Roles for Laminin in Embryogenesis: Exencephaly, Syndactyly, and Placentopathy in Mice Lacking the Laminin {alpha}5 Chain

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© The Rockefeller University Press, 0021-9525/1998//1713 $5.00
The Journal of Cell Biology, Volume 143, Number 6, , 1998 1713-1723

Article

Roles for Laminin in Embryogenesis: Exencephaly, Syndactyly, and Placentopathy in Mice Lacking the Laminin ${alpha}$ 5 Chain

Jeffrey H. Miner^*, Jeanette Cunningham, and Joshua R. Sanes

^* Department of Medicine, Renal Division and Department of Anatomy and Neurobiology, Washington University School of Medicine, St. Louis, Missouri 63110

Laminins are the major noncollagenous glycoproteins of all basallaminae (BLs). They are ${alpha}$ /β/ ${gamma}$ heterotrimers assembled from10 known chains, and they subserve both structural and signalingroles. Previously described mutations in laminin chain genesresult in diverse disorders that are manifested postnatallyand therefore provide little insight into laminin's roles in embryonic development. Here, we show that the laminin ${alpha}$ 5 chainis required during embryogenesis. The ${alpha}$ 5 chain is present invirtually all BLs of early somite stage embryos and then becomesrestricted to specific BLs as development proceeds, includingthose of the surface ectoderm and placental vasculature. BLsthat lose ${alpha}$ 5 retain or acquire other ${alpha}$ chains. Embryos lackinglaminin ${alpha}$ 5 die late in embryogenesis. They exhibit multiple developmental defects, including failure of anterior neuraltube closure (exencephaly), failure of digit septation (syndactyly),and dysmorphogenesis of the placental labyrinth. These defectsare all attributable to defects in BLs that are ${alpha}$ 5 positivein controls and that appear ultrastructurally abnormal in itsabsence. Other laminin ${alpha}$ chains accumulate in these BLs, butthis compensation is apparently functionally inadequate. Our results identify new roles for laminins and BLs in diversedevelopmental processes.

Key Words: basement membrane • development • placenta • knockout mice • limb deformities

Abbreviations used in this paper: AER, apical ectodermal ridge; BL, basal lamina; BrdU, 5-bromo-2'-deoxy-uridine; E, embryonic day.

Address correspondence to Jeffrey H. Miner, Renal Division,Washington University School of Medicine, 660 S. Euclid Ave.,St. Louis, MO 63110. Tel.: (314) 362-8235. Fax: (314) 362-8237.E-mail: minerj{at}thalamus.wustl.edu

CELLS in most tissues of vertebrates and invertebrates bearcoats of basal laminae (BLs),¹ thin layers of extracellularmatrix whose main components are laminin, collagen IV, entactin/nidogen,and sulfated proteoglycans (Timpl, 1996; Timpl and Brown, 1996).Laminins are glycoproteins that self-assemble to form the majornoncollagenous network of all BLs (Chung et al., 1979; Timpl et al., 1979;Yurchenco and O'Rear, 1994). All laminins studied to date areheterotrimers composed of one ${alpha}$ , one β, and one ${gamma}$ chain (Timpl, 1996).Five ${alpha}$ , three β, and two ${gamma}$ chains have now been identified, which can associate to form at least 11 heterotrimers. DifferentBLs contain distinct complements of laminin trimers, allowingBLs to subserve distinct functions while maintaining a uniformstructure.

In adults, BLs provide structural support for tissues, serveas scaffolds to organize regeneration after tissue damage,and underlie physiological functions such as renal glomerularfiltration (Timpl, 1989; Yurchenco and O'Rear, 1994). The importanceof laminin to the proper function of BLs is underscored bythe phenotypes of known mutations in laminin chain genes: thelaminin ${alpha}$ 2 gene is mutated in some congenital muscular dystrophies (Sunada et al., 1994; Xu et al., 1994; Helbling-Leclerc et al., 1995);mutations in any one of the ${alpha}$ 3, β3, or ${gamma}$ 2 chain genes causesjunctional epidermolysis bullosa, a skin blistering disease(Aberdam et al., 1994; Pulkkinen et al., 1994; McGrath et al., 1995;Kuster et al., 1997); and targeted mutagenesis of the lamininβ2 chain gene impairs both neuromuscular and renal function(Noakes et al., 1995a,b). BLs and the laminins they containare also likely to play critical roles in embryos by providingsignals for cell proliferation, migration, and differentiationand by serving as cell attachment sites (Timpl, 1989; Yurchenco and O'Rear, 1994).However, no hitherto described mutations in laminin genes leadto major embryonic defects. Thus, either other laminin chainsplay predominant roles during development, or laminins mightbe dispensable for embryogenesis.

One good candidate for a laminin chain that could be involvedin developmental processes is the laminin ${alpha}$ 5 chain (Miner et al., 1995).This chain associates with the ${gamma}$ 1 chain and either β1 orβ2 to form laminins 10 and 11, respectively (Miner et al., 1997).The laminin ${alpha}$ 5 gene is expressed in many fetal and adult tissues,including kidney, lung, skeletal muscle, skin, and intestine,and laminin ${alpha}$ 5 protein is present in specific BLs within thesetissues (Durbeej et al., 1996; Lentz et al., 1997; Miner et al., 1997;Patton et al., 1997; Sorokin et al., 1997a,b). Recently, purified laminin 11 has been shown to induce responses from culturedneurons and Schwann cells that are qualitatively different fromthose induced by laminins 1, 2, or 4 ( ${alpha}$ 1/β1/ ${gamma}$ 1, ${alpha}$ 2/β1/ ${gamma}$ 1,and ${alpha}$ 2/β2/ ${gamma}$ 1, respectively) (Patton et al., 1997, 1998).These results suggested that laminin ${alpha}$ 5 might have unique developmentalroles.

To explore roles of laminin ${alpha}$ 5 in embryos, we have documentedits localization and generated mice lacking this chain. Weshow that laminin ${alpha}$ 5 is present in most embryonic and extraembryonicBLs at early stages, that it becomes restricted to a distinctsubset of BLs as development proceeds, and that its loss leadsto fetal lethality. Numerous defects were apparent in mutanthomozygotes, including failure of neural tube closure (exencephaly),failure of digit septation (syndactyly), and dysmorphogenesis of the placenta. In each case, we consider mechanisms that may explain how loss of laminin ${alpha}$ 5 disrupts normal development.

