Placental failure and impaired vasculogenesis result in embryonic lethality for neuropathy target esterase-deficient mice

Age-dependent neurodegeneration resulting from widespread apoptosis of neurons and glia characterize the Drosophila Swiss Cheese (SWS) mutant. Neuropathy target esterase (NTE), the vertebrate homologue of SWS, reacts with organophosphates which initiate a syndrome of axonal degeneration. NTE is expressed in neurons and a variety of nonneuronal cell types in adults and fetal mice. To investigate the physiological functions of NTE, we inactivated its gene by targeted mutagenesis in embryonic stem cells. Heterozygous NTE(+/-) mice displayed a 50% reduction in NTE activity but underwent normal organ development. Complete inactivation of the NTE gene resulted in embryonic lethality, which became evident after gastrulation at embryonic day 9 postcoitum (E9). As early as E7.5, mutant embryos revealed growth retardation which did not reflect impaired cell proliferation but rather resulted from failed placental development; as a consequence, massive apoptosis within the developing embryo preceded its resorption. Histological analysis indicated that NTE is essential for the formation of the labyrinth layer and survival and differentiation of secondary giant cells. Additionally, impairment of vasculogenesis in the yolk sacs and embryos of null mutant conceptuses suggested that NTE is also required for normal blood vessel development.     

Neuropathy target esterase: An essential enzyme for neural development and axonal maintenance

Neuropathy target esterase (NTE) is an endoplasmic reticulum-anchored protein conserved across species. The N-terminal regulatory region of NTE contains three cyclic nucleotide binding domains while the C-terminal catalytic domain has a patatin domain. The NTE gene is expressed in mouse early at embryonic day 7 and its expression is maintained throughout embryonic development. NTE protein is mainly distributed in the nervous system with a pattern that is more restricted to large neurons in older animals. NTE regulates phospholipid metabolism and is known to be a phospholipase B. Knockout of NTE is embryonic lethal in mice, indicating that NTE is essential for embryonic survival. Neuronal specific NTE knockouts survive to adulthood, but show vacuolation and neuronal loss characteristic of neurodegenerative diseases. Recently, mutations in human NTE have been shown to cause a hereditary spastic paraplegia called NTE-related motor neuron disorder, suggesting a critical role for NTE in the nervous system.     

Effect of over-expression of neuropathy target esterase on mammalian cell proliferation

Neuropathy target esterase (NTE), the human homologue of a protein required for brain development in Drosophila, is expressed primarily in neural cells but is also detected in non-neural cells. Although NTE has been proposed to play a role in neurite outgrowth and process elongation during neurodifferentiation, the function of NTE has not been defined in neural cells. In this study we have investigated the possible role of NTE in neuroblastoma cells and non-neural cells using an over-expression strategy. Over-expression of NTE in human neuroblastoma SH-SY5Y cells and monkey kidney COS7 cells led to an accumulation of NTE on the cytoplasmic surface of the endoplasmic reticulum and inhibition of cell proliferation. In particular, high levels of NTE arrested COS7 cells at G2/M stage yet was not associated with arrest at a particular phase of the cell cycle in SH-SY5Y cells. Moreover, over-expression of NTE did not induce apoptosis in two kinds of cell lines as assessed by flow cytometry. These results suggest that the role of NTE over-expression in cell proliferation is associated with different mechanisms in different cells.     

XNAP, a conserved ankyrin repeat-containing protein with a role in the Notch pathway during Xenopus primary neurogenesis.

The Notch signaling pathway plays an important role in many cell-fate decisions during development. Here we investigate the regulation and function of the conserved gene XNAP, which is a member of the Delta-Notch synexpression group in Xenopus. XNAP encodes a small protein with two C-terminal tandem ankyrin repeats which is expressed in the neurectoderm and in the presomitic mesoderm in a pattern that resembles that of other component of the Notch pathway. When a myc-tag form of XNAP is overexpressed in Xenopus or Hela cells, XNAP protein is detected both in the nucleus and the cytoplasm. In embryos and in animal cap assays, XNAP expression is activated, perhaps directly, by the Notch pathway and this activation appears to be Su(H) dependent. Overexpression of XNAP in embryos decreases Notch signaling, which leads to an increase in the number of primary neurons that form within the domains of the neural plate where neurogenesis normally occurs. In culture Hela cells, XNAP overexpression interferes with ICD activation of a Notch regulated reporter gene. Together, these data indicate that XNAP is a novel target of the Notch pathway that may, in a feedback loop, modulate its activity.     

