Formation of Hirano Bodies after Inducible Expression of a Modified Form of an Actin-Cross-Linking Protein

Hirano bodies are cytoplasmic inclusions composed mainly of actin and actin-associated proteins. The formation of Hirano bodies during various neurodegenerative disorders, including Alzheimer''s disease and amyotrophic lateral sclerosis, has been reported. Although the underlying molecular mechanisms that lead to the formation of these inclusions in the brain are not known, expression of the C-terminal fragment (CT) (amino acids 124 to 295) from the endogenous 34-kDa actin-binding protein of Dictyostelium discoideum leads to the formation of actin inclusions in vivo. In the current study, we report the development of an inducible expression system to study the early phases of Hirano body formation using an inducible promoter system (rnrB). By fusing the CT to a green fluorescent protein (CT-GFP), we monitored protein expression and localization by fluorescence microscopy, flow cytometry, and Western blot analysis. We observed an increase in the number and size of inclusions formed following induction of the CT-GFP vector system. Time-lapse microscopy studies revealed that the CT-GFP foci associated with the cell cortex and fused to form a single large aggregate. Transmission electron microscopy further demonstrates that these inclusions have a highly ordered ultrastructure, a pathological hallmark of Hirano bodies observed in postmortem brain samples from patients with various neurodegenerative disorders. Collectively, this system provides a method to visualize and characterize the events that surround early actin inclusion formation in a eukaryotic model.Neurodegenerative diseases are characterized pathologically by the formation of protein deposits localized to specific regions of the brain. Notably, protein aggregates derived from the amyloid precursor protein, the microtubule-associated protein tau, and α-synuclein have received much attention. However, the intracellular aggregations of actin and actin-binding proteins known as Hirano bodies are less well known. Hirano bodies were first identified in brains affected by Pick''s disease and amyotrophic lateral sclerosis (8, 17). Subsequent studies identified these aggregates in a number of neurodegenerative diseases and other conditions that cause persistent brain injury (7). Although it is clear from this and other observations that the main constituents of Hirano bodies are actin and actin-binding proteins which assemble to form a characteristic ultrastructure (3), little is known about the mechanisms that underlie Hirano body formation. To further understand the spatial and temporal events that surround the formation of these inclusions in vivo, a live cell model that mimics the formation of these structures is necessary. The discovery that Dictyostelium discoideum cells expressing a carboxy-terminal fragment (CT) of the 34-kDa calcium-sensitive actin-binding protein (ABP34) form Hirano bodies in vivo (1, 12, 13) provides a tantalizing clue to a possible mechanism of protein aggregation.Using Dictyostelium as a live cell model system provides the opportunity to control protein expression levels. In this study, we report the expression of the CT fused to green fluorescent protein (GFP) under the control of a constitutive (actin 15) and an inducible ribonucleotide reductase (rnrB) promoter using the DXA-GFP2 and RNR plasmid vectors, respectively (4, 10, 11). Using this system, we demonstrate that a fusion between the CT and the GFP tag (CT-GFP) provides a unique stable probe to observe CT dynamics in living cells. Expression of the CT-GFP fusion from the inducible RNR system triggered the formation of small protein inclusions visible by fluorescence microscopy at basal expression levels. Following promoter induction, there was a robust increase in the size and number of protein aggregates formed. Over time, the number of total inclusions decreased, but the average size of the remaining aggregates was larger. Our observations of live cells expressing CT-GFP show a pattern of aggregate formation where small aggregates combined to form larger inclusions. These inclusions were usually found at the rear of moving Dictyostelium cells.     

Methionine Requirements of Rats in Various Body Weights

A niaD gene encoding nitrate reductase was isolated from Aspergillus oryzae KBN616 and sequenced. The structural gene comprises 2973 bp and 868 amino acids, which showed a high degree of similarity to nitrate reductases from other filamentous fungi. The coding sequence is interrupted by six introns varying in size from 48 to 98 bp. The intron positions are all conserved among the niaD genes from A. oryzae, Aspergillus nidulans, and Aspergillus niger. A homologous transformation system was developed for an industrial shoyu koji mold, A. oryzae KBN616, based on the nitrate reductase (niaD) of the nitrate assimilation pathway.     