Materials and Methods

Top
Abstract
Materials and Methods
Results
Discussion
References

Histology
Immunofluorescence microscopy was performed on cryostat sectionsas described previously (Miner et al., 1997). Antisera to mouselaminins ${alpha}$ 4 and ${alpha}$ 5 were described previously (Miner et al., 1997).The recombinant fragment used to generate anti–laminin ${alpha}$ 5 antiserum comprised amino acids 1415–1642 (Miner et al., 1995),which are COOH-terminal to the region deleted in Lama5 –/–embryos. Several other antibodies were provided by generouscolleagues: anti–laminin ${alpha}$ 2 from Peter Yurchenco (RobertWood Johnson Medical School, Piscataway, NJ; Cheng et al., 1997);anti–laminin-5 ( ${alpha}$ 3β3 ${gamma}$ 2) from Robert Burgeson (CBRC,Harvard Medical School, Charlestown, MA; Marinkovich et al., 1992);anti–keratin 14 from Elaine Fuchs (University of Chicago,Chicago, IL; Stoler et al., 1988); and anti–laminin β1(5A2) and anti- ${alpha}$ 1 (8B3) from Dale Abrahamson (University of Alabamaat Birmingham; Abrahamson et al., 1989). We showed previouslythat 5A2 specifically recognizes the β1 chain (Martin et al., 1995)and have now used similar methods to show that 8B3 recognizesmouse laminin ${alpha}$ 1 (data not shown). A commercial antibody to mouse laminin ${gamma}$ 1 (MAB1914) was from Chemicon International (Temecula,CA). Cy3- and FITC-conjugated secondary antibodies were from ICN/Cappel (Costa Mesa, CA).

For semithin and thin sectioning, embryos were fixed in 4% paraformaldehyde,4% glutaraldehyde in 0.1 M cacodylate buffer and processed as described (Noakes et al., 1995b). 2-µm sections werecut with glass knives and stained with toluidine blue for lightmicroscopy. Thin sections were cut with a diamond knife andstained with lead citrate plus uranyl acetate for electron microscopy.

To label and detect dividing cells in embryos, we used the 5-Bromo-2'-deoxy-uridine(BrdU) Labeling and Detection Kit II (Boehringer Mannheim Corp.,Indianapolis, IN). Pregnant females were injected intraperitoneallywith 0.15 ml of 10 mM BrdU per 10 g of body weight. After 1h, the mice were killed, and the embryos were removed, frozen,and sectioned at 7 µm on a cryostat. The label was detectedin nuclei according to the manufacturer's instructions.

To stain cartilage in embryos, we used Alcian blue 8GX (SigmaChemical Co., St. Louis, MO). Fixation, staining, and clearingwere performed as described (Jegalian and De Robertis, 1992).

Generation and Genotyping of Mutant Mice
A ${lambda}$ clone containing exons encoding parts of domains VI, V, andIVb of laminin ${alpha}$ 5 was obtained by screening a 129sv mouse genomiclibrary (Stratagene, La Jolla, CA) with the 5' 900 bp of thecDNA previously described by Miner et al. (1995). To constructa targeting vector, two consecutive XbaI fragments totaling3.5 kb and encoding 113 amino acids (129– 241 in Miner et al., 1995)were replaced with an in frame lacZ cDNA and a PGK neo cassette.The neo cassette was derived from the vector pPNT, which alsosupplied PGK HSV-tk for negative selection (Tybulewicz et al., 1991;see Fig. 2 A). The mutated chromosomal segment was transferredto R1 ES cells by electroporation, and transfectants were selectedwith G418 (400 µg/ml) and FIAU (0.2 µM). Approximately450 clones were screened by PCR, and a single homologous recombinantclone was obtained. Cells from this clone were injected intoC57BL/6J blastocysts by standard methods. Three chimeras transmittedthe mutation to their offspring. Homozygotes derived from eachof these founders exhibited the same phenotypes, and all phenotypessegregated with the mutation, even after five generations ofcrossing to C57BL/6J mice. We never detected lacZ activityin heterozygotes or homozygotes, presumably because the signalsequence of the laminin ${alpha}$ 5 protein forces the catalytic domainof the lacZ protein into the endoplasmic reticulum, where itis inactive.

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Figure 2 Targeted mutagenesis of the Lama5 gene. (A) The targeting vector deleted exons encoding 113 amino acids and replaced them with an in frame lacZ cDNA and the PGK neo selectable marker. N, NcoI; X, XbaI. (B) Southern analysis of genomic DNA from E13.5 embryos demonstrates the existence of the three expected genotypes, confirming that targeting was successful and that homozygous mutants were alive at this age. The probe, shown in A, was from outside the short arm of the targeting vector. (C and D) Presence of laminin ${alpha}$ 5 protein in control (C) but not mutant (D) distal limb ectodermal BL at E13.5, detected immunohistochemically with antisera to epitopes outside of the targeted region. Bar, 50 µm.

Mice were genotyped either by Southern blot or by PCR. For Southern analysis, genomic DNA was prepared from embryos, digested withNcoI, fractionated on an agarose gel, transferred to nitrocellulose,and probed with a fragment just outside the short arm of homology(Fig. 2 A). For PCR, lacZ-specific primers were used to identifythe mutated allele, and Lama5 primers from within the deletedregion were used to identify the wild-type allele.

Ra/+ mice were purchased from The Jackson Laboratory (Bar Harbor,ME).

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

Widespread Expression of Laminin ${alpha}$ 5 in Embryos
We began this study by determining the distribution of the laminin ${alpha}$ 5 chain in embryonic tissues. Sections were double-labeledwith a previously characterized rabbit antiserum to ${alpha}$ 5 (Miner et al., 1997)and a monoclonal antibody to the ${gamma}$ 1 chain. ${gamma}$ 1 is present in allBLs described to date and therefore serves as a general markerfor them.

