Fumiaki Maruo

Denitrification, a novel type of respiratory metabolism in fungal mitochondrion.

Subcellular localization and coupling to ATP synthesis were investigated with respect to the denitrifying systems of two fungi, Fusarium oxysporum and Cylindrocarpon tonkinense. Dissimilatory nitrate reductase of F. oxysporum or nitrite reductase of C. tonkinense could be detected in the mitochondrial fraction prepared from denitrifying cells of each fungus. Fluorescence immunolocalization, cofractionation with mitochondrial marker enzymes, and cytochromes provided evidence that the denitrifying enzymes are co-purified with mitochondria. Respiratory substrates such as malate plus pyruvate, succinate, and formate were effective donors of electrons to these activities in the mitochondrial fractions. Moreover, nitrite and nitrate reduction were shown to be coupled to the synthesis of ATP with energy yields (P:NO3− or P:2e ratios) of 0.88 to 1.4, depending upon whether malate/pyruvate or succinate were provided as substrates. Nitrate or nitrite reductase activity was inhibited by inhibitors such as rotenone, antimycin A, and thenoyltrifluoroacetone. Thus, fungal denitrification activities are localized to mitochondria and are coupled to the synthesis of ATP. The existence of these novel respiration systems are discussed with regard to the origin and evolution of mitochondria.

Visual cycle protein RPE65 persists in new retinal cells during retinal regeneration of adult newt

Adult newts can regenerate their entire retina through transdifferentiation of the retinal pigment epithelium (RPE). The objective of this study was to redescribe the retina regeneration process by means of modern biological techniques. We report two different antibodies (RPE‐No.112 and MAB5428) that recognize the newt homolog of RPE65, which is involved in the visual cycle and exclusively label the RPE cell‐layer in the adult newt eye. We analyzed the process of retinal regeneration by immunohistochemistry and immunoblotting and propose that this process should be divided into nine stages. We found that the RPE65 protein is present in the RPE‐derived new retinal rudiment at 14 days postoperative (po) and in the regenerating retinas at the 3–4 cell stage (19 days po). These observations suggest that certain characteristics of RPE cells overlap with those of retinal stem/progenitor cells during the period of transdifferentiation. However, RPE65 protein was not detected in either retinal stem/progenitor cells in the ciliary marginal zone (CMZ) of adult eyes or in neuroepithelium present during retina development, where it was first detected in differentiated RPE. Moreover, the gene expression of RPE65 was drastically downregulated in the early phase of transdifferentiation (by 10 days po), while those of Connexin43 and Pax‐6, both expressed in regenerating retinas, were differently upregulated. These observations suggest that the RPE65 protein in the RPE‐derived retinal rudiment may represent the remainder after protein degradation or discharge rather than newly synthesized protein. J. Comp. Neurol. 40:391–407, 2006.

A developmentally regulated switch from stem cells to dedifferentiation for limb muscle regeneration in newts

The newt, a urodele amphibian, is able to repeatedly regenerate its limbs throughout its lifespan, whereas other amphibians deteriorate or lose their ability to regenerate limbs after metamorphosis. It remains to be determined whether such an exceptional ability of the newt is either attributed to a strategy, which controls regeneration in larvae, or on a novel one invented by the newt after metamorphosis. Here we report that the newt switches the cellular mechanism for limb regeneration from a stem/progenitor-based mechanism (larval mode) to a dedifferentiation-based one (adult mode) as it transits beyond metamorphosis. We demonstrate that larval newts use stem/progenitor cells such as satellite cells for new muscle in a regenerated limb, whereas metamorphosed newts recruit muscle fibre cells in the stump for the same purpose. We conclude that the newt has evolved novel strategies to secure its regenerative ability of the limbs after metamorphosis.

The newt reprograms mature RPE cells into a unique multipotent state for retinal regeneration.