Lysine Requirements of Rats of Various Body Weights

The lysine requirements of rats of various body weights were estimated using the feeding and isotope tests.

The regression equation obtained by the feeding test was Y= 1.03 – 0.58 log X. Where Y is lysine percentage of the diet and X is the mean of initial and final body weights (g) of rats achieving optimal growth gains during the feeding period.

The regression equation obtained by the isotope test was 7=0.90 – 0.49 log X, where Y and X are lysine percentage in the diet and body weights (g) of rats achieving optimal growth gains at the injection time respectively.     

Methionine Requirements of Chickens with Various Body Weights

Methionine requirements of male White Leghorn chickens were estimated at 5 stages of growth by growth and the recovery of ¹⁴C in respiratory carbon dioxide. The methionine requirement for maximum daily gain decreased with increasing age according to the equation; log Y=?0.000243 ×? 3.22, where Y and X represent the methionine requirement as percentage of the diet and g of average body weight of the chickens during the experimental periods that achieved maximum daily gain. The recovery percentage of ¹⁴C derived from methionine-1-¹⁴C remained low, and then increased rapidly. The methionine requirement found from the recovery of ¹⁴C also decreased with increasing dietary methionine levels according to the equation; log Y=?0.000216 ×? 3.02, where Y and X represent the methionine requirement as percentages of the diet and g of body weights of chickens at the beginning of the recovery test for ¹⁴C. Dietary cystine spared the methionine requirement for growth, but did not affect the recovery of ¹⁴C in the respiratory carbon dioxide.     

Formation of Hirano bodies induced by expression of an actin cross-linking protein with a gain-of-function mutation

Hirano bodies are paracrystalline actin filament-containing structures reported to be associated with a variety of neurodegenerative diseases. However, the biological function of Hirano bodies remains poorly understood, since nearly all prior studies of these structures were done with postmortem samples of tissue. In the present study, we generated a full-length form of a Dictyostelium 34-kDa actin cross-linking protein with point mutations in the first putative EF hand, termed 34-kDa ΔEF1. The 34-kDa ΔEF1 protein binds calcium normally but has activated actin binding that is unregulated by calcium. The expression of the 34-kDa ΔEF1 protein in Dictyostelium induces the formation of Hirano bodies, as assessed by both fluorescence microscopy and transmission electron microscopy. Dictyostelium cells bearing Hirano bodies grow normally, indicating that Hirano bodies are not associated with cell death and are not deleterious to cell growth. Moreover, the expression of the 34-kDa ΔEF1 protein rescues the phenotypes of cells lacking the 34-kDa protein and cells lacking both the 34-kDa protein and α-actinin. Finally, the expression of the 34-kDa ΔEF1 protein also initiates the formation of Hirano bodies in cultured mouse fibroblasts. These results show that the failure to regulate the activity and/or affinity of an actin cross-linking protein can provide a signal for the formation of Hirano bodies. More generally, the formation of Hirano bodies is a cellular response to or a consequence of aberrant function of the actin cytoskeleton.     

Hirano bodies in health and disease

Recent findings shed light on the physiological function of enigmatic structures called Hirano bodies, which were first described more than 30 years ago.     

