Changes in β-Galactosidase activity during differentiation and dedifferentiation inDictyostelium discoideum

β-Galactosidase (EC 3.2.1.23) ofDictyostelium discoideum was investigated for its properties and activity during differentiation and dedifferentiation. β-Galactosidase of this organism had a pH optimum at 3.5. The specific activity of this enzyme was increased gradually from the time of initiation of differentiation and reached a peak at the aggregation stage. Then the activity of the enzyme showed a slight decrease followed by a further increase and reached a maximum at early culmination. During dedifferentiation of cells disaggregated from a slug, the activity of the enzyme was increased, reached a maximum after 3 hr of incubation and then decreased nearly to the original level of activity after completion of dedifferentiation. This increase in the enzyme activity coincided with decomposition of acid mucopolysaccharide contained in the prespore specific vacuoles, and both processes were sensitive to cycloheximide. No increase in the activity of acetylglucosaminidase (EC 3.2.1.30), another lysosomal enzyme, was observed during the process. Possible roles of β-galactosidase in cell type conversion as well as in dedifferentiation of the prespore cell were discussed.     

萝卜贮藏期过氧化物酶活性及同工酶谱研究

为了研究萝卜贮藏期过氧化物酶的活性变化和作用 ,利用愈创木酚法和聚丙烯酰胺凝胶电泳方法检测在贮藏期萝卜过氧化物酶的活性及同工酶谱 ,实验结果表明 :不同品种的萝卜在不同贮藏时期其过氧化物酶活性及同工酶谱存在差异。贮藏时间越长过氧化物酶活性越高 ,同工酶谱酶带增多。萝卜色素含量越高 ,POD活性也越高 ,因此 ,在萝卜贮藏期有可能过氧化物酶在清除细胞内H2 O2 方面起主要作用     

Regulation of ascorbate peroxidase activity in dark-grown radish cotyledons by a catalase inhibitor, 3-Amino-1,2,4-Triazole

The present study was performed to see the physiological role of cytosolic ascorbate peroxidase (APX) and its relationship to other enzymes involved in the H₂O₂ scavenging metabolism, and also to elucidate the regulation of APX expression in dark-grown radish (Raphanus sativus L. cv Taiwang) cotyledons. To do so, 3-amino-l,2,4-triazole (aminotriazole), a known specific inhibitor of catalase, was used to simulate a catalase-deficient phenomenon in cotyledons. Aminotriazole, in very low concetration (10^-4 M), inhibited remarkably the development of catalase activity in cotyledons during dark germination. This inhibition of catalase by aminotriazole, however, did not result in any significant changes in the growth response and the H₂O₂ level of developing cotyledons. In addition, the development of guaiacol peroxidase (GPX) activity was also not significantly affected. Unlike GPX, cytosolic APX activity was induced rapidly and reached a 1.7-fold increase in aminotriazole treated cotyledons at day 7 after germination. However,in vitro incubation of cytosolic APX preparation from cotyledons with aminotriazole did not result in any significant change in activity. One cytosolic APX isozyme (APXa) band involved in this APX activation was predominantly intensified in a native polyacrylamide gel by activity staining assay. This means that this APXa isozyme seems to play a key role in the expression of cytosolic APX activity. On the other hand, 2-day-old control seedlings treated with exogenous 1 mM H₂O₂ for 1 h showed a significant increase of cytosolic APX acitivity even in the absence of aminotriazole. Also, 2 μM cycloheximide treatment substantially inhibited the increase of APX activity due to aminotriazole. Based on these results, we suggest that a radish cytosolic APX could probably be substituted for catalase in H₂O₂ removal and that the expression of APX seems to be regulated by a change of endogenous H₂O₂ level which couples to APX protein synthesis in a translation stage in cotyledons.     

Regulation of thioredoxin peroxidase activity by C-terminal truncation.

Thioredoxin peroxidase is a member of peroxiredoxin (Prx) family, which uses a thioredoxin (Trx) as an immediate electron donor for the reduction of peroxide. We have identified C-terminal truncated TPx from Schizosaccharomyces pombe and also have found the truncated form is significantly tenacious against the inactivation of H2O2 than the intact form. Peroxidase assay of a series of recombinant C-terminal truncation mutants (Delta192, Delta191, Delta188, Delta184, Delta176, and Delta165) revealed that TPx could be inactivated (Delta192), reactivated (Delta191-Delta176) and reinactivated (Delta165) by serial truncation from C-terminus. We did not find any significant kinetic difference among reactivated forms; however, distinctive loss of affinity to H2O2 (K(m) = 5 microM) than that of the intact form (<5 microM, undeterminable) was monitored. Characterization of a series of Lys(191) point mutants manifested that the loss of affinity caused by a deprivation of positive charge born in Lys(191) and the loss of affinity resulted in the resistibility to H2O2. Disk inhibition assay with S. pombe cells overexpressing wild-type, Delta192 and Delta191 mutants evidenced that the truncated forms functioning in vitro as well as in vivo.     

