In situ localization of beta-glucans in the cell wall of Schizosaccharomyces pombe.

The chemical composition of the cell wall of Sz. pombe is known as beta-1,3-glucan, beta-1,6-glucan, alpha-1,3-glucan and alpha-galactomannan; however, the three-dimensional interactions of those macromolecules have not yet been clarified. Transmission electron microscopy reveals a three-layered structure: the outer layer is electron-dense, the adjacent layer is less dense, and the third layer bordering the cell membrane is dense. In intact cells of Sz. pombe, the high-resolution scanning electron microscope reveals a surface completely filled with alpha-galactomannan particles. To better understand the organization of the cell wall and to complement our previous studies, we set out to locate the three different types of beta-glucan by immuno-electron microscopy. Our results suggest that the less dense layer of the cell wall contains mainly beta-1,6-branched beta-1,3-glucan. Occasionally a line of gold particles can be seen, labelling fine filaments radiating from the cell membrane to the alpha-galactomannan layer, suggesting that some of the radial filaments contain beta-1,6-branched beta-1,3-glucan. beta-1,6-glucan is preferentially located underneath the alpha-galactomannan layer. Linear beta-1,3-glucan is exclusively located in the primary septum of dividing cells. beta-1,6-glucan only labels the secondary septum and does not co-localize with linear beta-1,3-glucan, while beta-1,6-branched beta-1,3-glucan is present in both septa. Linear beta-1,3-glucan is present from early stages of septum formation and persists until the septum is completely formed; then just before cell division the label disappears. From these results we suggest that linear beta-1,3-glucan is involved in septum formation and perhaps the separation of the two daughter cells. In addition, we frequently found beta-1,6-glucan label on the Golgi apparatus, on small vesicles and underneath the cell membrane. These results give fresh evidence for the hypothesis that beta-1,6-glucan is synthesized in the endoplasmic reticulum-Golgi system and exported to the cell membrane.

Characteristic biological effects of itraconazole on L929 fibroblasts and their cell membrane.

Itraconazole (ITCZ), a triazole antifungal agent, was studied for its effects on the morphology and function of L929 fibroblasts. L929 fibroblasts were cultured for 20 h with ITCZ or one of several other triazoles (fluconazole, ketoconazole, and hydroxy-itraconazole [ITCZ-OH]) at the concentration of 0.5 microg/ml. Among these agents, only ITCZ and its metabolite ITCZ-OH markedly elongated the cells bidirectionally. Scanning electron microscopy studies showed that the surface of the elongated cells was smoother than that of the untreated cells. The viability of L929 cells cultured with 0.5 microg/ml of ITCZ for 20 h was not lowered. However, after treatment with 0.0375% sodium deoxycholate (DOC) solution, the viability of the cells treated with ITCZ, as evaluated by the 3-(4,5-dimethyl-2thiazoyl)-2,5-diphenyl-2H-tetrazolium bromide (MTT) proliferation assay or the release of lactic dehydrogenase from cytoplasm, was decreased. When L929 cells were cultured in the presence of a combination of ITCZ and vincristine, their growth was synergistically inhibited. This synergism was also observed when ITCZ was replaced by ITCZ-OH, but not by the other azoles. These findings suggest that the exposure of L929 fibroblasts to low ITCZ concentrations affects the physiological nature of their cell membrane.

Ultrastructure of cell wall of the cps8 actin mutant cell in Schizosaccharomyces pombe.

A Schizosaccharomyces pombe cps8 mutant, of which the gene encodes a mutant actin with an amino acid substitution of Asp for Gly(273) [J. Ishiguro and W. Kobayashi (1996) FEBS Lett. 392, 237-241], was used to determine the role of the actin cytoskeleton in cell wall formation. In the cps8 mutant cells, atomic force microscopic and scanning electron microscopic images showed abnormal depolarized and branched morphology. Fibrous material covered a part of the surface of growing cps8 cells. Transmission electron microscopic images showed variable thickness of the cell wall due to multilayering of cell wall materials, and aberrant multisepta due to diagonal growth of the primary septum, whereas the normal primary septum grows at a right angle from the cortex. This abnormal septum formation may induce abnormality of the cell with multinuclei and/or multisepta, caused by non-separation of daughter cells. These results indicate that actin plays an important role in cell wall and septum formation.

Movement of turritella spermatozoa: direction of propagation and chirality of flagellar bends.