Laminin ${alpha}$ 5 was present in virtually all ${gamma}$ 1-positive BLs at embryonicday (E) 8.5 (Fig. 1, A and B). These included the BL underlyingthe neural folds and the surface ectoderm, as well as BLs associatedwith gut epithelium. Thus, laminin ${alpha}$ 5 is not only a major ${alpha}$ chainin adult BLs (Miner et al., 1997) but also a prominent componentof BLs at early somite stages. At later stages, however, thedistribution of ${alpha}$ 5 became restricted to a subset of BLs. In thespinal cord, for example, ${alpha}$ 5 was found throughout the pial BLat E9.5 (Fig. 1 E), but levels then decreased in dorsal regions,and by E13.5, this chain was confined to the floorplate at theventral midline (Fig. 1 H). On the other hand, ${alpha}$ 5 remained abundantin the surface ectodermal BL throughout embryogenesis (Fig.1 and data not shown).

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Figure 1 Distribution of laminin ${alpha}$ 1 and ${alpha}$ 5 chains in embryonic and extraembryonic BLs. Sections of embryos at the indicated ages were labeled with antibodies specific for the laminin ${alpha}$ 1, ${alpha}$ 5, or ${gamma}$ 1 chains. The ${gamma}$ 1 chain is present in, and thus serves to mark, all BLs. (A–C) BLs underlying the unclosed neuroepithelium (n), the surface ectoderm (se), and the gut epithelium (g) contain both ${alpha}$ 1 and ${alpha}$ 5 chains at E8.7. (D–F) After neural tube closure, ${alpha}$ 5 levels decrease in the neuroepithelial BL, and ${alpha}$ 1 levels decrease in the surface ectodermal BL. (G–I) By E13.5, ${alpha}$ 5 is confined to the BL adjacent to the floorplate of the spinal cord (sc) (arrow in H) and to the notochord (nc), whereas ${alpha}$ 1 is found throughout the pial BL but is absent from the notochord. Neither chain is present in BLs of blood vessels within and outside the spinal cord. These vascular BLs contain laminin ${alpha}$ 4 (not shown). (J–L) In E10.5 heart, both ${alpha}$ 1 and ${alpha}$ 5 are found in the atria (a) and in the ventricles (v), though levels of ${alpha}$ 1 are low in ventricle. (M–O) In the nascent placental labyrinth, the BLs at the base of embryonic blood vessels in the ectoplacental plate (epp) contain both ${alpha}$ 1 and ${alpha}$ 5, whereas the tips of vessels that have migrated towards the maternal blood spaces (arrowheads) contain ${alpha}$ 5 but lack ${alpha}$ 1. N and O are from a single, doubly labeled section. (P–R) In E13.5 placental labyrinth, the fetal blood vessel BLs contain both ${alpha}$ 1 and ${alpha}$ 5 throughout their lengths. Bar, 10 µm for A–C and P–R, 20 µm for all other panels.

The presence of BLs rich in ${gamma}$ 1 but poor in ${alpha}$ 5 at later stagessuggested that other ${alpha}$ chains were being expressed. We testedthis idea by staining sections with antibodies specific forthe ${alpha}$ 1– ${alpha}$ 4 chains. Levels of ${alpha}$ 2– ${alpha}$ 4 were low at E8.5–9.5,but the laminin ${alpha}$ 1 chain was codistributed with ${alpha}$ 5 in most BLsat this stage (Fig. 1, C and F, and data not shown). Later,as ${alpha}$ 5 became restricted to a subset of BLs, ${alpha}$ 1 became restrictedto a largely complementary subset, so the extent of their colocalizationdecreased. For example, the ectodermal and neuroectodermal BLswere rich in both ${alpha}$ 1 and ${alpha}$ 5 at the earliest stages examined,but each chain became restricted to distinct regions as development proceeded. Whereas ${alpha}$ 5 remained abundant in ectodermal BL butbecame restricted to the floor plate of the neural tube, ${alpha}$ 1remained abundant in the neural tube (Fig. 1, H and I) butwas gradually lost from the ectoderm. Though ${alpha}$ 3 was not detectedat E8.5–10.5, it became a major component of ectodermalBL by E12.5, as shown previously (Aberdam et al., 1994) anddiscussed below.

In some BLs, levels of both ${alpha}$ 1 and ${alpha}$ 5 were low. In heart, forexample, ${alpha}$ 1 and ${alpha}$ 5 were both detected in atria at E9.5 and laterages, but ventricular expression of ${alpha}$ 1 and ${alpha}$ 5 was low and regionallyrestricted throughout the embryonic period (Fig. 1, J–L).Likewise, small ${gamma}$ 1-positive blood vessels that arose withinthe brain, spinal cord, and mesenchymal regions lacked both ${alpha}$ 1 and ${alpha}$ 5 (Fig. 1, G–I; see also Klein et al., 1990). Atleast one of the other known ${alpha}$ chains, ${alpha}$ 2– ${alpha}$ 4, was foundin these regions. For example, BLs of ventricular muscle wererich in ${alpha}$ 2, and blood vessels were rich in ${alpha}$ 4 (data not shown).

We also examined the distribution of the laminin ${alpha}$ 1 and ${alpha}$ 5 chainsin extraembryonic tissues. At all stages examined, Reichert'smembrane was rich in laminin ${alpha}$ 1 but contained comparatively little ${alpha}$ 5, whereas the yolk sac and amnion contained both ${alpha}$ 1 and ${alpha}$ 5 atE10.5 and later ages (data not shown). The few blood vesselBLs found inside the nascent placental labyrinth at E9.5 contained ${gamma}$ 1 and ${alpha}$ 5 but not ${alpha}$ 1, whereas all three chains were found in vesselBLs near their origins in the ectoplacental plate (Fig. 1, M–O). Finally, at E13.5, the BLs of fetal vessels in the more mature placental labyrinth were rich in ${gamma}$ 1 and both ${alpha}$ 5and ${alpha}$ 1 (Fig. 1, P–R). Thus, ${alpha}$ 5 is a prominent componentof many extraembryonic as well as embryonic BLs.

