The structure of the large subunit rRNA expressed in blood stages of Plasmodium falciparum

The RNA structurome in the asexual blood stages of malaria pathogen plasmodium falciparum

Plasmodium falciparum is a deadly human pathogen responsible for the devastating disease called malaria. In this study, we measured the differential accumulation of RNA secondary structures in coding and non-coding transcripts from the asexual developmental cycle in P. falciparum in human red blood cells. Our comprehensive analysis that combined high-throughput nuclease mapping of RNA structures by duplex RNA-seq, SHAPE-directed RNA structure validation, immunoaffinity purification and characterization of antisense RNAs collectively measured differentially base-paired RNA regions throughout the parasite's asexual RBC cycle. Our mapping data not only aligned to a diverse pool of RNAs with known structures but also enabled us to identify new structural RNA regions in the malaria genome. On average, approximately 71% of the genes with secondary structures are found to be protein coding mRNAs. The mapping pattern of these base-paired RNAs corresponded to all regions of mRNAs, including the 5' UTR, CDS and 3' UTR as well as the start and stop codons. Histone family genes which are known to form secondary structures in their mRNAs and transcripts from genes which are important for transcriptional and post-transcriptional control, such as the unique plant-like transcription factor family, ApiAP2, DNA-/RNA-binding protein, Alba3 and proteins important for RBC invasion and malaria cytoadherence also showed strong accumulation of duplex RNA reads in various asexual stages in P. falciparum. Intriguingly, our study determined stage-specific, dynamic relationships between mRNA structural contents and translation efficiency in P. falciparum asexual blood stages, suggesting an essential role of RNA structural changes in malaria gene expression programs.

tRNA epitranscriptomics and biased codon are linked to proteome expression in Plasmodium falciparum

Among components of the translational machinery, ribonucleoside modifications on tRNAs are emerging as critical regulators of cell physiology and stress response. Here, we demonstrate highly coordinated behavior of the repertoire of tRNA modifications of Plasmodium falciparum throughout the intra-erythrocytic developmental cycle (IDC). We observed both a synchronized increase in 22 of 28 modifications from ring to trophozoite stage, consistent with tRNA maturation during translational up-regulation, and asynchronous changes in six modifications. Quantitative analysis of ~2,100 proteins across the IDC revealed that up- and down-regulated proteins in late but not early stages have a marked codon bias that directly correlates with parallel changes in tRNA modifications and enhanced translational efficiency. We thus propose a model in which tRNA modifications modulate the abundance of stage-specific proteins by enhancing translation efficiency of codon-biased transcripts for critical genes. These findings reveal novel epitranscriptomic and translational control mechanisms in the development and pathogenesis of Plasmodium parasites.

Eukaryote-specific rRNA expansion segments function in ribosome biogenesis

The secondary structure of ribosomal RNA (rRNA) is largely conserved across all kingdoms of life. However, eukaryotes have evolved extra blocks of rRNA sequences, relative to those of prokaryotes, called expansion segments (ES). A thorough characterization of the potential roles of ES remains to be done, possibly because of limitations in the availability of robust systems to study rRNA mutants. We sought to systematically investigate the potential functions, if any, of the ES in 25S rRNA of Saccharomyces cerevisiae by deletion mutagenesis. We deleted 14 of the 16 different eukaryote-specific ES in yeast 25S rRNA individually and assayed their phenotypes. Our results show that all but two of the ES tested are necessary for optimal growth and are required for production of 25S rRNA, suggesting that ES play roles in ribosome biogenesis. Further, we classified expansion segments into groups that participate in early nucleolar, middle, and late nucleoplasmic steps of ribosome biogenesis, by assaying their pre-rRNA processing phenotypes. This study is the first of its kind to systematically identify the functions of eukaryote-specific expansion segments by showing that they play roles in specific steps of ribosome biogenesis. The catalog of phenotypes we identified, combined with previous investigations of the roles ribosomal proteins in large subunit biogenesis, leads us to infer that assembling ribosomes are composed of distinct RNA and protein structural neighborhood clusters that participate in specific steps of ribosome biogenesis.