Isoprenoids Are Essential for Fruiting Body Formation in Myxococcus xanthus

It was recently shown that Myxococcus xanthus harbors an alternative and reversible biosynthetic pathway to isovaleryl coenzyme A (CoA) branching from 3-hydroxy-3-methylglutaryl-CoA. Analyses of various mutants in these pathways for fatty acid profiles and fruiting body formation revealed for the first time the importance of isoprenoids for myxobacterial development.Myxobacteria are unique among the prokaryotes as (i) they can form highly complex fruiting bodies under starvation conditions, even up to microscopic tree-like structures (28); (ii) they can move on solid surfaces using different motility mechanisms (16); (iii) they produce some of the most cytotoxic secondary metabolites, with epothilone already in clinical use against cancer (2, 3); and (iv) they harbor the largest prokaryotic genomes found so far (15, 27). The large genome might be directly related to their complex life-style and the diverse secondary (3) and primary (9) metabolisms. Already in 2002 we found that myxobacteria are able to produce isovaleryl coenzyme A (IV-CoA) and compounds derived thereof via a new pathway that branches from 3-hydroxy-3-methylglutaryl-CoA (HMG-CoA), which is the central intermediate of the well-known mevalonate-dependent isoprenoid biosynthesis (Fig. ​(Fig.1)1) (22, 23). Usually IV-CoA is derived from leucine degradation via the branched-chain keto acid dehydrogenase (BKD) complex (24), which is also the preferred pathway to IV-CoA in the myxobacteria Myxococcus xanthus and Stigmatella aurantiaca (Fig. ​(Fig.2A).2A). However, in bkd mutants, where no or only residual leucine degradation is possible (30), the alternative pathway is induced (Fig. ​(Fig.2B),2B), presumably to ensure the production of iso-fatty acids (iso-FAs) (5). A possible reason for this alternative pathway is the importance of IV-CoA-derived compounds in the complex myxobacterial life cycle, which is the starvation-induced formation of fruiting bodies in which the cells differentiate into myxospores. We showed that this pathway is induced during fruiting body formation in M. xanthus when leucine is limited. Under these conditions, this pathway might be more important for protein synthesis than for lipid remodeling, as lipids are present in excess during development due to the surface reduction from vegetative rods to round myxospores as described previously (29). Examples of IV-CoA-derived compounds are the unusual iso-branched ether lipids, which are almost exclusively produced in the developing myxospores. They might serve as structural lipids and signaling compounds during fruiting body formation (26).Open in a separate windowFIG. 1.Biosynthesis of IV-CoA and compounds derived thereof and biosynthesis of isoprenoids in M. xanthus. Broken arrows indicate multistep reactions; supplementation (double-lined arrows) with MVL and IVA can be used to complement selected mutants.Open in a separate windowFIG. 2.Short representations of proposed metabolic fluxes through the IV-CoA/isoprenoid network. Broken arrows indicate no metabolic flux. (A) DK1622 (wild type); (B) DK5643 (Δbkd); (C) DK5624 (Δbkd mvaS::kan); (D) HB002 (Δbkd liuC::kan); (E) HB002 with 1 mM IVA; (F) HB002 with 1 mM MVL. Ac-CoA, acetyl-CoA; MVA, mevalonic acid.In M. xanthus, we could recently identify candidate genes involved in the alternative pathway from HMG-CoA to IV-CoA. We also described the genes required for the degradation pathway of leucine and subsequently also those involved in the transformation of IV-CoA to HMG-CoA (4). In myxobacteria leucine is an important precursor for isoprenoid biosynthesis, as was already shown elsewhere for the biosynthesis of steroids (7) and prenylated secondary metabolites like aurachin (22) or leupyrrins (6), as well as volatiles like geosmin or germacradienol in M. xanthus and S. aurantiaca (11, 13). The interconnection of iso-FAs and isoprenoid biosynthesis made it difficult to assign functions to these compound classes during fruiting body formation in M. xanthus because it cannot be excluded that reduced leucine degradation also impairs isoprenoid biosynthesis. A mutant strain of M. xanthus that was blocked in the degradation of leucine and the alternative pathway had a deletion in the bkd locus as well as a plasmid insertion in the mvaS gene encoding the HMG-CoA synthase (strain DK5624). This double mutation severely affected isoprenoid biosynthesis (5), and cultures of DK5624 must be supplemented with mevalonolactone (MVL; the cyclized form of mevalonic acid) in order to enable growth (Fig. ​(Fig.2C).2C). Since we have identified the genes involved in IV-CoA biosynthesis and the mevalonate pathway (4), we can now start to identify differences between strains that show deficiencies in iso-FAs and strains that show deficiencies in isoprenoids via simple analysis of the FA profile and analysis of the myxobacterial development of selected mutants.All mutants used in this study (HB002 [Δbkd liuC::kan], HB015 [Δbkd MXAN_4265::kan], DK5624 [Δbkd mvaS::kan], HB019 [Δbkd mvaS::kan mvaS⁺], and HB020 [Δbkd MXAN_4265::kan mvaS⁺]) have been published previously (4), and FA analysis as well as myxobacterial fruiting body formation has also been described previously (26).M. xanthus HB002 (Δbkd liuC) shows only residual amounts of iso-FAs, as both leucine degradation and the alternative pathway to IV-CoA are blocked (Fig. ​(Fig.2D)2D) and its capability to form fruiting bodies is strongly reduced (Fig. ​(Fig.3).3). The residual amount of iso-FAs results from a second BKD activity in M. xanthus that has been identified by residual leucine incorporation as well as by residual enzymatic activity in bkd mutants (23, 30). This second BKD activity might be a side activity of the pyruvate dehydrogenase or a related chemical oxidative decarboxylation, as no second bkd locus could be identified in the genome (unpublished results). Moreover, growth of HB002 is not MVL dependent because the block in the alternative pathway does not affect isoprenoid biosynthesis, as