Interference with function of a homeobox gene in Xenopus embryos produces malformations of the anterior spinal cord

XIHbox 1 is expressed in a narrow band across the cervical region of Xenopus embryos. The gene produces two related proteins: "long" and "short" XIHbox 1 homeodomain proteins. Injection of antibodies to the long XIHbox 1 protein into 1-cell embryos caused a phenotype in which the anterior spinal cord was morphologically transformed into a hindbrain-like structure. This alteration was restricted to the region normally expressing long XIHbox 1 protein. Injection of long protein mRNA disrupted segmentation and tissue organization without inhibiting cell proliferation. Injection of short protein mRNA into 1-cell embryos produced spinal cord malformations similar, but not identical, to those caused by the antibodies, suggesting antagonistic roles for long and short XIHbox 1 proteins. We immunostained tadpoles carrying extended hindbrains for N-CAM and consistently found defective organization of spinal nerves over the affected region.     

Immunological detection of potential signal-transduction proteins expressed during wheat somatic tissue culture.

An immunochemical approach was used to detect the expression of putative guanine nucleotide-binding proteins (G-proteins), arrestin, and nucleoside diphosphate kinases during wheat (Triticum aestivum) tissue culture initiated from immature embryos. Both the soluble and membrane extracts from the immature embryos revealed bands of 58, 40, and 16 kD with antibodies to G-protein (alpha subunit), arrestin, and nucleoside diphosphate kinase, respectively. These proteins were overexpressed in vitro in both nonembryogenic callus and embryogenic cultures. An additional soluble protein (32 kD) was detected by anti-G alpha antibodies in cultured tissues but not in immature embryos, suggesting a possible function in cell multiplication. Moreover, somatic embryogenesis was associated with the appearance of a 29-kD protein reactive with anti-arrstin antibodies, both in soluble and membrane fractions. Tissue-cultured genetic stocks of Chinese Spring wheat, including the disomic, 36 ditelosomic, and 6 nullisomic-tetrasomic wheat lines, were used to ascertain the chromosomal location of the genes encoding the 29-kD arrestin-like protein. The lack of a signal with the nonembryogenic ditelosomic 3 D short chromosome arm line suggests that the 3 D long chromosome arm possesses at least one gene involved in the expression of the 29-kD protein. The putative role of the 29-kD protein in signal-transduction regulating embryogenesis is discussed.     

High-level expression in Escherichia coli of calcium-binding domains of an embryonic sea urchin protein

A plasmid expression vector is described having features that facilitate high-level expression of eukaryotic DNA in Escherichia coli. The vector, designated pMAM17, carries the ColE1 rop gene under the control of the thermally inducible lambda PL promoter. The rop gene product is a negative regulator of ColE1 DNA replication, and its high-level expression is lethal to cells. However, cells harboring a plasmid with an insert in the rop gene grow normally under these conditions. pMAM17 has been used to investigate the properties of a family of proteins expressed in the dorsal ectoderm of sea urchin embryos. The coding sequences of these proteins (termed Spec proteins) have homology to the troponin C superfamily. Large amounts of the Rop-Spec fusion protein were produced at 42 degrees C in E. coli. Unfractionated E. coli extracts containing the fusion protein could be used to produce antibodies that were highly specific for Spec proteins present in crude extracts of sea urchin embryos. Analysis of the Rop-Spec fusion protein on SDS-polyacrylamide gels in the presence and absence of EGTA indicated that the fusion protein bound calcium ions in a manner characteristic of proteins of the troponin C superfamily. This behavior provides biochemical evidence that the Spec proteins are functionally homologous to other members of this superfamily.     

抗果蝇zip基因产物抗体的制备和胚胎zip蛋白分布的研究

zip基因为果蝇晚期神经发生所必需。分子生物学研究表明,zip基因产物是一个膜上整合糖蛋白,可能作为神经细胞的识别或粘联分子参与神经系统的发生。通过基因工程的方法,我们提取了lacZ-zip融合蛋白,继而免疫兔子制备了抗lacZ-zip融合蛋白抗体。该抗体在经过蛋白质印迹鉴定后,用于整幅果蝇胚胎的标记。结果显示zip基因产物主要在胚带缩短后表达,表明zip基因可能参与了晚期神经的发生。抗zip抗体除了识别中枢神经系统(CNS)中的个别神经元外,还标记了侧神经纤维,证实了以前的推测,即在CNS中表达的zip基因可能参与神经纤维束化的建立和维持。     

Proteome comparative analysis of gynogenetic haploid and diploid embryos of goldfish (Carassius auratus)

Recently, it was found that in the gynogenetic haploid and diploid embryos of goldfish, which have exactly the same genome, the haploid condition results in obstruction of gene expression and abnormal development while the diploid embryos have normal gene expression and development. A diploid-dependent regulatory apparatus was proposed to regulate gene expression. To study the difference at the protein expression level of the embryos of haploid and diploid in development, we extracted the total proteins of both the gynogenetic haploid and diploid embryos of goldfish in the same eye formation stage. Two-dimensional polyacrylamide gel electrophoresis was used to separate proteins. The stained gel images were analyzed with the PDQUEST software. A part of protein spots that were differentially expressed in haploid and diploid embryos were identified by matrix assisted laser desorption/ionisation-time of flight-mass spectrometry and database analysis. Sixteen protein spots that were absolutely different (only expressed in diploid embryos but not in haploid embryos or vice versa) and 16 protein spots that were up- and downregulated were identified unambiguously, which include some proteins that are correlative with eyes development, nerve development, developing regulation, cell differentiation, and signal transduction. The different significantly gene expression during embryos developing between diploid and haploid is demonstrated.     

