ISOLATION AND CHARACTERIZATION OF A PRESPORE SPECIFIC STRUCTURE OF THE CELLULAR SLIME MOLD, DICTYOSTELIUM DISCOIDEUM

A method was described for isolation of the prespore specific vacuole (PSV) from slugs of the cellular slime mold, D. discoideum . A cellular component, which was fractionated in accordance with immunohistochemical staining using heteroplastic antispore serum, was found to consist of only the PSV. It was thus concluded that the PSV is identical with the cytoplasmic granule which has been shown by the antiserum to be specifically present in the prespore cell, and hence that the PSV is the only structure which contains the prespore specific substance (antigenic mucopolysaccharide). The isolated PSV contained polysaccharide equivalent to 14% of its protein content, and antigenic mucopolysaccharide constitutes about 60% of the total polysaccharide.     

Changes in spatial and temporal localization of Dictyostelium homologues of TRAP1 and GRP94 revealed by immunoelectron microscopy

TRAP1 (tumor necrosis factor receptor-associated protein 1) is a member of the molecular chaperone HSP90 (90-kDa heat shock protein) family. In this study, we mainly examined the behavior of Dictyostelium TRAP1 homologue, Dd-TRAP1, during Dictyostelium development by immunoelectron microscopy. In vegetatively growing D. discoideum Ax-2 cells, Dd-TRAP1 locates in nucleolus and vesicles in addition to the cell cortex including cell membrane. Many of Dd-TRAP1 molecules moved to the mitochondrial matrix in response to differentiation, although Dd-TRAP1 on the cell membrane seems to be retained. Some Dd-TRAP1 was also found to be secreted to locate outside the cell membrane in Ax-2 cells starved for 6 h. At the multicellular slug stage, Dd-TRAP1 was primarily located in mitochondria and cell membrane in both prestalk and prespore cells. More importantly, in differentiating prespore cells, a significant number of Dd-TRAP1 locates in the PSV (prespore-specific vacuole) that is a sole cell type-specific organelle and essential for spore wall formation, whereas some Dd-TRAP1 in the cell cortical region of prestalk cells. These findings strongly suggest the importance of Dd-TRAP1 regulated temporally and spatially during Dictyostelium development. Incidentally, we also have certified that the glucose-regulated protein 94 (Dd-GRP94) is predominantly located in Golgi vesicles and cisternae, followed by its colocalization with Dd-TRAP1 in the PSV.     

Involvement of the TRAP-1 homologue, Dd-TRAP1, in spore differentiation during Dictyostelium development

Tumor necrosis factor receptor-associated protein 1 (TRAP1) is a member of the molecular chaperone HSP90 (90-kDa heat shock protein) family. We have previously demonstrated that Dictyostelium discoideum TRAP1 (Dd-TRAP1) synthesized at the vegetative growth phase is retained during the whole course of D. discoideum development, and that at the multicellular slug stage, it is located in prespore-specific vacuoles (PSVs) of prespore cells as well as in the cell membrane and mitochondria. Thereupon, we examined the function of Dd-TRAP1 in prepore and spore differentiation, using Dd-TRAP1-knockdown cells (TRAP1-RNAi cells) produced by the RNA interference method. As was expected, Dd-TRAP1 contained in the PSV was found to be exocytosed during sporulation to constitute the outer-most layer of the spore cell wall. In the TRAP1-RNAi cells, PSV formation and therefore prespore differentiation were significantly impaired, particularly under a heat stress condition. Although the TRAP1-RNAi cells formed apparently normal-shaped spores with a cellulosic wall, the spores were less resistant to heat and detergent treatments, as compared with those of parental MB35 cells derived from Ax-2 cells. These findings strongly suggest that Dd-TRAP1 may be closely involved in late development including spore differentiation, as well as in early development as realized by its induction of prestarvation response.     

