The Arabidopsis gene PROLIFERA is required for proper cytokinesis during seed development

The Arabidopsis thaliana (L.) Heynh. gene PROLIFERA (PRL) is a member of the MCM family of genes that are required for DNA replication during the S phase of the cell cycle. PRL is expressed in dividing cells throughout plant development. During reproductive development, PRL is expressed in both the developing megaspore mother cells and microspore mother cells, but is not expressed in the developing microgametophyte, suggesting that it does not function in the final haploid divisions leading to the production of a mature pollen grain. Disruption of PRL leads to megagametophyte and embryo lethality. prl mutant embryos arrest at a variety of stages, and often show defects in cytokinesis. Multinucleate cells and non-stereotypical cell division planes are commonly observed in developing prl mutant embryos, although mcm mutations in other organisms have not been reported to affect cytokinesis. These observations suggest that PRL may play a role in cytokinesis that is distinct from its role in regulating DNA replication. Additionally, a novel cytokinesis checkpoint that monitors cell cycle progression may exist in Arabidopsis.     

Arabidopsis adaptor protein 1G is critical for pollen development

Pollen development is a pre-requisite for sexual reproduction of angiosperms, during which various cellular activities are involved. Pollen development accompanies dynamic remodeling of vacuoles through fission and fusion, disruption of which often compromises pollen viability. We previously reported that the Y subunit of adaptor protein 1(AP1G) mediates synergid degeneration during pollen tube reception.Here, we demonstrate that AP1G is essential for pollen development. AP1G loss-of-function resulted in male gametophytic lethality due to defective pollen development. By ultrastructural analysis and fluorescence labeling, we demonstrate that AP1G loss-of-function compromised dynamic vacuolar remodeling during pollen development and impaired vacuolar acidification of pollen. Results presented here support a key role of vacuoles in gametophytic pollen development.     

Arabidopsis AtVPS15 plays essential roles in pollen germination possibly by interacting with AtVPS34

VPS 15 protein is a component of the phosphatidylinositol 3-kinase complex which plays a pivotal role in the development of yeast and mammalian cells.The knowledge about the function of its homologue in plants remains limited.Here we report that AtVPS15, a homologue of yeast VPS15p in Arabidopsis,plays an essential role in pollen germination.Homozygous T-DNA insertion mutants of AtVPS15 could not be obtained from the progenies of self-pollinated heterozygous mutants.Reciprocal crosses between atvpslS mutants and wild-type Arabidopsis revealed that the T-DNA insertion was not able to be transmitted by male gametophytes.DAPI staining, Alexander’s stain and scanning electron microscopic analysis showed that atvpsl5 heterozygous plants produced pollen grains that were morphologically indistinguishable from wild-type pollen,whereas in vitro germination experiments revealed that germination of the pollen grains was defective.GUS staining analysis of transgenic plants expressing the GUS reporter gene driven by the AtVPS15 promoter showed that AtVPSI5 was mainly expressed in pollen grains.Finally,DUALmembrane yeast two-hybrid analysis demonstrated that AtVPS15 might interact directly with AtVPS34.These results suggest that AtVPS15 is very important for pollen germination,possibly through modulation of the activity of PI3-kinase.     

SPINDLY is a nuclear-localized repressor of gibberellin signal transduction expressed throughout the plant

SPY (SPINDLY) encodes a putative O-linked N-acetyl-glucosamine transferase that is genetically defined as a negatively acting component of the gibberellin (GA) signal transduction pathway. Analysis of Arabidopsis plants containing a SPY::GUS reporter gene reveals that SPY is expressed throughout the life of the plant and in most plant organs examined. In addition to being expressed in all organs where phenotypes due to spy mutations have been reported, SPY::GUS is expressed in the root. Examination of the roots of wild-type, spy, and gai plants revealed phenotypes indicating that SPY and GAI play a role in root development. A second SPY::GUS reporter gene lacking part of the SPY promoter was inactive, suggesting that sequences in the first exon and/or intron are required for detectable expression. Using both subcellular fractionation and visualization of a SPY-green fluorescent protein fusion protein that is able to rescue the spy mutant phenotype, the majority of SPY protein was shown to be present in the nucleus. This result is consistent with the nuclear localization of other components of the GA response pathway and suggests that SPY's role as a negative regulator of GA signaling involves interaction with other nuclear proteins and/or O-N-acetyl-glucosamine modification of these proteins.     

