Regulation of biosynthesis and intracellular localization of rice and tobacco homologues of nucleosome assembly protein 1

The nucleosome assembly protein 1 (NAP1) is considered to be a conserved histone chaperone, facilitating the assembly of nucleosomes in all eukaryotes. However, studies in yeast and animal cells also indicated that NAP1 proteins have diverse functions likely independent of nucleosome-assembly activity. Here, we describe the isolation and characterization of cDNAs encoding NAP1-like proteins from the monocotyledon rice ( Oryza sativa L.) and the dicotyledon tobacco ( Nicotiana tabacum L.). Northern-blot analysis demonstrated that the two rice NAP1-like genes are predominantly expressed in stem tissues such as root and shoot apical meristems as well as in young flowers. During the cell cycle, all four tobacco NAP1-like genes are highly expressed, with one of them showing a slightly increased expression at the G1/S transition. These results are consistent with a role for plant NAP1-like proteins in cell division. In vitro binding assays revealed that different NAP1-like proteins bind, with distinct relative binding strengths, to different classes of histone. Intracellular localization analyses showed that some NAP1-like proteins could be targeted into the nucleus whereas others are exclusively cytoplasm-localized. It is thus likely that different plant NAP1-like proteins have distinct functions in vivo. Plant NAP1-like proteins were observed to concentrate around the metaphase plate and in the phragmoplast, suggesting a role in mitotic events and cytokinesis.     

Interaction of nucleosome assembly proteins abolishes nuclear localization of DGKζ by attenuating its association with importins

Diacylglycerol kinase (DGK) is involved in the regulation of lipid-mediated signal transduction through the metabolism of a second messenger diacylglycerol. Of the DGK family, DGKζ, which contains a nuclear localization signal, localizes mainly to the nucleus but translocates to the cytoplasm under pathological conditions. However, the detailed mechanism of translocation and its functional significance remain unclear. To elucidate these issues, we used a proteomic approach to search for protein targets that interact with DGKζ. Results show that nucleosome assembly protein (NAP) 1-like 1 (NAP1L1) and NAP1-like 4 (NAP1L4) are identified as novel DGKζ binding partners. NAP1Ls constitutively shuttle between the nucleus and the cytoplasm in transfected HEK293 cells. The molecular interaction of DGKζ and NAP1Ls prohibits nuclear import of DGKζ because binding of NAP1Ls to DGKζ blocks import carrier proteins, Qip1 and NPI1, to interact with DGKζ, leading to cytoplasmic tethering of DGKζ. In addition, overexpression of NAP1Ls exerts a protective effect against doxorubicin-induced cytotoxicity. These findings suggest that NAP1Ls are involved in a novel molecular basis for the regulation of nucleocytoplasmic shuttling of DGKζ and provide a clue to examine functional significance of its translocation under pathological conditions.     

Distinct roles for histone chaperones in the deposition of Htz1 in chromatin

Histone variant Htz1 substitution for H2A plays important roles in diverse DNA transactions. Histone chaperones Chz1 and Nap1 (nucleosome assembly protein 1) are important for the deposition Htz1 into nucleosomes. In literatures, it was suggested that Chz1 is a Htz1–H2B-specific chaperone, and it is relatively unstructured in solution but it becomes structured in complex with the Htz1–H2B histone dimer. Nap1 (nucleosome assembly protein 1) can bind (H3–H4)₂ tetramers, H2A–H2B dimers and Htz1–H2B dimers. Nap1 can bind H2A–H2B dimer in the cytoplasm and shuttles the dimer into the nucleus. Moreover, Nap1 functions in nucleosome assembly by competitively interacting with non-nucleosomal histone–DNA. However, the exact roles of these chaperones in assembling Htz1-containing nucleosome remain largely unknown. In this paper, we revealed that Chz1 does not show a physical interaction with chromatin. In contrast, Nap1 binds exactly at the genomic DNA that contains Htz1. Nap1 and Htz1 show a preferential interaction with AG-rich DNA sequences. Deletion of chz1 results in a significantly decreased binding of Htz1 in chromatin, whereas deletion of nap1 dramatically increases the association of Htz1 with chromatin. Furthermore, genome-wide nucleosome-mapping analysis revealed that nucleosome occupancy for Htz1p-bound genes decreases upon deleting htz1 or chz1, suggesting that Htz1 is required for nucleosome structure at the specific genome loci. All together, these results define the distinct roles for histone chaperones Chz1 and Nap1 to regulate Htz1 incorporation into chromatin.     