The marine snail, Turritella communis, produces two types of spermatozoa, named apyrene and eupyrene. Eupyrene spermatozoa are usually paired, but unpaired ones are involved in fertilization. Movements of these spermatozoa were analyzed using a video camera with a high-speed shutter. The eupyrene spermatozoa usually swim with the head foremost but are able to swim flagellum foremost. A reversal of the direction of their swimming was found to be the result of a change in the direction of flagellar bend propagation, which changed with calcium concentration. Reversal of the direction of bend propagation was accompanied by a reversal of direction of the rotational movement of the spermatozoa around their long axis, suggesting that the bending waves keep the sense of their three-dimensional form. The swimming speed of apyrene spermatozoa in natural seawater was about one-eighth of that of the eupyrene ones and remained almost constant in highly viscous medium. The swimming speed of conjugated eupyrene spermatozoa was the same as that of unpaired spermatozoa over a wide viscosity range (<3,000 cP). No advantage of swimming by two spermatozoa could be detected in Turritella spermatozoa.

Rat liver phosphoribosylpyrophosphate synthetase is activated by free Mg2+ in a manner that overcomes its inhibition by nucleotides.

Phosphoribosylpyrophosphate synthetase is activated by Pi and free Mg2+ as an essential activator and inhibited by nucleotides, especially ADP and GDP. The rat liver enzyme is a complex aggregate of two highly homologous catalytic subunits (PRS I and PRS II) and two associated proteins (PAP39 and PAP41). PRS I is more sensitive to inhibition by ADP and GDP than is PRS II. The native liver enzyme showed a weaker sensitivity to inhibition by nucleotides than expected from its composition. To further understand the regulation of the liver enzyme, kinetic studies of each subunit component and the liver enzyme regarding Mg2+ activation and inhibition by ADP and GDP were carried out. Assay conditions were designed to keep free Mg2+ at constant concentrations. (1) GDP, as MgGDP, did not affect the apparent Km values of PRS I for MgATP and ribose-5-phosphate but did dramatically increase the apparent Ka value for free Mg2+. (2) In contrast, ADP, as MgADP, increased the Km value for MgATP of PRS I as well as the Ka value for free Mg2+. (3) High concentrations of free Mg2+ almost completely nullified the inhibitory effect of MgGDP and partly that of MgADP on PRS I. (4) At low free Mg2+ concentrations within the physiological range, inhibition by the nucleotides is of physiological significance and conversely, variation in free Mg2+ concentrations critically affects the enzyme activity in the presence of inhibitory nucleotides. (5) The response of PRS II and the native liver enzyme is similar to that of PRS I, while the effects of MgGDP and MgADP were smaller than that on PRS I. (6) We propose that MgGDP binds to a regulatory site of PRS I and PRS II and MgADP to the substrate MgATP site and also the regulatory site. The allosteric interaction of the regulatory site and the Mg2+ binding site is also considered.

Protease activation following UV irradiation is linked to hypomutability in human cells selected for resistance to combination of UV and antipain.

In order to examine the relationship between activation of an antipain-sensitive protease and suppression of mutability in UV (UVC)-irradiated human cells, a human cell variant with the high protease activity induced by UV was established and characterized for its susceptibility to UV-induced mutagenicity. Cells of a hypermutable cell strain, RSa, were mutagenized with ethyl methanesulfonate and irradiated with 10 J/m2 UV, followed by exposure to 20 mM antipain for 34 h. Whereas the combined treatment was totally lethal to RSa cells not treated with ethyl methanesulfonate, one surviving clone was isolated from the mutagenized cells and designated UVAP-1. When fibrinolytic protease activity was measured from extracts of the cell, it was found that the protease activity was elevated promptly after UV irradiation, reaching the maximum at 10 min post-irradiation. This protease activity was inhibited by antipain. After UV irradiation the phenotypic mutation frequencies of UVAP-1 cells were much lower than those of the parent RSa cells, as evaluated by the generation of clones resistant to ouabain-killing. Furthermore, mutation at the K-ras codon 12 in genomic DNA was detected in RSa cells but not in UVAP-1 cells. Thus, the protease activation was correlated with the decreased levels of UV-mutagenicity in UVAP-1 cells, supporting the possible involvement of the antipain-sensitive protease activity in the regulation of cellular mutability following UV irradiation.

Dynamics of cell wall formation in fission yeast, Schizosaccharomyces pombe.

