Chloroplast division: squeezing the photosynthetic captive

Chloroplasts have evolved from a cyanobacterial endosymbiont and have been retained in eukaryotic cells for more than one billion years via chloroplast division and inheritance by daughter cells during cell division. Recent studies revealed that chloroplast division is performed by a large protein complex at the division site, encompassing both the inside and the outside of the two envelope membranes. The division complex has retained a few components of the cyanobacterial division complex to go along with other components supplied by the host cell. On the basis of the information about the division complex, we are beginning to understand how the division complex evolved, and how eukaryotic host cells regulate chloroplast division during proliferation and differentiation.     

Chloroplast division in cultured cells of the hornwortAnthoceros punctatus

Using cultured cells of the hornwortAnthoceros punctatus, the change in the relative chloroplast DNA content in each stage of chloroplast division was investigated to clarify the relationship between the division cycle of a chloroplast and a cell nucleus. Samples of cultured cells were stained with 4′,6-diamidino-2-phenylindole (DAPI) and then observed with an epifluorescence microscope and a chromosome image analyzing system (CHIAS). A chloropiast in cultured cells duplicated DNA with an increase in size. When a chloroplast began to divide, it was constricted in the middle, taking a dumbbell shape, and then divided into two daughter chloroplasts. In cultured cells of this species, the pattern of quantitative change of chloroplast DNA, that is, the DNA replication pattern of chloroplasts, corresponded to that of cell nuclear DNA in mitosis.     

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     

Chloroplast targeting of chloroplast division FtsZ2 proteins in Arabidopsis

Plant nuclear genomes encode chloroplast division proteins homologous to the eubacterial cell division protein FtsZ. In higher plants, FtsZ genes constitute a small gene family that consists of two subgroups, FtsZ1 and FtsZ2. It was previously hypothesized that members of one family (FtsZ1) targeted chloroplasts, while members of the other family (FtsZ2) localized in the cytoplasm. We determined the full-length cDNA sequences of two FtsZ2 genes from Arabidopsis thaliana (AtFtsZ2-1 and AtFtsZ2-2) and found that the genes encode polypeptides of 478 and 473 amino acids, respectively, and both contain N-terminal extensions beyond what have previously been predicted. The N-terminal regions of both AtFtsZ2-1 and AtFtsZ2-2 were expressed as green fluorescent protein (GFP) fusions under the cauliflower mosaic virus 35S promoter in bombarded tobacco cells. Confocal laser scanning microscopy revealed both fusions exclusively localized to chloroplasts, demonstrating that the N-terminal regions function as chloroplast-targeting signals in vivo. Thus, FtsZ2 proteins function within chloroplasts.     

Chloroplast division machinery as revealed by immunofluorescence and electron microscopy

The division of chloroplasts (plastids) is critical for the viability of photosynthetic eukaryotes. Previously we reported on the chloroplast division apparatus, which consists of inner and outer double or triple rings (PD rings). Chloroplasts are assumed to arise from bacterial endosymbionts, while bacterial division is instigated by a bacterial cytokinesis Z-ring protein (FtsZ). Here we present immunofluorescence and electron-microscopic evidence of chloroplast division via complex machinery involving the FtsZ and PD rings in the higher plant Pelargonium zonale Ait. Prior to invagination, the FtsZ protein was attached to a ring at the stromal division site. Following formation of the FtsZ ring, the inner stromal and outer cytosolic PD rings appeared, signifying the initiation of invagination. The FtsZ ring and the PD rings were found at the leading edge of chloroplast constriction throughout division. During chloroplast division, neither the FtsZ nor the inner rings changed width, but the volume of the outer ring gradually increased. We suggest that the FtsZ ring determines the division region, after which the inner and outer PD rings are formed as a lining for the FtsZ ring. With the outer ring providing the motivating force, the FtsZ and inner PD rings ultimately decompose to their base components.     

Organization of work in the honeybee: a compromise between division of labour and behavioural flexibility

Although the caste concept has been central to our understanding of the organization of work in social insect colonies, the concept has been the subject of considerable recent criticism. Theoretically, it has been suggested that temporal castes are too inflexible to allow a colony to rapidly reallocate labour in response to changing conditions. In addition, several authors have suggested that task switching is so prevalent that it precludes even the possibility of a rigidly controlled temporal caste system. This study addresses these two criticisms by presenting and testing a revision of the temporal caste concept that recognizes two categories of tasks: those that require a physiological specialization for their efficient performance, and those that all workers are equally able to perform. Only those tasks requiring a physiological specialization are relevant to the temporal caste concept. Two castes of honeybees were shown to vary in response to increased nectar influx, which requires a physiological specialization, but not to heat stress, which requires no specialization. This work suggests that the organization of work in social insect colonies reflects a compromise between selection for the benefits of division of labour and opposing selection for flexibility in task allocation.     

