The 68 kDa DNA compacting nucleoid protein from soybean chloroplasts inhibits DNA synthesis in vitro

Nucleoids were purified from chloroplasts of dividing soybean cells and their polypeptide composition analyzed by SDS-polyacrylamide gel electrophoresis. Of the 15–20 nucleoid-associated polypeptides, several demonstrated DNA binding activity. Upon disruption of the nucleoids with high concentrations of NaCl, a subset of these proteins and the majority of chloroplast DNA were recovered in the supernatant after centrifugation. Removal of the salt by dialysis resulted in formation of nucleoprotein complexes resembling genuine nucleoids. Purification of these structures revealed three major proteins of 68, 35 and 18 kDa. After purification of the 68 kDa protein to homogeneity, this protein was able to compact purified chloroplast DNA into a nucleoid-like structure in a protein concentration-dependent fashion. Addition of the 68 kDa protein to an in vitro chloroplast DNA replication system resulted in complete inhibition of nucleotide incorporation at concentrations above 300 ng of 68 kDa protein per g of template DNA. These results led to in situ immunofluorescence studies of chloroplasts replicating DNA which suggested that newly synthesized DNA is not co-localized with nucleoids. Presumably, either the plastid replication machinery has means of removing nucleoid proteins prior to replication or the concentration of nucleoid proteins is tightly regulated and the proteins turned over in order to allow replication to proceed.     

Visualization of plastid nucleoids in situ using the PEND-GFP fusion protein

Plastid DNA is a circular molecule of 120-150 kbp, which is organized into a protein-DNA complex called a nucleoid. Although various plastids other than chloroplasts exist, such as etioplasts, amyloplasts and chromoplasts, it is not easy to observe plastid nucleoids within the cells of many non-green tissues. The PEND (plastid envelope DNA-binding) protein is a DNA-binding protein in the inner envelope membrane of developing chloroplasts, and a DNA-binding domain called cbZIP is present at its N-terminus. We made various PEND-green fluorescent protein (GFP) fusion proteins using the cbZIP domains from various plants, and found that they were localized in the chloroplast nucleoids in transient expression in leaf protoplasts. In stable transformants of Arabidopsis thaliana, PEND-GFP fusion proteins were also localized in the nucleoids of various plastids. We have succeeded in visualizing plastid nucleoids in various intact tissues using this stable transformant. This technique is useful in root, flower and pollen, in which it had been difficult to observe plastid nucleoids. The relative arrangement of nucleoids within a chloroplast was kept unchanged when the chloroplast moved within a cell. During the division of plastid, nucleoids formed a network structure, which made possible equal partition of nucleoids.     

Structure,composition, and distribution of plastid nucleoids in Narcissus pseudonarcissus