liuC encodes a dehydratase/hydratase that is involved in the conversion of HMG-CoA to 3-methylglutaconyl-CoA and vice versa (4). As expected, the FA profile (4) as well as the developmental phenotype (data not shown) can be complemented (Fig. ​(Fig.2E)2E) by the addition of isovaleric acid (IVA), the free acid of IV-CoA, indicating the importance of iso-branched compounds for development in M. xanthus. Unexpectedly, addition of MVL (Fig. ​(Fig.2F)2F) also partially restored fruiting body formation without restoring the FA profile (Fig. ​(Fig.3).3). Similarly, M. xanthus HB015 (Δbkd MXAN_4265::kan) can produce only traces of iso-FAs, as both pathways to IV-CoA are blocked. MXAN_4265 encodes a protein with similarity to a glutaconyl-CoA transferase subunit, but from our previous results, we postulated it to be involved in the alternative pathway to IV-CoA (Fig. ​(Fig.1)1) (4). The respective mutant shows a severely impaired developmental phenotype, which can be complemented not only by the addition of IVA (not shown) but also by the addition of MVL (Fig. ​(Fig.3).3). Again, no change in the FA profile was observed after the addition of MVL. However, a plasmid insertion into MXAN_4265 has a polar effect on mvaS, which is the last gene in this five-gene operon and which is crucial for HMG-CoA formation from acetoacetyl-CoA and acetyl-CoA. Therefore, we assume that both pathways to HMG-CoA are blocked in HB015: no HMG-CoA can be made from acetyl-CoA and hardly any can be made via leucine degradation. In order to prove this hypothesis, we complemented HB015 with an additional copy of mvaS under the constitutive T7A1 promoter as described previously, using the plasmid pCK4267exp (4). The resulting strain, HB020 (Δbkd MXAN_4265::kan mvaS⁺), showed a restored developmental phenotype but still produced only trace amounts of iso-FAs.Open in a separate windowFIG. 3.Fruiting body formation on TPM agar in selected mutants at 24, 48, and 72 h after starvation. Numbers refer to the relative amounts (in percentages) of the most abundant iso-FA, iso-15:0, which is indicative of iso-FAs in general. Strains were DK1622 (wild type), HB002 (Δbkd liuC::kan), HB015 (Δbkd MXAN_4265::kan), DK5624 (Δbkd mvaS::kan), HB019 (Δbkd mvaS::kan mvaS⁺), and HB020 (Δbkd MXAN_4265::kan mvaS⁺). DK5624 was grown with 0.3 mM MVL prior to starvation, and the cells were washed and plated on TPM with or without 1 mM of MVL.The data from HB002, HB015, and HB020 indicate an important function of the mevalonate-dependent isoprenoid pathway for fruiting body formation in M. xanthus. Therefore, MVL addition can at least partially complement the developmental phenotype of DK5624, which cannot form fruiting bodies without MVL (Fig. ​(Fig.3).3). However, genetic complementation with mvaS in HB019 resulted in the expected complementation of the fruiting body formation and the FA profile (Fig. ​(Fig.3,3, bottom row).Leucine is one of the most abundant proteinogenic amino acids. It is also an essential amino acid for M. xanthus (8), which has a predatory life-style (1), as it lives on other bacteria and fungi that contain a lot of leucine. Moreover, leucine is very efficiently incorporated into isoprenoids like geosmin and aurachin (10, 22). Thus, one can conclude that in fact leucine degradation is the major pathway for HMG-CoA biosynthesis instead of the usual formation via acetoacetyl-CoA and acetyl-CoA by the HMG-CoA synthase MvaS as indicated in Fig. ​Fig.2A.2A. No difference in growth was observed between culture with and culture without MVL for HB002 (Δbkd liuC::kan) and HB015 (Δbkd MXAN_4265::kan) in rich medium (data not shown), probably due to the complete MvaS activity (in HB002) or residual BKD activity (in HB002 and HB015), resulting in all precursors for the mevalonate-dependent isoprenoid biosynthesis still being present in excess under these conditions. However, under starvation conditions a small reduction in HMG-CoA biosynthesis caused by completely blocked leucine degradation (as in HB002 due to the mutation in liuC [Fig. ​[Fig.2D])2D]) or reduced leucine degradation and a mutation in mvaS (as in HB015) might each result in a reduced isoprenoid level, which can be complemented at least partially by the addition of MVL. This would also explain the difference in the developmental phenotypes of HB002 and HB015, with the phenotype being more severe in HB002 (Fig. ​(Fig.3).3). The fact that complementation with IVA is in all cases more efficient than that with MVL can be explained by the role of the already-mentioned isolipids. They can be produced only after IVA addition, which also complements the (developmental) phenotype of some of these mutants (26).As isoprenoids represent probably the most diverse class of natural products (14), it is very hard to predict which particular isoprenoids might be responsible for the observed effects. Several isoprenoids (7, 11-13), prenylated secondary metabolites (6, 22), and carotenoids (18-21) are known from myxobacteria in general, and a major volatile compound from M. xanthus is the terpenoid geosmin (13). In order to test whether geosmin might be required for fruiting body formation, we constructed a plasmid insertion mutant in MXAN_6247, which is involved in the cyclization of farnesyl diphosphate to geosmin, following published procedures (4, 5). The resulting strain, HB022, showed the expected loss in geosmin production but no developmental phenotype (data not shown).Additionally, it cannot be excluded that prenylated proteins, sugars, or quinones from the respiratory chain are important for fruiting body formation. Moreover, stigmolone has been described as a pheromone involved in fruiting body formation in S. aurantiaca (25). Although its biosynthesis has not been elucidated yet, stigmolone could be an isoprenoid as well, which is deducible from the two iso-branched residues within its chemical structure (17). Nevertheless, the importance of isoprenoids for M. xanthus is evident from the data presented, and clearly more work is needed to identify the compound(s) involved.     