The reprogramming of retinal pigment epithelium (RPE) cells in the adult newt immediately after retinal injury is an area of active research for the study of retinal disorders and regeneration. We demonstrate here that unlike embryonic/larval retinal regeneration, adult newt RPE cells are not directly reprogrammed into retinal stem/progenitor cells; instead, they are programmed into a unique state of multipotency that is similar to the early optic vesicle (embryo) but preserves certain adult characteristics. These cells then differentiate into two populations from which the prospective-neural retina and -RPE layers are formed with the correct polarity. Furthermore, our findings provide insight into the similarity between these unique multipotent cells in newts and those implicated in retinal disorders, such as proliferative vitreoretinopathy, in humans. These findings provide a foundation for biomedical approaches that aim to induce retinal self-regeneration for the treatment of RPE-mediated retinal disorders.

Monoclonal antibodies against Drosophila ovaries: their reaction with ovarian and embryonic antigens

A library of monoclonal antibodies (MAbs) against Drosophila ovarian antigens was established. Each of the MAbs was characterized by its immunohistochemical binding pattern to sections from egg chambers at various stages of oogenesis. Sixteen of the 18 MAbs were found to bind to antigens in mature oocytes. Among the 16 antigens, two were also located in cytoplasm of cell types in the egg chamber other than the oocyte, at all stages of oogenesis. Four made their appearance in nurse cell cytoplasm at mid-vitellogenic stages and shifted to oocyte cytoplasm at a later stage, and ten appeared at the vitellogenic stage and confined their distribution to oocyte cytoplasm. All these antigens were distributed evenly in cytoplasm of mature oocytes. However, some of these antigens were noticed to change their distribution during early embryogenesis as to be localized in a specific region of embryos.

Localization of a DNA topoisomerase II to mitochondria inDictyostelium discoideum: Deletion mutant analysis and mitochondrial targeting signal presequence

DNA topoisomerase II ofDictyostelium discoideum (TopA), the gene (topA) encoding which we cloned, was shown to have an additional N-terminal region which contains a putative mitochondrial targeting signal presequence. We constructed overexpression mutants which expressed the wild-type or the N-terminally deleted enzyme, and examined its localization by immunofluorescence microscopy and proteinase K digestion experiment. These experiments revealed that the enzyme is located in the mitochondria by virtue of the additional N-terminal region. Furthermore, in the cell extract depleted the enzyme by immunoprecipitation, nuclear DNA topoisomerase II activity was not decreased. These results confirmed that TopA is located in the mitochondria, even through its amino acid sequence is highly similar to those of nuclear type topoisomerase II of other organisms. Thus, this report is the first to establish the location of the mitochondrial targeting signal presequence in DNA topoisomerase II and in proteins ofD. discoideum directly by analyzing deletion mutants.

Expression of Two Classes of Pax6 Transcripts in Reprogramming Retinal Pigment Epithelium Cells of the Adult Newt

The adult newt has the remarkable ability to regenerate a functional retina from retinal pigment epithelium (RPE) cells, even when the neural retina (NR) is completely lost from the eye. In this system, RPE cells are reprogrammed into a unique state of multipotent cells, named RPESCs, in an early phase of retinal regeneration. However, the signals that trigger reprogramming remain unknown. Here, to approach this issue we focused on Pax6, a transcription factor known to be expressed in RPESCs. We first identified four classes (v1, v2, v3 and v4) of Pax6 variants in the eye of adult newt, Cynops pyrrhogaster. These variants were expressed in most tissues of the intact eye in different combinations but not in the RPE, choroid or sclera. On the basis of this information, we investigated the expression of Pax6 in RPE cells after the NR was removed from the eye by surgery (retinectomy), and found that two classes (v1 and v2) of Pax6 variants were newly expressed in RPE cells 10 days after retinectomy, both in vivo and in vitro (RLEC system). In the RLEC system, we found that Pax6 expression is mediated through a pathway separate from the MEK-ERK pathway, which is required for cell cycle re-entry of RPE cells. These results predict the existence of a pathway that may be of fundamental importance to a better understanding of the reprogramming of RPE cells in vivo.