The size, frequency and distribution of the nucleoids of chloroplasts (cl-nucleoids) and chromoplasts (cr-nucleoids) of the daffodil have been investigated in situ using the DNA-specific fluorochrome 46-diamidino-2-phenylindole. Chromoplasts contain fewer nucleoids (approx. 4) than chloroplasts (> 10), and larger chromoplasts (cultivated form, approx. 4) contain more than smaller ones (wild type, approx. 2). During chromoplast development the nucleoid number decreases in parallel with the chlorophyll content. Each nucleoid contains 2–3 plastome copies on average. In chloroplasts the nucleoids are evenly distributed, whereas they are peripherally located in chromoplasts. The fine structure of isolated cl-and cr-nucleoids, purified either by Sepharose 4B-CL columns or by metrizamide gradients, was investigated electron microscopically. The cl-nucleoids consist of a central protein-rich core with naked DNA-loops protruding from it. In cr-nucleoids, on the other hand, the total DNA is tightly packed within the proteinaceous core. The protein-containing core region of the nucleoids is made up of knotty and fibrillar sub-structures with diameters of 18 and 37 nm, respectively. After proteinase treatment, or incressing ion concentration, most of the proteins are removed and the DNA is exposed even in the case of cr-nucleoids, the stability of which proved to be greater than that of cl-nucleoids. The chemical composition of isolated plastid nucleoids has been determined qualitatively and quantitatively. Chromoplast-nucleoids contain, relative to the same DNA quantity, about six times as much protein as cl-nucleoids. Accordingly the buoyant density of cr-nucleoids in metrizamide gradients is higher than that of cl-nucleoids. In addition to DNA and protein, RNA could be found in the nucleoid fraction. No pigments were present. The cr-and cl-nucleoids have many identical proteins. There are, however, also characteristic differences in their protein pattern which are possibly related to the different expression of the genomes of chloroplasts and chromoplasts. Nucleoids of both plastid types contain some proteins which also occur in isolated envelope membranes (probably partly in the outer membrane) and thus possibly take part in binding the DNA to membranes.Abbreviations cl- chloroplast - cr- chromoplast - DAPI 46-diamidino-2-phenylindole - DNase deoxyribonuclease - kDa kilodaltons - MG purified by metrizamide gradients - SC purified by Sepharose CL-4B column gel filtration - SDS-PAGE sodium dodecylsulfate-polyacrylamide gel electrophoresis     

MFP1 is a thylakoid-associated,nucleoid-binding protein with a coiled-coil structure

Plastid DNA, like bacterial and mitochondrial DNA, is organized into protein–DNA complexes called nucleoids. Plastid nucleoids are believed to be associated with the inner envelope in developing plastids and the thylakoid membranes in mature chloroplasts, but the mechanism for this re-localization is unknown. Here, we present the further characterization of the coiled-coil DNA-binding protein MFP1 as a protein associated with nucleoids and with the thylakoid membranes in mature chloroplasts. MFP1 is located in plastids in both suspension culture cells and leaves and is attached to the thylakoid membranes with its C-terminal DNA-binding domain oriented towards the stroma. It has a major DNA-binding activity in mature Arabidopsis chloroplasts and binds to all tested chloroplast DNA fragments without detectable sequence specificity. Its expression is tightly correlated with the accumulation of thylakoid membranes. Importantly, it is associated in vivo with nucleoids, suggesting a function for MFP1 at the interface between chloroplast nucleoids and the developing thylakoid membrane system.     

Detection and localization of a chloroplast-encoded HU-like protein that organizes chloroplast nucleoids

Chloroplast DNA (cpDNA) is packed into discrete structures called chloroplast nucleoids (cp-nucleoids). The structure of cpDNA is thought to be important for its maintenance and regulation. In bacteria and mitochondria, histone-like proteins (such as HU and Abf2, respectively) are abundant and play important roles in DNA organization. However, a primary structural protein has yet to be found in cp-nucleoids. Here, we identified an abundant DNA binding protein from isolated cp-nucleoids of the primitive red alga Cyanidioschyzon merolae. The purified protein had sequence homology with the bacterial histone-like protein HU, and it complemented HU-lacking Escherichia coli mutants. The protein, called HC (histone-like protein of chloroplast), was encoded by a single gene (CmhupA) in the C. merolae chloroplast genome. Using immunofluorescence and immunoelectron microscopy, we demonstrated that HC was distributed uniformly throughout the entire cp-nucleoid. The protein was expressed constitutively throughout the cell and the chloroplast division cycle, and it was able to condense DNA. These results indicate that HC, a bacteria-derived histone-like protein, primarily organizes cpDNA into the nucleoid.     

