Ribosomal biosynthesis of α-amanitin in Galerina marginata

Amatoxins, including α-amanitin, are bicyclic octapeptides found in mushrooms (Agaricomycetes, Agaricales) of certain species in the genera Amanita, Galerina, Lepiota, and Conocybe. Amatoxins and the chemically similar phallotoxins are synthesized on ribosomes in Amanita bisporigera, Amanita phalloides, and Amanita ocreata. In order to determine if amatoxins are synthesized by a similar mechanism in another, distantly related mushroom, we obtained genome survey sequence data from a monokaryotic isolate of Galerinamarginata, which produces α-amanitin. The genome of G. marginata contains two copies of the α-amanitin gene (GmAMA1-1 and GmAMA1-2). The α-amanitin proprotein sequences of G. marginata (35 amino acids) are highly divergent from AMA1 of A. bisporigera except for the toxin region itself (IWGIGCNP in single-letter amino acid code) and the amino acids immediately upstream (N[A/S]TRLP). G. marginata does not contain any related toxin-encoding sequences besides GmAMA1-1 and GmAMA1-2. DNA from two other α-amanitin-producing isolates of Galerina (G. badipes and G. venenata) hybridized to GmAMA1, whereas DNA from the toxin non-producing species Galerinahybrida did not. Expression of the GmAMA1 genes was induced by growth on low carbon. RNASeq evidence indicates that both copies of GmAMA1 are expressed approximately equally. A prolyl oligopeptidase (POP) is strongly implicated in processing of the cyclic peptide toxins of A. bisporigera and Conocybe apala. G. marginata has two predicted POP genes; one, like AbPOPB of A. bisporigera, is present only in the toxin-producing isolates of Galerina and the other, like AbPOPA of A. bisporigera, is present in all species. Our results indicate that G.marginata biosynthesizes amatoxins on ribosomes by a pathway similar to Amanita species, involving a genetically encoded proprotein of 35 amino acids that is post-translationally processed by a POP. However, due to the high degree of divergence, the evolutionary relationship between AMA1 in the genera Amanita and Galerina is unclear.     

Amatoxins in wood-rotting Galerina marginata

Amatoxins, bicyclic octapeptide derivatives responsible for severe hepatic failure, are present in several Basidiomycota species belonging to four genera, i.e. Amanita, Conocybe, Galerina and Lepiota. DNA studies for G. autumnalis, G. marginata, G. oregonensis, G. unicolor and G. venenata (section Naucoriopsis) determined that these species are the same, supporting the concept of Galerina marginata complex. These mostly lignicolous species are designated as white-rot fungi having a broad host range and capable of degrading both hardwoods and softwoods. Twenty-seven G. marginata basidiomes taken from different sites and hosts (three sets) as well as 17 A. phalloides specimens (three sets) were collected in French locations. The 44 basidiomes were examined for amatoxins and phallotoxins using high-performance liquid chromatography. Toxinological data for the wood-rotting G. marginata and the ectomycorrhizal A. phalloides species were compared and statistically analyzed. The acidic and neutral phallotoxins were not detected in any G. marginata specimen, whereas the acidic (β-Ama) and neutral (α-Ama and γ-Ama) amanitins were found in all basidiomes from either Angiosperms or Gymnosperms hosts. The G. marginata amatoxin content varied from 78.17 to 243.61 μg.mg(-1) of fresh weight and was elevated significantly in one set out of three. The amanitin amounts from certain Galerina specimens were higher than those from some A. phalloides basidiomes. Relationship between the amanitin distribution and the chemical composition of substrate was underlined and statistically validated for the white-rot G. marginata. Changes in nutritional components from decayed host due to enzymatic systems and genetic factors as well as environmental conditions seem to play a determinant role in the amanitin profile. Variability noticed in the amanitin distribution for the white-rot G. marginata basidiomes was not observed for the ectomycorrhizal A. phalloides specimens.     

