Effects of antibiotics that inhibit the bacterial peptidoglycan synthesis pathway on moss chloroplast division

Moss chloroplasts should prove useful for studying the cyanobacteria-derived system in chloroplasts. To determine the effects of antibiotics that inhibit bacterial peptidoglycan synthesis, the numbers of chloroplasts in treated Physcomitrella patens cells were counted. Ampicillin and D-cycloserine caused a rapid decrease in the number of chloroplasts per cell. Fosfomycin affected half of the cells, while vancomycin affected a few cells. Conversely, bacitracin had no effect. With the decrease in chloroplast number, macrochloroplasts appeared in antibiotic-treated cells. Removal of the antibiotics resulted in the recovery of chloroplast number, suggesting that the decrease in number was directly dependent on the antibiotic treatment. Microscopic observations showed that the decrease in the number of chloroplasts resulted from cell division without chloroplast division. These results suggest that enzymes derived from the bacterial peptidoglycan synthesis pathway are related to moss chloroplast division.     

Isolation of mutant lines with decreased numbers of chloroplasts per cell from a tagged mutant library of the moss Physcomitrella patens

Eleven mutant lines exhibiting decreased numbers of chloroplasts per cell were isolated from 8 800 tagged mutant lines of Physcomitrella patens by microscopic observations. Chloronema subapical cells in wild-type plants had a mean of 48 chloroplasts, whereas chloroplast numbers in subapical cells in mutant lines 215 and 222 decreased to 75 % of that in the wild type. Seven mutant lines - 473, 122, 221, 129, 492, 207, and 138 - had about half as many chloroplasts as the wild type. Mutant line 11 had a few remarkably enlarged chloroplasts, and mutant line 347 had chloroplasts of various sizes. Whereas the cell volume was the same as in the wild type in mutant lines 222, 473, 221, 129, 492, and 207, the cell volume of the other mutants increased. The chloroplast number of leaf cells was the same as that of chloronema cells in each mutant line when gametophores could be formed. Treatment with ampicillin decreased the number of chloroplasts in all mutant lines. Southern hybridization using DNA in tags as probes showed that only one insertion occurred in mutant lines 473 and 221. To determine whether the tagged DNA inserted into the known genes for plastid division, we isolated the PpMinD1, PpMinD2, and PpMinE1 genes. Genomic polymerase chain reaction analysis showed that the PpFtsZ and PpMinD/E genes were not disrupted by the insertion of the tags in mutant lines 11 and 347, respectively.     

Characterization of chloroplast division using the Arabidopsis mutant arc5.

arc5 is a chloroplast division mutant of Arabidopsis thaliana. To identify the role of ARC5 in the chloroplast replication process we have followed the changes in arc5 chloroplasts during their perturbed division. ARC5 does not affect proplastid division but functions at a later stage in chloroplast development. Chloroplasts in developing mesophyll cells of arc5 leaves do not increase in number and all of the chloroplasts in mature leaf cells show a central constriction. Young arc5 chloroplasts are capable of initiating the division process but fail to complete daughter-plastid separation. Wild-type plastids increase in number to a mean of 121 after completing the division process, but in the mutant arc5 the approximately 13 plastids per cell are still centrally constricted but much enlarged. As the arc5 chloroplasts expand and elongate without dividing, the internal thylakoid membrane structure becomes flexed into an undulating ribbon. We conclude that the ARC5 gene is necessary for the completion of the last stage of chloroplast division when the narrow isthmus breaks, causing the separation of the daughter plastids.     

烟草NtFtsZ2-1基因参与叶绿体分裂和扩大的调节

叶绿体虽然是植物细胞内一种极其重要的细胞器,但其分裂的分子机制尚不很清楚。已经证明FtsZ蛋白作为真核细胞分裂装置的一个关键成分,参与叶绿体的分裂过程。烟草的FtsZ基因属于2个不同的家族,在对NtFtsZ1家族成员研究的基础上,用正义和反义表达技术研究了NtFtsZ2家族成员NtFtsZ2-1基因在转基因烟草中的功能。显微分析结果表明NtFtsZ2-1基因的表达水平异常增强或减弱都会严重干扰叶绿体的正常分裂过程,导致叶绿体在形态和数目上的异常（体积明显增大,数目显著减少）,而单个叶肉细胞中叶绿体的总表面积在正反义转基因烟草和野生型烟草之间保持了相对稳定,没有发生明显的变化。同时还证明NtFtsZ2-1基因表达的变化对叶绿素含量和叶绿体的光合作用能力没有直接的影响。据此我们认为NtFtsZ2-1基因参与叶绿体的分裂和体积的扩大,其表达水平的波动会改变植物中叶绿体的数目和大小,而且在叶绿体的数目与体积之间可能存在一种补偿机制,保证叶绿体能最大限度地吸收光能,从而使光合作用得以正常进行。     