Differential,temporal and spatial expression of genes involved in storage oil and oleosin accumulation in developing rapeseed embryos: implications for the role of oleosins and the mechanisms of oil-body formation

The temporal and spatial expression of oleosin and ₉-stearoyl-ACP desaturase genes and their products has been examined in developing embryos of rapeseed, Brassica napus L. var. Topas. Expression of oleosin and stearate desaturase genes was measured by in situ hybridisation at five different stages of development ranging from the torpedo stage to a mature-desiccating embryo. The temporal pattern of gene expression varied dramatically between the two classes of gene. Stearate desaturase gene expression was relatively high, even at the torpedo stage, whereas oleosin gene expression was barely detectable at this stage. By the stage of maximum embryo fresh weight, stearate desaturase gene expression had declined considerably while oleosin gene expression was at its height.In contrast to their differential temporal expression, the in situ labelling of both classes of embryo-specific gene showed similar, relatively uniform patterns of spatial expression throughout the embryo sections. Immunogold labelling of ultra-thin sections from radicle tissue with anti-oleosin antibodies showed similar patterns to sections from cotyledon tissue. However, whereas at least three oleosin isoforms were detectable on western blots of homogenates from cotyledons, only one isoform was found in radicles. This suggests that some of the oleosin isoforms may be expressed differentially in the various types of embryo tissue. The differential timing of stearate desaturase and oleosin gene expression was mirrored by similar differences in the timing of the accumulation of their ultimate products, i.e. storage oil and oleosin proteins. Oil-body fractions prepared from young (2.5 mg) embryos contained very little oleosin protein, as examined by SDS-PAGE and western blotting, whereas identically prepared fractions from dry seeds contained over 10% (w/w) oleosin. Dehydration of oil bodies from young embryos resulted in their breakdown and coalescence into large clumps of oil which could not be re-emulsified, even after rehydration. In contrast, the oleosin-rich oil bodies from mature embryos were stable to dehydration and subsequent rehydration. It is suggested that, in developing rapeseed embryos, the accumulation of storage oil and oleosins is not concomitant but that the eventual deposition of oleosins onto the surfaces of storage oil bodies is essential for their stability during seed desiccation.Abbreviations ABA abscisic acid - ACP acyl carrier protein - GLC gas-liquid chromatography - PBS phosphate-buffered saline     

Cloning and characterization of barley long chain acyl-CoA oxidase and its possible regulation by glucose

A barley ( Hordeum vulgare L.) full-length clone coding for long chain acyl-CoA oxidase (ACX), key enzyme of β -oxidation, was isolated by cDNA library screening and 5'-rapid amplification of cDNA ends. The cDNA encodes for a polypeptide of 667 amino acids, with a molecular mass of 74.5 kDa. The amino acid sequence, beside an extensive similarity with other plant and mammalian ACXs, showed a PTS1 peroxisomal targeting signal at the C terminus and a conserved FAD-binding domain. The gene was over-expressed in E. coli and the fusion protein was shown to possess long chain acyl-CoA oxidase activity. Polyclonal antibodies were raised against a large fragment of the protein encoded by the barley putative ACX gene. Northern and Western analysis demonstrated that a basal level of long chain ACX is always present along the barley life cycle, while a higher level of expression is typical of actively growing tissues such as germinating embryos, ovary before anthesis, developing embryos, shoots and roots apexes. In vitro germination experiments with glucose and glucose analogues provided evidence about the involvement of a glucose-deriving signal in the positive modulation of ACX expression. This result highlights the role of ACX, not only during oil reserve mobilization, but also in plant growth and metabolism.     

Knockdown of two splice variants of Ca(2+)/calmodulin-dependent protein kinase Iδ causes developmental abnormalities in zebrafish, Danio rerio

We isolated cDNA clones for zebrafish Ca(2+)/calmodulin-dependent protein kinase I (zCaMKI) δ isoforms by expression screening using cDNA library from embryos at 72-h post-fertilization (hpf). There are two splice variants with different C-terminal sequences, comprising of 392 and 368 amino acids, and they are designated zCaMKIδ-L (long form) and zCaMKIδ-S (short form), respectively. Although recombinant zCaMKIδ-L and zCaMKIδ-S expressed in Escherichia coli showed essentially the same catalytic properties including substrate specificities, they showed different spatial and temporal expression. Western blotting analysis using the isoform-specific antibodies revealed that zCaMKIδ-L clearly appeared from 36hpf but zCaMKIδ-S began to appear at 60hpf and thereafter. zCaMKIδ-S was predominantly expressed in brain, while zCaMKIδ-L was widely distributed in brain, eye, ovary and especially abundantly expressed in skeletal muscle. The gene knockdown of zCaMKIδ using morpholino-based antisense oligonucleotides induced significant morphological abnormalities in zebrafish embryos. Severe phenotype of embryos exhibited short trunk, kinked tail and small heads. These phenotypes could be rescued by coinjection with the recombinant zCaMKIδ, but not with the kinase-dead mutant. These results clearly indicate that the kinase activity of zCaMKIδ plays a crucial role in the early stages in the embryogenesis of zebrafish.     