Facilitated Penetration of Amanitin—Albumin Conjugates into Hepatocytes after Coupling with Fluorescein

α-AMANITIN, a cyclic peptide of the toadstool Amanita phalloides^1,2, causes necrosis of liver and kidney cells, the first morphological lesions occurring in the nuclei^3,4. It acts by binding to RNA polymerase in eukaryotic .cells and inhibiting the enzyme^5–9. The hepatotoxicity of amanitin increases several times when it is conjugated to albumin, probably because of a slower rate of elimination of the toxin through the glomeruli^4,10. It is unlikely that the amanitin-albumin conjugate enters the hepatocyte by a mechanism involving its albumin moiety; it was therefore suggested¹¹ that penetration of the liver cells is consequent on binding of the amanitin group to the carrier involved in transport of this peptide. This led us to consider more generally the facilitation of penetration into cells by large molecules by means of binding to another molecule for which a carrier exists on the cell membrane^12,13.     

β-鹅膏毒肽的反相高效液相色谱分离纯化*

用反相高效液相色谱,以0.02mol/L醋酸铵-乙腈为流动相的梯度洗脱模式,在295nm吸收值的条件下,灰花纹鹅膏菌Amanitafuliginea的肽类毒素可以被成功的分离和纯化。单个肽类毒素的鉴定是用反相高效液相色谱和质谱同时进行。用这一方法可从灰花纹鹅膏菌中分离纯化出β-鹅膏毒肽(β-amanitin),产量可达到:1158靏/g(干重),产品纯度达98%以上,回收率为95.3%。β-鹅膏毒肽的分子量为919.3Da。这个方法可用于其它鹅膏菌肽类毒素的分离纯化。     

Processing of the Phalloidin Proprotein by Prolyl Oligopeptidase from the Mushroom Conocybe albipes