Involvement of nucleocytoplasmic shuttling of yeast Nap1 in mitotic progression

Nucleosome assembly protein 1 (Nap1) is widely conserved from yeasts to humans and facilitates nucleosome formation in vitro as a histone chaperone. Nap1 is generally localized in the cytoplasm, except that subcellular localization of Drosophila melanogaster Nap1 is dynamically regulated between the cytoplasm and nucleus during early development. The cytoplasmic localization of Nap1 is seemingly incompatible with the proposed role of Nap1 in nucleosome formation, which should occur in the nucleus. Here, we have examined the roles of a putative nuclear export signal (NES) sequence in yeast Nap1 (yNap1). yNap1 mutants lacking the NES-like sequence were localized predominantly in the nucleus. Deletion of NAP1 in cells harboring a single mitotic cyclin gene is known to cause mitotic delay and temperature-sensitive growth. A wild-type NAP1 complemented these phenotypes while nap1 mutant genes lacking the NES-like sequence or carboxy-terminal region did not. These and other results suggest that yNap1 is a nucleocytoplasmic shuttling protein and that its shuttling is important for yNap1 function during mitotic progression. This study also provides a possible explanation for Nap1's involvement in nucleosome assembly and/or remodeling in the nucleus.     

新基因水稻 OsLSD1 的克隆及拟南芥和水稻类 LSD1 基因家族的生物信息学分析

类 LSD1 (LSD1-like) 基因家族是一类特殊的 C2C2 型锌指蛋白基因,编码植物特有的转录因子 . 目前已经研究的 2 个成员拟南芥 LSD1 (lesions stimulating disease resistance 1) 和 LOL1 (LSD-One-Like 1) 基因均参与植物细胞程序化死亡 (programmed cell death, PCD) 的调控 . 从水稻 cDNA 文库中克隆到 1 个类 LSD1 基因,命名为 OsLSD1. 该基因长 988 bp ,包含一个 432 bp 的开放阅读框,推导的氨基酸序列 (143 个氨基酸 ) 含有 3 个内部保守的锌指结构域 . DNA 印迹结果表明 OsLSD1 基因在水稻基因组中为单拷贝,且在根、茎和叶中表达 . 借助于生物信息学分析技术,从拟南芥和水稻数据库中各识别出 5 个和 7 个 ( 包括 OsLSD1) 类 LSD1 基因 . 分析了这些类 LSD1 基因的结构,蛋白质结构域组成 . 系统进化分析表明,无论基于编码区的核苷酸或氨基酸序列都可以将这些类 LSD1 基因分为 2 类 . 虽然不存在拟南芥或水稻特有的类 LSD1 蛋白,但有些结构域是水稻所特有的,也有些基因是来源于复制事件 .     

Cellular expression and localization of DGKζ-interacting NAP1-like proteins in the brain and functional implications under hypoxic stress