Cytoplasmic differentiation and dedifferentiation in the fungusAllomyces

Summary The basophilic nuclear cap, main criterion of intracellular differentiation in the gametes ofAllomyces, has been studied as for its origin in the gametangia (ribosomal aggregation process combined with RNA-protein neosynthesis) and its disintegration in the zygotes at germination. At this stage, spatial separation of ribosomal material and phosphatase-positive mitochondria comes to an end through some kind of auxinic incitement. The RNA nuclear cap appears also as contributing some of its material for the DNA doubling preceding first mitosis in the germlings.

---

Résumé Le corps paranucléaire basophile, principal critère de la différenciation intracellulaire des gamétes d'Allomyces, a été étudié à deux points de vue: 1) son origine: aggrégation de ribosomes préexistants dans les gamétanges, combinée avec une néosynthèse d'ARN-protéines; 2) sa désintégration dans les zygotes en germination, mettant fin à la séparation spatiale du matériel ribosomique et des mitochondries phosphatase +, à la suite de quelque incitation de nature auxinique. La matière ribonucléique du corps paranucléaire paraît contribuer, dans une certaine mesure, au doublement de la teneur nucléaire en ADN intervenant avant la première mitose dans les plantules.

     

Regulation of LAT52 promoter activity during pollen tube growth through the pistil of Nicotiana alata.

The pollen-specific promoter of the LAT52 gene is known to direct expression of marker proteins during the last stages of pollen maturation and in very early pollen tube growth.We have examined the expression of LAT52-GUS during later stages of pollen tube growth in style and ovary of the relatively long-styled species Nicotiana alata. GUS activity was detected histochemically and found to be present in germinating pollen grains of N. alata and in tubes growing through the upper part of the style. No GUS activity was detected in 99% of the pollen tubes growing through the lower part of the style, but activity was present in tubes within the ovary. This finding indicates that the LAT52 promoter is regulated in growing pollen tubes, and is most active during the earliest and latest stages of pollen tube growth. GUS activity was also detected in some ovules, where it presumably marked the release of pollen tube cytoplasm into the ovule. The distribution of ovules with GUS activity within the ovary is not consistent with high-precision pollen tube guidance to the ovule. Received: 16 August 1999 / Revision accepted: 20 December 1999     

Regulation of cellular differentiation during Dictyostelium morphogenesis.

In Dictyostelium there are multiple prestalk cell types that have a complex pattern of directed cell movement during slug formation and culmination. Three extracellular signals, cyclic AMP, DIF and ammonia, control cell type differentiation. Recently there has been considerable progress in understanding their modes of action and interaction.     

Methodological approaches for studying apoplastic redox activity: 2. Regulation of peroxidase activity

This work is devoted to the study of mechanisms of substrate regulation of extracellular peroxidase (ECPOX) activity at a distant stress (wounding) signal transmission from aboveground organ (leaf) of wheat (Triticum aestivum L., cv. Kazanskaya Yubileinaya) seedlings to the roots. Along with the high dianizidine peroxidase activity, the extracellular solution manifested 3,4-dihydrooxi-L-phenylalanine peroxidase, ascorbate peroxidase, and catalase activities. Dianizidine peroxidases were represented by several isoforms and had broad substrate specificity. It was found that ECPOX was released from the roots into the growing solution and its activity in the solution increased with root growth. Excision of the apical leaf parts in seedlings induced a sharp activation of root ECPOX in the growing solution. The interaction between ECPOX substrates at oxidation in two- and three-component systems is demonstrated. The role of ECPOX in the control of ROS balance in the plant cell apoplast might be determined by competitive and complementary interactions between different peroxidase substrates. Such substrate-substrate regulation of peroxidase activities may be important for stress-induced oxidative burst in plant cells.     

Regulation of PRDX1 peroxidase activity by Pin1

Pin1 isomerizes the phosphorylated Ser/Thr-Pro peptide bonds and regulates the functions of its binding proteins by inducing conformational changes. Involvement of Pin1 in the aging process has been suggested based on the phenotype of Pin1-knockout mice and its interaction with lifespan regulator protein, p66^Shc. In this study, we utilize a proteomic approach and identify peroxiredoxin 1 (PRDX1), another regulator of aging, as a novel Pin1 binding protein. Pin1 binds to PRDX1 through interacting with the phospho-Thr⁹⁰-Pro⁹¹ motif of PRDX1, and this interaction is abolished when the Thr⁹⁰ of PRDX1 is mutated. The Pin1 binding motif, Thr-Pro, is conserved in the 2-Cys PRDXs, PRDX1–4 and the interactions between Pin1 and PRDX2–4 are also demonstrated. An increase in hydrogen peroxide buildup and a decrease in the peroxidase activity of 2-Cys PRDXs were observed in Pin1^?/? mouse embryonic fibroblasts (MEFs), with the activity of PRDXs restored when Pin1 was re-introduced into the cells. Phosphorylation of PRDX1 at Thr⁹⁰ has been shown to inhibit its peroxidase activity; however, how exactly the activity of PRDX1 is regulated by phosphorylation still remains unknown. Here, we demonstrate that Pin1 facilitates the protein phosphatase 2A-mediated dephosphorylation of PRDX1, which helps to explain the accumulation of the inactive phosphorylated form of PRDX1 in Pin1^?/? MEFs. Collectively, we identify Pin1 as a novel PRDX1 binding protein and propose a mechanism for Pin1 in regulating the metabolism of reactive oxygen species in cells.     