The peptide toxins of poisonous Amanita mushrooms are bicyclic octapeptides (amatoxins) or heptapeptides (phallotoxins). In Amanita bisporigera, α-amanitin and phallacidin are synthesized as 35- and 34-amino acid proproteins, respectively, in which the amino acid sequences found in the mature toxins are flanked by conserved amino acid sequences. The presence of invariant Pro residues immediately upstream of the toxin regions and as the last predicted amino acid in the toxin regions themselves suggests that a Pro-specific peptidase is responsible for the initial post-translational processing of the Amanita toxin proproteins. We purified an enzyme from the phalloidin-producing mushroom Conocybe albipes that cleaves a synthetic 22-mer phalloidin peptide to release the mature toxin peptide (AWLATCP). Mass spectrometric analysis of the purified protein combined with isolation and sequencing of the encoding gene indicates that the responsible processing enzyme is a member of the prolyl oligopeptidase (POP) subfamily of proteases (EC 3.4.21.26). The processing enzyme was able to use the chromogenic POP substrate benzyloxycarbonyl-Gly-Pro-p-nitroanilide and was inhibited by the specific POP inhibitor benzyloxycarbonyl-Pro-prolinal. Both Pro bonds in the proprotein are cleaved by the same enzyme, with the C-terminal Pro bond cleaved first or much faster than the N-terminal Pro bond. Transient accumulation of the N-terminal intermediate indicates that cleavage is not strongly processive. A synthetic peptide representing the phallacidin proprotein was also cleaved by the POP of C. albipes, but a precursor of amanitin (which is not made by C. albipes) was cleaved inefficiently.Deadly poisonous mushrooms in the genera Amanita, Galerina, Lepiota, and Conocybe synthesize the cyclic peptide amatoxins and phallotoxins (1–4). Structurally, amatoxins (e.g. α-amanitin) are bicyclic octapeptides, and phallotoxins (e.g. phalloidin and phallacidin) are chemically related bicyclic heptapeptides. Both are hydroxylated and contain a Trp-Cys cross-bridge (tryptathionine), which has not been found in other natural products (5). Phallotoxins also contain one d amino acid (d-hydroxy-Asp or d-Thr). Despite their chemical similarity, amatoxins and phallotoxins have different modes of action; amatoxins are specific inhibitors of RNA polymerase II, and phallotoxins bind and stabilize F-actin (6, 7).Unlike other known cyclic peptides from fungi, the amatoxins and phallotoxins are biosynthesized on ribosomes instead of nonribosomal peptide synthetases (8). In A. bisporigera, the genes for α-amanitin and phallacidin are translated as 35 and 34-amino acid proproteins, respectively (8). Although α-amanitin and phallacidin have only three amino acids in common, the upstream and downstream sequences of the proproteins are highly similar. Furthermore, the genome of A. bisporigera contains at least another 20 related sequences which collectively are characterized by conserved sequences flanking a hypervariable “toxin” region of 7–10 amino acids (8) (Fig. 1B). We refer to this family of genes as the MSDIN family for the first five highly conserved amino acids of the proproteins. Apparently, these poisonous mushrooms have evolved a mechanism of combinatorial peptide biosynthesis that uses the same biochemical template to synthesize a wide range of small, cyclic peptides.Open in a separate windowFIGURE 1.A, The sequence of the phalloidin proprotein of A. phalloides (8). The amino acids of the mature toxin are underlined. The two cleaved Pro residues are shown in bold text. B, WebLogo (41) representation of 14 predicted MSDIN sequences from Amanita species (A. bisporigera, A. phalloides, or A. ocreata). C, C. albipes growing in cultivated lawn on the Michigan State University campus, June, 2008. In A, a 3-amino acid gap has been introduced before the C-terminal Pro because the toxin regions of some of the MSDIN sequences in the WebLogo alignment have 10 amino acids, whereas phalloidin has only 7. Also, the sequence of the phalloidin proprotein in A has been truncated from its actual 34 amino acids to 31 amino acids to facilitate its alignment with the sequences shown in B. This is because only genomic sequences are available for most of the MSDIN sequences shown in B, and based on cDNAs for AMA1 and PHA1, the other MSDIN sequences probably have an intron interrupting the antepenultimate codon. The sequences in B are GenBank^TM accession numbers {"type":"entrez-nucleotide","attrs":{"text":"EU196139","term_id":"194303446","term_text":"EU196139"}}EU196139–{"type":"entrez-nucleotide","attrs":{"text":"EU196155","term_id":"159033025","term_text":"EU196155"}}EU196155. The length of the toxin region between the N-terminal invariant Pro and including the C-terminal invariant Pro varies from 7 to 10 amino acids in different members of the MSDIN family. One, two, or three X''s were placed within the toxin region before the C-terminal conserved Pro residue in B for toxin peptides of nine, eight, or seven amino acids, respectively.Among the conserved amino acids in the MSDIN gene family are two invariant Pro residues flanking the hypervariable region (Fig. 1B). All known amatoxins and phallotoxins contain one Pro, and A. phalloides is also known to make other cyclic peptides (of 6–10 amino acids), all of which contain at least one Pro residue (4). Post-translational processing of the MSDIN proproteins is predicted to involve cleavage at these Pro residues, resulting in one Pro remaining in the toxin and the other being removed (Fig. 1B).The goal of the present work was to identify the enzyme that cleaves the MSDIN proproteins to release the peptides of the mature toxins. To identify the responsible peptidase, it was necessary to find a practical starting material. Most toxin-producing fungi in the genus Amanita are obligately ectomycorrhizal with their host plants, and they grow very slowly and do not produce toxins in culture. Galerina marginata produces toxins in culture but grows slowly (9). Some species of the mushroom genus Conocybe produce phallotoxins or amatoxins (1, 3). Conocybe species are abundant locally at certain seasons. In particular, Conocybe albipes (Fig. 1C), which produces the phallotoxin phalloidin, grows on lawns in the Midwest United States, and in the spring it is possible to collect large (>1 kg) quantities (10). For these reasons we chose C. albipes as a starting material for identification of the enzyme that processes the toxin proproteins. Here we report the purification of the enzyme that releases the mature heptapeptide from a phallotoxin precursor and show that it is a member of the prolyl oligopeptidase (POP)² subfamily of serine proteases.     