Differential regulation of imprinting in the murine embryo and placenta by the Dlk1-Dio3 imprinting control region

Genomic imprinting is an epigenetic mechanism controlling parental-origin-specific gene expression. Perturbing the parental origin of the distal portion of mouse chromosome 12 causes alterations in the dosage of imprinted genes resulting in embryonic lethality and developmental abnormalities of both embryo and placenta. A 1 Mb imprinted domain identified on distal chromosome 12 contains three paternally expressed protein-coding genes and multiple non-coding RNA genes, including snoRNAs and microRNAs, expressed from the maternally inherited chromosome. An intergenic, parental-origin-specific differentially methylated region, the IG-DMR, which is unmethylated on the maternally inherited chromosome, is necessary for the repression of the paternally expressed protein-coding genes and for activation of the maternally expressed non-coding RNAs: its absence causes the maternal chromosome to behave like the paternally inherited one. Here, we characterise the developmental consequences of this epigenotype switch and compare these with phenotypes associated with paternal uniparental disomy of mouse chromosome 12. The results show that the embryonic defects described for uniparental disomy embryos can be attributed to this one cluster of imprinted genes on distal chromosome 12 and that these defects alone, and not the mutant placenta, can cause prenatal lethality. In the placenta, the absence of the IG-DMR has no phenotypic consequence. Loss of repression of the protein-coding genes occurs but the non-coding RNAs are not repressed on the maternally inherited chromosome. This indicates that the mechanism of action of the IG-DMR is different in the embryo and the placenta and suggests that the epigenetic control of imprinting differs in these two lineages.     

Suppressors of a Gpa1 Mutation Cause Sterility in Saccharomyces Cerevisiae

The Saccharomyces cerevisiae GPA1 gene encodes a protein highly homologous to the α subunit of mammalian G proteins and is essential for haploid cell growth. We have selected 77 mutants able to suppress the lethality resulting from disruption of GPA1 (gpa1::HIS3). Two strains bearing either of two recessive mutations, sgp1 and sgp2, in combination with the disruption mutation, showed a cell type nonspecific sterile phenotype, yet expressed the major α-factor gene (MFα1) as judged by the ability to express a MFα1-lacZ fusion gene. The sgp1 mutation was closely linked to gpa1::HIS3 and probably occurred at the GPA1 locus. The sgp2 mutation was not linked to GPA1 and was different from the previously identified cell type nonspecific sterile mutations (ste4, ste5, ste7, ste11 and ste12). sgp2 GPA1 cells showed a fertile phenotype, indicating that the mating defect caused by sgp2 is associated with the loss of GPA1 function. While expression of a FUS1-lacZ fusion gene was induced in wild-type cells by the addition of α-factor, mutants bearing sgp1 or sgp2 as well as gpa1::HIS3 constitutively expressed FUS1-lacZ. These observations suggest that GPA1 (SGP1) and SGP2 are involved in mating factor-mediated signal transduction, which causes both cell cycle arrest in the late G(1) phase and induction of genes necessary for mating such as FUS1.     

