ofprimary anti-IgG antiserum with a 2.5-fold excess of mouse IgGcompletely abolished immunostaining (data not shown).
Fig. 1. Ig-ir is present in wild-type fetal cerebral cortex. Adjacent sagittal cryostat sections through an E16 wild-type cortex werestained with anti-mouse IgG (heavy and light chain) antiserum(A, D), cresyl violet (B), or anti-synapsin I antiserum (C). Ig-iris present in the subplate (sp) and marginal zone (mz) of thecortex, continuing posteriorly into the hippocampal primordium(h) (A). The ventricular zone (vz) and cortical plate (cp) areunstained. The superior portion of the thalamus (t) also exhibitsIg-ir. B, Cresyl violet staining reveals cell body location anddelineates fetal cortical zones. C, Synapsin I immunoreactivity,known to label the subplate and marginal zone, is similar in itslocalization to Ig-ir. D, In more lateral sagittal sections, fibersradiating to and from the cortex are Ig-immunoreactive. ge, Ganglioniceminence. Scale bars: A-C, 200 µm; D, 100 µm. A-C, Left indicatesrostral; top, dorsal.
[View Larger Version of this Image (79K GIF file)]

Fig. 2. Ig-ir is present in wild-type fetal hindbrain and spinal cord. A, In a sagittal section through the hindbrain and spinal cordat E16, stained with anti-IgG antiserum, Ig-ir appears to be localizedto fiber tracts in ventral regions. B, An adjacent cresyl violet-stainedsection shows that Ig-immunoreactive regions are cell-sparse,indicating the presence of fiber tracts. pn, Pons; pf, pontineflexure; m, medulla; sc, spinal cord. Scale bar, 200 µm.
[View Larger Version of this Image (198K GIF file)]

Ig-ir is RAG-1- and RAG-2-dependent
To determine the RAG-dependence of the CNS Ig-ir, embryos of mice homozygous for a deletion of either RAG-1 or RAG-2, whichhave no Igs (Mombaerts et al., 1992; Shinkai et al., 1992; Spanopoulouet al., 1994), were examined by immunohistochemistry. Ig-ir wasabsent from all RAG-1 $-$ / $-$ cortical areas (Fig. 3A), as it wasfrom the rest of the CNS and the embryo (data not shown). An identicalresult was obtained using RAG-2 $-$ / $-$ embryos (Fig. 3D). For bothmutations, Ig-ir was absent, despite qualitatively normal corticalmorphology and normal immunoreactivity for synapsin I (Fig. 3B,C,E).Genotypes of all wild-type and RAG $-$ / $-$ animals were confirmedby Southern blot (e.g., Fig. 3F); because of introduction of anotherNcoI site by integration of the RAG-1 knock-out vector (Mombaertset al., 1992) and another EcoRI site by integration of the RAG-2knock-out vector (Shinkai et al., 1992), $-$ / $-$ animals can be detectedby blotting genomic DNA cut with the appropriate restriction enzyme.
Fig. 3. Ig-ir is absent from RAG-1 and RAG-2 $-$ / $-$ CNS. Adjacent sagittal sections through E16 RAG-1 $-$ / $-$ (A-C) and E16 RAG-2 $-$ / $-$ (D,E) cortex were stained with anti-mouse IgG antiserum (A, D), cresylviolet (B, E), or anti-synapsin I (C). Ig-ir seen in wild-typecortex is absent from RAG-1 $-$ / $-$ cortex (A), despite qualitativelynormal cortical zones (B, cresyl violet-stained adjacent section).C, An adjacent RAG-1 $-$ / $-$ section stained for synapsin I suggeststhat the absence of Ig-ir is not attributable to the absence ofa subplate zone. The same blood vessel can be identified in Aand C. A similar result is obtained in E16 RAG-2 $-$ / $-$ cortex (D,E). F, A representative Southern blot of genomic DNA using probesdistinguishing RAG-1 (Mombaerts et al., 1992) or RAG-2 $-$ / $-$ (Shinkaiet al., 1992) mice from wild type. kb, Kilobases; mz, marginalzone; cp, cortical plate; sp, subplate; vz, ventricular zone.Scale bar, 200 µm. Left indicates rostral; top, dorsal.
[View Larger Version of this Image (83K GIF file)]