The evolution of the regulatory mechanism of chloroplast division

Chloroplasts arose from a cyanobacterial endosymbiont and multiply by division, reminiscent of their free-living ancestor. However, chloroplasts can not divide by themselves, and the division is performed and controlled by proteins that are encoded by the host nucleus. The continuity of chloroplasts was originally established by synchronization of endosymbiotic cell division with host cell division, as seen in existent algae. In contrast, land plant cells contain multiple chloroplasts, the division of which is not synchronized, even in the same cell. Land plants have evolved cell and chloroplast differentiation systems in which the size and number of chloroplasts (or other types of plastids) change along with their respective cellular function by changes in the division rate. We recently reported that PLASTID DIVISION (PDV) proteins, land-plant specific components of the chloroplast division apparatus, determined the rate of chloroplast division. The level of PDV protein is regulated by the cell differentiation program based on cytokinin, and the increase or decrease of the PDV level gives rise to an increase or decrease in the chloroplast division rate. Thus, the integration of PDV proteins into the chloroplast division machinery enabled land plant cells to change chloroplast size and number in accord with the fate of cell differentiation.Key words: chloroplast division, cell cycle, cell differentiation, cytokinin, endosymbiosis, evolution     

arc6, A Fertile Arabidopsis Mutant with Only Two Mesophyll Cell Chloroplasts

A novel mutant of Arabidopsis thaliana, arc6 (accumulation and replication of chloroplasts), has been isolated from a transfer DNA-mutagenized population of Arabidopsis seedlings. arc6 has the most extreme arc mutant phenotype we have yet described, with only one to three chloroplasts per leaf mesophyll cell compared to a mean of 83 in cells of the wild-type var Wassilewskija. The chloroplasts of arc6 are 20-fold larger than wild-type chloroplasts.Chloroplast division is almost certainly precluded in arc6 mesophyll cells, since chloroplast number per cell does not increase during mesophyll cell expansion. arc6 chloroplasts are long and thin in cross-section and only one-half the width of wild-type chloroplasts and the arrangement of thylakoid membranes is largely unaltered. arc6 segregates as a monogenic recessive nuclear mutation in a normal Mendelian manner and the arc6 phenotype is stably inherited for at least four generations. arc6 plants grow normally and are fertile, although the rosette leaves appear curled and twisted. arc6 plants accumulate 70 to 75% of the biomass of wild type. The phenotype of this novel mutant is discussed in relation to the nature of the control of chloroplast division in leaf cells.     

Chloroplast division in higher plants requires members of two functionally divergent gene families with homology to bacterial ftsZ.

The division of plastids is critical for viability in photosynthetic eukaryotes, but the mechanisms associated with this process are still poorly understood. We previously identified a nuclear gene from Arabidopsis encoding a chloroplast-localized homolog of the bacterial cell division protein FtsZ, an essential cytoskeletal component of the prokaryotic cell division apparatus. Here, we report the identification of a second nuclear-encoded FtsZ-type protein from Arabidopsis that does not contain a chloroplast targeting sequence or other obvious sorting signals and is not imported into isolated chloroplasts, which strongly suggests that it is localized in the cytosol. We further demonstrate using antisense technology that inhibiting expression of either Arabidopsis FtsZ gene (AtFtsZ1-1 or AtFtsZ2-1) in transgenic plants reduces the number of chloroplasts in mature leaf cells from 100 to one, indicating that both genes are essential for division of higher plant chloroplasts but that each plays a distinct role in the process. Analysis of currently available plant FtsZ sequences further suggests that two functionally divergent FtsZ gene families encoding differentially localized products participate in chloroplast division. Our results provide evidence that both chloroplastic and cytosolic forms of FtsZ are involved in chloroplast division in higher plants and imply that important differences exist between chloroplasts and prokaryotes with regard to the roles played by FtsZ proteins in the division process.     