Diacylglycerol kinase (DGK) catalyzes conversion of a lipid second messenger diacylglycerol to another messenger molecule phosphatidic acid. Consequently, DGK plays a pivotal role in cellular pathophysiology by regulating the levels of these two messengers. We reported previously that DGKζ translocates from the nucleus to cytoplasm in hippocampal neurons under ischemic/hypoxic stress. In addition, we also identified nucleosome assembly protein 1 (NAP1)-like proteins NAP1L1 and NAP1L4 as novel DGKζ-interacting partners using a proteomic approach and revealed that these NAP1-like proteins induce cytoplasmic translocation of DGKζ in overexpressed cells because NAP1-like proteins associate with the nuclear localization signal of DGKζ and block its nuclear import via importin α. In the present study, we examined whether NAP1-like proteins are expressed in the brain and whether the molecular interaction of DGKζ and NAP1-like proteins would be changed in the brain after hypoxic stress. Immunohistochemistry revealed that NAP1L1 and NAP1L4 are widely expressed in neurons and glial cells in the brain with some differences. After 3 days of transient whole-body hypoxic stress, DGKζ translocated from the nucleus to cytoplasm in hippocampal pyramidal neurons, whereas NAP1-like proteins remained in the cytoplasm. Contrary to our expectations, NAP1-like proteins showed no change in their expression levels. The molecular interaction between DGKζ and NAP1-like proteins was attenuated after hypoxic stress. These results suggest that DGKζ cytoplasmic translocation in neurons under hypoxic stress is regulated by some mechanism which differs from that mediated by NAP1-like proteins.     

Structural evidence for Nap1‐dependent H2A–H2B deposition and nucleosome assembly

Nap1 is a histone chaperone involved in the nuclear import of H2A–H2B and nucleosome assembly. Here, we report the crystal structure of Nap1 bound to H2A–H2B together with in vitro and in vivo functional studies that elucidate the principles underlying Nap1‐mediated H2A–H2B chaperoning and nucleosome assembly. A Nap1 dimer provides an acidic binding surface and asymmetrically engages a single H2A–H2B heterodimer. Oligomerization of the Nap1–H2A–H2B complex results in burial of surfaces required for deposition of H2A–H2B into nucleosomes. Chromatin immunoprecipitation‐exonuclease (ChIP‐exo) analysis shows that Nap1 is required for H2A–H2B deposition across the genome. Mutants that interfere with Nap1 oligomerization exhibit severe nucleosome assembly defects showing that oligomerization is essential for the chaperone function. These findings establish the molecular basis for Nap1‐mediated H2A–H2B deposition and nucleosome assembly.     

Expression and functional analysis of musashi-like genes in planarian CNS regeneration

The remarkable regenerative ability of planarians is made possible by a system of pluripotent stem cells. Recent molecular biological and ultrastructural studies have revealed that planarian stem cells consist of heterogeneous populations, which can be classified into several subsets according to their differential expression of RNA binding protein genes. In this study, we focused on planarian musashi family genes. Musashi encodes an evolutionarily conserved RNA binding protein known to be expressed in neural lineage cells, including neural stem cells, in many animals. Here, we investigated whether planarian musashi-like genes can be used as markers for detecting neural fate-restricted cells. Three musashi family genes, DjmlgA, DjmlgB and DjmlgC (Dugesia japonica musashi-like gene A, B, C), and Djdmlg (Dugesia japonica DAZAP-like/musashi-like gene) were obtained by searching a planarian EST database and 5′ RACE, and each was found to have two RNA recognition motifs. We analyzed the types of cells expressing DjmlgA, DjmlgB, DjmlgC and Djdmlg by in situ hybridization, RT-PCR and single-cell RT-PCR analysis. Although Djdmlg was expressed in X-ray-sensitive stem cells and various types of differentiated cells, expression of the other three musashi-like genes was restricted to neural cells, as we expected. Further detailed analyses yielded the unexpected finding that these three planarian musashi family genes were predominantly expressed in X-ray-resistant differentiated neurons, but not in X-ray-sensitive stem cells. RNAi experiments suggested that these planarian musashi family genes might be involved in neural cell differentiation after neural cell-fate commitment.     

