Two-dimensional gel electrophoresis of ribosomal proteins from streptomycin-sensitive and streptomycin-resistant mutants of Chlamydomonas reinhardi.

Ribosomal proteins from three mutant strains of Chlamydomonas reinhardi were analysed and compared by one-dimensional and two-dimensional gel electrophoresis. One mutant was streptomycin-sensitive the other two were streptomycin-resistant, one with a Mendelian the other with a non-Mendelian pattern of inheritance. In the 30-S subunits of chloroplast ribosomes approximately 25 proteins are found and in the 50-S subunits 34 proteins. The 40-S subunits of cytoplasmic ribosomes contain about 31 proteins and the 60-S subunits 44 proteins. The molecular weights of most proteins in all subunits are in the range of 10 000 to 35 000. However, the 60-S subunits contain in addition a protein of molecular weight 50 000 and the 30-S subunits show 6-7 bands of molecular weights from 50 000 to 83 000. The proteins of the cytoplasmic 80-S ribosomes or of their subunits from all three mutants are electrophoretically identical. The proteins of the 70-S organellar ribosomes and both of their subunits show distinct differences between the three strains. Our results indicate that organellar ribosomal proteins are in part controlled by nuclear DNA and in part by organellar DNA.     

The tatC gene cluster is essential for viability in halophilic archaea

In prokaryotes the twin-arginine translocase (Tat) is a unique transport system for the export of folded proteins. The Tat pathway is usually involved in the export of a small proportion of extracytoplasmic proteins. An exception is found in halophilic archaea, in which the majority of secretory proteins have been predicted to be Tat-dependent. All haloarchaea analysed to date contain two genes encoding homologues of the Tat-component TatC. In all of these cases both genes are located adjacently on the chromosome, indicating that they form a functional unit. We show that this gene cluster is essential for viability in haloarchaea, which is in complete contrast to all other prokaryotes that have been tested thus far.     

Pentatricopeptide repeat proteins and their emerging roles in plants.

Several protein families with tandem repeat motifs play a very important role in plant development and defense. The pentatricopeptide repeat (PPR) protein family, one of the largest families, is the most perplexing one in plants. PPR proteins have been implicated in many crucial functions broadly involving organelle biogenesis and plant development. PPR motifs are degenerate motifs, each with 35-amino-acid sequences and are present in tandem arrays of 2-27 repeats per protein. Although PPR proteins are found in other eukaryotes, their large number is probably required in plants to meet the specific needs of organellar gene expression. The repeats of PPR proteins form a superhelical structure to bind a specific ligand, probably a single-stranded RNA molecule, and modulate its expression. Functional studies on different PPR proteins have revealed their role in organellar RNA processing, fertility restoration in CMS plants, embryogenesis, and plant development. Functional genomic techniques can help identify the diverse roles of the PPR family of proteins in nucleus-organelle interaction and in plant development.     

Predotar: A tool for rapidly screening proteomes for N-terminal targeting sequences

Probably more than 25% of the proteins encoded by the nuclear genomes of multicellular eukaryotes are targeted to membrane-bound compartments by N-terminal targeting signals. The major signals are those for the endoplasmic reticulum, the mitochondria, and in plants, plastids. The most abundant of these targeted proteins are well-known and well-studied, but a large proportion remain unknown, including most of those involved in regulation of organellar gene expression or regulation of biochemical pathways. The discovery and characterization of these proteins by biochemical means will be long and difficult. An alternative method is to identify candidate organellar proteins via their characteristic N-terminal targeting sequences. We have developed a neural network-based approach (Predotar--Prediction of Organelle Targeting sequences) for identifying genes encoding these proteins amongst eukaryotic genome sequences. The power of this approach for identifying and annotating novel gene families has been illustrated by the discovery of the pentatricopeptide repeat family.     