金黄滴虫叶绿体拟核的荧光镜检及电镜观察

金黄滴虫细胞在用DNA特异的荧光染料DAPI处理后,在荧光显微镜下细胞核和叶绿体拟核均散发蓝色荧光,穗晰可见。每一叶绿体有一拟核,拟核沿叶绿体的周缘排列,形状相当于叶绿体的轮廓,成不规则的两叶形环。环的全长约在20—30υm之间。 拟核环大多是单线的,有些拟核环出现或短或长的双线部分,有时甚至几乎整个拟核环都可变为双线。这表明拟核环通过“纵裂”而形成双环,在叶绿体分裂时,分别进入两个子叶绿体。这一情况在电镜照片上得到了证实。 叶绿体分裂和细胞分裂之间似乎不存在严格的相关性,这是导致细胞中叶绿体数目多于1个的原因。     

SYNCHRONIZATION OF CHLOROPLAST DIVISION IN THE ULTRAMICROALGA CYANIDIOSCHYZON MEROLAE (RHODOPHYTA) BY TREATMENT WITH LIGHT AND APHIDICOLIN

A system of highly synchronized chloroplast divisions was developed in the unicellular red alga Cyanidioschyzon merolae De Luca, Taddei, & Varano. Chloroplast divisions were examined by epifluorescence microscopy following treatments with light and inhibitors. When the cells during stationary phase were transferred into a new medium under a 12:12 h LD cycle, chloroplasts, mitochondria, and cell nuclei divided synchronously in that order soon after the initiation of dark periods. More than 40% of the cells contained dividing chloroplasts. To obtain a system of highly synchronized cell division and chloroplast division, the cells synchronized by a 12:12 h LD cycle were treated with various inhibitors. Nocodazole and propyzamide did not affect cell and organelle divisions, whereas aphidicolin markedly inhibited cell-nuclear divisions and cytokinesis and induced a delay in chloroplast division. More than 80% of the cells contained dividing chloroplasts when cells synchronized by light were treated with aphidicolin for 12 h. This synchronized system will be useful for studies of the molecular and cellular mechanisms of organelle divisions .     

Behavior of Chloroplast Nucleus during Chloroplast Development and Degeneration in Chlamydomonas reinhardii

Changes in morphology of chloroplast nuclei (cp-nuclei), totalcp-DNA content, number of cp-nuclei, oxygen-evolution activityand chlorophyll (a and b) content were examined during the degenerationand development of chloroplasts, using Chlamydomonas reinhardiicells which had been incubated on solid medium for various periods. Under 4'-6-diamidino-2-phenylindole (DAPI) epifluorescence microscopy,each cell that had been incubated for 7 days had one cell nucleus,one cup-shaped chloroplast and about 10 small, dispersed cp-nucleiin the chloroplast. One day after incubation of these cellson fresh medium, the cell volume and cp-nuclei increased insize 2-3 fold, but rapidly decreased in size after cell division.After about 7 days of incubation, cells ceased to divide andcp-nuclei began to associate with each other. At about 20 daysthey formed a ring-shaped structure surrounding the pyrenoid,followed by condensation into one cp-nuclear particle near thepyrenoid. When 41-day-old cells, having only one cp-nucleus,were reinoculated on fresh solid medium, the cp-nucleus increasedin size 2–3 fold, divided into several cp-nuclear particlesand then dispersed into the chloroplast, forming a bead-likestructure, before cell division. From microscopic fluorometry,a 4-fold increase in total cp-DNA content per chloroplast, withoutan increase in the number of cp-nuclear particles per chloroplast,occurred one day after the start of the experiment and one dayafter reinoculation of 41-day-old cells onto fresh medium. Theprocess of condensation of dispersed cp-nuclear particles intoone cp-nucleus during degeneration of the chloroplast was notaccompanied by any change in total cp-DNA content per chloroplast.A large peak of oxygen-evolution (0.6–0.9 pmoles/cell/hour)was seen one day after inoculation and reinoculation of thecells. The chlorophyll content (a+b) was high (1.2–2.2pg/cell) during the first week of incubation, after which itgradually decreased. (Received December 18, 1985; Accepted April 2, 1986)     