Autophagy contributes to degradation of Hirano bodies

Hirano bodies are actin-rich inclusions reported most frequently in the hippocampus in association with a variety of conditions including neurodegenerative diseases, and aging. We have developed a model system for formation of Hirano bodies in Dictyostelium and cultured mammalian cells to permit detailed studies of the dynamics of these structures in living cells. Model Hirano bodies are frequently observed in membrane-enclosed vesicles in mammalian cells consistent with a role of autophagy in the degradation of these structures. Clearance of Hirano bodies by an exocytotic process is supported by images from electron microscopy showing extracellular release of Hirano bodies, and observation of Hirano bodies in the culture medium of Dictyostelium and mammalian cells. An autophagosome marker protein Atg8-GFP, was co-localized with model Hirano bodies in wild type Dictyostelium cells, but not in atg5- or atg1-1 autophagy mutant strains. Induction of model Hirano bodies in Dictyostelium with a high level expression of 34 kDa ΔEF1 from the inducible discoidin promoter resulted in larger Hirano bodies and a cessation of cell doubling. The degradation of model Hirano bodies still occurred rapidly in autophagy mutant (atg5-) Dictyostelium, suggesting that other mechanisms such as the ubiquitin-mediated proteasome pathway could contribute to the degradation of Hirano bodies. Chemical inhibition of the proteasome pathway with lactacystin, significantly decreased the turnover of Hirano bodies in Dictyostelium providing direct evidence that autophagy and the proteasome can both contribute to degradation of Hirano bodies. Short term treatment of mammalian cells with either lactacystin or 3-methyl adenine results in higher levels of Hirano bodies and a lower level of viable cells in the cultures, supporting the conclusion that both autophagy and the proteasome contribute to degradation of Hirano bodies.     