The ribosomal DNA plasmids of entamoeba

In most organisms, the nuclear ribosomal RNA (rRNA) genes are highly repetitive and arranged as tandem repeats on one or more chromosomes. In Entamoeba, however, these genes are located almost exclusively on extrachromosomal circular DNA molecules with no clear evidence so far of a chromosomal copy. Such an uncommon location of rRNA genes may be a direct consequence of cellular physiology, as suggested by studies with Saccharomyces cerevisiae mutants in which the rDNA is extrachromosomal. In this review, Sudha Bhattacharya, Indrani Som and Alok Bhattacharya summarize current knowledge on the structural organization and replication of the Entamoeba rDNA plasmids. Other than the rRNAs encoded by these molecules, no protein-coding genes (including ribosomal protein genes) are found on any of them. They are unique among plasmids in that they do not initiate replication from a fixed origin but use multiple sites dispersed throughout the molecule. Further studies should establish the unique biochemical features of Entamoeba that lead to extrachromosomal rDNA.

The Effects of Glucose Concentration on the Reciprocal Regulation of rRNA Promoters in Plasmodium falciparum

The developmental progression of Plasmodium falciparum is remarkably sensitive to glucose concentration. We have investigated the effects of glucose concentration on the parasite development cycle as reflected by changes of ribosomal RNA (rRNA) transcription. We showed that glucose starvation differentially affects transcriptional control of the rRNA genes by sharply repressing transcription from those loci involved with asexual development of the parasite while up-regulating transcription at those loci involved with sexual development of the parasite. Temperature change also effects regulation of transcription. We found that the effects of temperature and glucose were synergistic. We identified and compared the upstream region of the transcription start sites of each gene. These putative promoter structures are considerably different from one another and contain structures remarkably similar to rRNA control elements in other organisms.

Three multigene families in Plasmodium parasites: facts and questions

Multigene families optimise fitness by providing a set of related genes with possibly different temporal and/or topological expression patterns. We analyse here the structural organisation and sequence diversity of the rDNA, sera and var C Plasmodium falciparum families, and discuss their consequences for parasite biology. The low rDNA copy number, which reduces reshuffling, is probably the corollary of the need for functionally distinct rRNAs in the insect and in the vertebrate host. The unusual intra-genome and population rDNA sequence diversity results in cells equipped with mosaic ribosome sets. The functional constraints are such that ribosome compatibility could influence parasite fitness and contribute to population structuring. Unlike the dispersed rDNA units, the sera family is arranged as a tandem gene cluster, with seven contiguous similar genes, and one more distantly related paralog. We address the question of the inclusion criteria in family definition. We discuss the results concerning the SERA proteins expression and function in the context of the long overlooked multigene family. The var C module is shared by var genes, 'orphan' var C and var C pseudogenes. Analysis of 125 var C deduced protein sequences highlights a well-conserved framework, including putative phosphorylation sites, consistent with the proposed function of mediating interaction with cytoskeletal proteins. The 5' and 3' flanking sequences of the var C pseudogenes are heterogeneous. In contrast, the flanking sequences of the uninterrupted var C modules show remarkable conservation. This is interesting in view of the silencing activity of the var intronic sequence on var expression. The 5' flanking sequence dichotomy reported for internal and sub-telomeric var genes extends to the 3' flanking sequences. This has profound implications for transcription regulation and generation of diversity. The var C family suggests a role for pseudogenes as a diversity reservoir and in genome dynamics by promoting ectopic recombination.

