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First published online August 18, 2003
doi: 10.1242/10.1242/dev.00635

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The lipid phosphatase LPP3 regulates extra-embryonic vasculogenesis and axis patterning

Diana Escalante-Alcalde^1,*, Lidia Hernandez¹, Hervé Le Stunff³, Ryu Maeda², Hyun-Shik Lee², Jr-Gang-Cheng¹, Vicki A. Sciorra⁴, Ira Daar², Sarah Spiegel³, Andrew J. Morris⁴ and Colin L. Stewart^1,

¹ Cancer and Developmental Biology Laboratory, Division of Basic Science, National Cancer Institute, Frederick, MD 21702, USA
² Regulation of Cell Growth Laboratory, Division of Basic Science, National Cancer Institute, Frederick, MD 21702, USA
³ Department of Biochemistry and Molecular Biophysics, Medical College of Virginia Campus, Virginia Commonwealth University, Richmond, VA 23298,USA
⁴ Department of Cell and Developmental Biology, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599-7090, USA

View larger version (80K): [in a new window]   Fig. 1. Embryonic expression pattern of LPP genes. LPP1 in situ hybridization in an E9.5 embryo (left sense, right antisense) with a uniform ubiquitous expression (purple color). (B) LPP2 in situ hybridization in an E9.5 embryo (left sense, right antisense). LPP2 is weakly but still widely expressed (purple color). (C-K) LPP3 expression in LPP3-IRESlacZ embryos as revealed by ß-galactosidase staining (blue). (C,D) E6.5 embryos showing expression in the extra-embryonic ectoderm (Ex). (E,F) In E7.5 embryos LPP3 is expressed in the anterior (a) domain of the embryo and extra-embryonic membranes. (E) lateral and (F) frontal views. ve, visceral endoderm; ch, chorion. (G,H) E8.0 embryo showing expression of LPP3 in (G) the chorion and anterior domain of the embryo and (H) around (arrows) the node (n) and in the tip of the allantois (all). (I) E8.5 embryo showing strong LPP3 expression in the allantois (all) and paraxial mesoderm. (J) E9.5 embryo showing expression in the somites (s), developing gut (*) and the chorio-allantoic placenta (p). (K) E10.5 embryo showing LPP3 expression in the limb with strongest expression in the apical ectodermal ridge (AER) and continued expression in the umbilical cord (u).

View larger version (36K): [in a new window]   Fig. 2. Inactivation of LPP3 by homologous recombination in ES cells. (A) Gene targeting strategy. The exon containing the 3rd outer loop, containing part of the catalytic domain (box), was deleted (top). The structure of the wild-type allele (middle) and targeted allele (bottom) after homologous recombination are shown. The fragments used for confirming 5' and 3' recombination as well as the location of the primers used for PCR genotyping (arrows) are indicated. (B) LPP3 genotyping by Southern blot. BamHI and BglI digested DNAs were tested with 5' and 3' probes respectively. (C) Genotype of embryos by PCR. DNA samples of yolk sacs were used for amplification of mutant and wild-type allele products using the set of 3 primers indicated in A. Wild-type product = 302 bp; mutant product = 500 bp. (D) Northern blot of embryoid body (EBs) total RNA shows the presence of a smaller transcript (-177 bp) in homozygous mutant cells resulting from the deletion of the exon. (E) Western blot of primary cultured cells revealed a reduction in the levels of LPP3 in heterozygous cells (compare to wild-type) and the absence of any intact protein in homozygous mutant cells. The 36 kDa upper band corresponds to the glycosylated form of the enzyme. (F) PKC phosphorylation in heterozygous and homozygous mutant EBs cultured for 12 days. A phospho (pan)-PKC antibody was used to indirectly measure PKC activation. A reduction of around 50% phospho-pan PKC was observed in the homozygous compared with the heterozygous tissues. Actin was used as a control for amount of protein loaded.

View larger version (105K): [in a new window]   Fig. 3. Phenotype of LPP3-deficient embryos. (A,B) E9.5 wild-type embryo showing the vascularization of the yolk sac (A, arrows), and normal embryonic development at this stage (B); the embryo has turned and the allantois has contacted the chorion. In this individual the connection was lost because of the removal of the extra-embryonic membranes. (C,D) E9.5 homozygous null sibling of the embryo shown in (A,B). The extra-embryonic membranes appear thin, pale, with an anemic appearance and no indication of large blood vessel formation (C). The embryo was smaller and developmentally delayed. The most evident malformation is the abnormal development of the allantois (all). (E) A unique LPP3-/- embryo (right) recovered at E10 showing an advanced developmental progression. Despite an almost normal appearance, the allantois (all) of this embryo formed a very compact mass of tissue. The differentiation of allantoic endothelial cells was demonstrated by the presence of the endothelial marker flk-1 (brown staining). A heterozygous sibling is shown on the left. (F) Semithin section through the allantois of an E9.5 mutant embryo showing blood vessels formation (arrows) and differentiation of hematopoietic cells (asterisk). Scale bars, 0.5 mm.