Production of Laminin ${alpha}$ 5–deficient Mice
To determine the function of laminin ${alpha}$ 5, we mutated the laminin ${alpha}$ 5 gene (Lama5) using a targeting vector that deleted exons encodingportions of the NH₂-terminal domains VI and V (Fig. 2 A). Withthis strategy, only 211 of 3,718 amino acids were upstreamof the deletion; transcription originating from the Lama5 promotershould be terminated by SV-40 sequences in the vector; andtranslation of any resulting mRNAs should be terminated by multiple stop codons. The targeting vector was transferred to R1 ES cells (Nagy et al., 1993) by electroporation, and a single homologous recombinant clone was obtained from 450screened. Cells from this clone were injected into C57BL/6Jblastocysts to produce three germline chimeras. Heterozygotes,which displayed no obvious abnormalities, were back-crossedto wild-type C57BL/6J mice for at least three generations toobtain a more defined genetic background. Initial and back-crossedheterozygotes were bred, but no live homozygotes were detectedamong $~$ 40 offspring, indicating that mice require laminin ${alpha}$ 5 tocomplete development.

To determine when homozygotes were dying, we killed timed pregnantfemales at E8.5–17.5. PCR (not shown), and Southern blotanalyses (Fig. 2 B) showed that homozygotes were alive at E13.5.Immunostaining of tissues from confirmed homozygotes showeda complete absence of laminin ${alpha}$ 5 protein (Fig. 2, C and D).Of 267 E8.5–16.5 embryos scored, 61 (23%) were Lama5–/–, suggesting that most homozygotes survivedwell past the implantation stage. However, defects became apparentafter E9, and some homozygotes were dead in litters taken between E13.5 and 16.5. No homozygotes lived past E17. Consistent withthe broad distribution of laminin ${alpha}$ 5, defects were visible inmany tissues, including the limb, neural tube, and placenta.In the following sections, we describe these defects and considermechanisms that could account for them. Defects in some internalorgans, including lung, heart, intestine, and kidney, werealso observed; these will be described elsewhere (Miner, J.H.,manuscript in preparation).

Syndactyly
In normal mice, distal extremities of limbs are initially paddle-shaped,then septation occurs to form digits. The distal limbs of Lama5–/– embryos were also initially paddle-shaped,but then became club-like and failed to form separate digits,a phenomenon known as syndactyly. This defect was visible atE12.5, as soon as septation began in controls. It became moreobvious at later ages and was apparent in all Lama5 –/–mice examined (Fig. 3, A and B). The forelimbs were more severelyaffected than the hindlimbs; little if any septation occurredin mutant forelimbs, but digits 1 and 5 exhibited partial separationin hindlimbs by E14.5.

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Figure 3 Syndactyly in Lama5 –/– embryos. Controls are on the left and mutants on the right. (A and B) Whole mount dorsal views of E14.5 fore- and hindlimbs. Digits 1 and 5 are partially septated in the mutant hindlimb. (C and D) Alcian blue staining at E13.5 demonstrates proper patterning in the mutant. Digits 2 and 3 are closely apposed but are not fused (arrows). (E and F) Alcian blue staining at E15.5 shows complete fusion of mutant digits 2 and 3 (arrows) and the absence of distal phalanges from digits 2–4 in the mutant forelimb.

Syndactyly could result either from a failure of pattern formationwithin the distal limb, or from failure to form septa betweendigits that were otherwise well formed. To distinguish betweenthese alternatives, we stained limbs from mutant and controlembryos with Alcian blue, which selectively stains cartilage.Digit pattern was established normally in Lama5 –/–embryos at E13.5 (Fig. 3, C and D), indicating that ${alpha}$ 5 was notrequired for the complex developmental processes that initiallypattern the distal limb. Later, however, the phalanges of digits2 and 3 fused (Fig. 3, E and F). This sequence suggests thatthe defective cartilage pattern is secondary to, rather thana cause of, the syndactyly in Lama5 mutants.

Genesis of the Limb Defect
We used light and electron microscopy to learn how absence oflaminin ${alpha}$ 5 results in syndactyly. The following descriptionrefers to forelimbs, but similar results were obtained in hindlimbs.In normal development, the forelimb bud is visible at E9. Itis covered by a continuous ectodermal epithelium, which overliesthe mesenchymal cells of the dermis. The basal surface of theepithelial cells is coated by a laminin ${alpha}$ 5–rich BL, whichseparates ectoderm from dermis (Fig. 2 C). The ectodermal anddermal layers appeared similar in mutants and controls duringearly embryogenesis (not shown).

As the limb bud elongates, cells are added to the ectoderm sothat it completely covers the limb at all times. In mutants,however, $~$ 200-µm gaps appeared in the distal epidermisslightly ventral to the tip of each digit condensation (Fig.4, A and B). Mesenchymal cells migrated or were extruded throughthese gaps. Some of these cells may have been sloughed intothe amniotic fluid, but many remained associated with the external(peridermal) surface of the epithelium and migrated from thehole to form a continuous, multilayered coat over each digittip (Fig. 4, B and C). As a result, the surface ectoderm thickenedand became covered on both sides by a dermis at the limb tip (Fig. 4 C), and a second BL formed at the ectopic ectodermal/dermalinterface (Fig. 4 D). Apparently, either the surface ectoderm"doubled back" on itself to maintain a basal relationship withthe displaced mesenchymal cells, or, alternatively, the presenceof displaced mesenchyme on the apical side of the epithelialcells induced a repolarization and/or a reorganization of someof these cells, producing a second epithelial/mesenchymal interface.In either case, the additional cells in the epithelium were clearly of epidermal lineage, as shown by immunostaining withan antibody to the keratinocyte-specific antigen keratin 14(Stoler et al., 1988). This antibody stained all surface ectodermalcells as well as the full width of the thickened mutant epitheliumat this stage (data not shown). Because the interdigital mesenchymeis intimately involved in digit septation (see Jiang et al., 1998and references therein), its depletion from the interior mightbe expected to impede this process. Depleted mesenchyme couldalso lead to the observed digit fusion, and the doubled ectodermcould physically impede proper septation. Together, these abnormalitiesappear sufficient to account for the syndactyly observed inLama5 –/– embryos.