Analysis of CMF1 reveals a bone morphogenetic protein-independent component of the cardiomyogenic pathway

Disruption of the CMF1 function in anterior mesoderm inhibits cardiac myogenesis in avian embryos. In the present study, we show that CMF1 is a member of an emerging family of proteins that includes centromeric protein-F, mitosin, and LEK1. These proteins are characterized by their large size (350 kDa), dynamic subcellular distribution, and potential functions in cell division and differentiation. The current data suggest that CMF1 is a unique member of this family by virtue of its restricted protein expression and variant subcellular distribution. Immunochemical analysis demonstrates that CMF1 protein is expressed in cardiogenic cells prior to the activation of cardiac structural gene products. In addition, we show that expression of CMF1 is not dependent on the bone morphogenetic protein (BMP) signaling pathway during development. Still, CMF1 cannot direct cardiomyogenesis in the absence of such factors as NKX-2.5. Taken with our previous data, this study suggests that CMF1 is a BMP-independent component of the cardiomyogenic pathway.     

Subcellular localization and activity of multidrug resistance proteins

The multidrug resistance (MDR) phenotype is associated with the overexpression of members of the ATP-binding cassette family of proteins. These MDR transporters are expressed at the plasma membrane, where they are thought to reduce the cellular accumulation of toxins over time. Our data demonstrate that members of this family are also expressed in subcellular compartments where they actively sequester drugs away from their cellular targets. The multidrug resistance protein 1 (MRP1), P-glycoprotein, and the breast cancer resistance protein are each present in a perinuclear region positive for lysosomal markers. Fluorescence-activated cell sorting analysis suggests that these three drug transporters do little to reduce the cellular accumulation of the anthracycline doxorubicin. However, whereas doxorubicin enters cells expressing MDR transporters, this drug is sequestered away from the nucleus, its subcellular target, in vesicles expressing each of the three drug resistance proteins. Using a cell-impermeable inhibitor of MRP1 activity, we demonstrate that MRP1 activity on intracellular vesicles is sufficient to confer a drug resistance phenotype, whereas disruption of lysosomal pH is not. Intracellular localization and activity for MRP1 and other members of the MDR transporter family may suggest different strategies for chemotherapeutic regimens in a clinical setting.     

Energy-dependent accumulation of daunorubicin into subcellular compartments of human leukemia cells and cytoplasts.

Anthracycline accumulation was evaluated by flow cytometry or radiolabeled drug assays in cells and cytoplasts (enucleated cells) prepared from parental and multidrug-resistant human K562 leukemia cells. Treatment with energy inhibitors, such as dinitrophenol (DNP) or sodium azide/deoxyglucose, led to a marked decrease in daunorubicin accumulation in parental cells and cytoplasts. Another ionophore, monensin, also caused a significant decrease in daunorubicin accumulation; however, ATPase inhibitors ouabain, vanadate, and N-ethylamaleimide had little or no effect. The lysosomatropic agents chloroquine and methylamine caused a moderate decrease in anthracycline accumulation. Fluorescence microscopy showed that the DNP-sensitive daunorubicin uptake occurred in a nonnuclear subcellular compartment. Studies using increasing daunorubicin concentrations demonstrated fluorescence quenching that occurred in the nonnuclear, DNP-sensitive compartment. The effect of inhibitors on the accumulation of rhodamine 123 and acridine orange strongly implicated lysosomes as the principal compartment of this inhibitable daunorubicin accumulation. Cytoplasts from P-glycoprotein containing multidrug-resistant K562 cells demonstrated a verapamil-reversible, decreased daunorubicin accumulation that was observed in resistant whole cells. Verapamil pretreatment of cytoplasts from resistant cells revealed the subcellular DNP-sensitive uptake present in parental cytoplasts. These studies demonstrate that cytoplasts are an effective means to study drug transport in mammalian cells without nuclear drug binding. Parental K562 cells and cytoplasts exhibit an energy-dependent accumulation of daunorubicin into cytoplasmic organelles that is also present in resistant cells and cytoplasts when P-glycoprotein mediated efflux is inhibited.     

