An improved immunofluorescence staining method for chloroplast proteins

Key message

An improved immunofluorescence staining method significantly facilitates the visualization of the subcellular localization of interested proteins in chloroplasts.

Abstract

As an important technical approach, immunofluorescence staining is widely used in the subcellular localization study of interested proteins. During the study of the functions of chloroplast division proteins, immunofluorescence staining was frequently adopted. Previously, a method has been developed to study the localization of a chloroplast division protein, FtsZ. However, it is laborious and time-consuming. In this study, we report a modified immunofluorescence staining method, in which protoplasts were isolated from leaf tissues, and then fixed for immunofluorescence staining. The time of the experiment was significantly reduced to several hours. Furthermore, we used correction pen in the fixation procedure and a new way to coat the slide, which greatly saved the cost of the experiment. With the chloroplast division protein ARC6 as an example, we can get a good fluorescence signal. Moreover, the localization of ARC6 in two chloroplast division mutants, arc3 and arc5, and three other plant species, such as cabbage, radish and pea, was also successfully analyzed with our new method. Overall, the immunofluorescence staining method we reported here is very practical, and it significantly facilitates the visualization of the subcellular localization of interested proteins in plant cells.

     

FGsub: <Emphasis Type="Italic">Fusarium graminearum</Emphasis> protein subcellular localizations predicted from primary structures

Background

The fungal pathogen Fusarium graminearum (telomorph Gibberella zeae) is the causal agent of several destructive crop diseases, where a set of genes usually work in concert to cause diseases to crops. To function appropriately, the F. graminearum proteins inside one cell should be assigned to different compartments, i.e. subcellular localizations. Therefore, the subcellular localizations of F. graminearum proteins can provide insights into protein functions and pathogenic mechanisms of this destructive pathogen fungus. Unfortunately, there are no subcellular localization information for F. graminearum proteins available now. Computational approaches provide an alternative way to predicting F. graminearum protein subcellular localizations due to the expensive and time-consuming biological experiments in lab.

Results

In this paper, we developed a novel predictor, namely FGsub, to predict F. graminearum protein subcellular localizations from the primary structures. First, a non-redundant fungi data set with subcellular localization annotation is collected from UniProtKB database and used as training set, where the subcellular locations are classified into 10 groups. Subsequently, Support Vector Machine (SVM) is trained on the training set and used to predict F. graminearum protein subcellular localizations for those proteins that do not have significant sequence similarity to those in training set. The performance of SVMs on training set with 10-fold cross-validation demonstrates the efficiency and effectiveness of the proposed method. In addition, for F. graminearum proteins that have significant sequence similarity to those in training set, BLAST is utilized to transfer annotations of homologous proteins to uncharacterized F. graminearum proteins so that the F. graminearum proteins are annotated more comprehensively.

Conclusions

In this work, we present FGsub to predict F. graminearum protein subcellular localizations in a comprehensive manner. We make four fold contributions to this filed. First, we present a new algorithm to cope with imbalance problem that arises in protein subcellular localization prediction, which can solve imbalance problem and avoid false positive results. Second, we design an ensemble classifier which employs feature selection to further improve prediction accuracy. Third, we use BLAST to complement machine learning based methods, which enlarges our prediction coverage. Last and most important, we predict the subcellular localizations of 12786 F. graminearum proteins, which provide insights into protein functions and pathogenic mechanisms of this destructive pathogen fungus.