View larger version (63K): [in a new window]   Fig. 4. LPP3-/- yolk sacs show abnormal vasculogenesis. (A) External appearance of the yolksac in normal (top) and homozygous mutant (bottom) conceptuses recovered at E10.5. In the mutant note the complete absence of blood vessels and a very delayed embryo with its corresponding amnion that can be observed through the yolk sac. (B,C) Development of the vascular plexus in an E10.5 wild-type yolk sac. Formation and ramification of large blood vessels is evident when blood cells are detected by their endogenous peroxidase activity (B) or by staining endothelial cells using a flk-1 probe (C). (D) PECAM-1 detection of endothelial cells in a wild-type mouse embryo at E8.5 showing the formation of the dorsal aortas. (E,F) An E10.5 LPP3-/- yolk sac showing a poor development of the vascular plexus. No large blood vessels were formed. Blood cells and endothelial cells were detected as in B and C. (G) PECAM-1 detection of endothelial cells in a LPP3-deficient embryo at E9.5 showing the formation of the dorsal aortas.

View larger version (111K): [in a new window]   Fig. 5. Extra-embryonic expression of LPP3 partially rescues the placental phenotype and reveals abnormal allantoic vasculogenesis. (A) Rosa26LPP3-/- chimeric embryo recovered at E10.5. In the presence of wild-type extra-embryonic tissue (blue), the allantois from this embryo, entirely derived from LPP3-/- cells, contacted the chorion (arrow). The embryo is also developmentally delayed. (B) Rosa26LPP3-/- chimeric embryo recovered at E10.5. This embryo, formed by a mixture of wild-type (blue) and mutant cells showed more advanced development. Compare with the size and stage of development of the littermate embryo shown in A. The allantois also contacted the chorion (not shown). (C) Transverse section through the chorio-allantoic region of the embryo shown in A. The section corresponded to the maximum diameter of the chorioallantoic region. Although LPP-/- mutant cells (pink) contacted the chorion (arrowheads), the allantois remained as a compact mass of tissue that did not invade the chorion. (D) Transverse section through the chorio-allantoic region of the mixed chimera shown in B. Chorioallantoic placental development was enhanced in the presence of a mixed population of LPP+/+ (blue) and LPP-/- cells. Chorionic development was enhanced, as shown by the wavy appearance of the chorion (arrowheads), increased diameter of the placenta and the formation of large allantoic blood vessels (arrow). Note that the endothelial cells from the umbilical cord vessels were predominantly of wild-type genotype (inset, blue cells). (E) Allantois from a 5-somite wild-type embryo cultured for 36 hours. Note that the PECAM1 positive endothelial cells (brown) developed a flat network of thin capillary-like structures. (F) Allantois from a 5-somite LPP3-/- embryo treated as in E. A mass of PECAM1-positive endothelial cells remained in the center of the explant.

View larger version (62K): [in a new window]   Fig. 6. LPP3 deficiency results in axis duplication. (A,B) An E9.5 LPP3-/-conceptus where the anterior part (hf) of the embryo developed outside the yolk sac (ys) and also exhibited abnormal vasculogenesis (A). When dissected from the extra-embryonic membranes (B), the embryo showed abnormal development of the allantois (all). (C) Cross section through an abnormal embryo showing deficiency in mesenchymal tissue around the paraxial mesoderm. Two large blood vessels (bv) have developed ventral to the somites. d, dorsal. (D) Higher magnification of C showing the neural tube (nt) clearly duplicated in the ventral region, in which a double notochord (*) is also evident. A third somite (s) row has formed ventrally to both notochords. (E,F) Shh and Twist double whole-mount in situ hybridization in LPP3-/- embryos with axis duplication. (E) In some embryos, two short Shh-positive notochords (n) were observed without an additional somite row forming between them. (F) In others, a clear Twist-positive extra somite row formed between the duplicated Shh-positive notochords. (G-H) At E8.5 (G) and E7.5 (H) LPP3-/- embryos (right) develop outside the yolk sac unlike the nornal littermate (left). A constriction between the embryonic and extra-embryonic tissues (arrowhead) is present. In the null embryos the brachyury-expressing primitive streak is shorter in the mutant embryo that in the wild type. A, anterior; P, posterior. (G) E8.5 embryos, (H) E7.5 embryos. (I) On the left, two E7.0 embryos show normal brachyury expression in the primitive streak. On the right, two abnormal littermates show retarded development (equivalent to E6.5), one of which shows primitive streak duplication (arrows). (J) Posterior view of a LPP3-/- embryo recovered at E8.5. Brachyury expression revealed the presence of a common primitive streak-like structure from which two axial mesoderm-like structures have formed. (K) dkk1 expression in an E7.5 LPP3 heterozygous (left) and homozygous mutant (right) embryos. While dkk1 expression extends from the proximal AVE to the distal visceral endoderm in the heterozygous embryo, in the LPP3 null embryo weak dkk1 staining is restricted to a band of cells located in the distal visceral endoderm (arrow). An abnormal outgrowth of tissue formed exactly below the dkk1 expression domain of this mutant embryo (small arrow). The arrowheads indicate the junction between the embryonic and extra-embyonic tissues. A, anterior; P, posterior. (L) Hex and Wnt3 expression are also altered in E7.0 LPP3 null embryos. Hex-positive cells accumulate in the distal tip of the egg cylinder and Wnt3 expression is also found in the anterior embryonic ectoderm (arrows). In normal embryos Hex is expressed in the AVE and Wnt3 is restricted to the posterior embryonic ectoderm. Bars: 250 µm.