The immunoreactive molecule in the CNS resembles Ig light chain
To determine the identity of the immunostained molecule, Western blot analyses were performed using the same anti-IgG antiseraused for immunohistochemistry, recognizing both heavy and lightchains of IgG. Control Western blots (Fig. 4A) confirmed thatthe anti-IgG antisera did indeed recognize the expected mouseheavy and light chain Ig proteins; in both a purified mouse IgGpreparation and a protein sample from adult spleen, bands of ~55kDa, corresponding to $gamma$ heavy chain, and of ~25 kDa, correspondingto the common $kappa$ or $lambda$ light chains, were detected. WEHI 231, amature B-cell line expressing IgM containing $kappa$ light chain, producedonly a light chain immunoreactive band, as expected for theseantisera.
Fig. 4. Western blot analysis of wild-type fetal brain detects a 25 kDa light chain-like molecule. A, A Western blot of control proteinsamples indicates that the anti-IgG antiserum recognizes the expectedIg proteins in a purified mouse IgG preparation and in an adultspleen sample (SPL.): a 55 kDa band corresponding to $gamma$ heavy chainand a 25 kDa band corresponding to $kappa$ or $lambda$ light chain. The B-cellline WEHI 231 produces $kappa$ light chain, which is detected, and µheavy chain, which is not detected by the anti-IgG antiserum.[The 55 and 25 kDa bands are unequal in the spleen sample, becausethe antiserum recognizes light chains common to all Ig classes(IgM, IgA, IgD, IgE, and IgG) present in the spleen but only heavychains of the $gamma$ (G) class; these represent only a portion of allheavy chain proteins. In addition, light chain heterogeneity isresponsible for the thickness of the 25 kDa band in spleen andIgG samples compared with the monoclonal WEHI 231 band.] B, Animmunoreactive band comigrating with light chain at ~25 kDa isclearly detected in wild-type brain samples at E12, E14, E16,and P1. No immunoreactive bands are detected in brain samplesfrom E16 RAG-1 or RAG-2 $-$ / $-$ mice or in P1 brain samples from twoindependently derived RAG-1 $-$ / $-$ strains (denoted a and b). A duplicatebrain sample blot probed with anti-synapsin I is shown as a loadingand transfer control (synapsin doublet appears as a single bandbecause of gel concentration); comparisons can be made among differentsamples at the same age but not between ages. kDa, Kilodaltons.
[View Larger Version of this Image (16K GIF file)]

Analysis of wild-type brain samples from E12 through postnatal day 1 (P1) using anti-IgG antisera identified a single bandthat co-migrated with Ig light chain at ~25 kDa (Fig. 4B). Theintensity of the immunoreactive band increased between E12 andE14, peaked at E16, and was near the limit of detection by P1.No band corresponding in size to $gamma$ heavy chain could be detectedin these or any other wild-type brain sample examined, despiteinternal positive controls demonstrating the ability of the assayto detect $gamma$ heavy chain (see Fig. 4A,B, far left lane). Further,antisera specific for $gamma$ or µ heavy chain detected no specificimmunoreactive bands (data not shown).

Consistent with the immunohistochemistry results, the 25 kDa light chain-like band was absent from brain protein extractsof E16 RAG-1 $-$ / $-$ or RAG-2 $-$ / $-$ mice (Fig. 4B). No other bands weredetected in these samples nor in P1 brain samples from two independentlyderived RAG-1 $-$ / $-$ mutants (denoted a and b). Western blots ofthe same set of wild-type and RAG $-$ / $-$ brain samples probed withan antiserum specifically recognizing mouse $kappa$ light chain producedresults identical to those obtained with the anti-IgG antisera(data not shown). In situ hybridization experiments using a $kappa$ light chain constant region riboprobe, however, did not detectany transcript expression in wild-type fetal brain (data not shown).