The Drosophila homolog of human AF10/AF17 leukemia fusion genes (Dalf) encodes a zinc finger/leucine zipper nuclear protein required in the nervous system for maintaining EVE expression and normal growth

Sibling neurons in the embryonic central nervous system (CNS) of Drosophila can adopt distinct states as judged by gene expression and axon projection. In the NB4-2 lineage, two even-skipped (eve)-expressing sibling neuronal cells, RP2 and RP2sib, are formed in each hemineuromere. Throughout embryogenesis, only RP2, but not RP2sib, maintains eve expression. In this report, we describe a P-element induced mutation that alters the expression pattern of EVE in RP2 motoneurons in the Drosophila embryonic CNS. The mutation was mapped to a Drosophila homolog of human AF10/AF17 leukemia fusion genes (alf), and therefore named Dalf. Like its human counterparts, Dalf encodes a zinc finger/leucine zipper nuclear protein that is widely expressed in embryonic and larval tissues including neurons and glia. In Dalf mutant embryos, the RP2 motoneuron no longer maintains EVE expression. The effect of the Dalf mutation on EVE expression is RP2-specific and does not affect other characteristics of the RP2 motoneuron. In addition to the embryonic phenotype, Dalf mutant larvae are retarded in their growth and this defect can be rescued by the ectopic expression of a Dalf transgene under the control of a neuronal GAL4 driver. This indicates a requirement for Dalf function in the nervous system for maintaining gene expression and the facilitation of normal growth.     

Keratinocytes enriched for stem cells are protected from anoikis via an integrin signaling pathway in a Bcl-2 dependent manner

In zebrafish, the basic helix-loop-helix (bHLH) gene neuroD specifies distinct neurons in the spinal cord. A preliminary experiment indicated that a related bHLH gene, ndr1a, normally expressed only in the olfactory organ in late embryos, also functions as neuroD to induce ectopic formation of spinal cord neurons in early embryos after introduction of its mRNA into early embryos. To define the functional specificity of these bHLH proteins, several mutant forms with selected point mutations in the basic domain were constructed and tested for inducing sensory neurons in the spinal cord. Our data indicate that the functional specificity of NeuroD to define sensory neurons is mainly due to a single residue (asparagine 11) in its basic domain.     

bHLH Transcription factors and mammalian neuronal differentiation

The basic helix-loop-helix (bHLH) factor Mashl is expressed in the developing nervous system. Null mutation of Mash1 results in loss of olfactory and autonomic neurons and delays differentiation of retinal neurons, indicating that Mash1 promotes neuronal differentiation. Other bHLH genes, Math/NeuroD/Neurogenin, all expressed in the developing nervous system, have also been suggested to promote neuronal differentiation. In contrast, another bHLH factor, HES1, which is expressed by neural precursor cells but not by neurons, represses Mash1 expression and antagonizes Mash1 activity in a dominant negative manner. Forced expression of HES1 in precursor cells blocks neuronal differentiation in the brain and retina, indicating that HES1 is a negative regulator of neuronal differentiation. Conversely, null mutation of HES1 up-regulates Mash1 expression, accelerates neuronal differentiation, and causes severe defects of the brain and eyes. Thus, HES1 regulates brain and eye morphogenesis by inhibiting premature neuronal differentiation, and the down-regulation of HES1 expression at the right time is required for normal development of the nervous system. Interestingly, HES1 can repress its own expression by binding to its promoter, suggesting that negative autoregulation may contribute to down-regulation of HES1 expression during neural development. Recent studies indicate that HES1 expression is also controlled by RBP-J, a mammalian homologue of Suppressor of Hairless [Su(H)], and Notch, a key membrane protein that may regulate lateral specification through RBP-J during neural development. Thus, the Notch → RBP-J → HES1 ÷ Mash1 pathway may play a critical role in neuronal differentiation.     

Molecular cloning and expression pattern of a Cubitus interruptus homologue from the mulberry silkworm Bombyx mori

Mutations in the human Crumbs homologue 1 (CRB1) gene cause severe retinal dystrophies. CRB1 is homologous to Drosophila Crumbs, a protein essential for establishing and maintaining epithelial polarity. We have isolated the mouse orthologue, Crb1, and analyzed its expression pattern in embryonic and post-natal stages. Crb1 is expressed exclusively in the eye, and the central nervous system. In the developing eye, expression of Crb1 is detected in the retinal progenitors, and later on becomes restricted to the differentiated photoreceptor cells where it remains active up to the adult stage. In the developing neural tube, expression of Crb1 is restricted to its most ventral structures, coinciding with the expression domain of Nkx2.2. In the adult brain, Crb1 expression is defined to areas where the production and migration of neurons occurs in adulthood.     