View larger version (30K): [in a new window]   Fig. 7. LPP3 regulates ß-catenin-mediated TCF transcriptional activity. (A) ß-catenin transcriptional activity in wild-type and LPP3 null ES cells, as measured by luciferase levels produced from the transfected reporter construct TOPFlash. ß-catenin-mediated TCF activity is upregulated approx. 10- to 15-fold in the LPP3 null ES cells. (B) Transfection of HEK293 cells (which lack endogenous LPP3 activity) with the NH2 truncated (stabilized) ß-catenin results in high levels of ß-catenin-mediated transcription. These levels are attenuated by co-transfection of increasing levels of LPP3. As a control, a ß-catenin unresponsive construct (FOPFlash) was used in these experiments. LPP3 activity in the transfected cells was verified by the release of 32P from labeled LPA. (C) Increasing levels of transfected LPP3 also inhibits endogenous ß-catenin-mediated transcription in the HEK293 cells. (D) Phosphatase-deficient LPP3 also inhibits ß-catenin-mediated TCF transcription. HEK 293 cells transfected with TOPFlash reporter construct and an LPP3 expression cassette carrying the Ser197Thr mutation that inactivates the phosphatase site inhibited TCF/ß-catenin transcription. (E) Western analysis of extracts from the transfected cells in B show that higher concentrations of LPP3 decreased phosphorylation at Ser9 in GSK-3, which correlates with GSK-3 having an increased inhibitory effect on ß-catenin. This coincides with the levels of ß-catenin dephosphorylated at Ser37/Thr41 (the stabilized form) being reduced by increasing LPP3 levels.

View larger version (33K): [in a new window]   Fig. 8. Effect of LPP3 in Wnt target gene expression. Expression analysis of Wnt target genes during EB differentiation. Semi-quantitative RT-PCR analysis of markers at the indicated days in culture. The loading control was the Hprt gene. Bmp4 did not show significant differences in expression during EB differentiation. In contrast, while brachyury expression (a direct transcriptional target of the Wnt signaling pathway) decreased after 6 days in culture in heterozygous EBs, its expression was increased and prolonged in LPP3-/- EBs.

View larger version (94K): [in a new window]   Fig. 9. Effect of LPP3 in Xenopus axial patterning. (A-C) Effect of murine LPP3 mRNA injection in Xenopus embryo development. Stage 36 larvae (A) uninjected, (B) injected dorsally or (C) ventrally with 1 ng of mLPP3 mRNA. Inserts show translated LPP3 protein. Note that only the larvae injected dorsally had abnormal anterior development. (D-H) In situ hybridization of un-injected and dorsally injected Xenopus embryos with markers for anterior development (stage 22). (D,E) Xotx2 detection in uninjected (bottom) and dorsally injected (top) embryos. Some injected embryos lacked (D) or had reduced (E) Xotx2 expression. Reduced and fused eyes can be observed in the injected embryo (E, arrow). (F) Xpax6 detection in uninjected (bottom) and dorsally injected (top) embryos. Injected embryos lacked distinguishable eye staining. (G) Embryos injected ventrally with Xwnt3a show a duplicated axis. (H) Co-injection of mLPP3 with Xwnt3a mRNA rescues secondary axis formation but results in a weak dorsalizalized phenotype. (I) Axis duplication induced by ventral injection of Xwnt8. (J) Co-injection of Xwnt8 with LPP3 mRNA inhibited axis duplication, but the embryos still retained a weak dorsalization phenotype.