Nucleosome assembly proteins NAP1L1 and NAP1L4 modulate p53 acetylation to regulate cell fate

The p53 tumor suppressor regulates expression of genes involved in various stress responses. Upon genotoxic stress, p53 induces target genes regulating cell cycle arrest for survival or apoptosis. Nevertheless, detailed mechanisms of how p53 selectively regulates these opposing outcomes remain unclear. For this study, we investigated p53 regulatory mechanisms exerted by nucleosome assembly protein 1-like 1 (NAP1L1) and NAP1L4, both of which are identified as DGKζ-interacting proteins. Here we demonstrate that, under normal conditions, NAP1L1 knockdown decreases Lys320 acetylation of p53 with attenuated proarrest p21 expression, whereas NAP1L4 knockdown increases Lys320 acetylation with enhanced p21 expression. These conditions lead respectively to facilitation and suppression of cell growth. Under genotoxic stress conditions, NAP1L1 knockdown increases Lys382 acetylation with enhanced proapoptotic Bax levels, thereby facilitating cell death. By contrast, NAP1L4 knockdown decreases Lys382 acetylation with attenuated Bax levels, thereby suppressing apoptosis. These results suggest that NAP1L1 and NAP1L4 regulate cell fate by controlling the expression of p53-responsive proarrest and proapoptotic genes through selective modulation of p53 acetylation at specific sites during normal homeostasis and in stress-induced responses.     

A beta-hairpin comprising the nuclear localization sequence sustains the self-associated states of nucleosome assembly protein 1

The histone chaperone nucleosome assembly protein 1 (NAP1) is implicated in histone shuttling as well as nucleosome assembly and disassembly. Under physiological conditions, NAP1 dimers exist in a mixture of various high-molecular-weight oligomers whose size may be regulated by the cell cycle-dependent concentration of NAP1. Both the functional and structural significance of the observed oligomers are unknown. We have resolved the molecular mechanism by which yeast NAP1 (yNAP1) dimers oligomerize by applying x-ray crystallographic, hydrodynamic, and functional approaches. We found that an extended β-hairpin that protrudes from the compact core of the yNAP1 dimer forms a stable β-sheet with β-hairpins of neighboring yNAP1 dimers. Disruption of the β-hairpin (whose sequence is conserved among NAP1 proteins in various species) by the replacement of one or more amino acids with proline results in complete loss of yNAP1 dimer oligomerization. The in vitro functions of yNAP1 remain unaffected by the mutations. We have thus identified a conserved structural feature of NAP1 whose function, in addition to presenting the nuclear localization sequence, appears to be the formation of higher-order oligomers.     

Transcriptional cascade from Math1 to Mbh1 and Mbh2 is required for cerebellar granule cell differentiation

Cerebellar granule cells (CGCs) are the most abundant neuronal type in the mammalian brain, and their differentiation is regulated by the basic helix-loop-helix gene, Math1. However, little is known about downstream genes of Math1 and their functions in the cerebellum. To investigate them, we have here established an electroporation-based in vivo gene transfer method in the developing mouse cerebellum. Misexpression of Math1 ectopically induced expression of Bar-class homeobox genes, Mbh1 and Mbh2, which are expressed by CGCs. Conversely, their expression was repressed in CGCs by knockdown of Math1. These findings, taken together with chromatin immunoprecipitation assays, suggest that Math1 directly regulates the Mbh genes in CGCs. Furthermore, a dominant-negative form of the Mbh proteins disrupted proper formation of the external granule layer and differentiation of CGCs, whereas misexpression of the Mbh genes ectopically induced expression of a CGC marker in nonneuronal cells, indicating that the Mbh proteins are required for the differentiation of CGCs.     

Identification of Immunodominant B-cell Epitope Regions of Reticulocyte Binding Proteins in Plasmodium vivax by Protein Microarray Based Immunoscreening