FORMATION OF A PRESPORE SPECIFIC STRUCTURE FROM A MITOCHONDRION DURING DEVELOPMENT OF THE CELLULAR SLIME MOLD DICTYOSTELIUM DISCOIDEUM

The origin of a unique vacuole (PSV), which was specifically present in the prespore cell of the cellular slime mold Dictyostelium discoideum. was investigated electronmicroscopically. A considerable number of PSV-mitochondrion complexes was found in the intermediate fraction between a pure PSV and a pure mitochondria fractions, which were obtained by isopicnic centrifugation of cellular components of the prespore cell. Similar complexes were also observed in the differentiating prespore cells. Furthermore, the activity of succinic dehydrogenase, a typical mitochondrial enzyme was found cytochemically to be localized in the PSV as well as in mitochondria. From these results, it was concluded that the PSV was formed from the mitochondrion through some intermediate steps.     

CHANGES OF THE PRESPORE SPECIFIC STRUCTURE DURING DEDIFFERENTIATION AND CELL TYPE CONVERSION OF A SLIME MOLD CELL

In the slug of the cellular slime mold, Dictyostelium discoideum , are differentiated the anterior prestalk cells and the posterior prespore cells, whose differentiation is characterized by formation of the prespore specific vacuole (PSV). The ultrastructural changes of the PSV were investigated during dedifferentiation of a prespore cell disaggregated from a slug and also during conversion of the cell type, caused by fragmentation of a slug, between the prespore and the prestalk cells.
During the dedifferentiation, the PSV first lost its lining membrane which subsequently congregated, together with the inner filamentous material, to form some electron dense granules. Finally, the vacuole membrane was punctured, and the granules were released into cytoplasm. During conversion of the prespore to the prestalk cell, the PSV was degraded through the same process as in dedifferentiation, but the degradation proceeded much more synchronously in a converting cell. When a prestalk fragment was isolated from a slug, formation of the PSV was detected in no cell until 2 hr of incubation. After a lag, the PSV was formed in a converting cell through the process which is not a simple reversal of its degrading process.     

Developing Dictyostelium cells contain the lysosomal enzyme alpha- mannosidase in a secretory granule

The prespore vesicle (PSV) is an organelle which secretes spore coat proteins and gal/galNAc polysaccharides from prespore cells of Dictyostelium. By combining the techniques of protein A-gold immunocytochemistry and ricin-gold affinity cytochemistry we have demonstrated colocalization of the lysosomal enzyme alpha-mannosidase with gal/galNAc polysaccharides in prespore vesicles and the spore coat. To determine the origin of prespore vesicles a series of pulse- chase experiments were performed. Cells were labeled with [35S]methionine or [35S]sulfate at different times during development and allowed to differentiate in the presence of unlabeled methionine or sulfate for various periods of time. The cells were homogenized and intracellular organelles were separated using Percoll density gradient centrifugation. The distribution of [35S]methionine-labeled alpha- mannosidase and [35S]sulfate-labeled glycoproteins in the Percoll gradients was determined. It was found that prespore vesicles contained protein which was previously found in lysosomes. Newly labeled protein also entered these vesicles. The data suggest that developing Dictyostelium cells either restructure preexisting lysosomes into prespore vesicles or transport protein between these two organelles. We propose that secretory granules and lysosomes may have a common biosynthetic origin and may be evolutionarily related.     

The nucleotide sequence of the Desulfovibrio gigas desulforedoxin gene indicates that the Desulfovibrio vulgaris rbo gene originated from a gene fusion event.

Expression of the rbo gene from Desulfovibrio vulgaris Hildenborough in Escherichia coli minicells and Western blotting (immunoblotting) of Desulfovibrio cell extracts with antibodies raised against a synthetic peptide indicated the presence of a 14-kDa polypeptide product, as expected from the gene sequence. Cloning and sequencing of the gene (dsr) for desulforedoxin, a 4-kDa redox protein from Desulfovibrio gigas, showed that it is formed by expression of an autonomous gene of 111 bp, not by processing of a 14-kDa protein. The results indicate that the rbo gene product, which has a 4-kDa desulforedoxin domain as the NH2 terminus, may have arisen by gene fusion. Shuffling and fusion of genes for redox protein domains can explain the large variety of redox proteins found in sulfate-reducing bacteria.     