Lateral gene transfer occurring in haloarchaea: an interpretative imitation study

Lateral gene transfer (LGT) plays an important role in the molecular evolution of haloarchaea. Polyethylene glycol-mediated LGT in haloarchaea has been demonstrated in the laboratory, yet few explanations have been put forward for the apparently common, natural occurrence of plentiful plasmids within haloarchaeal cells. In this study, LGT was induced in two genera of haloarchaea, Haloferax and Halorubrum, by modification of salt concentration of media-a factor that may vary naturally in native haloarchaeal habitat. Minimal growth salt concentrations (MGSCs) of four strains of haloarchaea from these two genera were established, and transformations using two circular double-stranded DNAs (dsDNAs), pSY1 and pWL102, were then produced in media at strain-appropriate MGSCs. The four strains of haloarchaea were transformed successfully by both kinds of dsDNAs with an efficiency of 10(2)-10(3) transformants per microgram dsDNA. The transformation under reduced salt concentration may be an imitation of natural LGT of dsDNA into haloarchaea when salinity in normally hypersaline environments is altered by sudden introduction of fresh water-for example, by rainfall, snow-melt, or flooding-providing a reasonable interpretation for haloarchaea being naturally richer in plasmids than any other known organisms.     

Development of pyrF-based gene knockout systems for genome-wide manipulation of the archaea Haloferax mediterranei and Haloarcula hispanica

The haloarchaea Haloferax mediterranei and Haloarcula hispanica are both polyhydroxyalkanoate producers in the domain Archaea, and they are becoming increasingly attractive for research and biotechnology due to their unique genetic and metabolic features. To accelerate their genome-level genetic and metabolic analyses, we have developed specific and highly efficient gene knockout systems for these two haloarchaea. These gene knockout systems consist of a suicide plasmid vector with the pyrF gene as the selection marker and a uracil auxotrophic haloarchaeon (ΔpyrF) as the host. For in-frame deletion of a target gene, the suicide plasmid carrying the flanking region of the target gene was transferred into the corresponding ΔpyrF host. After positive selection of the single-crossover integration recombinants (pop-in) on AS-168SY medium without uracil and counterselection of the double-crossover pyrF-excised recombinants (pop-out) with 5-fluoroorotic acid (5-FOA), the target gene knockout mutants were confirmed by PCR and Southern blot analysis. We have demonstrated the effectiveness of these systems by knocking out the crtB gene which encodes a phytoene synthase in these haloarchaea. In conclusion, these well-developed knockout systems would greatly accelerate the functional genomic research of these halophilic archaea.     

Understanding protein translocation across chloroplast membranes: Translocons and motor proteins

Subcellular organelles in eukaryotes are surrounded by lipid membranes.In an endomembrane system,vesicle trafficking is the primary mechanism for the delivery of organellar proteins to specific organelles.However,organellar proteins for chloroplasts,mitochondria,the nucleus,and peroxisomes that are translated in the cytosol are directly imported into their target organelles.Chloroplasts are a plant-specific organelle with outer and inner envelope membranes,a dual-membrane structure that is simil...     

Genetic and biochemical analysis of the twin-arginine translocation pathway in halophilic archaea

The twin-arginine translocation (Tat) pathway is present in a wide variety of prokaryotes and is capable of exporting partially or fully folded proteins from the cytoplasm. Although diverse classes of proteins are transported via the Tat pathway, in most organisms it facilitates the secretion of a relatively small number of substrates compared to the Sec pathway. However, computational evidence suggests that haloarchaea route nearly all secreted proteins to the Tat pathway. We have expanded previous computational analyses of the haloarchaeal Tat pathway and initiated in vivo characterization of the Tat machinery in a model haloarchaeon, Haloferax volcanii. Consistent with the predicted usage of the this pathway in the haloarchaea, we determined that three of the four identified tat genes in Haloferax volcanii are essential for viability when grown aerobically in complex medium. This represents the first report of an organism that requires the Tat pathway for viability when grown under such conditions. Deletion of the nonessential gene had no effect on the secretion of a verified substrate of the Tat pathway. The two TatA paralogs TatAo and TatAt were detected in both the membrane and cytoplasm and could be copurified from the latter fraction. Using size exclusion chromatography to further characterize cytoplasmic and membrane TatA proteins, we find these proteins present in high-molecular-weight complexes in both cellular fractions.     

Extremely halophilic archaea and the issue of long-term microbial survival

Halophilic archaebacteria (haloarchaea) thrive in environments with salt concentrations approaching saturation, such as natural brines, the Dead Sea, alkaline salt lakes and marine solar salterns; they have also been isolated from rock salt of great geological age (195–250 million years). An overview of their taxonomy, including novel isolates from rock salt, is presented here; in addition, some of their unique characteristics and physiological adaptations to environments of low water activity are reviewed. The issue of extreme long-term microbial survival is considered and its implications for the search for extraterrestrial life. The development of detection methods for subterranean haloarchaea, which might also be applicable to samples from future missions to space, is presented.     