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Figure 4 Discontinuity of epidermis and BL in the distal limb. (A–C) Toluidine blue–stained semithin sections of distal limb from control (A) and mutant (B and C) E14.5 embryos. The surface ectoderm (se) is continuous in controls (A). In mutants, in contrast, the ectoderm has been breached, and extruded mesenchymal cells (m) have migrated along the outer surface of the limb (B). A nearby section from the same mutant limb shows a thickened surface ectoderm (*) between the outer and inner mesenchymal populations (C). (D) Immunostaining of Lama5 –/– limb with an antibody to laminin ${gamma}$ 1 demonstrates the presence of BL material on both sides of the thickened ectoderm (arrowheads), suggesting that the ectoderm has maintained a proper relationship with the displaced mesenchymal cells. (E and F) Ultrastructural analysis of distal limb BL at E14.5 shows a dense, continuous BL (arrowhead) in the control (E) but a patchy, discontinuous BL in the mutant (F). Bars: (in D) 62.5 µm for A–C, 50 µm for D; (in F) 0.25 µm for E and F.

How does loss of laminin ${alpha}$ 5 lead to the discontinuities anda thickened epithelium at the limb tip? Ultrastructural analysesshowed that the BL associated with the mutant ectoderm in thelimb tip was patchy and discontinuous compared with that seenin controls (Fig. 4, E and F). In contrast, the ectodermalBL in the proximal part of the limb was similar in mutantsand controls (data not shown). We surmise that the discontinuitiesobserved in the distal BL rendered it unable to maintain eitherits own integrity or that of the surface ectoderm, leadingto rupture of the ectoderm under the stress of distal limboutgrowth. As a result, mesenchymal cells from within the limbpassed through the hole and migrated along the outer surfaceof the limb, thereby both depleting the interior of mesenchymeand capping the limb tip.

We also considered the possibility that syndactyly resultedfrom defects in the apical ectodermal ridge (AER). The AERis a morphologically distinct epithelium that runs from anteriorto posterior at the distal margin of the limb bud. It formsin the ectoderm at E10.5 and is necessary for limb outgrowth(Martin, 1998). That limb outgrowth occurs in the Lama5 mutantsindicates that AER function is not severely disrupted by theabsence of ${alpha}$ 5 from the ectodermal BL. On the other hand, wedid observe that the most distal phalanges of mutant forelimb digits 2, 3, and 4 were missing or severely shortened (Fig.3 E). Thus, the discontinuities at the distal tips of the limbs may lead to subtle defects in the AER that contribute to defectsin both outgrowth and patterning (see also Jiang et al., 1998).Such subtle defects in the AER could combine with the mesenchymaland ectodermal abnormalities discussed above to account forboth syndactyly and the missing distal phalanges.

Exencephaly
In $~$ 60% of Lama5 –/– fetuses examined, the brainwas enlarged and misshapen, and it was not covered by skinor skull (Fig. 5, A and B); the remaining mutants appearedto have grossly normal heads (data not shown). This partially penetrant defect is termed exencephaly, a condition in whichthe cranial vault fails to develop, and the tissues of thebrain are exposed (Wallace and Knights, 1978). We do not knowwhy this defect is partially penetrant, but we do note thatpartial penetrance has been observed in other mutant strainsthat exhibit exencephaly (Wallace and Knights, 1978; Macdonald et al., 1989;Vogelweid et al., 1993; Harris and Juriloff, 1997).

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Figure 5 Exencephaly in Lama5 –/– embryos. (A and B) Whole mount views of control and mutant embryos at E13.5. Exencephalics lack the skin and skull that normally enclose the brain and have a topologically "inside out" brain that does not develop properly. The skin and skull of the control was dissected away to allow direct comparison of mutant and normal brains. (C and D) Immunohistochemical localization of proliferating cells with anti-BrdU and alkaline phosphatase chemistry after labeling for 1 h in utero with BrdU. (C) In normal neural tissue (n), BrdU-labeled cells (arrow) are confined to the ventricular zone. v, ventricle. (D) In exencephalics, labeled cells (arrow) are found on the outer surface of the neural tissue. This surface would have been ventricular had the neural tube closed, but now it is in direct contact with amniotic fluid. Skin and skull (s) overlay the brain in the control but are missing from the mutant. Pia is indicated by dashed lines. (E and F) Toluidine blue–stained sections through the anterior of E8.7 control and mutant embryos; the neural tube is unclosed at this stage in both control and mutant. Electron micrographs shown in Fig. 6 were obtained from these regions. Bars: (B) 1 mm; (D) 0.25 mm; (F) 0.2 mm.

Exencephaly is caused by failure of the anterior neural tubeto close. As a result, the left and right sheets of nonneuralsurface ectoderm do not fuse at the dorsal midline or detachfrom the neural tube, but remain contiguous with the neuroepitheliumthroughout development. Histological analyses of embryos atmultiple gestational ages confirmed that this aspect of exencephalywas evident in the affected embryos (data not shown).

A major consequence of exencephaly is that the neuroepitheliumis topologically "inside out." In normal mice, neurons areborn in a ventricular zone of proliferating cells that abutsan interior sealed ventricle, and then they migrate towardthe outer pial surface to form the cortical plate. The topologyof exencephalic brains predicts that the proliferating cellsshould lie on the outer surface or abut a "pseudoventricle"that is actually continuous with the extraembryonic space.To assess the polarity of the neuroepithelium in Lama5 –/–embryos, we labeled dividing cells in E13.5 embryos with BrdUfor 1 h and detected incorporation immunohistochemically infrozen sections. Control brains and brains of Lama5 –/–mice that were not exencephalic showed characteristic labeling near the ventricles, where proliferating cells normally resideat this stage (Fig. 5 C and data not shown). In exencephalicbrains, labeling was observed in cells on the outer surface(Fig. 5 D) as well as near the pseudoventricles (not shown).These patterns confirm that the cranial defect observed in theabsence of laminin ${alpha}$ 5 is exencephaly.

Genesis of the Neural Defect
To determine how a lack of laminin ${alpha}$ 5 leads to exencephaly, weexamined the ultrastructure of the cranial neural tube andits neighboring ectoderm in controls and mutants at E8.7, theage just before the anterior neuropore closes in normal embryos(Kaufman, 1992). Low-magnification views of sections representativeof those that were used for electron microscopy demonstratedthat the anterior neuropore was nearly but not completely closedin both control and mutant embryos (Fig. 5, E and F). If theabsence of laminin ${alpha}$ 5 led to significant ultrastructural defects,we expected them to be detectable at this stage.