     

Split-ubiquitin yeast two-hybrid interaction reveals a novel interaction between a natural resistance associated macrophage protein and a membrane bound thioredoxin in Brassica juncea

Natural resistance associated macrophage proteins (NRAMPs) are evolutionarily conserved metal transporters involved in the transport of essential and nonessential metals in plants. Fifty protein interactors of a Brassica juncea NRAMP protein was identified by a Split-Ubiquitin Yeast-Two-Hybrid screen. The interactors were predicted to function as components of stress response, signaling, development, RNA binding and processing. BjNRAMP4.1 interactors were particularly enriched in proteins taking part in photosynthetic or light regulated processes, or proteins predicted to be localized in plastid/chloroplast. Further, many interactors also had a suggested role in cellular redox regulation. Among these, the interaction of a photosynthesis-related thioredoxin, homologous to Arabidopsis HCF164 (High-chlorophyll fluorescence164) was studied in detail. Homology modeling of BjNRAMP4.1 suggested that it could be redox regulated by BjHCF164. In yeast, the interaction between the two proteins was found to increase in response to metal deficiency; Mn excess and exogenous thiol. Excess Mn also increased the interaction in planta and led to greater accumulation of the complex at the root apoplast. Network analysis of Arabidopsis homologs of BjNRAMP4.1 interactors showed enrichment of many protein components, central to chloroplastic/cellular ROS signaling. BjNRAMP4.1 interacted with BjHCF164 at the root membrane and also in the chloroplast in accordance with its proposed function related to photosynthesis, indicating that this interaction occurred at different sub-cellular locations depending on the tissue. This may serve as a link between metal homeostasis and chloroplastic/cellular ROS through protein–protein interaction.     

Tracking the elusive 5′ exonuclease activity of <Emphasis Type="Italic">Chlamydomonas reinhardtii</Emphasis> RNase J

Key message

Chlamydomonas RNase J is the first member of this enzyme family that has endo- but no intrinsic 5′ exoribonucleolytic activity. This questions its proposed role in chloroplast mRNA maturation.

Abstract

RNA maturation and stability in the chloroplast are controlled by nuclear-encoded ribonucleases and RNA binding proteins. Notably, mRNA 5′ end maturation is thought to be achieved by the combined action of a 5′ exoribonuclease and specific pentatricopeptide repeat proteins (PPR) that block the progression of the nuclease. In Arabidopsis the 5′ exo- and endoribonuclease RNase J has been implicated in this process. Here, we verified the chloroplast localization of the orthologous Chlamydomonas (Cr) RNase J and studied its activity, both in vitro and in vivo in a heterologous B. subtilis system. Our data show that Cr RNase J has endo- but no significant intrinsic 5′ exonuclease activity that would be compatible with its proposed role in mRNA maturation. This is the first example of an RNase J ortholog that does not possess a 5′ exonuclease activity. A yeast two-hybrid screen revealed a number of potential interaction partners but three of the most promising candidates tested, failed to induce the latent exonuclease activity of Cr RNase J. We still favor the hypothesis that Cr RNase J plays an important role in RNA metabolism, but our findings suggest that it rather acts as an endoribonuclease in the chloroplast.

     

Cloning and functional characterization of the <Emphasis Type="Italic">SmNCED3</Emphasis> in <Emphasis Type="Italic">Salvia miltiorrhiza</Emphasis>

As one of the most important phytohormones, the abscisic acid (ABA) is often used to breed stress-tolerant crop lines with both higher yields and active ingredient contents. In higher plants, the 9-cis-epoxycarotenoid dioxygenase (NCED) has been found to be a regulatory enzyme involved in ABA biosynthesis. In research, the novel gene SmNCED3 was isolated from S. miltiorrhiza. The open reading frame of SmNCED3 was 1725-bp, and it was encoding 574 amino acids with a calculated molecular mass of 63,822 kDa, which was verified by the expression of SmNCED3 in E. coli. The deduced SmNCED3 amino acid sequence had high sequence homology with NCED sequences from other plants and contained a putative chloroplast transit targeting signal peptide at its N terminus. Phylogenetic analysis demonstrated that SmNCED3 had a closer affinity to NCED3 in Arabidopsis thaliana (AtNCED3). The 1732-bp 5′ flanking sequence of SmNCED3 was also cloned. It contained several phytohormone response elements, biotic or abiotic stress-related elements, and plant development-related elements. Real-time PCR revealed that SmNCED3 was highly expressed in leaves, and was strongly induced by exogenous ABA. A subcellular localization experiment indicated that SmNCED3 was located in chloroplast stroma, chloroplast membranes, and thylakoid membranes. The overexpression of SmNCED3 promoted ABA accumulation. These results indicated that SmNCED3 might be a rate-limiting gene regulating ABA biosynthesis, and improving abiotic stresses tolerance and active ingredient contents in plants.     