Degradation of neuropathy target esterase by the macroautophagic lysosomal pathway

AimsNeuropathy target esterase (NTE) was proposed as the initial target during the process of organophosphate-induced delayed neuropathy (OPIDN) in humans and some sensitive animals. NTE was recently identified as a novel phospholipase B that is anchored to the cytoplasmic side of the endoplasmic reticulum. However, little is known about the degradation of NTE. In this study, we have investigated the role of the macroautophagic-lysosomal pathway in NTE degradation in neuronal and non-neuronal cells.Main methodsMacroautophagy inhibitors and activators were used to interrupt the lysosomal pathway, and NTE protein level was followed using western blotting analysis. A fluorescent microscopy assay was used to determine the co-localization of NTE and lysosomes.Key findingsWestern blotting analysis showed that the macroautophagy inhibitors 3-methyladenine and ammonium chloride increased the levels of a heterologously expressed NTE-GFP fusion protein as well as endogenous NTE. Starvation had the opposite effect. The role of macroautophagy in NTE degradation was further supported by the co-localization of exogenous NTE with lysosomes in starved COS7 cells. Furthermore, the contribution of NTE activity and protein domains to the degradation of NTE by macroautophagy was investigated, showing that both the transmembrane and regulatory domains played a role in the degradation of NTE and that the catalytic domain, and thus NTE activity, was not involved.SignificanceOur findings clearly demonstrate, for the first time, that the macroautophagy/lysosome pathway plays a role in controlling NTE quantity, providing a further understanding of the function of NTE.     

苹果黑腐皮壳菌CAP超家族蛋白VmPR1c的降解功能域和降解途径

真菌与寄主互作过程中常分泌多种效应蛋白,但植物病原真菌CAP超家族蛋白是否参与致病过程尚不明确。基于苹果黑腐皮壳菌Valsa mali基因组CAP同源基因研究发现VmPR1c敲除后突变体致病性明显下降,但VmPR1c蛋白在表达过程中被降解。本研究借助BLAST、NCBI CDD web server、SignalP 4.1、TMHMM 2.0等进行序列分析,利用缺失突变法及在蛋白表达过程中加蛋白酶抑制剂分别对该蛋白的降解功能域和降解途径进行了探索。C端区段缺失突变结果显示,突变涉及CAP结构域中的α-helix结构和CBM区域时,Western blot条带呈现明显加深;涉及CTE区域及CAP结构域中的半胱氨酸时,Western blot条带则呈现不同程度地减弱。替换VmPR1c的信号肽或突变其信号肽切割位点序列,Western blot条带均有不同程度地加深。分别对CTE和NTE中的脯氨酸进行点突变后,蛋白降解更加严重。在蛋白表达过程中加入蛋白酶体抑制剂MG132和溶酶体抑制剂chloroquine,与对照VmPR1c ^△SP-GFP相比,Western blot结果无明显变化,表明VmPR1c蛋白序列C端区域中的CTE、信号肽及其切割位点序列以及CAP结构域中的α-helix结构介导其降解,其中CTE和NTE中的脯氨酸对该蛋白具保护作用。此外,VmPR1c的降解不通过蛋白酶体和溶酶体途径。     

A Xenopus c-kit-related receptor tyrosine kinase expressed in migrating stem cells of the lateral line system

The mammalian c-kit receptor tyrosine kinase gene is required during embryogenesis for the survival and/or proliferation of three migrating stem cell populations: primordial germ cells, haematopoietic stem cells and neural crest-derived melanoblasts. We have cloned a Xenopus gene, XKrkl, whose closest relative is c-kit. Differences in the expression pattern suggest that XKrkl is not the Xenopus homologue of c-kit; however, it is expressed in a migrating stem cell population, the precursor cells for the mechanosensory lateral line system. XKrkl is the first reported marker for lateral line stem cells.     

Expression pattern of 5''-nucleotidase in Dictyostelium.

In order to analyze the expression pattern of the 5′-nucleotidase (5nt) gene in Dictyostelium, we made a fusion construct in which the 5nt promoter directed the expression of β-galactosidase gene. The reporter gene was not active in vegetative amoebae but was expressed during the aggregation stage. At the slug stage, 5nt was highly expressed in pstAB cells. As the slug moved along the substratum, high activity of β-galactosidase was detected in cells that were left behind in the slime trail. In the completed fruiting body, 5nt was expressed in the lower cup, the anterior like cells (ALC) and the basal disc.     