Tankyrase 1 interacts with Mcl-1 proteins and inhibits their regulation of apoptosis

Mcl-1L (myeloid cell leukemia-1 long) is an antiapoptotic Bcl-2 family protein discovered as an early induction gene during leukemia cell differentiation. Previously, we identified Mcl-1S (short) as a short splicing variant of the Mcl-1 gene with proapoptotic activity. To identify Mcl-1-interacting proteins, we performed yeast two-hybrid screening and found cDNAs encoding tankyrase 1. This protein possesses poly(ADP-ribose) polymerase activity and presumably facilitates the turnover of substrates following ADP-ribosylation. In yeast and mammalian cells, tankyrase 1 interacts with both Mcl-1L and Mcl-1S, but does not bind to other Bcl-2 family proteins tested. Analysis of truncated tankyrase 1 mutants indicated that the first 10 ankyrin repeats are involved in interaction with Mcl-1. In the N terminus of Mcl-1, a stretch of 25 amino acids is sufficient for binding to tankyrase 1. Overexpression of tankyrase 1 antagonizes both Mcl-1L-mediated cell survival and Mcl-1S-induced cell death. Furthermore, coexpression of tankyrase 1 with Mcl-1L or Mcl-1S decreased the levels of Mcl-1 proteins. Although tankyrase 1 down-regulates Mcl-1 protein expression, no ADP-ribosylation of Mcl-1 was detected. In contrast, overexpression of Mcl-1 proteins suppressed the ADP-ribosylation of the telomeric repeat binding factor 1, another tankyrase 1-interacting protein. Thus, interaction of Mcl-1L and Mcl-1S with tankyrase 1 could serve as a unique mechanism to decrease the expression of these Bcl-2 family proteins, thereby leading to the modulation of the apoptosis pathway.     

Quantitative Proteomics Reveals Remodeling of Protein Repertoire Across Life Phases of Daphnia pulex

Although the microcrustacean Daphnia is becoming an organism of choice for proteomic studies, protein expression across its life cycle have not been fully characterized. Proteomes of adult females, juveniles, asexually produced embryos, and the ephippia‐resting stages containing sexually produced diapausing freezing‐ and desiccation‐resistant embryos are analyzed. Overall, proteins with known molecular functions are more likely to be detected than proteins with no detectable orthology. Similarly, proteins with stronger gene model support in two independent genome assemblies can be detected, than those without such support. This suggests that the proteomics pipeline can be applied to verify hypothesized proteins, even given questionable reference gene models. In particular, upregulation of vitellogenins and downregulation of actins and myosins in embryos of both types, relative to juveniles and adults, and overrepresentation of cell‐cycle related proteins in the developing embryos, relative to diapausing embryos and adults, are observed. Upregulation of small heat‐shock proteins and peroxidases, as well as overrepresentation of stress‐response proteins in the ephippium relative to the asexually produced non‐diapausing embryos, is found. The ephippium also shows upregulation of three trehalose‐synthesis proteins and downregulation of a trehalose hydrolase, consistent with the role of trehalose in protection against freezing and desiccation.     

The giant gene of Drosophila encodes a b-ZIP DNA-binding protein that regulates the expression of other segmentation gap genes.

The sequence of a cDNA from the giant gene of Drosophila shows that its product has a basic domain followed by a leucine zipper motif. Both features contain characteristic conserved elements of the b-ZIP family of DNA-binding proteins. Expression of the gene in bacteria or by in vitro translation yields a protein that migrates considerably faster than the protein extracted from Drosophila embryos. Treatment with phosphatase shows that this difference is due to multiple phosphorylation of the giant protein in the embryo. Ectopic expression of the protein in precellular blastoderm embryos produces abnormal phenotypes with a pattern of segment loss closely resembling that of Krüppel mutant embryos. Immunological staining shows that giant, ectopically expressed from the hsp70 promoter, represses the expression of both the Krüppel and knirps segmentation gap genes. The analysis of the interactions between Krüppel, knirps and giant reveals a network of negative regulation. We show that the apparent positive regulation of knirps by Krüppel is in fact mediated by a negative effect of Krüppel on giant and a negative effect of giant on knirps. giant protein made in bacteria or in embryos binds in vitro to the Krüppel regulatory elements CD1 and CD2 and recognizes a sequence resembling the binding sites of other b-ZIP proteins.