Cloning and Function Characterization of Two Dehydroascorbate Reductases from Kiwifruit (<Emphasis Type="Italic">Actinidia chinensis</Emphasis> L.)

Dehydroascorbate reductase (DHAR, EC 1.8.5.1) plays a critical role in the regeneration of l-ascorbic acid (AsA). To date, there is virtually no information on the molecular characteristics of DHAR in kiwifruit, an economically and nutritionally important horticultural crop with remarkably high AsA concentration. Here, we isolated two cDNAs encoding putative DHARs (designated as AcDHAR1 and AcDHAR2) from Actinidia chinensis cv. Hongyang. Both in silico and subcellular localization analyses demonstrated that AcDHAR1 and AcDHAR2 were targeted to cytosol and chloroplast, respectively. The recombinant AcDHAR1 and AcDHAR2 were expressed in Escherichia coli and purified using Ni-affinity chromatography. Enzymatic study shows both of them are thermostable and possess a relatively high affinity to dehydroascorbate with an optimal pH ranging from 6 to 8. In addition, transgenic Arabidopsis thaliana plants separately expressing either AcDHAR1 or AcDHAR2 were shown to have significantly increased AsA concentration and enhanced tolerance to salinity. The present study suggested that AcDHAR1 and AcDHAR2 may play a protective role in response to environmental stimuli in kiwifruit.     

Predicting essential proteins based on subcellular localization,orthology and PPI networks

Background

Essential proteins play an indispensable role in the cellular survival and development. There have been a series of biological experimental methods for finding essential proteins; however they are time-consuming, expensive and inefficient. In order to overcome the shortcomings of biological experimental methods, many computational methods have been proposed to predict essential proteins. The computational methods can be roughly divided into two categories, the topology-based methods and the sequence-based ones. The former use the topological features of protein-protein interaction (PPI) networks while the latter use the sequence features of proteins to predict essential proteins. Nevertheless, it is still challenging to improve the prediction accuracy of the computational methods.

Results

Comparing with nonessential proteins, essential proteins appear more frequently in certain subcellular locations and their evolution more conservative. By integrating the information of subcellular localization, orthologous proteins and PPI networks, we propose a novel essential protein prediction method, named SON, in this study. The experimental results on S.cerevisiae data show that the prediction accuracy of SON clearly exceeds that of nine competing methods: DC, BC, IC, CC, SC, EC, NC, PeC and ION.

Conclusions

We demonstrate that, by integrating the information of subcellular localization, orthologous proteins with PPI networks, the accuracy of predicting essential proteins can be improved. Our proposed method SON is effective for predicting essential proteins.

     

Chloroplast ribonucleoprotein-like proteins of the moss <Emphasis Type="Italic">Physcomitrella patens</Emphasis> are not involved in RNA stability and RNA editing

Many RNA recognition motif (RRM)-containing proteins are known to exist in chloroplasts. Major members of the RRM protein family, which are chloroplast ribonucleoproteins (cpRNPs), have been investigated in seed plants, including tobacco and Arabidopsis thaliana, but never in early land plants, such as bryophytes. In this study, we surveyed RRM proteins encoded in the moss Physcomitrella patens genome and predicted 25 putative chloroplast RRM proteins. Among them, two RRM-containing proteins, PpRBP2a and PpRBP2b, resembled cpRNPs and were thus referred to as cpRNP-like proteins. However, knockout mutants of either one or two PpRBP2 genes exhibited a wild type-like phenotype. Unlike Arabidopsis cpRNPs, the levels of mRNA accumulation in chloroplasts were not affected in the PpRBP2 knockout mutants. In addition, the efficiency of RNA editing was also not altered in the mutants. This suggests that PpRBP2a and 2b may be functionally distinct from Arabidopsis cpRNPs.     