In control embryos, the basal surfaces of the ectoderm andneuroectoderm were coated by a continuous BL, but discontinuitieswere apparent at the junction of ectoderm and neuroectoderm,the area through which neural crest cells later migrate fromthe dorsal neural tube to the periphery (Fig. 6, B–E).The mutant BL was similar to that of controls in being continuousbeneath the neuroectoderm and ectoderm but discontinuous atthe ectodermal–neuroectodermal junction (Fig. 6, F, H,and I). Lama5 –/– ectodermal BL differed from thatof controls, however, along a strip bordering the neural folds:the ectodermal BL of controls was continuous, whereas that ofmutants was thin and patchy (Fig. 6 G). This difference wasseen in several mutant/control littermate pairs. Interestingly,Schoenwolf and colleagues have suggested that this strip ofectoderm is involved in generating forces that are necessaryto close the neural tube (Schoenwolf and Smith, 1990; Hackett et al., 1997).We speculate that weakness of the BL in this region decreasesthe amount of lateral force the ectoderm can generate on theneural folds, thereby leading to sporadic failure of cranialneural tube closure.

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Figure 6 Electron micrographs of epithelial BLs in the heads of control (B–E) and mutant (F–I) embryos at E8.7. (A) Drawing indicating the approximate origins of the sections shown in B–I. The narrow line represents the BL. (B and F) Lateral cranial surface ectoderm. (C and G) Surface ectoderm near the dorsal midline. (D and H) Junction of surface ectoderm and neuroepithelium. (E and I) Neuroepithelium. BLs are intact in both mutants and controls beneath lateral ectoderm and neuroepithelium. BLs are discontinuous in both mutants and controls near the junction of ectoderm and neuroepithelium. Beneath the surface ectoderm near the neural folds, however, control BL is intact, whereas mutant BL is disrupted. This region of the ectoderm has been shown to be important in neural tube closure (see text). n, neuroepithelium; se, surface ectoderm; arrowheads, BL. Bar, 0.5 µm.

Molecular Compensation
In some laminin mutants, loss of one chain results in compensatoryupregulation of other chains. For example, laminin β1is found ectopically in the mature glomerular basement membranein kidneys of mice with a targeted mutation in the lamininβ2 chain gene. This compensatory response produces a structurallyintact BL that nevertheless does not function properly as afilter (Noakes et al., 1995b). Likewise, loss of laminin ${alpha}$ 2in dy/dy mice results in upregulation of ${alpha}$ 4, which is, however,insufficient to prevent muscular dystrophy (Patton et al., 1997).In view of these precedents, we assessed the consequences oflaminin ${alpha}$ 5 deficiency on the composition of ectodermal BL. In control embryos, ${alpha}$ 3, ${alpha}$ 5, and ${gamma}$ 1 were present in ectodermal BLat E13.5, but ${alpha}$ 1, ${alpha}$ 2, and ${alpha}$ 4 were undetectable (Fig. 7, A–E).In mutants, the entire surface ectoderm was coated by a laminin ${gamma}$ 1–positive BL, consistent with electron microscopic observationsthat the discontinuities in this structure were small and sparse(data not shown), except at the particular sites discussed above.The ${alpha}$ 5 chain was absent, as expected, but the ${alpha}$ 3 chain was retainedat apparently normal levels. In addition, the ${alpha}$ 1, ${alpha}$ 2, and ${alpha}$ 4 chains were present in many but not all segments of mutant ectodermalBL (Fig. 7, F–J, and data not shown). Thus, absence oflaminin ${alpha}$ 5 led to retention and/or ectopic accumulation of the ${alpha}$ 1, ${alpha}$ 2, and ${alpha}$ 4 chains. The preservation of the mutant BL may resultfrom the retention of ${alpha}$ 3-containing laminins or the ectopicaccumulation of ${alpha}$ 1-, ${alpha}$ 2-, and ${alpha}$ 4-containing laminins. Conversely,the localized defects in mutant BL that lead to exencephalyand syndactyly may reflect either regional differences in the extent of compensation or uniform weakness that renders theBL vulnerable in regions subjected to greatest stress.

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Figure 7 Molecular compensation for loss of laminin ${alpha}$ 5 in Lama5 –/– ectoderm. E13.5 controls (A–E) and mutants (F–J) were stained with antisera specific for the five known laminin ${alpha}$ chains. Micrographs show surface ectoderm from the flank. Normal ectodermal BL (arrowheads) contained only ${alpha}$ 3 and ${alpha}$ 5 at this age, but mutant BL contained the ${alpha}$ 1– ${alpha}$ 4 chains. Thus, ${alpha}$ 1, ${alpha}$ 2, and ${alpha}$ 4 were upregulated in response to loss of ${alpha}$ 5. Bar, 50 µm.

Placental Dysmorphogenesis
Syndactyly and exencephaly seemed unlikely to account for thedeath of homozygous mutants at E14–17. Moreover, evenmutants without exencephaly died by E17. Cardiac abnormalitieswere also observed, but these were relatively minor and onlyseen in some of the Lama5 –/– embryos (Miner, J.H.,manuscript in preparation). We therefore examined extraembryonictissues from mutant and control embryos. Reichert's membraneand the yolk sac of Lama5 –/– embryos were similarto those in controls, but the placental labyrinth was clearlymalformed. The labyrinth is the part of the placenta in whichthe fetal and maternal circulations come into close proximityto exchange gases, nutrients, and wastes. In mice, the placental labyrinth is composed primarily of trophoblasts and endothelialcells, both derived from the embryo. The endothelial cells formthe vessels through which the embryonic blood circulates. Threelayers of trophoblasts surround these vessels and line theadjacent spaces through which the maternal blood flows (Cross et al., 1994;Hogan et al., 1994). The endothelium and the innermost trophoblast layer are separated from each other by a BL that, as shown in Fig. 1, is normally rich in laminin ${alpha}$ 5.

