Every successful pregnancy requires proper embryo implantation. Low implantation rate is a major problem during infertility treatments using assisted reproductive technologies (ART) 1 . Here we report a new molecular influence on implantation through the lysophosphatidic acid (LPA) receptor LPA 3 2-4 . Targeted deletion of LPA 3 in mice resulted in significantly reduced litter size, which could be attributed to delayed implantation and altered embryo spacing. These two events led to delayed embryonic development, hypertrophic placentas shared by multiple embryos, and embryonic death. An enzyme demonstrated to influence implantation, cyclooxygenase-2 (COX-2) 5 , was downregulated in LPA 3 -deficient uteri during preimplantation. Down regulation of COX-2 led to reduced levels of prostaglandins that are critical for implantation 1 . Exogenous administration of the prostaglandins PGE 2 and cPGI into LPA 3 -deficient females rescued delayed implantation but did not rescue defects in embryo spacing. These data identify LPA 3 receptor-mediated signalling as a new influence on implantation and further indicate linkage between LPA signalling and prostaglandin biosynthesis.Multiple factors can adversely affect successful pregnancy. Two of these factors are failed synchronization between embryonic and endometrial development during implantation and occurrence of multiple gestations (especially monochorionic gestation), which can result in fetal demise 1,6-9 . These factors are particularly important for the clinical success and efficacy of ART. One molecular factor that has been previously implicated in female reproduction is the small, bioactive phospholipid LPA 10 . LPA has a range of influences that are mediated by at least four G protein-coupled receptors, LPA 1-4 2 . Deletion of LPA 1 and LPA 2 in mice revealed roles for these receptors in neural development, craniofacial formation, neuropathic pain, and altered cellular signalling, but without obvious effects on female reproduction 11-Correspondence and requests for materials should be addressed to J. Chun (e-mail:jchun@scripps.edu).. 6 These authors contributed equally to the work. Functional deletion of LPA 3 was achieved by replacing a fragment covering the untranslated region and the start codon in exon 2 with a neomycin-resistance gene in reverse orientation in R1 embryonic stem cells (supplementary Fig. S1). The LPA 3 -deficient mice were born with normal Mendelian frequency without sexual bias (supplementary Table S1), and appeared grossly normal (data not shown). However, LPA 3 -deficient females produced litter sizes of less than 50% compared to that from wild-type (WT) and LPA 3 heterozygote (Het) controls (supplementary Table S2), and showed a statistically significant prolongation of pregnancy (20.9±0.5 days, vs. 19.4±0.7 days in WT/Het controls, P<0.05). These phenotypes were independent of stud genotype, indicating defects in female reproduction. Supplementary InformationTowards determining whether LPA 3 deletion might directly affect the female...
The adhesion molecule L1 is a member of the immunoglobulin superfamily. L1 is involved in various recognition processes in the CNS and PNS, and binding to L1 can activate signal transduction pathways. Mutations in the human L1 gene are associated with a variable phenotype, including mental retardation and anomalous development of the nervous system, referred to as 'CRASH' (corpus callosum hypoplasia, retardation, adducted thumbs, spastic paraplegia, and hydrocephalus). We generated an animal model of these conditions by gene targetting. Mutant mice were smaller than wild-type and were less sensitive to touch and pain, and their hind-legs appeared weak and uncoordinated. The size of the corticospinal tract was reduced and, depending on genetic background, the lateral ventricles were often enlarged. Non-myelinating Schwann cells formed processes not associated with axons and showed reduced association with axons. In vitro, neurite outgrowth on an L1 substrate and fasciculation were impaired. The mutant mouse described here will help to elucidate the functions of L1 in the nervous system and how these depend on genetic influences.
The Alzheimer's disease b-amyloid precursor protein (APP) is a member of a larger gene family that includes the amyloid precursor-like proteins, termed APLP1 and APLP2. We previously documented that APLP2 APLP1À/À and APLP2while APLP1 À/À APP À/À mice and single mutants were viable. We now report that mice lacking all three APP/ APLP family members survive through embryonic development, and die shortly after birth. In contrast to doublemutant animals with perinatal lethality, 81% of triple mutants showed cranial abnormalities. In 68% of triple mutants, we observed cortical dysplasias characterized by focal ectopic neuroblasts that had migrated through the basal lamina and pial membrane, a phenotype that resembles human type II lissencephaly. Moreover, at E18.5 triple mutants showed a partial loss of cortical Cajal Retzius (CR) cells, suggesting that APP/APLPs play a crucial role in the survival of CR cells and neuronal adhesion. Collectively, our data reveal an essential role for APP family members in normal brain development and early postnatal survival.
Together, these data demonstrate that human brain cells (both neurons and non-neuronal cells) can be aneuploid and that the resulting genetic mosaicism is a normal feature of the human CNS.
The many biological responses documented for lysophospholipids that include lysophosphatidic acid and sphingosine 1-phosphate can be mechanistically attributed to signaling through specific G protein-coupled receptors. At least nine receptors have now been identified, and the total number is likely to be larger. In this brief review, we note cogent features of lysophospholipid receptors, including the current nomenclature, signaling properties, development of agonists and antagonists, and physiological functions.
Presenilins mediate an unusual intramembranous proteolytic activity known as ␥-secretase, two substrates of which are the Notch receptor (Notch) and the -amyloid precursor protein (APP). ␥-Secretase-mediated cleavage of APP, like that of Notch, yields an intracellular fragment [APP intracellular domain (AICD)] that forms a transcriptively active complex. We now demonstrate a functional role for AICD in regulating phosphoinositide-mediated calcium signaling. Genetic ablation of the presenilins or pharmacological inhibition of ␥-secretase activity (and thereby AICD production) attenuated calcium signaling in a dose-dependent and reversible manner through a mechanism involving the modulation of endoplasmic reticulum calcium stores. Cells lacking APP (and hence AICD) exhibited similar calcium signaling deficits, and-notablythese disturbances could be reversed by transfection with APP constructs containing an intact AICD, but not by constructs lacking this domain. Our findings indicate that the AICD regulates phosphoinositide-mediated calcium signaling through a ␥-secretasedependent signaling pathway, suggesting that the intramembranous proteolysis of APP may play a signaling role analogous to that of Notch.
We present a flexible and highly specific targeting method for lentiviral vectors based on single-chain antibodies recognizing cell-surface antigens. We generated lentiviral vectors specific for human CD105(+) endothelial cells, human CD133(+) hematopoietic progenitors and mouse GluA-expressing neurons. Lentiviral vectors specific for CD105 or for CD20 transduced their target cells as efficiently as VSV-G pseudotyped vectors but discriminated between endothelial cells and lymphocytes in mixed cultures. CD133-targeted vectors transduced CD133(+) cultured hematopoietic progenitor cells more efficiently than VSV-G pseudotyped vectors, resulting in stable long-term transduction. Lentiviral vectors targeted to the glutamate receptor subunits GluA2 and GluA4 exhibited more than 94% specificity for neurons in cerebellar cultures and when injected into the adult mouse brain. We observed neuron-specific gene modification upon transfer of the Cre recombinase gene into the hippocampus of reporter mice. This approach allowed targeted gene transfer to many cell types of interest with an unprecedented degree of specificity.
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