Autophagy contributes to degradation of Hirano bodies

Hirano bodies are actin-rich inclusions reported most frequently in the hippocampus in association with a variety of conditions including neurodegenerative diseases, and aging. We have developed a model system for formation of Hirano bodies in Dictyostelium and cultured mammalian cells to permit detailed studies of the dynamics of these structures in living cells. Model Hirano bodies are frequently observed in membrane-enclosed vesicles in mammalian cells consistent with a role of autophagy in the degradation of these structures. Clearance of Hirano bodies by an exocytotic process is supported by images from electron microscopy showing extracellular release of Hirano bodies, and observation of Hirano bodies in the culture medium of Dictyostelium and mammalian cells. An autophagosome marker protein Atg8-GFP, was co-localized with model Hirano bodies in wild type Dictyostelium cells, but not in atg5(-) or atg1-1 autophagy mutant strains. Induction of model Hirano bodies in Dictyostelium with a high level expression of 34 kDa DeltaEF1 from the inducible discoidin promoter resulted in larger Hirano bodies and a cessation of cell doubling. The degradation of model Hirano bodies still occurred rapidly in autophagy mutant (atg5(-)) Dictyostelium, suggesting that other mechanisms such as the ubiquitin-mediated proteasome pathway could contribute to the degradation of Hirano bodies. Chemical inhibition of the proteasome pathway with lactacystin, significantly decreased the turnover of Hirano bodies in Dictyostelium providing direct evidence that autophagy and the proteasome can both contribute to degradation of Hirano bodies. Short term treatment of mammalian cells with either lactacystin or 3-methyl adenine results in higher levels of Hirano bodies and a lower level of viable cells in the cultures, supporting the conclusion that both autophagy and the proteasome contribute to degradation of Hirano bodies.     

Telomeric DNA Mediates De Novo PML Body Formation

The cell nucleus harbors a variety of different bodies that vary in number, composition, and size. Although these bodies coordinate important nuclear processes, little is known about how they are formed. Among the most intensively studied bodies in recent years is the PML body. These bodies have been implicated in gene regulation and other cellular processes and are disrupted in cells from patients suffering from acute promyelocytic leukemia. Using live cell imaging microscopy and immunofluorescence, we show in several cell types that PML bodies are formed at telomeric DNA during interphase. Recent studies revealed that both SUMO modification sites and SUMO interaction motifs in the promyelocytic leukemia (PML) protein are required for PML body formation. We show that SMC5, a component of the SUMO ligase MMS21-containing SMC5/6 complex, localizes temporarily at telomeric DNA during PML body formation, suggesting a possible role for SUMO in the formation of PML bodies at telomeric DNA. Our data identify a novel role of telomeric DNA during PML body formation.     

Morphology and Round Body Formation in Vibrio marinus

The morphology of Vibrio marinus MP-1 was studied by phase and electron microscopy. The ultrastructure of the vibrio form of V. marinus was found to be typically gram-negative with a trilaminar plasma membrane and cell wall. The coccoid or round bodies noted in otherwise pure cultures of V. marinus were frequently found in early and late stationary phase of growth. The round bodies in ultrathin section were found to contain at least one, and often three or four, cell units. Three types of round bodies were observed in ultrathin section, each differing in size and behavior: "spherules," "spheres" or the "round body," and "giant cells" or "macrospheres." The round bodies appeared to be associated with, or to result from, the constrictive cell division of V. marinus.     