Labelling halophilic Archaea using 13C and 15N stable isotopes: a potential tool to investigate haloarchaea consumption by metazoans

The use of stable isotope (SI) labelling and tracing of live diets is currently considered one of the most comprehensive tools to detect their uptake and assimilation by aquatic organisms. These techniques are indeed widely used in nutritional studies to follow the fate of specific microbial dietary components, unraveling trophic interactions. Nevertheless, to the current date our understanding of aquatic trophic relationships has yet to include a whole domain of life, the Archaea. The aim of the present research was, therefore, to describe a halophilic Archaea (haloarchaea) labelling procedure, using the SI ¹³C and ¹⁵N, to enable the application of SI tracing in future studies of haloarchaea consumption by aquatic metazoans. To this end, three ¹³C enriched carbon sources and two ¹⁵N enriched nitrogen sources were tested as potential labels to enrich cells of three haloarchaea strains when supplemented to the culture medium. Our overall results indicate ¹³C-glycerol as the most effective carbon source to achieve an efficient ¹³C enrichment in haloarchaea cells, with Δδ¹³C values above 5000‰ in all tested haloarchaea strains. As for ¹⁵N enriched nitrogen sources, both (¹⁵NH₄)₂SO₄ and ¹⁵NH₄Cl seem to be readily assimilated, also resulting in efficient ¹⁵N enrichment in haloarchaea cells, with Δδ¹⁵N values higher than 20,000‰. We believe that the proposed methodology will allow for the use of SI labelled haloarchaea biomass in feeding tests, potentially providing unambiguous confirmation of the assimilation of haloarchaea biomass by aquatic metazoans.

     

DYW-type PPR proteins in a heterolobosean protist: plant RNA editing factors involved in an ancient horizontal gene transfer?

A particular type of pentatricopeptide repeat (PPR) proteins with variable length of the 35 aa PPR motifs and conserved carboxyterminal extensions, named the PLS proteins, was so far exclusively identified in land plants. Several PLS proteins with such domain extensions (E, E+, DYW) were shown to be involved in plant organellar RNA editing but their evolutionary origin had remained enigmatic. We here report the first case of DYW-type PLS proteins outside of the plant kingdom in the protist Naegleria gruberi and hypothesize on horizontal gene transfer in very early land plant evolution.     

Statistical and functional analyses of viral and cellular proteins with N-terminal amphipathic alpha-helices with large hydrophobic moments: importance to macromolecular recognition and organelle targeting.

A total of 1,911 proteins with N-terminal methionyl residues were computer screened for potential N-terminal alpha-helices with strong amphipathic character. By the criteria of D. Eisenberg (Annu. Rev. Biochem. 53:595-623, 1984), only 3.5% of nonplastid, nonviral proteins exhibited potential N-terminal alpha-helices, 18 residues in length, with hydrophobic moment values per amino acyl residue ([muH]) in excess of 0.4. By contrast, 10% of viral proteins exhibited corresponding [muH] values in excess of 0.4. Of these viral proteins with known functions, 55% were found to interact functionally with nucleic acids, 30% were membrane-interacting proteins or their precursors, and 15% were structural proteins, primarily concerned with host cell interactions. These observations suggest that N-terminal amphipathic alpha-helices of viral proteins may (i) function in nucleic acid binding, (ii) facilitate membrane insertion, and (iii) promote host cell interactions. Analyses of potential amphipathic N-terminal alpha-helices of cellular proteins are also reported, and their significance to organellar or envelope targeting is discussed.     