Effects of ageing on peroxidase activity and localization in radish (Raphanus sativus L.) seeds

Peroxidase activity was assayed in crude extracts of integument, cotyledons and embryo axis of radish seeds, deteriorated under accelerated ageing conditions. Over five days of ageing, in which germination decreased from 100 to 52%, the enzyme activity in integument was higher than that in other seed parts, increasing in the first days of ageing and then decreasing sharply in extremely aged seeds. Polyacrylamide gel electrophoresis analysis showed four peroxidase isoenzymes with MM of 98, 52.5, 32.8 and 29.5 kDa in the embryo axis of unaged seeds, and only the 32.8 and 29.5 kDa MM isoforms in the integument and cotyledons. In these parts of the seed, only the 29.5 kDa MM isoenzyme increased in activity in early days of ageing and decreased there-after. In the embryo axis, the 29.5 kDa MM isoenzyme activity increased slowly in the first day of ageing, while the 98 and 52.5 kDa MM isoenzyme activities disappeared. A cytochemical localization of peroxidase activity in the various tissues showed that main differences between unaged and extremely aged seeds occurred in the embryo axis.     

木质部细胞分化和脱分化的机理

木质部细胞的分化过程包括了密切不可分的细胞程序死亡和次生壁构建两个过程。现在的研究主要是将两个过程分开来研究,各自在细胞生物学和分子生物学上取得了不少进展,有关次生细胞壁方面的研究时间长,成果也较大。有关木质部细胞脱分化的研究相对较少,但也已取得了可喜的进展。     

Regulation of promoter activity of ferredoxin-dependent glutamate synthase

The GLU1 promoter for Fd-glutamate synthase (Fd-GOGAT, EC 1.4.1.7) of Arabidopsis thaliana (ecotype Columbia) confers the expression of the β-glucuronidase (GUS) reporter gene on transgenic tobacco (Nicotiana tabacum L. cv. Xanthi) transformed with the GLU1 promoter-GUS construct. Histochemical analysis reveals that GUS expression is associated with mesophyll and vascular tissue of 14-d-old tobacco seedlings. Red light substitutes for white light and induces a 2-fold increase in the GUS expression associated with mesophyll, veins and vascular tissue. Sucrose also serves as a signal to induce GUS expression in mesophyll and veins of cotyledons. Mature leaves, adapted to the dark for 3 d, conserves the red light- and white light-dependent inductions of GUS activity, while GUS expression is repressed by white light in roots. The mesophyll-located expression of the GLU1 promoter suggests that Fd-glutamate synthase has a function in the photorespiratory ammonium cycling and primary ammonium assimilation. The distinct location of GLU1 promoter expression in the vascular tissue supports the view that Fd-glutamate synthase synthesises glutamate for intracellular transport of glutamine and glutamate.     

Regulation of cytoplasmic tubulin carboxypeptidase activity during neural and muscle differentiation: characterization using a microtubule-based assay.

A cycle of posttranslational modification of alpha-tubulin has previously been described in higher eukaryotes, in which a C-terminal tyrosine residue is removed and replaced by two complementary cytoplasmic enzymes. The activity of the detyrosinating enzyme, tubulin carboxypeptidase (TCP), and its potential for regulating the level of detyrosinated (Glu) subunits in microtubules (MTs) is of great interest, since TCP catalyzes the primary modification of tubulin and since the level of Glu alpha-tubulin in MTs increases during a variety of differentiative and morphogenetic events. As a first step in examining the role of TCP in cellular morphogenesis, it was necessary to develop an assay for TCP with sufficient sensitivity and specificity to detect TCP activity during these events. Unlike previously described assays for TCP, ours makes use of the affinity TCP exhibits for MTs. NGF-induced neurite outgrowth in PC-12 cells was accompanied by a moderate (approximately 2-fold) increase in TCP activity, while myogenesis of L6 cells resulted in an almost insignificant decrease in activity. Measurements of TCP activity during differentiation were correlated with the level of extract Tyr tubulin, which increased (approximately 37%) during neurite outgrowth and was unchanged during myogenic differentiation. Our results suggest that TCP activity is regulated relative to its substrate, Tyr tubulin, and that changes in MT dynamics, rather than enzymatic activities, are the primary determinants of MT posttranslational modification state during differentiation. In addition, the assay we have devised for TCP and the characterization of TCP during differentiation may allow the future delineation of the mechanism(s) of regulation of TCP and the role this enzyme plays in modulating MT function during differentiation.