Functional and biochemical dissection of the structure-specific nuclease ARTEMIS

During V(D)J recombination, the RAG1 and RAG2 proteins form a complex and initiate the process of rearrangement by cleaving between the coding and signal segments and generating hairpins at the coding ends. Prior to ligation of the coding ends by DNA ligase IV/XRCC4, these hairpins are opened by the ARTEMIS/DNA-PKcs complex. ARTEMIS, a member of the metallo-beta-lactamase superfamily, shares several features with other family members that act on nucleic acids. ARTEMIS exhibits exonuclease and, in concert with DNA-PKcs, endonuclease activities. To characterize amino acids essential for its catalytic activities, we mutated nine evolutionary conserved histidine and aspartic acid residues within ARTEMIS. Biochemical analyses and a novel in vivo V(D)J recombination assay allowed the identification of eight mutants that were defective in both overhang endonucleolytic and hairpin-opening activities; the 5' to 3' exonuclease activity of ARTEMIS, however, was not impaired by these mutations. These results indicate that the hairpin-opening activity of ARTEMIS and/or its overhang endonucleolytic activity are necessary but its exonuclease activity is not sufficient for the process of V(D)J recombination.     

Chloroplast DNA systematics: a review of methods and data analysis

The field of plant molecular systematics is expanding rapidly, and with it new and refined methods are coming into use. This paper reviews recent advances in experimental methods and data analysis, as applied to the chloroplast genome. Restriction site mapping of the chloroplast genome has been used widely, but is limited in the range of taxonomic levels to which it can be applied. The upper limits (i.e., greatest divergence) of its application are being explored by mapping of the chloroplast inverted repeat region, where rates of nucleotide substitution are low. The lower limits of divergence amenable to restriction site study are being examined using restriction enzymes with 4-base recognition sites to analyze polymerase chain reaction (PCR)-amplified portions of the chloroplast genome that evolve rapidly. The comparison of DNA sequences is the area of molecular systematics in which the greatest advances are being made. PCR and methods for direct sequencing of PCR products have resulted in a mushrooming of sequence data. In theory, any degree of divergence is amenable to comparative sequencing studies. In practice, plant systematists have focused on two slowly evolving sequences (rbcL and rRNA genes). More rapidly evolving DNA sequences, including rapidly changing chloroplast genes, chloroplast introns, and intergenic spacers, and the noncoding portions of the nuclear ribosomal RNA repeat, also are being investigated for comparative purposes. The relative advantages and disadvantages of comparative restriction site mapping and DNA sequencing are reviewed. For both methods, the analysis of resulting data requires sufficient taxon and character sampling to achieve the best possible estimate of phylogenetic relationships. Parsimony analysis is particularly sensitive to the issue of taxon sampling due to the problem of long branches attracting on a tree. However, data sets with many taxa present serious computational difficulties that may result in the inability to achieve maximum parsimony or to find all shortest trees.     

Chloroplast division and morphology are differentially affected by overexpression of FtsZ1 and FtsZ2 genes in Arabidopsis

In higher plants, two nuclear gene families, FtsZ1 and FtsZ2, encode homologs of the bacterial protein FtsZ, a key component of the prokaryotic cell division machinery. We previously demonstrated that members of both gene families are essential for plastid division, but are functionally distinct. To further explore differences between FtsZ1 and FtsZ2 proteins we investigated the phenotypes of transgenic plants overexpressing AtFtsZ1-1 or AtFtsZ2-1, Arabidopsis members of the FtsZ1 and FtsZ2 families, respectively. Increasing the level of AtFtsZ1-1 protein as little as 3-fold inhibited chloroplast division. Plants with the most severe plastid division defects had 13- to 26-fold increases in AtFtsZ1-1 levels over wild type, and some of these also exhibited a novel chloroplast morphology. Quantitative immunoblotting revealed a correlation between the degree of plastid division inhibition and the extent to which the AtFtsZ1-1 protein level was elevated. In contrast, expression of an AtFtsZ2-1 sense transgene had no obvious effect on plastid division or morphology, though AtFtsZ2-1 protein levels were elevated only slightly over wild-type levels. This may indicate that AtFtsZ2-1 accumulation is more tightly regulated than that of AtFtsZ1-1. Plants expressing the AtFtsZ2-1 transgene did accumulate a form of the protein smaller than those detected in wild-type plants. AtFtsZ2-1 levels were unaffected by increased or decreased accumulation of AtFtsZ1-1 and vice versa, suggesting that the levels of these two plastid division proteins are regulated independently. Taken together, our results provide additional evidence for the functional divergence of the FtsZ1 and FtsZ2 plant gene families.     

Chloroplast proteomics: potentials and challenges

With the available Arabidopsis genome and near-completion of the rice genome sequencing project, large-scale analysis of plant proteins with mass spectrometry has now become possible. Determining the proteome of a cell is a challenging task, which is complicated by proteome dynamics and complexity. The biochemical heterogeneity of proteins constrains the use of standardized analytical procedures and requires demanding techniques for proteome analysis. Several proteome studies of plant cell organelles have been reported, including chloroplasts and mitochondria. Chloroplasts are of particular interest for plant biologists because of their complex biochemical pathways for essential metabolic functions. Information from the chloroplast proteome will therefore provide new insights into pathway compartmentalization and protein sorting. Some approaches for the analysis of the chloroplast proteome and future prospects of plastid proteome research are discussed here.     