水稻小G蛋白OsPra2基因的克隆及功能分析

利用micro array 技术对水稻幼苗在营养胁迫条件下根部基因表达的研究中发现: 一个与豌豆Pra2(小G蛋白)基因有同源性的基因的RNA水平在营养胁迫后再补充营养时, 表达量下降。用RT-PCR和PCR方法分别获得该基因的cDNA克隆—OsPra2和该基因翻译起始位点上游1 kb的启动子序列。OsPra2基因编码的蛋白质具有结合GTP/GDP的4个保守结构域和构成小G蛋白Rab家族的特有的结构域。该基因cDNA与GST蛋白基因融合表达载体在洋葱表皮细胞中的瞬间表达结果显示该蛋白定位在在细胞膜和细胞核上, OsPra2基因启动子与GUS报告基因融合表达转基因水稻显示该基因启动子驱动GUS在胚芽鞘和根中表达, 35S启动子驱动OsPra2基因过表达转基因水稻与野生水稻株型相比明显矮化, 类似BR缺陷型植物株型。本实验还对OsPra2和P450蛋白的相互作用及在BR代谢途径中的可能作用进行了分析。     

RGS14 is a mitotic spindle protein essential from the first division of the mammalian zygote

Heterotrimeric G protein alpha subunits, RGS proteins, and GoLoco motif proteins have been recently implicated in the control of mitotic spindle dynamics in C. elegans and D. melanogaster. Here we show that "regulator of G protein signaling-14" (RGS14) is expressed by the mouse embryonic genome immediately prior to the first mitosis, where it colocalizes with the anastral mitotic apparatus of the mouse zygote. Loss of Rgs14 expression in the mouse zygote results in cytofragmentation and failure to progress to the 2-cell stage. RGS14 is found in all tissues and segregates to the nucleus in interphase and to the mitotic spindle and centrioles during mitosis. Alteration of RGS14 levels in exponentially proliferating cells leads to cell growth arrest. Our results indicate that RGS14 is one of the earliest essential product of the mammalian embryonic genome yet described and has a general role in mitosis.     

PtABI3 impinges on the growth and differentiation of embryonic leaves during bud set in poplar

The Arabidopsis ABSCISIC ACID-INSENSITIVE3 (ABI3) protein plays a crucial role during late seed development and has an additional function at the vegetative meristem, particularly during periods of growth-arresting conditions and quiescence. Here, we show that the ABI3 homolog of poplar (PtABI3) is expressed in buds during natural bud set. Expression occurs clearly after perception of the critical daylength that initiates bud set and dormancy in poplar. In short-day conditions mimicking natural bud set, the expression of a chimeric PtABI3::beta-glucuronidase (GUS) gene occurred in those organs and cells of the apex that grow actively but will undergo arrest: the young embryonic leaves, the subapical meristem, and the procambial strands. If PtABI3 is overexpressed or downregulated, bud development in short-day conditions is altered. Constitutive overexpression of PtABI3 resulted in apical buds with large embryonic leaves and small stipules, whereas in antisense lines, bud scales were large and leaves were small. Thus, PtABI3 influences the size and ratio of embryonic leaves and bud scales/stipules that differentiate from the primordia under short-day conditions. These observations, together with the expression of PtABI3::GUS in embryonic leaves but not in bud scales/stipules, support the idea that wild-type PtABI3 is required for the relative growth rate and differentiation of embryonic leaves inside the bud. These experiments reveal that ABI3 plays a role in the cellular differentiation of vegetative tissues, in addition to its function in seeds.     

AtOPT3, a member of the oligopeptide transporter family,is essential for embryo development in Arabidopsis

A T-DNA-tagged population of Arabidopsis was screened for mutations in AtOPT3, which encodes a member of the oligopeptide (OPT) family of peptide transporters, and a recessive mutant allele, opt3, was identified. Phenotypic analysis of opt3 showed that most homozygous embryos were arrested at or before the octant stage of embryo development and that none showed the usual periclinal division leading to the formation of the protoderm. This defective phenotype could be reversed by complementation with the full-length, wild-type AtOPT3 gene. A beta-glucuronidase (GUS) fusion to DNA sequences upstream of the putative AtOPT3 ATG start codon was constructed, and the expression pattern was assayed in transgenic plants. AtOPT3 was expressed in the vascular tissues of seedlings and mature plants as well as in pollen. Consistent with the function of AtOPT3 in embryogenesis, AtOPT3::GUS expression also was detected in developing embryos and in the maternal tissues of seeds. These data suggest a critical role for peptide transport in early embryo development.     