The Initiation of Fruiting Body Formation in Myxococcus fulvus

Myxobacteria are exceptional bacteria in that they have an obvious complex life-cycle, resembling that of slime fungi, in which the feeding stage consists of individual rods moving with a gliding action on solid surfaces and subsequently forming fruiting bodies composed of numerous microcysts. The phase-contrast microscope provides a means of studying these processes which are as yet little understood. As observed in situ , by phase-contrast, the edge of the swarm of Myxococcus fulvus is composed of bacteria, singly or in groups, moving without orientation. The central area shows a pattern of ridges, with numerous small foci, at the centres of which the microcysts develop. Fruiting bodies are formed from groups of such foci. The critical factor for initiation of fruiting appears to be the concentration of cells.     

Phenoloxidase Activity and Fruiting Body Formation in Schizophyllum commune

Studies of induced haploid fruiting in the Basidiomycete Schizophyllum commune suggested that polyphenoloxidase enzymes may participate in the formation of fruiting bodies. Reported inhibitors of phenoloxidases were found to affect both the activity of these enzymes and the fruiting response. Fertile mycelia were found to give a positive Bavendamm reaction in situ, and cell-free extracts from fertile mycelia exhibited polyphenoloxidase activity when studied spectrophotometrically. Sterile mycelia, on the other hand, were devoid of these activities. Various kinds of mutant homo- and dikaryotic mycelia were studied, and the results suggested a correlation between phenoloxidase activity and fruiting body formation in S. commune.     

Clearance of a Hirano body-like F-actin aggresome generated by jasplakinolide

We have reported in a variety of mammalian cells the reversible formation of a filamentous actin (F-actin)-enriched aggresome generated by the actin toxin jasplakinolide (Lázaro-Diéguez et al., J Cell Sci 2008; 121:1415-25). Notably, this F-actin aggresome (FAG) resembles in many aspects the pathological Hirano body, which frequently appears in some diseases such as Alzheimer's and alcoholism. Using selective inhibitors, we examined the molecular and subcellular mechanisms that participate in the clearance of the FAG. Chaperones, microtubules, proteasomes and autophagosomes all actively participate to eliminate the FAG. Here we compile and compare these results and discuss the involvement of each process. Because of its simplicity and high reproducibility, our cellular model could help to test pharmacological agents designed to interfere with the mechanisms involved in the clearance of intracellular bodies and, in particular, of those enriched in F-actin.     

Early Stages in Wheat Endosperm Formation and Protein Body Initiation

The early stages of endosperm formation and protein body initiationare described for hard red winter wheat using light and transmissionelectron microscopy. Two days after flowering (DAF) the endospermwas a thin layer of coenocytic cytoplasm lining the embryo sac.By 4 DAF the endosperm had cellularized and completely filledthe embryo sac. Enough differentiation had occurred by 6 DAFto distinguish cells destined to become the aleurone layer,sub-aleurone region and central endosperm. Protein bodies wereinitiated at about 6–7 DAF and were first found near theGolgi apparatus. Wheat was ready for combine harvest at 34 DAF.Enlargement of the small protein bodies near the Golgi apparatusoccurred by several mechanisms: (1) fusion with one or moreof the dense Golgi vesicles or fusion with other protein bodies,(2) fusion with small electron-lucent Golgi-derived vesicles,(3) pinocytosis of a portion of the adjacent cytoplasm intothe developing protein body and (4) fusion of large proteinbodies with one another at later stages of grain development.Of the four mechanisms described, the pinocytotic vesicles andfusion of protein bodies were the most frequent and consistentprocesses observed. Direct connections between rough endoplasmicreticulum (RER) and protein bodies were not observed. The resultssuggest a rôle for the Golgi apparatus in the initiationof protein bodies. Also, the lack of RER derived vesicles suggestsa soluble mode of secretion of storage proteins involved inthe enlargement of protein bodies. Triticum aestivum, wheat endosperm, protein bodies Golgi apparatus