Expression of the light chain-like protein depends on maternal RAG-1
The absence of Ig-ir in RAG $-$ / $-$ embryos could be attributable to the lack of RAG expression either in the embryos or in themothers, who were $-$ / $-$ as well. To distinguish between these twopossibilities, RAG-1 $-$ / $-$ females were crossed with wild-type males.The resulting heterozygote embryos carried by these females couldnot have received any maternal RAG-dependent proteins such asIgs; however, embryos did have one functional copy of the RAG-1gene, which could allow them to produce RAG-dependent moleculesautonomously. Western blot analysis of E16 RAG-1 +/ $-$ brain samplesdid not reveal any immunoreactive bands (Fig. 5A, far right lane).Immunohistochemistry experiments on these heterozygotes demonstrateda similar absence of any Ig-ir (data not shown).
Fig. 5. Wild-type Ig-ir is reconstituted in RAG-1 $-$ / $-$ embryos by maternal injection with normal mouse serum. A Western blot of E16brain samples from various mice was probed with anti-IgG antiserum(A). Analysis of brain samples from E16 RAG-1 $-$ / $-$ mice derivedfrom females injected at E13.5 with normal mouse serum (R1 $-$ / $-$ + NMS) illustrates reconstitution of the wild-type 25 kDa Ig-immunoreactiveband. No immunoreactive bands are detected, however, in brainsamples from E16 RAG-1 +/ $-$ mice. As a loading and transfer control,a duplicate blot was probed with anti-synapsin I. B, A sagittalsection through the cortex of an E16 RAG-1 $-$ / $-$ serum-treated mousewas stained with anti-IgG antiserum. In contrast to untreatedRAG-1 $-$ / $-$ embryos (compare Fig. 3A), Ig-ir is present, althoughlocalization to the subplate and marginal zone is not as preciseas in wild-type embryos (see Discussion). Arrows delineate theapproximate borders of the subplate. C, A section through thehindbrain and spinal cord of the same mouse as in B, stained forIgG, shows that wild-type Ig-ir is also restored in these regions.m, Medulla; sc, spinal cord. Scale bar, 200 µm.
[View Larger Version of this Image (96K GIF file)]

Light chain-like protein can be reconstituted in the fetal RAG-1 $-$ / $-$ CNS
To confirm that the light chain-like molecule seen in the fetal CNS was maternally derived, pregnant RAG-1 $-$ / $-$ mice were injectedintraperitoneally at E13.5 with normal mouse serum containingIgs, which are absent from RAG $-$ / $-$ mice (Mombaerts et al., 1992;Shinkai et al., 1992). Embryos were analyzed by immunohistochemistryand Western blot at E16. Injection of pregnant RAG-1 $-$ / $-$ femaleswith normal mouse serum resulted in reconstitution of the wild-type25 kDa band in Western blot analyses of fetal RAG-1 $-$ / $-$ brain(Fig. 5A). A partial reconstitution of the wild-type pattern ofIg-ir was also observed when these serum-treated RAG-1 $-$ / $-$ embryoswere examined by immunohistochemistry. Ig-ir was apparent in thecerebral wall (Fig. 5B). A similar degree of reconstitution ofwild-type Ig-ir was also observed in the hindbrain and spinalcord (Fig. 5C).

DISCUSSION

The Ig-ir protein in the fetal CNS is Ig light chain
The molecule responsible for CNS Ig-ir is Ig light chain, based on convergent data. First, immunoreactivity in the cortexand other regions of the developing CNS was replicated using multipleantisera that recognize light chains of IgG. Second, these sameantisera detect a single protein species in wild-type fetal brainthat co-migrates with Ig light chain at 25 kDa on Western blots.This 25 kDa protein was also detected by an antiserum specificfor Ig $kappa$ light chain, but not by antisera specific for Ig $gamma$ orµ heavy chain. Third, both this 25 kDa protein and CNS Ig-ir insitu required RAG-1 and RAG-2; the only molecules known to requirethese two genes for their synthesis are Igs and T-cell receptors(Schatz et al., 1992). Fourth, this 25 kDa protein and Ig-ir insitu is dependent on maternal, but not fetal, RAG-1 expression.Fifth, maternal delivery of normal mouse serum in RAG-1 $-$ / $-$ micereconstitutes the 25 kDa protein in RAG-1 $-$ / $-$ fetal CNS. Thus,a 25 kDa, Ig-immunoreactive protein that requires both RAG-1 andRAG-2 is maternally derived and is present in normal serum meetscriteria for identification as Ig light chain.