Neuropathy target esterase and phospholipid deacylation

Certain organophosphates react with the active site serine residue of neuropathy target esterase (NTE) and cause axonal degeneration and paralysis. Cloning of NTE revealed the presence of homologues in eukaryotes from yeast to man and that the protein has both a catalytic and a regulatory domain. The latter contains sequences similar to the regulatory subunit of protein kinase A, suggesting that NTE may bind cyclic AMP. NTE is tethered via an amino-terminal transmembrane segment to the cytoplasmic face of the endoplasmic reticulum. Unlike wild-type yeast, mutants lacking NTE activity cannot deacylate CDP-choline pathway-synthesized phosphatidylcholine (PtdCho) to glycerophosphocholine (GroPCho) and fatty acids. In cultured mammalian cells, GroPCho levels rise and fall, respectively, in response to experimental over-expression, and inhibition, of NTE. A complex of PtdCho and Sec14p, a yeast phospholipid-binding protein, both inhibits the rate-limiting step in PtdCho synthesis and enhances deacylation of PtdCho by NTE. While yeast can maintain PtdCho homeostasis in the absence of NTE, certain post-mitotic metazoan cells may not be able to, and some NTE-null animals have deleterious phenotypes. NTE is not required for cell division in the early mammalian embryo or in larval and pupal forms of Drosophila, but is essential for placenta formation and survival of neurons in the adult. In vertebrates, the relative importance of NTE and calcium-independent phospholipase A2 for homeostatic PtdCho deacylation in particular cell types, possible interactions of NTE with Sec14p homologues and cyclic AMP, and whether deranged phospholipid metabolism underlies organophosphate-induced neuropathy are areas which require further investigation.     

Cloning, sequencing, and expression of the meso-diaminopimelate dehydrogenase gene from Bacillus sphaericus

The gene encoding the meso-diaminopimelate dehydrogenase of Bacillus sphaericus was cloned into E. coli cells and its complete DNA sequence was determined. The meso-diaminopimelate dehydrogenase gene consisted of 978 nucleotides and encoded 326 amino acid residues corresponding to the subunit of the dimeric enzyme. The amino acid sequence deduced from the nucleotide sequence of the enzyme gene of B. sphaericus showed 50% identity with those of the enzymes from Corynebacterium glutamicum and Brevibacterium flavum. The enzyme gene from B. sphaericus was highly expressed in E. coli cells. We purified the enzyme to homogeneity from a transformant with 76% recovery. The N-terminal amino acid of both the enzyme from B. sphaericus and the transformant were serine, indicating that the N-terminal methionine is removed by post-translational modification in B. sphaericus and E. coli cells.     

Expression of Zkrml2, a homologue of the Krml1/val segmentation gene, during embryonic patterning of the zebrafish (Danio rerio)

We have identified Zkrml2, a novel homologue of the segmentation gene Krml/val in zebrafish (Danio rerio). Zkrml2 shows 72% and 92% identity in its basic leucine zipper domain with mouse Krml1 and zebrafish val, respectively. Zkrml2 is expressed coincident with MyoD throughout the somites starting at the three somite stage, becomes restricted to the dermomyotome, and subsequently disappears. Transient expression is also detected in the reticulospinal and oculomotor neurons. Zkrml2 maps to the Oregon linkage group 11 (Boston Linkage group 14) with no mapped zebrafish mutations nearby.     

CRIM1, a novel gene encoding a cysteine-rich repeat protein, is developmentally regulated and implicated in vertebrate CNS development and organogenesis

Development of the vertebrate central nervous system is thought to be controlled by intricate cell-cell interactions and spatio-temporally regulated gene expressions. The details of these processes are still not fully understood. We have isolated a novel vertebrate gene, CRIM1/Crim1, in human and mouse. Human CRIM1 maps to chromosome 2p21 close to the Spastic Paraplegia 4 locus. Crim1 is expressed in the notochord, somites, floor plate, early motor neurons and interneuron subpopulations within the developing spinal cord. CRIM1 appears to be evolutionarily conserved and encodes a putative transmembrane protein containing an IGF-binding protein motif and multiple cysteine-rich repeats similar to those in the BMP-associating chordin and sog proteins. Our results suggest a role for CRIM1/Crim1 in CNS development possibly via growth factor binding.