Expression of the nucleus-encoded chloroplast division genes and proteins regulated by the algal cell cycle

Chloroplasts have evolved from a cyanobacterial endosymbiont and their continuity has been maintained by chloroplast division, which is performed by the constriction of a ring-like division complex at the division site. It is believed that the synchronization of the endosymbiotic and host cell division events was a critical step in establishing a permanent endosymbiotic relationship, such as is commonly seen in existing algae. In the majority of algal species, chloroplasts divide once per specific period of the host cell division cycle. In order to understand both the regulation of the timing of chloroplast division in algal cells and how the system evolved, we examined the expression of chloroplast division genes and proteins in the cell cycle of algae containing chloroplasts of cyanobacterial primary endosymbiotic origin (glaucophyte, red, green, and streptophyte algae). The results show that the nucleus-encoded chloroplast division genes and proteins of both cyanobacterial and eukaryotic host origin are expressed specifically during the S phase, except for FtsZ in one graucophyte alga. In this glaucophyte alga, FtsZ is persistently expressed throughout the cell cycle, whereas the expression of the nucleus-encoded MinD and MinE as well as FtsZ ring formation are regulated by the phases of the cell cycle. In contrast to the nucleus-encoded division genes, it has been shown that the expression of chloroplast-encoded division genes is not regulated by the host cell cycle. The endosymbiotic gene transfer of minE and minD from the chloroplast to the nuclear genome occurred independently on multiple occasions in distinct lineages, whereas the expression of nucleus-encoded MIND and MINE is regulated by the cell cycle in all lineages examined in this study. These results suggest that the timing of chloroplast division in algal cell cycle is restricted by the cell cycle-regulated expression of some but not all of the chloroplast division genes. In addition, it is suggested that the regulation of each division-related gene was established shortly after the endosymbiotic gene transfer, and this event occurred multiple times independently in distinct genes and in distinct lineages.     

ppGpp inhibits peptide elongation cycle of chloroplast translation system in vitro

Chloroplasts possess common biosynthetic pathways for generating guanosine 3',5'-(bis)pyrophosphate (ppGpp) from GDP and ATP by RelA-SpoT homolog enzymes. To date, several hypothetical targets of ppGpp in chloroplasts have been suggested, but they remain largely unverified. In this study, we have investigated effects of ppGpp on translation apparatus in chloroplasts by developing in vitro protein synthesis system based on an extract of chloroplasts isolated from pea (Pisum sativum). The chloroplast extracts showed stable protein synthesis activity in vitro, and the activity was sensitive to various types of antibiotics. We have demonstrated that ppGpp inhibits the activity of chloroplast translation in dose-effective manner, as does the toxic nonhydrolyzable GTP analog guanosine 5'-(β,γ-imido)triphosphate (GDPNP). We further examined polyuridylic acid-directed polyphenylalanine synthesis as a measure of peptide elongation activity in the pea chloroplast extract. Both ppGpp and GDPNP as well as antibiotics, fusidic acid and thiostrepton, inhibited the peptide elongation cycle of the translation system, but GDP in the similar range of the tested ppGpp concentration did not affect the activity. Our results thus show that ppGpp directly affect the translation system of chloroplasts, as they do that of bacteria. We suggest that the role of the ppGpp signaling system in translation in bacteria is conserved in the translation system of chloroplasts.     

Isolation and phenotypic characterization ofChlamydomonas reinhardtii mutants defective in chloroplast DNA segregation