IgG and small amounts of IgM are placentally transferred from mother to fetus during gestation in the mouse (Appleby and Catty,1983; Parr and Parr, 1985), although localization to the CNS hadnot been examined previously. Surprisingly, our Western blot analysesof brain protein extracts did not detect a band correspondingin size to Ig heavy chain (at least of $gamma$ or µ isotypes); onlya 25 kDa light chain band is detected. There are two possibleexplanations for this result. First, IgG reaches the fetal CNS,but the heavy chain is selectively degraded, whereas the lightchain is retained. This seems unlikely, because heavy chain degradationproducts were never detected. It remains possible that there isa small amount of Ig heavy chain below the limit of detectionon Western blots; however, maximizing the amount of brain proteinsample loaded did not reveal any heavy chain-like bands (datanot shown) despite heavy chains being clearly detectable in proteinsamples from spleen and in a purified IgG preparation (Fig. 4A).

A second, more likely explanation is that free light chain reaches the fetal CNS. Classical immunological studies have determinedthat stimulated B-cells can release significant amounts of freelight chain, estimated to be up to 10-20% of the total Ig production(Shapiro et al., 1966; Sølling, 1981). Consistent with this, freelight chains are found in normal serum (Berggård and Edelman,1963; Sølling, 1981). Thus, free light chain in the CNS couldbe derived from its presence in normal mouse serum. Intriguingly,there is already a known connection between free light chain andthe CNS; patients with multiple sclerosis (Rudick et al., 1985)and HIV infection (Elovaara et al., 1991) have high amounts offree light chain in their CSF compared with controls.

Ig light chain is localized to the subplate and marginal zone within the fetal cerebral cortex
The Ig light chain immunostaining was confined to the subplate and marginal zones within the embryonic cortex. Several otherplasma proteins have been observed in the developing mammaliancortex (Møllgard and Jacobsen, 1984; Møllgard et al., 1988; Dziegielewskaet al., 1993); however, none of them replicate the Ig immunostainingpattern seen in the wild-type embryos. Plasma proteins examined,such as albumin and transferrin (Møllgard and Jacobsen, 1984),are generally detected by immunohistochemistry in the ventricularzone and/or diffusely in the cortical plate. Furthermore, someplasma proteins are synthesized by the cells of the cortex (Møllgardet al., 1988; Dziegielewska et al., 1993). This is clearly notthe case for Ig light chain, because both Northern blot and insitu hybridization analyses using a $kappa$ light chain constant regionprobe failed to detect any transcript expression in wild-typefetal brain (data not shown). The characteristic localizationof Ig light chain in the fetal cortex distinguishes it from otherembryonic plasma proteins.

The Ig-ir in the cortices of RAG-1 $-$ / $-$ mice treated with normal serum was less distinctly localized to the subplate and marginalzone. This may be explained by the fact that the reconstitutionexperiments used a single injection with serum at E13.5, insteadof the potentially continuous maternal serum exposure in wild-typemice. With the development of the blood-brain barrier betweenE13 and E16 (Risau et al., 1986), continuous serum exposure maybe necessary to obtain the pattern and intensity of immunoreactivityseen in wild-type cortex. Despite this less distinct localization,the Ig-ir reconstituted by serum exposure was always associatedwith only the 25 kDa light chain band by Western blot analysis.

Ig-ir has been observed previously in the postnatal cat subplate, associated with a 56 kDa molecule. This molecule was firstdetected using monoclonal antibody SP1, derived from subplateantigens (Naegele et al., 1991), which appears to have overlappingrecognition properties with anti-cat IgG antiserum (Henschel andWahle, 1994; Dunn et al., 1995). The molecule, consistent in sizeand in some peptide sequence with IgG heavy chain, cannot be detectedin the fetal cat cortex (Naegele et al., 1991; Henschel and Wahle,1994); this, along with differences in antigen size, species,and antisera used, makes its relationship to Ig light chain detectedin the mouse unclear. However, we note that identification strategiesbased on biochemically isolating Ig molecules from wild-type CNS(Henschel and Wahle, 1994), regardless of species, are complicatedby unavoidable contamination from high levels of Ig present inserum and locally produced by B-cells.

In contrast to previous studies, we have made use of three independently derived mutations producing Ig-null phenotypes (twoRAG-1 $-$ / $-$ and one RAG-2 $-$ / $-$ ). This genetic approach has allowedus to (1) determine the identity of the molecule based on itsdependence on RAGs, in conjunction with its antigenic propertiesand size, and (2) discriminate between maternal and fetal sourcesof the CNS molecule through genetic crosses and normal serum reconstitutionexperiments in RAG-1 $-$ / $-$ mice. Although the possibility of speciesdifferences in CNS Ig molecules requires additional study, weconclude that maternally derived light chain is the molecule primarilyresponsible for the observed Ig-ir in the fetal mouse.