Drosophila <Emphasis Type="Italic">Nnf1</Emphasis> paralogs are partially redundant for somatic and germ line kinetochore function

Kinetochores allow attachment of chromosomes to spindle microtubules. Moreover, they host proteins that permit correction of erroneous attachments and prevent premature anaphase onset before bi-orientation of all chromosomes in metaphase has been achieved. Kinetochores are assembled from subcomplexes. Kinetochore proteins as well as the underlying centromere proteins and the centromeric DNA sequences evolve rapidly despite their fundamental importance for faithful chromosome segregation during mitotic and meiotic divisions. During evolution of Drosophila melanogaster, several centromere proteins were lost and a recent gene duplication has resulted in two Nnf1 paralogs, Nnf1a and Nnf1b, which code for alternative forms of a Mis12 kinetochore complex component. The rapid evolutionary divergence of centromere/kinetochore constituents in animals and plants has been proposed to be driven by an intragenome conflict resulting from centromere drive during female meiosis. Thus, a female meiosis-specific paralog might be expected to evolve rapidly under positive selection. While our characterization of the D. melanogaster Nnf1 paralogs hints at some partial functional specialization of Nnf1b for meiosis, we have failed to detect evidence for positive selection in our analysis of Nnf1 sequence evolution in the Drosophilid lineage. Neither paralog is essential, even though we find some clear differences in subcellular localization and expression during development. Loss of both paralogs results in developmental lethality. We therefore conclude that the two paralogs are still in early stages of differentiation.     

A Combined Approach of Quantitative Interaction Proteomics and Live-cell Imaging Reveals a Regulatory Role for Endoplasmic Reticulum (ER) Reticulon Homology Proteins in Peroxisome Biogenesis