Summary Each wild-typeChlamydomonas reinhardtii cell has one large chloroplast containing several nuclei (nucleoids). We used DNA insertional mutagenesis to isolate Chlamydomonas mutants which contain a single, large chloroplast (cp) nucleus and which we namedmoc (monokaryotic chloroplast). DAPI-fluorescence microscopy and microphotometry observations revealed thatmoc mutant cells only contain one cp-nucleus throughout the cell division cycle, and that unequal segregation of cpDNA occurred during cell division in themoc mutant. One cell with a large amount of cpDNA and another with a small amount of cpDNA were produced after the first cell division. Unequal segregation also occurred in the second cell division, producing one cell with a large amount (about 70 copies) of cpDNA and three other cells with a small amount (only 2–8 copies) of cpDNA. However, most individualmoc cells contained several dozen cpDNA copies 12 h after the completion of cell division, suggesting that cpDNA synthesis was activated immediately after chloroplast division. In contrast to the cpDNA, the mitochondrial (mt) DNA of themoc mutants was observed as tiny granules scattered throughout the entire cell. These segregated to each daughter cell equally during cell division. Electron-microscopic observation of the ultrastructure ofmoc mutants showed that a low-electron-density area, which was identified as the cp-nucleus by immunoelectron microscopy with anti-DNA antibody, existed near the pyrenoid. However, there were no other structural differences between the chloroplasts of wild-type cells andmoc mutants. The thylakoid membranes and pyrenoid were identical. Therefore, we propose that the novelmoc mutants are only defective in the dispersion and segregation of cpDNA. This strain should be useful to elucidate the mechanism for the segregation of cpDNA.Abbreviations DAPI 4,6-diamidino-2-phenylindole - VIMPCS video-intensified microscope photon-counting system     

The HC-pro protein of potato virus Y interacts with NtMinD of tobacco

Potato virus Y (PVY) infections often lead to altered numbers of host plant chloroplasts, as well as changes in morphology and inhibited photosynthesis. The multifunctional protein helper component-proteinase, HC-Pro, has been identified in PVY-infected leaf chloroplasts. We used yeast two-hybrid and bimolecular fluorescence complementation assays to demonstrate that HC-Pro can interact with the chloroplast division-related factor NtMinD in yeast and tobacco cells, respectively. In addition, we confirmed that residues 271 to 314 in NtMinD are necessary for its interaction with PVY HC-Pro in a yeast two-hybrid analysis using four NtMinD deletion mutants. These residues are necessary for the dimerization of NtMinD, which plays a vital role in chloroplast division. Thus, PVY HC-Pro may affect NtMinD activity by inhibiting the formation of NtMinD homodimers, and this may interfere with chloroplast division and contribute to changes in the numbers of chloroplast per cell observed in PVY-infected plants.     

Chloroplast division polarity,a marker of cell division planes during morphogenesis inBangia vermicularis Harvey (Rhodophyceae)

Summary Ultrastructural observations of dividing cells inBangia vermicularis revealed a type of chloroplast division (plastokinesis) not previously reported in the red algae. The polarity of this prekaryokinetic process serves as a reliable marker of the plane of cytokinesis, a key factor in establishing thallus morphology. At the onset of division one or more invaginations develop in the envelope of the large, lobed chloroplast and proceed centripetally through the stroma in the plane of the thylakoids, forming narrow cytoplasmic channels (CCs). The thylakoids are realigned somewhat, but are not constricted as the chloroplast is divided into two or more units. The number of resulting chloroplasts and the orientation of the CCs are dependent on cell type. Distinctive cylindrical cells at the base of the filamentous region, immediately distal to the holdfast, are shorter than broad and contain a central nucleus surrounded by a doughnutshaped chloroplast. The cylindrical morphology of the thallus is established early in the first periclinal division as multiple plastokinesis commences, generating several radially-arranged daughter chloroplasts. Cleavage of the original chloroplast is completed during subsequent cell divisions in the initial developmental stage, finally resulting in eight chloroplasts that are distributed to an equal number of wedge-shaped radial cells. Cells distal to the actively dividing basal cells are cuboidal and have a peripheral nucleus. Division of the single chloroplast prior to karyokinesis in these cells results in two or four daughter chloroplasts according to cell type. During or following plastokinesis, multilamellar bodies derived from the CE appear to serve as the source of membranes for the developing septum in the channels. Septa link to proliferations of the plasmalemma in areas of slight cell wall (CW) indentations, and are completed between daughter nuclei after karyokinesis, producing a cleavage channel. Subsequently, primary CW material is deposited between the two septal membranes. The shape and arrangement of daughter cells in each of the developmental stages in the thallus are defined by the planes of cell division. These are indicated by both the orientation of CCs and the polar orientation of nuclear division which is always at right angles to the CC.Abbreviations CC cytoplasmic channel - CE chloroplast envelope - CW cell wall - ER endoplasmic reticulum - MLB multilamellar body     

