Fertilization in Torenia fournieri: Actin organization and nuclear behavior in the central cell and primary endosperm

Studies of the living embryo sacs of Torenia fournieri reveal that the actin cytoskeleton undergoes dramatic changes that correlate with nuclear migration within the central cell and the primary endosperm. Before pollination, actin filaments appear as short bundles randomly distributed in the cortex of the central cell. Two days after anthesis, they become organized into a distinct actin network. At this stage the secondary nucleus, which is located in the central region of the central cell, possesses an associated array of short actin filaments. Soon after pollination, the actin filaments become fragmented in the micropylar end and the secondary nucleus is located next to the egg apparatus. After fertilization, the primary endosperm nucleus moves away from the egg cell and actin filaments reorganize into a prominent network in the cytoplasm of the primary endosperm. Disruption of the actin cytoskeleton with latrunculin A and cytochalasin B indicates that actin is involved in the migration of the nucleus     

Regulation of sporopollenin synthesis for pollen wall formation in plant

正Pollen wall is the most complicated cell wall in plant.It is composed of outer exine and inner intine with the exine further divided into sexine and nexine.The composition of intine layer is generally considered to be same as a plant cell wall which is mainly composed of cellulose.Nexine layer can only be observed under transmission electron microscope.Recent investigation suggested that the major composition of nexine is arabinogalactan proteins(Jia et al.,2015).The sexine layer is composed of sporopollenin which is quite stable     

Identification of novel nuclear localization signal within the ErbB-2 protein

ErbB2, a member of the receptor tyrosine kinase family, is frequently over-expressed in breast cancer. Proteolysis of the extracellular domain of ErbB2 results in constitutive activation of ErbB2 kinase. Recent study reported that ErbB2 is found in the nucleus. Here, we showed that ErbB2 is imported into the nucleus through a nuclear localization signal（NLS）-mediated mechanism. The NLS sequence KRRQQKIRKYTMRR （aa655-668） contains three clusters of basic amino acids and it is sufficient to target GFP into the nucleus. However, mutation in any basic amino acid cluster of this NLS sequence significantly affects its nuclear localization. Furthermore, it was found that this NLS is essential for the nuclear localization of ErbB2 since the intracellular domain of Erb2 lacking NLS completely abrogates its nuclear translocation. Taken together, our study identified a novel nuclear localization signal and reveals a novel mechanism underlying ErbB2 nuclear trafficking and localization.     

Identification of the nuclear matrix and chromosome scaffold in dinoflagellate Crypthecodinium cohnii

Dinolflagellate is one of the primitive eukaryotes,whose nucleus may represent one of the transition stages from prokaryotic nucleoid to typical eukaryotic nucleus,Using selective extraction together with embeddment-free section and whole mount electron microscopy,a delicate nuclear matrix filament network was shown,for the first time,in dinoflagellate Crypthecodinium cohnii nucleus,Chromosome residues are connected with nuclear matrix filaments to form a complete network spreading over the nucleus,Moreover,we demonstrated that the dinoflagellate chromosome retains a protein scafflod after the depletion of DNA and soluble proteins.This scaffold preserves the characterstic morphology of the chromosome.Two dimensional electrophoreses indicated that the nuclear matrix and chromosome scaffold are mainly composed of acidic proteins.Our results demonstrated that a framework similar th the nuclear matrix and chromosome scaffold in mammalian cells appears in this primitive eukaryote,suggesting that these structures may have been originated from the early stages of eukaryote evolution.     

Cryo-electron microscopy reveals high-resolution structures of 30-nm chromatin fibers in vitro

<正>Human chromosomes are the largest and most visible structures involved in the transfer of genetic information.The most striking property of a chromosome is that about three billion base pairs of the human genome are compacted into a nucleus of only several micrometers in diameter.It is well known that DNA in eukaryotic cells is initially packaged into nucleosomes by means of extensive association     

Characterization of MR-1, a novel myofibrillogenesis regulator in human muscle

Myofibrils are components of both cardiac and skeletalmuscle cells. Myofibrillogenesis is a highly complexprocess that involves the expression and assembly ofmuscle proteins into sarcomeres [1]. The key componentsof sarcomeres are two filamentary proteins, actin andmyosin. Sarcomeric myosin is the molecular motor thattransduces energy from the hydrolysis of ATP into directedmovement and drives sarcomere shortening and musclecontraction. Each myosin hexamer is composed of twoheavy chains, two…     

Identification of the nuclear matrix and chromosome scaffold in dinoflagellate Crypthecodinium cohnii~1

Dinoflagellate is one of the primitive eukaryotes,whosenucleus may represent one of the transition stages fromprokaryotic nucleoid to typical eukaryotic nucleus.Usingselective extraction together with embeddment-free sectionand whole mount electron microscopy,a delicate nuclearmatrix filament network was shown,for the first time,indinoflagellate Crypthecodinium cohnii nucleus.Chromosomeresidues are connected with nuclear matrix filaments to forma complete network spreading over the nucleus.Moreover,we demonstrated that the dinoflagellate chromosome retainsa protein scaffold after the depletion of DNA and solubleproteins.This scaffold preserves the characteristic mor-phology of the chromosome.Two dimensional elec-trophoreses indicated that the nuclear matrix and chromo- some scaffold are mainly composed of acidic proteins.Ourresults demonstrated that a framework similar to the nuclearmatrix and chromosome scaffold in mammalian cells appearsin this primitive eukaryote,suggesting that these structuresmay have been originated from the early stages of eukaryoteevolution.     