Studies on the dynamics of surface and intracellular structures during cell wall formation from the reverting protoplast of Schizosaccharomyces pombe were reviewed, and the correlation between cell wall formation and actin cytoskeleton, which is the most important conductor of the mechanism, is described in this paper. A close spatial and temporal relationship between actin cytoskeleton and cell wall formation was found by using wild type and actin point-mutant cps8 of S. pombe. Concomitant with the cell wall formation, dynamic behavior of the intracellular secretion machinery, especially the Golgi apparatus and secretory vesicles, was analyzed by three-dimensional reconstruction of 40 to 80 serial sections at five reverting stages. Total reverting protoplast volume increased by 3.8 and 4.3 times at 3 and 5 h, respectively, and the volume of the Golgi apparatus in the corresponding stages increased 2.3- and 2. 5-fold over the same periods. The number of secretory vesicles also markedly increased by 3.4 and 5.8 times over that of the corresponding reverting protoplasts. Actin point-mutant cps8 cells have abnormal structure in the cell wall and septum, and the distribution pattern of the actin cytoskeleton during the reversion process was different from wild-type protoplasts. The profiles of actin showed one or two thick cables and patches in the cytoplasm which remained throughout reversion. The development of crosslinkage of the glucan fibrils which are beta-1,3-glucan in nature on the reverting protoplast surface was defective; the glucan networks consisted of thin, rope-shaped fibrils up to 30 nm in width which formed a ribbon-shape 200 nm wide in wild-type reverting protoplasts. The intrafibrillar space is not filled with amorphous particles of alpha-galactomannan in nature. The secretion machinery was seen to have a similar profile as the wild type. The above results suggest that actin cytoskeleton may control secretion of beta-1,6-glucan and other cell wall substances such as alpha-glucan and alpha-galactomannan rather than beta-1,3-glucan. Study of the role of actin cytoskeleton in the cell wall formation is contributing to the development of antifungal agents together with basic cell biology.

Morphological effects of itraconazole on murine macrophage.

Morphological effects of itraconazole (ITCZ) on murine macrophages were examined by light microscopy (LM), scanning electron microscopy (SEM) and transmission electron microscopy (TEM), and compared with the effects of other antifungal agents. Thioglycolate-induced peritoneal macrophages were prepared from C3H/He J mice and cultured for 20 h in the presence of the antifungal azoles econazole, fluconazole, miconazole, ketoconazole, ITCZ, hydroxy-itraconazole (ITCZ-OH), and a polyene antibiotic amphotericin B (AMPH). Among these reagents, only ITCZ and its derivative ITCZ-OH were effective in causing morphological changes of murine macrophage as determined by LM and SEM. Macrophages treated with 2 microg/ml ITCZ or ITCZ-OH were stretched out bidirectionally, their surface was smooth and their 'ruffles' decreased. TEM observation showed that the bundles of the filamentous structure existed along the cell shape in the cytoplasm. These findings suggest that ITCZ and ITCZ-OH affect the morphology of macrophages.

[Augmentation of anti-Candida activity of neutrophils by macrophages treated with itraconazole].

Effects of itraconazole (ITCZ) on anti-Candida activity of a macrophage (MP)-neutrophil axis were examined in vitro. Murine peritoneal MP, stimulated by an enterococcal preparation FK-23, released tumor necrosis factor a (TNF) into the culture medium in 20 hr-culture period. This level of TNF production by the stimulated MP, which were measured by a bioassay or immunological assay, was heightened by co-stimulation with 0.5 mg/ml of ITCZ. Supernatants obtained from the culture medium of FK-23 and ITCZ-treated MP not only contained about 10 ng/ml of TNF but also had the capacity to enhance anti-Candida activity of murine neutrophils. This enhancement was blocked by pretreatment of the MP-supernatant with anti-TNF antibody. Observation by scanning electron microscope suggested that cell walls of the candida mycelia, the growth of which was inhibited by the neutrophils in the presence of either the MP-supernatant or TNF, sustained similar structural damage. These results suggest that ITCZ augments anti-Candida activity of neutrophils through enhanced production of TNF by MP in vitro.

[Inhibition of mycelial growth of Candida albicans by ascites fluid of tumor bearing mice].