a-鹅膏毒肽和二羟鬼笔毒肽的制备和鉴定(英文)

-鹅膏毒(环)肽和二羟鬼笔毒(环)肽是剧毒的鹅膏菌和其它几种致死毒菌中由一些修饰氨基酸组成的环肽毒素。由于-鹅膏毒肽对真核生物的mRNA合成的专一性抑制和和二羟鬼笔毒肽对肌动蛋白的专一性束缚,因而它们在分子生物学和细胞学研究中具有重要应用,对其需求逐步增加。为此,作者使用了一种改良的毒素提取方法,以制备高效液相色谱从灰花纹鹅膏菌中分离制备-鹅膏毒肽和二羟鬼笔毒肽,并通过紫外吸收光谱和质谱进行鉴定,表明-鹅膏毒肽和二羟鬼笔毒肽的分离效果好,纯度高。本方法对其它毒菌中的-鹅膏毒肽和二羟鬼笔毒肽的分离制备具有同样的应用价值。     

我国28种鹅膏菌主要肽类毒素的检测分析*

利用高效液相色谱(HPLC)技术对产于我国的28种鹅膏菌的主要肽类毒素(鹅膏毒肽和鬼笔毒肽)进行了检测分析,并和采于欧洲(德国)的毒鹅膏Amanita phalloides作对照,结果表明,3种东亚所特有的鹅膏菌(灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种)和欧洲毒鹅膏所含毒素种类多、含量高,其子实体菌盖部位主要毒素总量分别达到12583.7μg/g、8152.6μg/g、1058.2μg/g、7456.2μg/g干重子实体,这4种鹅膏菌可称之为剧毒鹅膏菌。其它25种鹅膏菌中有10种检测出含有微量鹅膏毒肽,含量在19.5μg/g-151.2μg/g之间。在4种剧毒鹅膏菌中,子实体组织部位不同,毒素含量以及鹅膏毒肽和鬼笔毒肽在其中的分布也不一样,菌盖中的毒素含量最高,菌柄的毒素含量次之,菌托中的毒素含量最低;对于灰花纹鹅膏、致命鹅膏和黄盖鹅膏白色变种,无论在菌盖、菌柄和菌托中,鹅膏毒肽类毒素的含量都高于鬼笔毒肽类毒素,尤其以α-amanitin的相对含量最高;而在欧洲毒鹅膏中,菌盖、菌柄和菌托中都以鬼笔毒肽为主,尤其以phallacidin的相对含量最高,并且从菌盖至菌柄到菌托,鬼笔毒肽的相对含量依次增加。     

Characterization and functional identification of a novel plant 4,5-extradiol dioxygenase involved in betalain pigment biosynthesis in Portulaca grandiflora