Peroxisome biogenesis initiates at the endoplasmic reticulum (ER) and maturation allows for the formation of metabolically active organelles. Yet, peroxisomes can also multiply by growth and division. Several proteins, called peroxins, are known to participate in these processes but little is known about their organization to orchestrate peroxisome proliferation. Here, we demonstrate that regulation of peroxisome proliferation relies on the integrity of the tubular ER network. Using a dual track SILAC-based quantitative interaction proteomics approach, we established a comprehensive network of stable as well as transient interactions of the peroxin Pex30p, an integral membrane protein. Through association with merely ER resident proteins, in particular with proteins containing a reticulon homology domain, and with other peroxins, Pex30p designates peroxisome contact sites at ER subdomains. We show that Pex30p traffics through the ER and segregates in punctae to which peroxisomes specifically append, and we ascertain its transient interaction with all subunits of the COPI coatomer complex suggesting the involvement of a vesicle-mediated transport. We establish that the membrane protein Pex30p facilitates the connection of peroxisomes to the ER. Taken together, our data indicate that Pex30p-containing protein complexes act as focal points from which peroxisomes can form and that the tubular ER architecture organized by the reticulon homology proteins Rtn1p, Rtn2p and Yop1p controls this process.All nucleated cells contain essential round-shaped organelles called peroxisomes, whose function is mainly associated with lipid metabolism (1). Depending on the cellular requirements, the size, number, and protein content of these single membrane-bound organelles can vary widely. Although peroxisomes are dispensable for unicellular species such as yeasts, they are essential for the development of multicellular organisms (2, 3). In human, mutations in PEX genes lead to defects in peroxisome function or formation and are associated with the development of lethal pathologies (4). These PEX genes code for proteins, called peroxins, which are involved in peroxisome assembly and maintenance (5).Two major routes seem to lead to peroxisome formation, namely, de novo biogenesis and growth/division of pre-existing peroxisomes. The division pathway operates with proteins of the Pex11 family and requires fission factors shared with mitochondria (6). Studies in yeast and mammalian cells revealed that through the action of the protein Pex3p peroxisome precursors can also originate from the endoplasmic reticulum (ER)¹ and, via import of membrane and matrix proteins, mature into fully functional organelles (7, 8). Furthermore, several peroxisomal membrane proteins were shown to migrate to peroxisomes via the ER (7, 9, 10). The molecular mechanism underlying the biogenic pathway of peroxisome formation has not been clarified so far. Recent data based on cell-free vesicle-budding reactions, however, demonstrated that several peroxisomal proteins traffic from the ER to peroxisomes in a COPII vesicle-independent manner (11). These observations point to the existence of vesicular events to mediate the transport of peroxisomal membrane proteins from the ER. In fact, analysis of secretory mutant yeast cells already suggest that part of the ER-associated secretory machinery is involved in peroxisome biogenesis (12).The de novo biogenesis of peroxisomes and the growth/division pathways are usually seen as independent routes; however, these events may be coordinated and, thus, intimately linked. Indeed, peroxisomes need to acquire membrane components to proliferate and it has been proposed that their binding to the cell cortex or to the cytoskeleton allows their partitioning and segregation during cell division (13–15).Among the proteins required for assembly of peroxisomes, the membrane proteins Pex23p and Pex24p play essential roles in the yeast Yarrowia lipolytica (16, 17). Homologs of these two proteins in Saccharomyces cerevisiae are Pex30p, Pex31p, and Pex32p, all containing at least one transmembrane domain and a dysferlin domain as common structural motifs, as well as Pex28p and Pex29p. In S. cerevisiae, these proteins seem to negatively control peroxisomal size and number (18, 19). Interestingly, Pex30p seems to exhibit species-specific differences in the regulation of peroxisome proliferation. While the lack of Pex30p in S. cerevisiae leads to an increase in the number of normal-sized peroxisomes (18), in Pichia pastoris its absence correlates with the appearance of fewer and clustered peroxisomes (20). Although peroxisomes are highly versatile organelles, under given conditions their total number per cell remains fairly constant owing to the delicate balance of proliferation, inheritance and degradation (21, 22). The question is: what are the molecular mechanisms responsible for the spatiotemporal organization of these events?Here, we present data obtained from a dual approach based on quantitative interaction proteomics using stable isotope labeling with amino acids in cell culture (SILAC) (23, 24) and live-cell imaging, revealing for the first time the dynamic interaction network around Pex30p and its function in the organization of ER-to-peroxisome membrane associations. We report the existence of a macromolecular membrane protein complex that acts as a hub for the regulation of peroxisome proliferation and movement. Our data suggest a direct role for the tubular cortical ER and the reticulon homology proteins Rtn1p, Rtn2p, and Yop1p in the regulation of peroxisome biogenesis. Furthermore, as an initially cortical-ER localized protein that interacts with reticulon homology proteins, Pex30p is shown in this work to establish contacts between ER tubules and peroxisomes and to specifically traffic through the ER. In summary, our data reveal a central role for Pex30p in the formation of ER-to-peroxisomes associations that appear to be involved in the coordination of peroxisome biogenesis and maintenance.     

Isolation and characterization of two <Emphasis Type="Italic">DREB1</Emphasis> genes encoding dehydration-responsive element binding proteins in chicory (<Emphasis Type="Italic">Cichorium intybus</Emphasis>)

Two novel DREB (dehydration-responsive element-binding protein) genes, designated as CiDREB1A and CiDREB1B, were cloned from chicory (Cichorium intybus). Both of these genes contained a conserved EREBP/AP2 domain and were classified into the A-1 subgroup of the DREB subfamily based on phylogenetic analysis. Quantitative real-time PCR analysis revealed that low temperature, but not ABA, greatly induced the expression of both CiDREB1 genes, suggesting that these genes are involved in ABA-independent stress signaling pathways. A subcellular localization assay revealed that both CiDREBs localized to the nucleus. In addition, we showed by yeast one-hybrid analysis that these two CiDREB proteins bind to the DRE motif of RD19A. These results suggest that CiDREB1A and CiDREB1B are important regulators of stress-responsive signaling in chicory.