Chloroplast signaling: retrograde regulation revelations

Developing chloroplasts are able to communicate their status to the nucleus and regulate expression of genes whose products are needed for photosynthesis. Heme is revealed to be a signaling molecule for this retrograde communication.     

Asymmetric division: a kinesin for spindle positioning

The meiotic spindles of animal eggs move to extremely asymmetric positions, close to the cell cortex. A recent paper has identified a motor complex that may move the meiotic spindle toward the cortex in Caenorhabditis elegans eggs.     

Direct Chloroplast Sequencing: Comparison of Sequencing Platforms and Analysis Tools for Whole Chloroplast Barcoding

Direct sequencing of total plant DNA using next generation sequencing technologies generates a whole chloroplast genome sequence that has the potential to provide a barcode for use in plant and food identification. Advances in DNA sequencing platforms may make this an attractive approach for routine plant identification. The HiSeq (Illumina) and Ion Torrent (Life Technology) sequencing platforms were used to sequence total DNA from rice to identify polymorphisms in the whole chloroplast genome sequence of a wild rice plant relative to cultivated rice (cv. Nipponbare). Consensus chloroplast sequences were produced by mapping sequence reads to the reference rice chloroplast genome or by de novo assembly and mapping of the resulting contigs to the reference sequence. A total of 122 polymorphisms (SNPs and indels) between the wild and cultivated rice chloroplasts were predicted by these different sequencing and analysis methods. Of these, a total of 102 polymorphisms including 90 SNPs were predicted by both platforms. Indels were more variable with different sequencing methods, with almost all discrepancies found in homopolymers. The Ion Torrent platform gave no apparent false SNP but was less reliable for indels. The methods should be suitable for routine barcoding using appropriate combinations of sequencing platform and data analysis.     

Control of cell division: a unifying hypothesis.

A constant feature of the initiation of cell division in a number of different cells is a rise in the intracellular level of calcium. The importance of cyclic nucleotides may depend on the way they interact with calcium. Cyclic AMP is apparently not an essential regulator of cell division but through its ability to modulate the intracellular level of calcium this cyclic nucleotide can exert profound effects on cell growth. In some systems (liver and salivary glands) cyclic AMP seems to augment the calcium signal whereas in others (lymphocytes and fibroblasts) it opposes calcium and can thus inhibit cell division. A rise in the level of calcium may be responsible for the parallel increase in cyclic GMP level which is usually associated with the stimulus to divide. An appealing feature of this calcium hypothesis is that it can account for the growth characteristics revealed by fibroblasts in tissue culture or embryonic cells during development. In both cases there is an initial phase of exponential growth during which I have proposed that the high level of calcium at mitosis persists into early G1 to provide the signal for the next division. In order to account for the sudden cessation of cell division at confluency, or at a specific stage during development, it is necessary to postulate that there is something different about the final mitosis which sets it apart from earlier mitoses. It is proposed that as the cells leave the last mitosis the level of calcium falls much more rapidly than it did during preceeding mitoses perhaps as a result of a more rapid rise in the level of cyclic AMP. This rapid rise in cyclic AMP level may have a dual function. Not only will it lower the level of calcium thus preventing further division, but it may also stimulate differentiation. Many of the embryonic cells which differentiate into specialized cells (lymphocytes, liver, salivary gland) retain the ability to divide if provided with appropriate stimuli. Although the nature of these stimuli vary considerably, they all seem to act by elevating the intracellular level of calcium.     

Mechanisms of cell division: lessons from a nematode

The mechanisms orchestrating spatial cell division control remain poorly understood. In animal cells, the position of the mitotic spindle dictates cleavage furrow placement, and thus plays a key role in governing spatial relationships between resulting daughter cells. The one-cell stage Caenorhabditis elegans embryo is an attractive model system to investigate the mechanisms underlying spindle positioning in metazoans. In this review, the experimental advantages of this model system for an in vivo dissection of cell division processes are first discussed. Next, three lines of experiments that were conducted to dissect the mechanisms governing spindle positioning in one-cell stage C. elegans embryos are summarized. First, localized laser micro-irradiations were utilized to identify the forces acting on spindle poles during anaphase. This work revealed that there is a precise imbalance of pulling forces acting on the two spindle poles, with the forces acting on the posterior spindle pole being in slight excess, thus explaining the asymmetric spindle position achieved by the end of anaphase. Second, an RNAi-based functional genomic screen was carried out to identify novel components required for generating these pulling forces. This uncovered that gpr-1/gpr-2, which encode GoLoco-containing proteins, as well as the previously identified Ga subunits goa-1/gpa-16, are required for generation of pulling forces on the spindle poles. Third, the zyg-8 locus was identified by mutational analysis to play a distinct role during anaphase spindle positioning. zyg-8 was found to encode a protein related to human Doublecortin, which is affected in patients with neuronal migration disorders. Moreover, ZYG-8 is a microtubule-associated protein that stabilizes microtubules against depolymerization. Together, these experimental approaches contribute to a better understanding of the mechanisms orchestrating spatial cell division control in metazoan organisms.