Folic acid stimulation of the Gα4 G protein-mediated signal transduction pathway inhibits anterior prestalk cell development in Dictyostelium

In Dictyostelium discoideum, several G proteins are known to mediate the transduction of signals that direct chemotactic movement and regulate developmental morphogenesis. The G protein alpha subunit encoded by the Galpha4 gene has been previously shown to be required for chemotactic responses to folic acid, proper developmental morphogenesis, and spore production. In this study, cells overexpressing the wild type Galpha4 gene, due to high copy gene dosage (Galpha4HC), were found to be defective in the ability to form the anterior prestalk cell region, express prespore- and prestalk-cell specific genes, and undergo spore formation. In chimeric organisms, Galpha4HC prespore cell-specific gene expression and spore production were rescued by the presence of wild-type cells, indicating that prespore cell development in Galpha4HC cells is limited by the absence of an intercellular signal. Transplanted wild-type tips were sufficient to rescue Galpha4HC prespore cell development, suggesting that the rescuing signal originates from the anterior prestalk cells. However, the deficiencies in prestalk-specific gene expression were not rescued in the chimeric organisms. Furthermore, Galpha4HC cells were localized to the prespore region of these chimeric organisms and completely excluded from the anterior prestalk region, suggesting that the Galpha4 subunit functions cell-autonomously to prevent anterior prestalk cell development. The presence of exogenous folic acid during vegetative growth and development delayed anterior prestalk cell development in wild-type but not galpha4 null mutant aggregates, indicating that folic acid can inhibit cell-type-specific differentiation by stimulation of the Galpha4-mediated signal transduction pathway. The results of this study suggest that Galpha4-mediated signals can regulate cell-type-specific differentiation by promoting prespore cell development and inhibiting anterior prestalk-cell development.     

Structure, expression, and inactivation by gene disruption of the Dictyostelium discoideum prespore gene EB4

We present the nucleotide sequence of the cell type specific prespore gene EB4 which encodes a protein containing a hydrophobic leader sequence and two distinct domains of amino acid repeats. By RNase protection experiments we have determined the genomic organization of the gene which differs substantially from the previously published data. An antibody directed against one of the repeat structures (hexamer repeat) specifically reacts with a developmentally regulated antigen of 58 kd. Gene disruption transformants were obtained by transformation with a genomic DNA fragment. The transformants express a 3' truncated mRNA and do not react with the anti-hexamer antibody. So far, we could not detect any phenotypic aberrations in the transformed cell line.     

A mitochondrion as the structural basis of the formation of a cell-type-specific organelle inDictyostelium development

Summary The mitochondrion has been mainly given attention as a self-reproductive and respiratory organelle. We report here that the mitochondrion may participate in the formation of a cell-type-specific organelle, coupling with the Golgi complex. During the development ofDictyostelium discoideum, the two types of cells, i.e., the anterior prestalk cells and the posterior prespore cells form a polarized cell mass. Prespore differentiation is characterized by the presence of unique vacuoles named PSVs (prespore-specific vacuoles) in the cytoplasm. Thus the PSV is the most essential organelle to understand the structural basis of cell differention in this organism. In differentiating prespore cells, the mitochondrion exerts a remarkable transformation to form a sort of vacuole (M-vacuole). Using a PSV specific antibody, it was immunocytochemically shown that a PSV antigen (C-10) is localized in the M-vacuole as well as in the lining membrane of PSV. Interestingly, the C-10 antigen was also noticed in the Golgi cisternae that had fused with M-vacuole. Based on these findings, we propose here a promising model which suggests how both mitochondria and Golgi cisternae may be coordinately involved in the PSV formation. This model will provide a new aspect of mitochondrial functions in cell differentiation.     

Dual Effects of cAMP on the Stability of Prespore Vesicles and 8-bromo cAMP-enhanced Maturation of Spore and Stalk Cells of Dictyostelium discoideum

It is well known that interconversion between prestalk and prespore cells occurs in 3-dimensional (3–D) isolates of Dictyostelium. The present work was undertaken to examine whether or not the interconversion occurs even in monolayer sheets. The results suggested that in monolayer sheets of either prespore or prestalk cells, the interconversion does not occur. Furthermore, effects of cAMP were examined in relation to the formation or loss of prespore vesicles (PSVs). In monolayer sheets, prespore cells retain their PSVs in the presence of cAMP, though they lose them in its absence. In 3–D masses, however, cAMP induces the conversion into stalk cells, stimulating PSV loss. In the case of prestalk cells, cAMP induces the maturation of prestalk cells to stalk cells in 3–D masses, but it does not induce stalk differentiation in monolayer sheets.
8-Bromo cAMP stimulates the maturation of prespore and prestalk cells into spore and stalk cells, respectively. However, the vegetative and the aggregative cells remain amoeboid even in its presence. These observations suggest that 8-bromo cAMP stimulates the maturation rather than inducing prespore and prestalk differentiation.     