Proteomics of chloroplast envelope membranes

Proteomics is a very powerful approach to link the information contained in sequenced genomes, like Arabidopsis, to the functional knowledge provided by studies of plant cell compartments, such as chloroplast envelope membranes. This review summarizes the present state of proteomic analyses of highly purified spinach and Arabidopsis envelope membranes. Methods targeted towards the hydrophobic core of the envelope allow identifying new proteins, and especially new transport systems. Common features were identified among the known and newly identified putative envelope inner membrane transporters and were used to mine the complete Arabidopsis genome to establish a virtual plastid envelope integral protein database. Arabidopsis envelope membrane proteins were extracted using different methods, that is, chloroform/methanol extraction, alkaline or saline treatments, in order to retrieve as many proteins as possible, from the most to the less hydrophobic ones. Mass spectrometry analyses lead to the identification of more than 100 proteins. More than 50% of the identified proteins have functions known or very likely to be associated with the chloroplast envelope. These proteins are (a) involved in ion and metabolite transport, (b) components of the protein import machinery and (c) involved in chloroplast lipid metabolism. Some soluble proteins, like proteases, proteins involved in carbon metabolism or in responses to oxidative stress, were associated with envelope membranes. Almost one third of the newly identified proteins have no known function. The present stage of the work demonstrates that a combination of different proteomics approaches together with bioinformatics and the use of different biological models indeed provide a better understanding of chloroplast envelope biochemical machinery at the molecular level.     

The role of lipids in plastid protein transport

The elaborate compartmentalization of plant cells requires multiple mechanisms of protein targeting and trafficking. In addition to the organelles found in all eukaryotes, the plant cell contains a semi-autonomous organelle, the plastid. The plastid is not only the most active site of protein transport in the cell, but with its three membranes and three aqueous compartments, it also represents the most topologically complex organelle in the cell. The chloroplast contains both a protein import system in the envelope and multiple protein export systems in the thylakoid. Although significant advances have identified several proteinaceous components of the protein import and export apparatuses, the lipids found within plastid membranes are also emerging as important players in the targeting, insertion, and assembly of proteins in plastid membranes. The apparent affinity of chloroplast transit peptides for chloroplast lipids and the tendency for unsaturated MGDG to adopt a hexagonal II phase organization are discussed as possible mechanisms for initiating the binding and/or translocation of precursors to plastid membranes. Other important roles for lipids in plastid biogenesis are addressed, including the spontaneous insertion of proteins into the outer envelope and thylakoid, the role of cubic lipid structures in targeting and assembly of proteins to the prolamellar body, and the repair process of D1 after photoinhibition. The current progress in the identification of the genes and their associated mutations in galactolipid biosynthesis is discussed. Finally, the potential role of plastid-derived tubules in facilitating macromolecular transport between plastids and other cellular organelles is discussed.     

The 70-kDa major DNA-compacting protein of the chloroplast nucleoid is sulfite reductase

The chloroplast nucleoid is a complex of chloroplast DNA and various, mostly uncharacterized proteins. An abundant 70-kDa protein of the isolated nucleoids of pea chloroplasts was identified as sulfite reductase by N-terminal sequence analysis as well as immunoblot analysis, spectrophotometry and enzyme activity analysis. Recombinant maize sulfite reductase was indeed able to compact chloroplast DNA and to form nucleoid-like particles in vitro. The role of sulfite reductase in the structural organization of the nucleoid is discussed.     

Isolation of nuclear encoded plastid ribosomal protein cDNAs

Summary A pea leaf cDNA library was constructed in the expression vector gt11 and screened with antisera raised against proteins extracted from 30S and 50S ribosomal subunits and 70S ribosomes prepared from isolated pea chloroplasts. Six recombinant phage were identified that encoded fusion proteins containing plastid ribosomal protein antigenic determinants. Phage-induced cell lysate proteins, containing the fusion proteins, were bound to nitrocellulose membranes and used as affinity matrices to prepare monospecific antibodies. These antibodies were then used to identify by Western blotting which plastid ribosomal protein shared antigenic determinants with the fusion proteins. cDNA inserts from the antigen-producing phage were used to hybrid-select complementary mRNAs. The cell-free translation products of these mRNAs were added to a pea chloroplast in vitro transport system and imported proteins analyzed by two-dimensional gel electrophoresis. The imported proteins comigrated with the plastid ribosomal proteins that were identified as being antigenically related to the fusion proteins produced by the corresponding recombinant phage. The imported proteins were 3,500–5,500 daltons smaller than their precursors.     