Functional Characterization of the Group Ⅰ Alphabaculovirus Specific Gene ac73

Baculoviridae is a family of large DNA viruses that specifically infect insects. It contains four genera, Alpha-, Beta-,Gamma-, and Deltabaculovirus. Alphabaculovirus is further divided into Group I and II, and Group I appears to be emerged most recently among all baculoviruses. Interestingly, there are 12 Group I specific genes that are only found in this lineage. Studying these genes is helpful to understand how baculoviruses evolved. Here, we reported the functional analyzing results of ac73, a function unknown Group I specific gene of Autographa californica multiple nucleopolyhedrovirus(Ac MNPV) which is the type species of baculovirus. The AC73 protein encoded by ac73 was found to be expressed during the late stage of infection and incorporated into the nucleocapsids of budded virus(BV) and occlusionderived virus(ODV). In infected cells, AC73 resided mainly in the ring zone region of the nucleus, and appeared to be assembled into occlusion bodies(OBs). The ac73 knockout and repaired viruses were constructed and studied by in vitro and in vivo infection. Although ac73 was not essential for BV and ODV or OB formation, the BV titer and viral infectivity in insect larvae of ac73 knockout Ac MNPV decreased by about 5–8 and 3–4 fold compared to those of wild type virus,respectively, suggesting ac73 contributed to infectious BV production and viral infectivity in vivo. This research provides new insight into the function of this Group I specific gene.     

Phylogeny and evolution of Perezia （Asteraceae： Mutisieae： Nassauviinae）

A molecular phylogenetic analysis of most of the species of Perezia reveals that, as traditionally defined, the genus is not monophyletic with two species more closely related to Nassauvia than to Perezia. In addition, our results show that Burkartia （Perezia） lanigera is related to Acourtia and is the only member of that clade in South America. The remaining species are monophyletic and show a pattern of an early split between a western temperate and an eastern subtropical clade of species. Within the western clade, the phylogeny indicates a pattern of diversification that proceeded from southern, comparatively low-elevation habitats to southern high-elevation habitats, and ultimately into more northern high-elevation habitats. The most derived clades are found in the high central Andes, where significant radiation has occurred.     

RanBPM is an acetylcholinesterase-interacting protein that translocates into the nucleus during apoptosis

Acetylcholinesterase （ACHE） expression may be induced during apoptosis in various cell types. Here, we used the C-terminal of AChE to screen the human fetal brain library and found that it interacted with Ran-binding protein in the microtubule-organizing center （RanBPM）. This interaction was further confirmed by coimmunoprecipitation analysis. In HEK293T cells, RanBPM and AChE were heterogeneously expressed in the cisplatin-untreated cytoplasmic extracts and in the cisplatin-treated cytoplasmic or nuclear extracts. Our previous studies performed using morphologic methods have shown that AChE translocates from the cytoplasm to the nucleus during apoptosis. Taken together, these results suggest that RanBPM is an AChE-interacting protein that is translocated from the cytoplasm into the nucleus during apoptosis, similar to the translocation observed in case of ACHE.     

Understanding protein translocation across chloroplast membranes: Translocons and motor proteins

Subcellular organelles in eukaryotes are surrounded by lipid membranes.In an endomembrane system,vesicle trafficking is the primary mechanism for the delivery of organellar proteins to specific organelles.However,organellar proteins for chloroplasts,mitochondria,the nucleus,and peroxisomes that are translated in the cytosol are directly imported into their target organelles.Chloroplasts are a plant-specific organelle with outer and inner envelope membranes,a dual-membrane structure that is simil...     

Cloning and sequencing of nifBHDKENX genes of Paenibacillus massiliensis T7 and its nif promoter analysis

Biological nitrogen fixation, that is, reduction of atmospheric dinitrogen to ammonia, is catalyzed by a complex metalloenzyme called nitrogenase. Nitro-genase is composed of the iron protein (dinitrogenase reductase) encoded by the nifH gene, and the mol…     

Upward organelle motility

<正>Eukaryotic cells contain a collection of membrane-bounded organelles,in addition to the nucleus,supporting the large size and diverse activities of this type of cell.Evolving with these compartments are filaments and enzymes that convert chemical energy into work(so-called motor proteins),a network collectively termed the cytoskeleton.Whether it is a chloroplast moving to optimally intercept light or the     

A Key to Genome Maze in 3D

正How a genome with linear length over meters is compacted into the micrometer-sized nucleus of higher eukaryotic cells,and how this compaction affects and is affected by the genome functionalities have puzzled biologists for decades.There are mainly two classes of technologies that are dedicated to the probing of genome spatial organization.Image-based analyses of three-dimensional(3D)fluorescence in situ hybridization(FISH)[1]have been widely used in genome spatial research.     