The placental labyrinth was significantly smaller in mutantsthan controls by E13.5 and remained smaller at later ages (datanot shown). Immunostaining with antibodies to laminin ${gamma}$ 1 (tolocalize BLs) and to PECAM (to localize endothelial cells)revealed that the network of fetal blood vessels was presentand associated with BLs in the mutants at E13.5. However, thecomplexity of vessel branching was markedly reduced in mutanthomozygotes, and the diameter of the vessels was significantlyincreased (Fig. 8, A and B). This defect was still apparentat E16.5, indicating that branching of the blood vessels wasnot merely developmentally delayed. The resulting simplificationof the labyrinth reduces the surface area available for exchangeof molecules between the fetal and maternal bloodstreams, and could thereby lead to placental insufficiency in mutants.Consistent with this possibility, mutant embryos were almostalways smaller than their normal littermates after E14.

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Figure 8 Placental dysmorphogenesis in the absence of laminin ${alpha}$ 5. (A and B) Immunostaining for laminin ${gamma}$ 1 at E13.5 reveals the network of fetal blood vessel BLs in the placental labyrinth. The mutant vessels (B) are fewer, less branched, and wider bore than those in the control (A). (C and D) Toluidine blue staining of E16.5 control (C) and mutant (D) labyrinth shows that large bore mutant vessels (arrows in D) are still present at this later stage. The endothelium appears to have detached from the trophoblasts in these vessels. (E and F) Transmission electron micrographs show definitively that some mutant fetal vessels (F) have become detached from the trophoblasts, leaving a cell-free space between the endothelium (e) and the trophoblasts (t), while in the control (E) the two cell layers remain closely apposed. (G and H) Higher power micrographs of vascular BL. In control (G), both endothelium and trophoblast are tightly adherent to this BL, whereas in the mutant (H), the BL is patchy and has lost attachment to the trophoblasts. Bars: (in D) 100 µm for A and B, 25 µm for C and D; (in F) 1 µm for E and F; (in H) 0.25 µm for G and H.

High-resolution light microscopic and ultrastructural studiesof plastic embedded tissue revealed an additional defect inmutant labyrinths. In controls, the fetal endothelium was separatedfrom the trophoblasts only by a BL, to which both cell layerswere tightly adherent (Fig. 8, C and E). In mutants, in contrast,the two cell layers were frequently separated from each otherby a cell-free space. In these regions of separation, the BLwas associated exclusively with the endothelial cell, leavingthe basal surface of the trophoblast uncoated (Fig. 8, D andF). Ultrastructurally, the mutant BL was heterogeneous in widthand exhibited splits and discontinuities (Fig. 8, G and H, anddata not shown). Thus, the trophoblasts failed to form stable adhesions with the laminin ${alpha}$ 5-deficient BL, suggesting that ${alpha}$ 5-containing laminins are necessary to maintain trophoblastadhesion to the BL. The abnormal separation of the fetal bloodvessels from the trophoblasts would have serious consequencesfor placental function and, together with the branching defectsdiscussed above, provide a plausible explanation for deathof the mutant embryos.

Phenotype of Lama5/ragged Trans-heterozygotes
The naturally occurring dominant mutation ragged (Ra) leadsto sparse fur in heterozygotes (Ra/+). Ragged homozygotes (Ra/Ra)are almost completely hairless and usually die before weaning(Carter and Phillips, 1954). We (Miner et al., 1997) and Durkin et al. (1997)previously noted that Lama5 maps to a region of mouse chromosome 2 very close to the ragged gene and raised the possibility that Ra is, in fact, a neomorphic allele of the Lama5 gene. If this were the case, Ra/Lama5 mice might resemble Ra/ Ramice because only mutant protein would be produced in bothcases. To test this possibility, we mated Ra/+ mice with Lama5+/– mice. We identified 11 mice out of 36 offspring from4 litters that were genotypically Lama5 +/– (as determinedby PCR) and phenotypically Ra/+ (by coat abnormality). Thisfrequency was not significantly different from that expected(9/36). None of these 11 mice had the severe abnormalitiesobserved in Ra/Ra homozygotes, and none died before weaning.Moreover, these mice had apparently normal amounts of laminin ${alpha}$ 5 protein in their kidney BLs, as assessed immunohistochemically(data not shown). It remains formally possible that Ra is adominant-negative mutation in Lama5 that is only lethal or severewhen present in two copies. However, we suspect that the raggeddefect does not result from a mutation in the Lama5 gene.

Discussion

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Abstract
Materials and Methods
Results
Discussion
References

Mutations have been generated or discovered for 5 of the 10laminin genes identified to date (see introduction). In allof these cases, embryogenesis proceeds essentially normally,and defects only become severe at or after birth. In contrast,the absence of laminin ${alpha}$ 5 leads to embryonic lethality. Lama5–/– homozygotes appear normal until about E9, butdevelopment is then progressively aberrant, and no embryoslive beyond E16.5. Multiple defects were observed, consistentwith the wide expression pattern of Lama5. Here, we focusedon the most severe defects: those observed in limb, head, andplacenta. In all three cases, ultrastructural analysis suggeststhat the phenotypes result fairly directly from defects inBLs that normally contain laminin ${alpha}$ 5.

Despite the multiple defects observed in Lama5 –/– embryos, we are unsure of why they die by E17. Exencephalyis an unlikely cause, since mice routinely live to birth inother models of exencephaly (Wallace and Knights, 1978; Macdonald et al., 1989;Vogelweid et al., 1993), and the Lama5 –/– fetuseswith normal neural tube closure also die by E17. Similarly,syndactyly is unlikely to be lethal. The observed placentaldefects may be at least partly responsible for mortality. First,the percentage of the placenta that contained the labyrinthof fetal blood vessels and maternal blood spaces was reducedin mutants. Second, the complexity of the fetal capillary networkwas significantly reduced compared with controls; the presenceof ${alpha}$ 5 but not ${alpha}$ 1 in the BLs at the distal tips of blood vesselsin the nascent placental labyrinth (Fig. 1) is consistent withit having a role in elaboration of the fetal vessel network.Third, portions of many fetal vessels were no longer juxtaposedto the trophoblasts by E16.5. Fourth, the vessel BLs themselveswere aberrant, varying in width and exhibiting splits and discontinuities.Thus, laminin ${alpha}$ 5 may be important in placental endothelial cellmigration and blood vessel branching, in trophoblast adhesionto BL, and in formation of a proper BL. Together, these defectswould be expected to impair exchange of gases, nutrients, andwastes between the fetal and maternal circulation, and thuscontribute to death of the fetuses by E17. We plan to testwhether these placental defects are wholly responsible forfetal death by aggregation of Lama5 –/– ES cellswith tetraploid wild-type embryos, which can contribute to formationof the placenta but not to the embryo itself (Nagy et al., 1993).