Betalains are pigments that replace anthocyanins in the majority of families of the plant order Caryophyllales. Betalamic acid is the common chromophore of betalains. The key enzyme of the betalain biosynthetic pathway is an extradiol dioxygenase that opens the cyclic ring of dihydroxy-phenylalanine (DOPA) between carbons 4 and 5, thus producing an unstable seco-DOPA that rearranges nonenzymatically to betalamic acid. A gene for a 4,5-DOPA-dioxygenase has already been isolated from the fungus Amanita muscaria, but no homolog was ever found in plants. To identify the plant gene, we constructed subtractive libraries between different colored phenotypes of isogenic lines of Portulaca grandiflora (Portulacaceae) and between different stages of flower bud formation. Using in silico analysis of differentially expressed cDNAs, we identified a candidate showing strong homology at the level of translated protein with the LigB domain present in several bacterial extradiol 4,5-dioxygenases. The gene was expressed only in colored flower petals. The function of this gene in the betalain biosynthetic pathway was confirmed by biolistic genetic complementation in white petals of P. grandiflora genotypes lacking the gene for color formation. This gene named DODA is the first characterized member of a novel family of plant dioxygenases phylogenetically distinct from Amanita sp. DOPA-dioxygenase. Homologs of DODA are present not only in betalain-producing plants but also, albeit with some changes near the catalytic site, in other angiosperms and in the bryophyte Physcomitrella patens. These homologs are part of a novel conserved plant gene family probably involved in aromatic compound metabolism.     

Three-Dimensional Ultrastructural Study of Oil and Astaxanthin Accumulation during Encystment in the Green Alga Haematococcus pluvialis

Haematococcus pluvialis is a freshwater species of green algae and is well known for its accumulation of the strong antioxidant astaxanthin, which is used in aquaculture, various pharmaceuticals, and cosmetics. High levels of astaxanthin are present in cysts, which rapidly accumulate when the environmental conditions become unfavorable for normal cell growth. It is not understood, however, how accumulation of high levels of astaxanthin, which is soluble in oil, becomes possible during encystment. Here, we performed ultrastructural 3D reconstruction based on over 350 serial sections per cell to visualize the dynamics of astaxanthin accumulation and subcellular changes during the encystment of H. pluvialis. This study showcases the marked changes in subcellular elements, such as chloroplast degeneration, in the transition from green coccoid cells to red cyst cells during encystment. In green coccoid cells, chloroplasts accounted for 41.7% of the total cell volume, whereas the relative volume of astaxanthin was very low (0.2%). In contrast, oil droplets containing astaxanthin predominated in cyst cells (52.2%), in which the total chloroplast volume was markedly decreased (9.7%). Volumetric observations also demonstrated that the relative volumes of the cell wall, starch grains, pyrenoids, mitochondria, the Golgi apparatus, and the nucleus in a cyst cell are smaller than those in green coccid cells. Our data indicated that chloroplasts are degraded, resulting in a net-like morphology, but do not completely disappear, even at the red cyst stage.     

Saccharomyces cerevisiae Npc2p is a functionally conserved homologue of the human Niemann-Pick disease type C 2 protein, hNPC2

Niemann-Pick Disease Type C (NP-C) is a fatal neurodegenerative disease, which is biochemically distinguished by the lysosomal accumulation of exogenously derived cholesterol. Mutation of either the hNPC1 or hNPC2 gene is causative for NP-C. We report the identification of the yeast homologue of human NPC2, Saccharomyces cerevisiae Npc2p. We demonstrate that scNpc2p is evolutionarily related to the mammalian NPC2 family of proteins. We also show, through colocalization, subcellular fractionation, and secretion analyses, that yeast Npc2p is treated similarly to human NPC2 when expressed in mammalian cells. Importantly, we show that yeast Npc2p can efficiently revert the unesterified cholesterol and GM1 accumulation seen in hNPC2-/- patient fibroblasts demonstrating that it is a functional homologue of human NPC2. The present study reveals that the fundamental process of NPC2-mediated lipid transport has been maintained throughout evolution.     