A Genetic Analysis of Chloroplast Division and Expansion in Arabidopsis thaliana

A nuclear recessive mutant of Arabidopsis thaliana, arc5, has been isolated in which there is no significant increase in chloroplast number during leaf mesophyll cell expansion and in which there are only 13 chloroplasts per mesophyll cell compared with 121 in wild-type cells. Mature arc5 chloroplasts in fully expanded mesophyll cells are 6-fold larger than in wild-type cells. A large proportion of arc5 chloroplasts also show some degree of central constriction, suggesting that the mutation has prevented the completion of the chloroplast division process. To examine the interaction of arc loci, a double mutant was constructed between arc1, a mutant possessing many small chloroplasts, and arc5. A second double mutant was also constructed between arc3, a previously discovered mutant also possessing few large chloroplasts per cell, and arc1. Analysis of these double mutants shows that chloroplast number per mesophyll cell is greater when arc5 and arc3 mutations are expressed in the arc1 background than when expressed alone. The cell-specific nature of arc mutants was also analyzed. The phenotypic traits characteristic of arc3 and arc5 are a reduction in chloroplast number and an increase in chloroplast size in mesophyll cells: these changes are also observed in reduced form in the epidermal and guard cell chloroplasts of arc3 and arc5 plants. Analysis of parenchyma sheath cell chloroplasts suggests that in leaves of arc1 plants the normal developmental distinction between mesophyll and parenchyma sheath chloroplasts is perturbed. The relevance of these findings to the analysis of the control of chloroplast division in mesophyll cells is discussed.     

COORDINATNE NUCLEAR AND CHLOROPLAST DIVISION IN UNILOCULAR SPORANGIA OF LAMINARIA ANGUSTATA (LAMINARIALES,PHAEOPHYCEAE)1

Changes in the number of nuclei and chloroplasts were examined during the process of unispore formation in unilocular sporangia of Laminaria angustata. Just before meiosis, eight chloroplasts were always present in unilocular sporangial mother cells. The number of chloroplasts remained constant through meiosis. After the resulting four nuclei divided again (third nuclear division), a close association between a nucleus and a chloroplast developed among each of the eight nuclei and eight chloroplasts. The eight chloroplasts divided ahost synchronously before the synchronous division of the eight nuclei. Following the 16 nucleate stage with 16 chloroplasts and the final 32 nucleate stage with 32 chloroplasts, 32 unispores, each with a nucleus and a chloroplast, were fomd in unilocular sporangza of L. angustata. Immunofluorescence microscopy using an anti-centrin antibody showed that two anticentrin-stained structures (as future mitotic poles) occurred adjacent to each of the premitotic four nuclei, and each spot was located near a chloroplast. Therefore, after the third division, each of the eight nuclei established close contact with a chloroplast presumably mediated by the centrosomes.     

Regulation of Brassica rapa chloroplast proliferation in vivo and in cultured leaf disks

Summary. To understand the regulatory mechanisms of chloroplast proliferation, chloroplast replication was studied in cultured leaf disks cut from plants of 25 species. In leaf disks from Brassica rapa var. perviridis, the number of chloroplasts per cell increased remarkably in culture. We examined chloroplast replication in this plant in vivo and in culture media with and without benzyladenine, a cytokinin. In whole plants, leaf cells undergo two phases from leaf emergence to full expansion: an early proliferative stage, in which mitosis occurs, and a differentiational stage after mitosis has diminished. During the proliferative stage, chloroplast replication keeps pace with cell division. In the differentiational phase, cell division ceases but chloroplast replication continues for two or three more cycles, with the number of chloroplasts per cell reaching about 60. In the leaf disks, the number of chloroplasts per cell increased from about 18 to 300 without benzyladenine, and to over 600 with benzyladenine, indicating that this cytokinin enhances chloroplast replication in cultured tissue. We also studied changes in ploidy and cell volume between in vivo cells and cells grown in culture with and without benzyladenine. Ploidy and cell volume increased in a manner very similar to that of the number of chloroplasts, suggesting a relationship between these phenomena.Correspondence and reprints: Department of Biological Sciences, Graduate School of Science, University of Tokyo, Hongo, Tokyo 113-0033, Japan.