Cloning and characterization of the annexin II receptor on human marrow stromal cells

Annexin II is a heterotetramer, consisting of two 11-kDa (p11) and two 36-kDa (p36) subunits, that is produced by osteoclasts and stimulates osteoclast formation. However, its receptor is unknown. We showed that annexin II binds to normal primary human marrow stromal cells and the Paget's marrow-derived PSV10 stromal cell line to induce osteoclast formation. 125I-Labeled annexin II binding assays with PSV10 cells demonstrated that there was a single class of annexin II receptors with a Kd of 5.79 nm and Bmax of 2.13 x 10(5) receptors/cell. Annexin III or annexin V did not bind this receptor. Using 125I-labeled annexin II binding to screen NIH3T3 transfected with a human marrow cDNA expression library, we identified a putative annexin II receptor clone, which encoded a novel 26-kDa type I membrane receptor protein when expressed in HEK 293 cells. HEK 293 cells transformed with the cloned annexin II receptor cDNA showed a similar binding affinity to annexin II as that observed in PSV10 cells. Chemical cross-linking experiments with biotinylated annexin II and intact PSV10 cells identified a 55-kDa band on Western blot analysis that reacted with both an anti-p11 antibody and streptavidin but not anti-p36 antibody. A rabbit polyclonal antibody raised against the putative recombinant annexin II receptor also recognized the same 26-kDa protein band detected in PSV10 cells. Importantly, the annexin II receptor antibody dose-dependently blocked the stimulatory effects of annexin II on human osteoclast formation, demonstrating that the receptor mediates the effects of annexin II on osteoclast formation.     

Requirements for primer synthesis by bacteriophage T7 63-kDa gene 4 protein. Roles of template sequence and T7 56-kDa gene 4 protein.

Gene 4 of bacteriophage T7 encodes two proteins, a 63-kDa protein and a colinear 56-kDa protein, that are essential for synthesis of leading and lagging strands during DNA replication. The gene 4 proteins together catalyze the synthesis of oligoribonucleotides, pppACC(C/A) or pppACAC, at the single-stranded DNA sequences 3'-CTGG(G/T)-5' or 3'-CTGTG-5', respectively. Purified 56-kDa protein has helicase activity, but no primase activity. In order to study 63-kDa gene 4 protein free of 56-kDa gene 4 protein, mutations were introduced into the internal ribosome-binding site responsible for the translation of the 56-kDa protein. The 63-kDa gene 4 protein was purified 16,000-fold from Escherichia coli cells harboring an expression vector containing the mutated gene 4. Purified 63-kDa gene 4 protein has primase, helicase, and single-stranded DNA-dependent dTTPase activities. The constraints of primase recognition sequences, nucleotide substrate requirements, and the effects of additional proteins on oligoribonucleotide synthesis by the 63-kDa gene 4 protein have been examined using templates of defined sequence. A three-base sequence, 3'-CTG-5', is necessary and sufficient to support the synthesis of pppAC dimers. dTTP hydrolysis is essential for oligoribonucleotide synthesis. Addition of a 7-fold molar excess of 56-kDa gene 4 protein to 63-kDa protein increases the number of oligoribonucleotides synthesized by 63-kDa protein 100-fold. The increase in oligonucleotides results predominantly from an increase in the synthesis of tetramers, with relatively little change in the synthesis of dimers and trimers. The presence of 56-kDa protein also causes 63-kDa protein to synthesize "pseudo-templated" pppACCCC pentamers at the recognition sequence 3'-CTGGG-5'. T7 gene 2.5 protein, a single-stranded DNA binding protein, increases the total number of oligoribonucleotides synthesized by 63-kDa gene 4 protein on single-stranded M13 DNA, but has no effect on the ratio of dimers to trimers and tetramers.