广东已知毒蘑菇种类

广东毒蘑菇种类有112种,分别隶属于子囊菌门(Ascomycota)的1科1属和担子菌门(Basidiomycota)的18科41属。其中种类最多的是鹅膏属(Amanita),有20种,占17.8%;其次为红菇属(Russula),有10种,占8.9%;第3是丝盖伞属(Inocybe),有8种,占7.1%。致命鹅膏(Amanitaexitialis)、铅绿褶菇(Chlorophyllum molybdites)和粗柄白鬼伞(Leucocoprinuscepaestipe)等是近几年在广州引起中毒的常见毒蘑菇种类,其中致命鹅膏的中毒死亡率最高。     

Localization and functional interrelationships among cytosolic Group IV, secreted Group V, and Ca2+-independent Group VI phospholipase A2s in P388D1 macrophages using GFP/RFP constructs

P388D(1) cells exposed to bacterial lipopolysaccharide (LPS) mobilize arachidonic acid (AA) for prostaglandin synthesis in two temporally distinct pathways. The "immediate pathway" is triggered within minutes by receptor agonists such as platelet-activating factor (PAF) but only if the cells have previously been primed with LPS for 1 h. The "delayed pathway" occurs in response to LPS alone over the course of several hours. We have now investigated the subcellular localization of both the Group IV cytosolic phospholipase A(2) (cPLA(2)) and the Group V secreted PLA(2) (sPLA(2)) during these two temporally distinct routes of AA release. We have prepared cells overexpressing fusion proteins of sPLA(2)-GFP and cPLA(2)-RFP. In the resting cells, cPLA(2)-RFP was uniformly located throughout the cytoplasm, and short-term treatment with LPS did not induce translocation to perinuclear and/or Golgi membranes. However, such a translocation occurred almost immediately after the addition of PAF to the cells. Long-term exposure of the cells to LPS led to the translocation of cPLA(2)-RFP to intracellular membranes after 3 h, and correlates with a significant release of AA in a cPLA(2)-dependent manner. At the same time period that the delayed association of cPLA(2) with perinuclear membranes is detected, an intense fluorescence arising from the sPLA(2)-GFP was found around the nucleus in the sPLA(2)-GFP stably transfected cells. In parallel with these changes, significant AA release was detected from the sPLA(2)-GFP transfectants in a cPLA(2)-dependent manner, which may reflect cross-talk between sPLA(2) and cPLA(2). The subcellular localization of the Group VIA Ca(2+)-independent PLA(2) (iPLA(2)) was also investigated. Cells overexpressing iPLA(2)-GFP showed no fluorescence changes under any activation condition. However, the iPLA(2)-GFP-expressing cells showed relatively high basal AA release, confirming a role for iPLA(2) in basal deacylation reactions. These new data illustrate the subcellular localization changes that accompany the distinct roles that each of the three kinds of PLA(2) present in P388D(1) macrophages play in AA mobilization.     

Subcellular distribution of human RDM1 protein isoforms and their nucleolar accumulation in response to heat shock and proteotoxic stress

The RDM1 gene encodes a RNA recognition motif (RRM)-containing protein involved in the cellular response to the anti-cancer drug cisplatin in vertebrates. We previously reported a cDNA encoding the full-length human RDM1 protein. Here, we describe the identification of 11 human cDNAs encoding RDM1 protein isoforms. This repertoire is generated by alternative pre-mRNA splicing and differential usage of two translational start sites, resulting in proteins with long or short N-terminus and a great diversity in the exonic composition of their C-terminus. By using tagged proteins and fluorescent microscopy, we examined the subcellular distribution of full-length RDM1 (renamed RDM1alpha), and other RDM1 isoforms. We show that RDM1alpha undergoes subcellular redistribution and nucleolar accumulation in response to proteotoxic stress and mild heat shock. In unstressed cells, the long N-terminal isoforms displayed distinct subcellular distribution patterns, ranging from a predominantly cytoplasmic to almost exclusive nuclear localization, suggesting functional differences among the RDM1 proteins. However, all isoforms underwent stress-induced nucleolar accumulation. We identified nuclear and nucleolar localization determinants as well as domains conferring cytoplasmic retention to the RDM1 proteins. Finally, RDM1 null chicken DT40 cells displayed an increased sensitivity to heat shock, compared to wild-type (wt) cells, suggesting a function for RDM1 in the heat-shock response.