Control of mitochondrial integrity in ageing and disease

Various molecular and cellular pathways are active in eukaryotes to control the quality and integrity of mitochondria. These pathways are involved in keeping a ‘healthy’ population of this essential organelle during the lifetime of the organism. Quality control (QC) systems counteract processes that lead to organellar dysfunction manifesting as degenerative diseases and ageing. We discuss disease- and ageing-related pathways involved in mitochondrial QC: mtDNA repair and reorganization, regeneration of oxidized amino acids, refolding and degradation of severely damaged proteins, degradation of whole mitochondria by mitophagy and finally programmed cell death. The control of the integrity of mtDNA and regulation of its expression is essential to remodel single proteins as well as mitochondrial complexes that determine mitochondrial functions. The redundancy of components, such as proteases, and the hierarchies of the QC raise questions about crosstalk between systems and their precise regulation. The understanding of the underlying mechanisms on the genomic, proteomic, organellar and cellular levels holds the key for the development of interventions for mitochondrial dysfunctions, degenerative processes, ageing and age-related diseases resulting from impairments of mitochondria.     

Reduced ribosomes of the apicoplast and mitochondrion of Plasmodium spp. and predicted interactions with antibiotics

Apicomplexan protists such as Plasmodium and Toxoplasma contain a mitochondrion and a relic plastid (apicoplast) that are sites of protein translation. Although there is emerging interest in the partitioning and function of translation factors that participate in apicoplast and mitochondrial peptide synthesis, the composition of organellar ribosomes remains to be elucidated. We carried out an analysis of the complement of core ribosomal protein subunits that are encoded by either the parasite organellar or nuclear genomes, accompanied by a survey of ribosome assembly factors for the apicoplast and mitochondrion. A cross-species comparison with other apicomplexan, algal and diatom species revealed compositional differences in apicomplexan organelle ribosomes and identified considerable reduction and divergence with ribosomes of bacteria or characterized organelle ribosomes from other organisms. We assembled structural models of sections of Plasmodium falciparum organellar ribosomes and predicted interactions with translation inhibitory antibiotics. Differences in predicted drug–ribosome interactions with some of the modelled structures suggested specificity of inhibition between the apicoplast and mitochondrion. Our results indicate that Plasmodium and Toxoplasma organellar ribosomes have a unique composition, resulting from the loss of several large and small subunit proteins accompanied by significant sequence and size divergences in parasite orthologues of ribosomal proteins.     

Organellar Na+/H+ exchangers: novel players in organelle pH regulation and their emerging functions

Mammalian Na+/H+ exchangers (NHEs) play a fundamental role in cellular ion homeostasis. NHEs exhibit an appreciable variation in expression, regulation, and physiological function, dictated by their dynamics in subcellular localization and/or interaction with regulatory proteins. In recent years, a subgroup of NHEs consisting of four isoforms has been identified, and its members predominantly localize to the membranes of the Golgi apparatus and endosomes. These organellar NHEs constitute a family of transporters with an emerging function in the regulation of luminal pH and in intracellular membrane trafficking as expressed, for example, in cell polarity development. Moreover, specific roles of a variety of cofactors, regulating the intracellular dynamics of these transporters, are also becoming apparent, thereby providing further insight into their mechanism of action and overall functioning. Interestingly, organellar NHEs have been related to mental disorders, implying a potential role in the brain, thus expanding the physiological significance of these transporters.     

Metagenomic study of red biofilms from Diamante Lake reveals ancient arsenic bioenergetics in haloarchaea

Arsenic metabolism is proposed to be an ancient mechanism in microbial life. Different bacteria and archaea use detoxification processes to grow under high arsenic concentration. Some of them are also able to use arsenic as a bioenergetic substrate in either anaerobic arsenate respiration or chemolithotrophic growth on arsenite. However, among the archaea, bioenergetic arsenic metabolism has only been found in the Crenarchaeota phylum. Here we report the discovery of haloarchaea (Euryarchaeota phylum) biofilms forming under the extreme environmental conditions such as high salinity, pH and arsenic concentration at 4589 m above sea level inside a volcano crater in Diamante Lake, Argentina. Metagenomic analyses revealed a surprisingly high abundance of genes used for arsenite oxidation (aioBA) and respiratory arsenate reduction (arrCBA) suggesting that these haloarchaea use arsenic compounds as bioenergetics substrates. We showed that several haloarchaea species, not only from this study, have all genes required for these bioenergetic processes. The phylogenetic analysis of aioA showed that haloarchaea sequences cluster in a novel and monophyletic group, suggesting that the origin of arsenic metabolism in haloarchaea is ancient. Our results also suggest that arsenite chemolithotrophy likely emerged within the archaeal lineage. Our results give a broad new perspective on the haloarchaea metabolism and shed light on the evolutionary history of arsenic bioenergetics.