Mitotic phosphorylation of PRC1 at Thr470 is required for PRC1 oligomerization and proper central spindle organization

During cell division, chromosome segregation is orchestrated by the interaction of spindle microtubules with thecentromere. A dramatic remodeling of interpolar microtubules into an organized central spindle between the separatingchromatids is required for the initiation and execution of cytokinesis. Central spindle organization requires mitotic kine-sins, the chromosomal passenger protein complex, and microtubule bundling protein PRC1. PRC1 is phosphorylated byCdc2 at Thr470 and Thr481 during mitosis. However, the functional relevance of PRC1 phosphorylation at Thr470 hasremained elusive. Here we show that expression of the non-phosphorylatable mutant PRC1~(T470A) but not the phospho-mimi-cking mutant PRC1~(T470E) causes aberrant organization of the central spindle. Immunoprecipitation experiment indicatesthat both PRC1~(T470A) and PRC1~(T470E) mutant proteins associate with wild-type PRC1, suggesting that phosphorylationof Thr470 does not alter PRC1 self-association. In addition, in vitro co-sedimentation experiment showed that PRC1binds to microtubule independent of the phosphorylation state of Thr470. Gel-filtration experiment suggested that phos-phorylation of Thr470 promotes oligomerization of PRC1. Given the fact that prevention of the Thr470 phosphorylationinhibits PRC1 oligomerization in vitro and causes an aberrant organization of central spindle in vivo, we propose thatthis phosphorylation-dependent PRC1 oligomerization ensures that central spindle assembly occurs at the appropriatetime in the cell cycle.     

Effect of Bcl—2 and caspase—3 on calcium distribution in apoptosis of HL—60 cells

Apoptosis manifests in two major execution programs downstream of the death signal:the caspase pathway and organelle dysfunction.An important antiapoptosis factor,Bcl-2 protein,contributes in caspase pathway of apoptosis.Calcium,an important intracellular signal element in cells,is also observed to have changes during apoptosis,which maybe affected by Bcl-2 protein.We have previously reported that in Harringtonine (HT) induced apoptosis of HL-60 cells,there‘s change of intracellular calcium distribution,oving from cytoplast especially Golgi‘s apparatus to nucleus and accumulating there with the highest concentration.We report here that caspase-3 becomes activated in HT-induced apoptosis of HL-60 cells,which can be inhibited by overexpression of Bcl-2 protein.No sign of apoptosis or intracellular calcium movement from Golgi‘s apparatus to nucleus in HL-60 cells overexpressing Bcl-2 or treated with Ac-DEVD-CHO,a specific inhibitor of caspase-3.The results indicate that activated caspase-2 can promote the movement of intracellular calcium from Golgi‘s apparatus to nucleus,and the process is inhibited by Ac-DEVD-CHO(inhibitor of caspase-3),and that Bcl-2 can inhibit the movement and accumulation of intracellular calcium in nucleus through its inhibition on caspase-3.Calcium relocalization in apoptosis seems to be irreversible,which is different from the intracellular calcium changes caused by growth factor.     

Multiple roles of PTEN isoforms PTENα and PTENβ in cellular activities and tumor development

<正>PTEN is a powerful tumor suppressor gene frequently mutated in human cancers and autism spectrum disorders.PTEN protein is located both in the cytoplasm and nucleus and can also be secreted from cells. The best characterized function of PTEN is its ability to dephosphorylate Ptd Ins(3,4,5)P3 and converts it back into PIP2 in the cytoplasm,therefore antagonizing the PI3K/AKT pathway which is mainly involved in regulation of cell growth, differentiation,     

Dynamic Actin Controls Polarity Induction de novo in Protoplasts

Cell polarity and axes are central for plant morphogenesis. To study how polarity and axes are induced de novo, we investigated protoplasts of tobacco Nicotiana tabacum cv. BY-2 expressing fluorescently-tagged cytoskeletal markers. We standardized the system to such a degree that we were able to generate quantitative data on the temporal patterns of regeneration stages. The synthesis of a new cell wall marks the transition to the first stage of regeneration, and proceeds after a long preparatory phase within a few minutes. During this preparatory phase, the nucleus migrates actively, and cytoplasmic strands remodel vigorously. We probed this system for the effect of anti-cytoskeletal compounds, inducible bundling of actin, RGD-peptides, and temperature. Suppression of actin dynamics at an early stage leads to aberrant tripolar cells, whereas suppression of microtubule dynamics produces aberrant sausage-like cells with asymmetric cell walls. We integrated these data into a model, where the microtubular cytoskeleton conveys positional information between the nucleus and the membrane controlling the release or activation of components required for cell wall synthesis. Cell wall formation is followed by the induction of a new cell pole requiring dynamic actin filaments, and the new cell axis is manifested as elongation growth perpendicular to the orientation of the aligned cortical microtubules.