The effects of ascites fluids and sera of tumor-bearing mice on the mycelial growth of Candida albicans were examined. When the ascites fluids or the sera obtained from mice inoculated with MM46 mammary carcinoma were added to the culture medium, mycelial growth of C. albicans was strongly inhibited. The molecular size of the growth inhibitory factor in the ascites fluids was estimated to be approximately 80 K dalton by gel-filtration chromatography. Ferric chloride (6 microM) neutralized the anti-Candida activity. On the basis of these results including morphological observation, a possible role of a transferrin-like molecule was discussed.

Abnormal DNA synthesis activity induced by X-rays in nevoid basal cell carcinoma syndrome cells.

DNA synthesis activity was examined in fibroblasts and isolated nuclei derived from patients with nevoid basal cell carcinoma syndrome (NBCCS) upon exposure to X-ray and ultraviolet (UV). The DNA synthesis activity in NBCCS fibroblasts increased after X-ray irradiation, i.e., to twice that on mock-irradiation, while it decreased in healthy donor-derived fibroblasts. The DNA synthesis activity in isolated nuclei of X-ray irradiated NBCCS fibroblasts also increased, i.e., more than twice that on mock-irradiated. In the experiments using synchronized cells, DNA synthesis activity showed the most marked increase when the fibroblasts at S phase were irradiated with X-rays. In contrast, UV-irradiated NBCCS fibroblasts showed no such increase in DNA synthesis. These results revealed that DNA synthesis is abnormally induced in X-ray irradiated NBCCS cells and that this abnormality might be related with the tendency of tumorigenesis in NBCCS patients after exposure to X-ray.

Kinetic and regulatory properties of rat liver phosphoribosylpyrophosphate synthetase complex are partly distinct from those of isolated recombinant component catalytic subunits.

Rat liver phosphoribosylpyrophosphate (PRPP) synthetase exists as complex aggregates composed of two catalytic subunits (PRS I and II, in a ratio of approximately 4:1) and two catalytically inactive PRPP synthetase-associated proteins. To better understand the significance of the complex structure, the properties of the native liver enzyme were compared with those of homologous aggregates of recombinant PRS I and PRS II (rPRS I and rPRS II). (1) The specific activity per catalytic subunits of the liver enzyme was about 2.5 times lower than that of rPRS I over a wide pH range. Km values for substrates and Ka values for Pi and Mg2+ of the three enzymes were similar. (2) Specific activity of the liver enzyme for the reverse reaction was about 2 times lower than those of rPRSs. Km values for substrates of the three enzymes were comparable. (3) The liver enzyme was more stable than were rPRSs when incubated at a high temperature or in the absence of stabilizing agents. (4) The liver enzyme was markedly less sensitive to inhibition by nucleotides compared to rPRS I. GDP at 1 mM inhibited the liver enzyme and rPRS I by 32 and 93%, respectively. This effect is not ascribable to molecular interaction between rPRS I and II, as reconstitution of the two did not alter the sensitivity to nucleotide inhibition. (5) Our observations suggest that complex aggregation states of the native enzyme not only suppress the activities but also stabilize the catalytic subunits and the associated proteins and remarkably reduce the sensitivity to inhibition by nucleotides.

Partial reconstitution of mammalian phosphoribosylpyrophosphate synthetase in Escherichia coli cells. Coexpression of catalytic subunits with the 39-kDa associated protein leads to formation of soluble multimeric complexes of various compositions.

Rat liver phosphoribosylpyrophosphate (PRPP) synthetase exists as complex aggregates composed of 34-kDa catalytic subunits (PRS I and PRS II) and homologous 39- and 41-kDa proteins termed PRPP synthetase-associated proteins (PAPs). While a negative regulatory role was indicated for PAPs, the physiological function of PAPs is less well understood. We attempted to prepare recombinant 39-kDa PAP (PAP39) and to reconstitute the enzyme complex. Free PAP39 was poorly expressed in Escherichia coli, while expression of protein fused with glutathione S-transferase was successful. The purified fusion protein had no PRPP synthetase activity, and bound to dissociated PRS I and PRS II, with a similar affinity. A free form of PAP39 prepared from the fusion protein formed insoluble aggregates. The enzyme complex was then partially reconstituted in situ by coexpression of PAP39 with PRS I or PRS II in E. coli cells. This coexpression led to formation of soluble complexes of various compositions, depending on the conditions. When the relative amount of PAP39 was higher, specific catalytic activities, in terms of the amount of the catalytic subunit, were lowered. PAP39 complexed with PRS I was more readily degraded by proteolysis than seen with PRS II, in vivo and in vitro. These results provide additional, strong evidence for that PAP39 has no catalytic activity in the enzyme complex, but does exert inhibitory effects in an amount-dependent manner, and that composition of the enzyme complex varies, depending on the relative abundance of components present at the site of aggregate formation.