In addition to exencephaly, syndactyly, and placentopathy, severaldefects were seen in internal organs of Lama5 –/–embryos, including small or absent kidneys, small or absenteyes, defects in lung lobe septation and bronchiolar branching,and reduced size of the left ventricle of the heart (Miner,J.H., manuscript in preparation). Some of these defects werevariable in severity and penetrance, but all can be associatedwith BLs that normally contain laminin ${alpha}$ 5. Though none of thesedefects alone appears sufficient to be responsible for fetaldeath, together with exencephaly and syndactyly, they may compromisethe health of the fetus enough that an otherwise tolerablelevel of placental malfunction becomes lethal.

The limb and cranial defects in Lama5 mutants may have a commonpathogenesis. Both are associated with localized structuraldeficiencies in regions of BLs that are likely to be subjectedto greater mechanical stress than are neighboring regions.In the limb, robust outgrowth occurs in the distal portionof the limb bud under the direction of the AER. In Lama5 mutants,this outgrowth may stress the laminin ${alpha}$ 5–deficient BLin this region, leading in turn to rupture of the overlyingectoderm and extrusion of mesenchymal cells. More proximal segmentsof the ectoderm and its underlying BL did not exhibit obviousdefects, and the proximal limb was normal. Likewise, neuraltube closure was defective in cranial regions, but not in morecaudal sections of the neural tube, consistent with the notion that elevation and closure of the large cranial neural folds that give rise to the brain generates more stress than elevationand closure of the much smaller caudal neural folds that giverise to the spinal cord. This stress may be maximal in the stripof ectoderm just lateral to the neural folds, which Schoenwolfand colleagues have shown to play a critical role in neuraltube closure (Hackett et al., 1997). In their experiments,removal of this portion of the ectoderm in chick embryos impairedelevation of the neural plate and prevented its bending towardsthe dorsal midline. It is in this region that the BL is discontinuousin Lama5 –/– mice but not in controls. We favorthe idea that impaired interactions with the defective BL decreasethe amount of lateral force the overlying ectoderm can generate.Thus, in both limb and head, mechanical stresses on weakened, ${alpha}$ 5-deficient BLs could result in rupture of the BL, which in turn would impair function of the overlying ectoderm.

This explanation is essentially mechanical. Another explanation,not mutually exclusive, is that laminin ${alpha}$ 5 has unique signalingfunctions necessary for development. Indeed, laminins are knownto be signaling molecules that interact with numerous signalingreceptors required for cellular integrity and motility, thebest studied of which are the integrins (Mercurio, 1995). Thus,some defects observed in the mutants could reflect lack of activationof laminin ${alpha}$ 5 receptors, or lack of some other ligand that is absent because the BL is disrupted. For example, the neuroepithelialBL is rich in laminin ${alpha}$ 5 at early stages, and this laminin mightbe required for the neuroepithelium to generate intrinsic forcesnecessary, along with ectoderm-derived forces, for neural tubeclosure (for review see Schoenwolf and Smith, 1990). Likewise,matrix-bound factors such as FGFs and Wnts have been implicatedin patterning of the vertebrate limb (Martin, 1998); their accumulationor localization might be perturbed in laminin ${alpha}$ 5–deficientBLs. In any event, our results show that BLs and the lamininsthey contain are required for neurulation and for proper digitseptation.

The finding that laminin ${alpha}$ 5 deficiency leads to localized structuraldefects in the BL is noteworthy, in that BLs lacking some othermajor components do not exhibit obvious structural defects.For example, laminin β2 is the only β chain so farfound in renal glomerular or neuromuscular synaptic BLs, butthese BLs appear structurally normal in mice lacking lamininβ2, apparently because laminin β1 substitutes forthe absent β2 chain (Noakes et al., 1995a,b; Patton et al., 1997).These BLs are functionally defective, however, so synapticand glomerular functions are impaired. Thus, molecular compensationpermits formation of a structurally intact but functionallyinadequate BL. Likewise, in humans and mice lacking the collagen ${alpha}$ 3– ${alpha}$ 5(IV) chains, which are normally the major collagen chains of the glomerular BL, the ${alpha}$ 1 and ${alpha}$ 2(IV) chains substituteto form an ultrastructurally normal BL. Eventually, however,this BL becomes severely damaged, and the kidney ceases tofunction properly (Kashtan and Kim, 1992; Cosgrove et al., 1996;Miner and Sanes, 1996; Kalluri et al., 1997). In Lama5 –/–mice, in contrast, at least some BLs are ultrastructurallydefective despite ectopic deposition of other ${alpha}$ chains. It remainsto be determined whether the severity of these defects reflectsquantitatively inadequate compensation by other ${alpha}$ chains, or whether ${alpha}$ 5 is uniquely qualified to maintain the structural integrity of BLs.

Acknowledgments

We thank D. Abrahamson, P. Yurchenco, R. Burgeson, and E. Fuchsfor antibodies; A. Nagy for ES cells; M. Nichol for ES cellculture and blastocyst injections; C. Kenoyer, J. Mudd, E. Ryan,and R. Lewis for technical assistance; C. Borgmeyer, J. Gross,and S. Weng for care of mice; T. Tolley (supported by NationalInstitutes of Health PO1HL29594) for help with histology; andR.M. Grady, Y. Sadovsky, D.M. Nelson, Z. Werb, and R. Kopanfor helpful discussions.

This work was supported by grants from the National Institutesof Health to J. Miner and to J.R. Sanes.

Submitted: 4 September 1998

Revised: 27 October 1998

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