Plasmodium falciparum can invade all stages of red blood cells, while Plasmodium vivax can invade only reticulocytes. Although many P. vivax proteins have been discovered, their functions are largely unknown. Among them, P. vivax reticulocyte binding proteins (PvRBP1 and PvRBP2) recognize and bind to reticulocytes. Both proteins possess a C-terminal hydrophobic transmembrane domain, which drives adhesion to reticulocytes. PvRBP1 and PvRBP2 are large (> 326 kDa), which hinders identification of the functional domains. In this study, the complete genome information of the P. vivax RBP family was thoroughly analyzed using a prediction server with bioinformatics data to predict B-cell epitope domains. Eleven pvrbp family genes that included 2 pseudogenes and 9 full or partial length genes were selected and used to express recombinant proteins in a wheat germ cell-free system. The expressed proteins were used to evaluate the humoral immune response with vivax malaria patients and healthy individual serum samples by protein microarray. The recombinant fragments of 9 PvRBP proteins were successfully expressed; the soluble proteins ranged in molecular weight from 16 to 34 kDa. Evaluation of the humoral immune response to each recombinant PvRBP protein indicated a high antigenicity, with 38-88% sensitivity and 100% specificity. Of them, N-terminal parts of PvRBP2c (PVX_090325-1) and PvRBP2 like partial A (PVX_090330-1) elicited high antigenicity. In addition, the PvRBP2-like homologue B (PVX_116930) fragment was newly identified as high antigenicity and may be exploited as a potential antigenic candidate among the PvRBP family. The functional activity of the PvRBP family on merozoite invasion remains unknown.     

Conservation of imprinting of MKRN3 and NAP1L5 in rabbits

Maternally imprinted genes of makorin ring finger protein 3 (MKRN3) and nucleosome assembly protein 1‐like 5 (NAP1L5) have been identified in many species but have not yet been investigated in rabbits. In this study, a polymorphism‐based approach and bisulfite‐sequencing PCR (BSP) were used to determine the imprinting status of MKRN3 and NAP1L5 in rabbits. The single nucleotide polymorphism (SNP)‐based sequencing results demonstrated that MKRN3 and NAP1L5 were expressed preferentially from the paternal allele. Furthermore, the BSP results showed the gamete‐specific methylation patterns and hemimethylation in brain and full methylation in liver were observed in MKRN3 and NAP1L5 respectively. Thus, we provide the first evidence that MKRN3 and NAP1L5 are paternally expressed genes and that the CpG islands located in the promoter region may be the putative differentially methylated region of these two genes in rabbits.     

TTLL10 is a protein polyglycylase that can modify nucleosome assembly protein 1

Certain proteins can undergo polyglycylation and polyglutamylation. Polyglutamylases (glutamate ligases) have recently been identified in a family of tubulin tyrosine ligase-like (TTLL) proteins. However, no polyglycylase (glycine ligase) has yet been reported. Here we identify a polyglycylase in the TTLL proteins by using an anti-poly-glycine antibody. The antibody reacted with a cytoplasmic 60-kDa protein that accumulated in elongating spermatids. Using tandem mass spectrometry of trypsinized samples, immunoprecipitated by the antibody from the TTLL10-expressing cells, we identified the 60-kDa protein as nucleosome assembly protein 1 (NAP1). Recombinant TTLL10 incorporated glycine into recombinant NAP1 in vitro. Mutational analyses indicated that Glu residues at 359 and 360 in the C-terminal part of NAP1 are putative sites for the modification. Thus, TTLL10 is a polyglycylase for NAP1.     

Death receptors and mitochondria: Two prime triggers of neural apoptosis and differentiation

Background

Stem cell therapy is a strategy far from being satisfactory and applied in the clinic. Poor survival and differentiation levels of stem cells after transplantation or neural injury have been major problems. Recently, it has been recognized that cell death-relevant proteins, notably those that operate in the core of the executioner apoptosis machinery are functionally involved in differentiation of a wide range of cell types, including neural cells.

Scope of review

This article will review recent studies on the mechanisms underlying the non-apoptotic function of mitochondrial and death receptor signaling pathways during neural differentiation. In addition, we will discuss how these major apoptosis-regulatory pathways control the decision between differentiation, self-renewal and cell death in neural stem cells and how levels of activity are restrained to prevent cell loss as final outcome.

Major conclusions

Emerging evidence suggests that, much like p53, caspases and Bcl-2 family members, the two prime triggers of cell death pathways, death receptors and mitochondria, may influence proliferation and differentiation potential of stem cells, neuronal plasticity, and astrocytic versus neuronal stem cell fate decision.

General significance

A better understanding of the molecular mechanisms underlying key checkpoints responsible for neural differentiation as an alternative to cell death will surely contribute to improve neuro-replacement strategies.