The DNA-compacting protein DCP68 from soybean chloroplasts is ferredoxin:sulfite reductase and co-localizes with the organellar nucleoid

The multiple copies of the chloroplast genome (plastome) are condensed and organized into nucleoids by a set of proteins. One of these, the DNA-binding protein DCP68 from soybean, has previously been shown to compact DNA and to inhibit DNA synthesis in vitro. N-terminal amino acid analysis and the absorption spectrum of the purified protein suggest that DCP68 is the siroheme protein sulfite reductase, a ferredoxin-dependent enzyme that participates in sulfur assimilation for cysteine and methionine biosynthesis. The in vivoassociation of this protein with chloroplast nucleoids was confirmed by immuno-colocalization with antibodies against sulfite reductase from Arabidopsis thaliana. These results suggest that DCP68 is a bifunctional chloroplast protein that participates in reductive sulfur assimilation and plays a role in organellar nucleoid organization. The fact that dephosphorylation by alkaline phosphatase affects the binding of purified DCP68 to DNA in vitro might be indicative of the way the interaction of the protein with the nucleoid is regulated in vivo.     

Nucleoid proteins of pea chloroplasts: detection of a protein homologous to ribosomal protein.

Basic proteins were isolated from purified pea chloroplast nucleoids by acid extraction. Using RP-HPLC, the component composition of the basic proteins was studied. SDS-PAGE of major HPLC-fractions showed that the basic nucleoid proteins are heterogeneous with mol. masses of components from 17 to 30 kDa. One polypeptide with mol. mass of 28 kDa (P28) was obtained by RP-HPLC. The sequencing of three tryptic peptides of P28 (T6, T17, and T19) showed that they are homologous to the ribosomal protein L19 of Saccharomyces cerevisiae. The possible functional role of ribosomal proteins in chloroplast nucleoids is discussed.     

The role of chloroplast membranes in the location of chloroplast DNA during the greening ofPhaseolus vulgaris etioplasts

Summary The location of DNA containing nucleoids has been studied in greening bean (Phaseolus vulgaris L.) etioplasts using electron microscopy of thin sections and the staining of whole leaf cells with the fluorochrome DAPI. At 0 hours illumination a diffuse sphere of cpDNA surrounds most of the prolamellar body. It appears to be made up of a number of smaller nucleoids and can be asymmetric in location. The DNA appears to be attached to the outside of the prolamellar body and to prothylakoids on its periphery. With illumination the nucleoid takes on a clear ring-like shape around the prolamellar body. The maximum development of the ring-like nucleoid at 5 hours illumination is associated with the outward expansion of the prolamellar body and the outward growth of the prothylakoids. At 5 hours the electron transparent areas lie in between the prothylakoids radiating out from the prolamellar body. Between 5 hours and 15 hours observations are consistent with the growing thylakoids separating the nucleoids as the prolamellar body disappears and the chloroplast becomes more elongate. At 15 hours the fully differentiated chloroplast has discrete nucleoids distributed throughout the chloroplast with evidence of thylakoid attachment. This is the SN (scattered nucleoid) distribution ofKuroiwa et al. (1981) and is also evident in 24 hours and 48 hours chloroplasts which have more thylakoids per granum. The changes in nucleoid location occur without significant changes in DNA levels per plastid, and there is no evidence of DNA or plastid replication.The observations indicate that cpDNA partitioning in dividing SN-type chloroplasts could be achieved by thylakoid growth and effectively accomplish DNA segregation, contrasting with envelope growth segregating nucleoids in PS-type (peripheral scattered nucleoids) chloroplasts. The influence of plastid development on nucleoid location is discussed.