Identification of the sequence responsible for the nuclear accumulation of the influenza virus nucleoprotein in Xenopus oocytes

Influenza virus nucleoprotein (NP), synthesized in Xenopus oocytes after injection of cloned NP cDNA, enters and accumulates in the nucleus. We have used in vitro mutagenesis of this cDNA to study the cellular distribution of mutated NP polypeptides. Mutants lacking amino acids 327-345 of wild-type NP enter the nucleus but do not accumulate there to the same extent as the wild-type protein, suggesting that this region has a role in nuclear accumulation. This possibility is further strengthened by similar studies involving the production of fusion proteins in which various amino-terminal sequences of the NP gene are fused to the complete chimpanzee alpha 1-globin sequence: when globin cDNA was injected into and expressed in oocytes the protein remains exclusively in the cytosol; however, when the globin cDNA is fused to a portion of NP cDNA that includes the region encoding amino acids 327-345, the resulting fusion protein enters and accumulates in the nucleus. Fusion proteins lacking this region of the NP enter but do not accumulate in the nucleus.     

Expression of the [beta]-Glucuronidase Gene in Pollen of Lily (Lilium longiflorum), Tobacco (Nicotiana tabacum), Nicotiana rustica,and Peony (Paeonia lactiflora) by Particle Bombardment

A [beta]-glucuronidase (GUS) gene that is under the control of the anther-specific LAT52 promoter of tomato (Lycopersicon esculentum) and the nopaline synthetase polyadenylation terminator was successfully expressed in pollen of Lilium longiflorum, Nicotiana tabacum, Nicotiana rustica, and Paeonia lactiflora using a pneumatic particle gun. The GUS gene in plasmid pBI221 was also expressed, to a lesser extent, in pollen of all of these species. The presence of methanol in the substrate solution for histochemical GUS assay and the incubation time in this solution influenced successful detection of GUS expression in bombarded pollen. Cytological analysis of GUS-expressing pollen of lily showed that introduced gold particles were seen in intracellular compartments of pollen, including the vegetative cytoplasm, vegetative nucleus, and generative cytoplasm.     

SOCS3 is essential in the regulation of fetal liver erythropoiesis.

SOCS3 (CIS3/JAB2) is an SH2-containing protein that binds to the activation loop of Janus kinases, inhibiting kinase activity, and thereby suppressing cytokine signaling. During embryonic development, SOCS3 is highly expressed in erythroid lineage cells and is Epo independent. Transgene-mediated expression blocks fetal erythropoiesis, resulting in embryonic lethality. SOCS3 deletion results in an embryonic lethality at 12-16 days associated with marked erythrocytosis. Moreover, the in vitro proliferative capacity of progenitors is greatly increased. SOCS3-deficient fetal liver stem cells can reconstitute hematopoiesis in lethally irradiated adults, indicating that its absence does not disturb bone marrow erythropoiesis. Reconstitution of lymphoid lineages in JAK3-deficient mice also occurs normally. The results demonstrate that SOCS3 is critical in negatively regulating fetal liver hematopoiesis.     

β-Glucuronidase gene and green fluorescent protein gene expression in de-exined pollen of Nicotiana tabacum by microprojectile bombardment

 Gene constructs containing the β-glucuronidase (GUS) gene or green fluorescent protein (GFP) gene under the control of pollen-specific promoter Zm13-260 from maize were introduced by particle bombardment into de-exined pollen of Nicotiana tabacum. The de-exined pollen exhibited transient expression of the GUS or GFP gene as indicated by histochemical and fluorescent assay, respectively. The frequency of de-exined pollen transformation with the GUS or GFP gene was approximately 6 and 3 times higher, respectively, than that of pollen with intact walls, indicating that pollen deprived of the exine barrier responded better to foreign gene transfer than did the original. Cytological observation of GUS-expressing pollen grains showed that introduced gold particles were visible in the cytoplasm and vegetative nucleus as well as in the generative nucleus. GFP-expressing pollen tubes were observed in the style even after pollination. Received: 28 October 1997 / Revision accepted: 13 April 1998