Turning the fate of reprogramming cells from retinal disorder to regeneration by Pax6 in newts.

The newt, a urodele amphibian, has an outstanding ability– even as an adult –to regenerate a functional retina through reprogramming and proliferation of the retinal pigment epithelium (RPE) cells, even though the neural retina is completely removed from the eye by surgery. It remains unknown how the newt invented such a superior mechanism. Here we show that disability of RPE cells to regenerate the retina brings about a symptom of proliferative vitreoretinopathy (PVR), even in the newt. When Pax6, a transcription factor that is re-expressed in reprogramming RPE cells, is knocked down in transgenic juvenile newts, these cells proliferate but eventually give rise to cell aggregates that uniformly express alpha smooth muscle actin, Vimentin and N-cadherin, the markers of myofibroblasts which are a major component of the sub-/epi-retinal membranes in PVR. Our current study demonstrates that Pax6 is an essential factor that directs the fate of reprogramming RPE cells toward the retinal regeneration. The newt may have evolved the ability of retinal regeneration by modifying a mechanism that underlies the RPE-mediated retinal disorders.

Monoclonal antibodies inhibiting mating reactivity exclusively of odd mating types in Paramecium caudatum

Summary Paramecium caudatum has the bipolar system of mating types and thus each syngen consists of two complementary mating types, even and odd types. Mating types are distinguished by the agglutination reaction when complementary mating types are mixed, but the substances (called the mating type substance) involved in specific cell recognition between complementary mating types have not so far been identified as the molecules in Paramecium. To identify the mating type substances we obtained 5 monoclonal antibodies inhibiting the mating reactivity of odd mating type of syngen 3. Cilia detached from the highly reactive odd mating type, pretreated with salt alcohol, were injected into mice and 5 monoclonal antibodies (OmA, OmB, OmC, OmD and OmE) were obtained after screening. All of them inhibited mating reactivity of all odd strains of syngen 3 examined but of no even strain without inhibiting action on the ciliary movement. Among 7 other syngens than syngen 3, cross reactivity in inhibition of mating reactivity, against odd types was observed to some degree in syngen 1, 5, 13, but not in syngen 4, 6, 12 when the four antibodies except OmB were used. Thus, the inhibiting action has no syngen specificity. Localization of the antigen recognized by these antibodies was examined by indirect immunofluorescence. Immunofluorescence was observed on the cilia of the ventral surface, mostly in the anterior tip which is known to be reactive in mating clump formation, and looked like beads in a line on the surface of the cilia. The mating type specificity of the inhibiting action and the localization on the cell strongly suggest that these antibodies recognize the mating type substances.

Implications of a Multi-Step Trigger of Retinal Regeneration in the Adult Newt

The newt is an amazing four-limbed vertebrate that can regenerate various body parts including the retina. In this animal, when the neural retina (NR) is removed from the eye by surgery (retinectomy), both the NR and the retinal pigment epithelium (RPE) eventually regenerate through the process of reprogramming and proliferation of RPE cells. Thus far, we have pursued the onset mechanism of adult newt retinal regeneration. In this study, using an in vitro system, we found that both mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) kinase (MEK)-ERK and β-catenin were involved in cell cycle re-entry of RPE cells. MEK-ERK signaling activity in RPE cells was strengthened by retinectomy, and nuclear translocation of β-catenin in RPE cells was induced by attenuation of cell–cell contact, which was promoted by incision of the RPE or its treatment with ethylene glycol tetraacetic acid (EGTA). EGTA is a Ca2+ chelator that disrupts cadherin-mediated cell–cell adhesion. Reinforcement of MEK-ERK signaling activity was a prerequisite for nuclear translocation of β-catenin. These results suggest that retinectomy followed by attenuation of cell–cell contact may trigger cell cycle re-entry of RPE cells. This study, together with our previous findings concerning the proliferation and multipotency of adult newt RPE cells, provides insight into the mechanism of the multi-step trigger in which the onset of retinal regeneration in the adult newt is rigorously controlled.