Cloning and sequencing of rat cDNA for the 41-kDa phosphoribosylpyrophosphate synthetase-associated protein has a high homology to the catalytic subunits and the 39-kDa associated protein.

Rat liver phosphoribosylpyrophosphate synthetase is a complex aggregate of 34-kDa catalytic subunits (PRS I and II) and 39- and 41-kDa associated proteins (PAP39 and 41). When the rat cDNA encoding PAP41 was isolated, the deduced protein sequence was seen to contain 369 amino acids with a calculated molecular mass of 41130. PAP41 has a 79 and 49% identity with PAP39 and PRSs, respectively. When conservative substitutions are included, PAP41 and the three other components have a 66% homology. PAP41 shares some common features with PAP39 and the two proteins form the PAP subfamily. The mRNA of PAP41 is present in all rat tissues we examined.

Calcium-dependent bidirectional power stroke of the dynein arms in sea urchin sperm axonemes.

Active sliding between doublet microtubules of sea urchin sperm axonemes that were demembranated with Triton X-100 in the presence or absence of calcium was induced with ATP and elastase at various concentrations of Ca2+ to examine the effects of Ca2+ on the direction of the power stroke of the dynein arms. Dark-field light microscopy of microtubule sliding revealed that the sliding from the axonemes demembranated with Triton and millimolar calcium and disintegrated with ATP and elastase showed various patterns of sliding disintegration, including loops of doublet microtubules formed near the head or the basal body. These loops were often thicker than the remaining axonemal bundle. In contrast, only thinner loops were found from the axonemes demembranated with Triton in the absence of calcium and disintegrated with ATP and elastase at high Ca2+ concentrations. Electron microscopic examination of the direction of microtubule sliding showed that the doublet microtubules in the axonemes demembranated in the presence of millimolar calcium moved toward the base of the axonemes by the dynein arms on the adjacent doublet microtubule as well as by their own dynein arms. Doublet microtubules in the axonemes demembranated in the absence of calcium moved toward the base of the axonemes only by their own dynein arms. Similar observations have been obtained from the axonemes from which the outer dynein arms were selectively extracted. From these observations, we can conclude that the dynein arms generate force in both directions and this feature of the dynein arms arises from at least the inner dynein arms.

Schizosaccharomyces pombe is more sensitive to pressure stress than Saccharomyces cerevisiae.

The effects of hydrostatic pressure on ultrastructure, microtubules and microfilaments of Schizosaccharomyces pombe were investigated by fluorescence microscopy, conventional electron microscopy and immunoelectron microscopy. Cells were treated with hydrostatic pressure from 0.1 to 400 MPa for 10 min at room temperature. The nuclear membrane was disrupted at above 100 MPa. At 150 MPa the matrixes of mitochondria had an electron dense area. At 250 MPa the cytoplasmic substances changed dramatically, the cellular organelles could hardly be detected and the fragmented nuclear membrane was barely visible. The fluorescence in alpha-tubulin was lost in most of the cells at 100 MPa. The gold particles for anti alpha-tubulin were not visible in the cells at the same level. Cell cycle specific actin distribution was lost even at 50 MPa, although actin dots localized at the central region remained unchanged. Thick actin cables appeared at 100 MPa. Complete depolymerization of F-actin was observed at 150 MPa. These results suggest that S. pombe cells were more sensitive than Saccharomyces cerevisiae cells. The damage to microtubules and nuclear membrane caused by hydrostatic pressure was though to be followed by breakdown of nuclear division apparatus and the inhibition of nuclear division. This damage might contribute to the frequent formation of polyploidy in S. pombe.

Cloning and sequencing of human complementary DNA for the phosphoribosylpyrophosphate synthetase-associated protein 39.

A human cDNA encoding a human homologue of the rat phosphoribosylpyrophosphate synthetase-associated protein of 39 kDa was isolated. The deduced protein contains 356 amino acids and has calculated molecular mass of 38561. The amino acid sequence is 98% identical to that of the rat. The corresponding mRNA is present in all human tissues examined.