Ig light chain localization suggests developmental roles
Light chain is present in the subplate and marginal zones of the fetal cerebral cortex, known sites of interactions betweena variety of cellular elements including migrating neurons, radialglia, and afferent and efferent projections (Rakic, 1977; Chunand Shatz, 1988a,b; DeCarlos and O'Leary, 1992). The time courseof light chain immunoreactivity also correlates with these events.Although the function of light chain in the cortex is unknown,its localization to the specialized environment of the subplateand marginal zones is consistent with the presence in these zonesof other adhesive molecules such as fibronectin (Stewart and Pearlman,1987; Chun and Shatz, 1988a), laminin (Hunter et al., 1992), andcondroitin sulfate proteoglycans (Sheppard et al., 1991). Thepossible interactions between Ig light chain and these adhesionmolecules warrant additional study.

Additional insight into the possible CNS function of light chain may be gained from examination of brain development in RAG $-$ / $-$ mice. Initial reports of a normal nervous system in RAG-1 $-$ / $-$ mice (Mombaerts et al., 1992) were based solely on gross morphologicalappearances of cresyl violet-stained adult brain sections. Further,the $-$ / $-$ mice examined were derived from heterozygous (+/ $-$ ) females(Mombaerts et al., 1992), which, having one copy of the RAG-1gene, would have functional Ig transferred to the developing embryos.Therefore, the brain phenotypes reported for these animals maydiffer from those of mice bred from homozygous ( $-$ / $-$ ) mothers.Despite normal gross morphology, subtle abnormalities may be present;in genetic null mutation studies of the neural IgSF moleculesN-CAM and MAG, for example, very mild deficits are observed, despitetheir postulated important developmental roles (Tomasiewicz etal., 1993; Cremer et al., 1994; Montag et al., 1994). This couldreflect genetic rescue of the phenotype by other IgSF members,which may substitute for absent molecules (Müller and Kypta,1995). MAG-deficient mice, for example, show an upregulation ofN-CAM at sites normally expressing MAG (Montag et al., 1994).A similar upregulation of N-CAM, L1, or other molecules in thesubplate of RAG-1 $-$ / $-$ mice could rescue a pronounced phenotype,despite the absence of light chain. The dynamics of IgSF expressionin the RAG $-$ / $-$ CNS deserve additional study.

An examination of CNS development in the absence of RAG expression is further complicated by the finding that RAG-1 transcriptsare present throughout the fetal and postnatal CNS (Chun et al.,1991). Because the CNS light chain is maternally derived and dependentnot only on RAG-1 but also on RAG-2, transcripts of which cannotreliably be detected in the CNS (Chun et al., 1991), it is unlikelyto be affected by RAG-1 activity in the fetal CNS. This is notsurprising, because any recombination events mediated by RAG-1in the absence of RAG-2, such as those that could occur in theCNS, are unlikely to be identical to the immunological V(D)J recombinationproduced synergistically by the two RAG genes (Schatz and Chun,1992; Chun and Schatz, 1993). The role of RAG-1 in the CNS remainsunknown.

Ig light chain may provide a maternal influence on fetal CNS development
A possible implication of our results is that the maternal immune system may contribute to fetal neural development in additionto its accepted roles in fetal passive immunity (Appleby and Catty,1983). Precedent for a maternal molecular contribution to thedevelopment of the fetal CNS comes from reports that maternallyderived melatonin can entrain the fetal suprachiasmatic nucleusto the circadian rhythm (Davis and Mannion, 1988). Additionalstudies of Ig light chain function in the fetal CNS should provideinsights into its role in neural development and into the dynamicsof maternal-fetal interactions during gestation.

FOOTNOTES

Received Feb. 10, 1997; accepted Feb. 19, 1997.

This work was supported by the National Institute of Mental Health and the James H. Chun Memorial Fund (J.C.) and by a NationalScience Foundation Graduate Fellowship (J.A.W.). We thank Ms.Carol Akita for expert histological assistance and Dr. David Schatz,Ms. Anne Blaschke, and Dr. Kristina Staley for critically readingthis manuscript.

Correspondence should be addressed to Dr. Jerold Chun, Department of Pharmacology, School of Medicine, University of California,San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0636.

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