Evolution of transcript structure and base composition of rDNA expansion segment D3 in ticks

Four to thirty-two copies of the rDNA 28S gene expansion segment D3 and flanking H14 stem were sequenced in six species of ticks (Ixodes: Ixodidae: Acari). Sequence match among species varied from 66% to 97%. Sequence length averaged 130 bases in I. persulcatus across eight Eurasian sites and averaged 186 bases in five other species across 19 Eurasian and North American sites. The difference in length represents one or more deletions totalling about 60 bases that correspond to stems S3 or S4 of the folded transcript. The typical transcript conformation was observed as one possible low energy structure in the five species of longer D3. The structure entails a basal loop with four stem/loop structures, S1-S4 (moving 5' to 3') atop stem H14. A secondary structure lacking S4 but possessing all other putative standard features of the D3 transcript is possible with the shorter I. persulcatus sequences. Interspecific sequence differences occur at higher frequency in loops and bulges vs. complementary pairing regions of stems. Insertion/deletion events (indels) and base substitutions accounted equally for sequence differences. Indels are flanked by similar sequences, suggesting that they occur by slippage during replication. The D3 of Ixodes species is composed of a degenerate set of subrepeats. Thus, unequal exchange among subrepeats may have caused the reduction in length of the I. persulcatus D3. Compensatory base substitution and compensatory insertion/deletion events are indicated by the failure of mutations to affect secondary structure. Transversions accounted for 64% of sequence differences and were biased toward the gain of G and U and the loss of A and C. This bias could re-establish intramolecular base pairing when disrupted by insertions or deletions that shift one side of a stem relative to the other. The distribution of sequence differences, biased substitution, and conservation of transcript conformation in D3 suggest selective constraint.

Microsequence heterogeneity and expression of the LSU rRNA genes within the two single copy ribosomal transcription units of Theileria parva

The nucleotide sequences of the large subunit ribosomal RNA coding genes within the two single copy ribosomal DNA transcription units of a cloned Theileria parva isolate from a buffalo were determined. The two LSU rRNA coding units differed by 11 nucleotide substitutions and two deletions of 1 and 6 bp, all located in the 5' end of the LSU coding region. We also observed microsequence heterogeneity between the two buffalo parasite LSU sequences and the previously determined LSU rRNA gene of a T. parva parasite isolated from cattle. At all positions which were variable between the two LSU rRNA coding sequences of the buffalo-derived parasite, either unit 1 or unit 2 matched the LSU rRNA coding sequence of the cattle-derived T. parva parasite in a mosaic pattern. Synthetic oligonucleotides specific for LSU units 1 and 2 of the buffalo T. parva were developed, and used to assay expression of the two units. Both units were expressed in the intra-lymphocytic schizont stage of T. parva. A 2.5-10-fold excess of rRNA derived from LSU unit 1, compared with unit 2, was observed in the schizont stage, the difference being attributable to variation in the level of expression of unit 2. Theileria represents the third genus of Sporozoan protozoa, in addition to Plasmodium and Babesia, exhibiting rRNA coding genes, which are divergent in sequence between different transcription units.

Large-subunit ribosomal RNA systematics of symbiotic dinoflagellates: morphology does not recapitulate phylogeny

Biochemical, histological, physiological, and genetic evidence indicates that dinoflagellates symbiotic with marine invertebrates are a heterogeneous complex of taxa, representing at least five genera in three orders. Despite a wealth of data regarding morphological, biochemical, and behavioral differences among symbiotic dinoflagellates, knowledge concerning patterns of diversification is limited. I analyzed approximately 900 bp of the 5' end of the large-subunit ribosomal RNA gene from 14 dinoflagellate isolates: six cultured Symbiodinium specimens, two cultured symbiotic Gymnodinium, two algal samples isolated from reef-building corals, an algal sample obtained from cultures of the jellyfish Cassiopea xamachana, and three free-living Gymnodinium isolates. Results show that morphological similarities among the examined symbiotic taxa do not necessarily correspond with molecular phylogeny. The included Symbiodinium taxa represent a paraphyletic assemblage while Gymnodinium is reconstructed as a polyphyletic assemblage. Analysis indicates that all the included symbiotic dinoflagellates descended from a common, symbiotic ancestor (though within the dinoflagellates, symbiosis is a polyphyletic trait). Additionally, two free-living dinoflagellates emerge within the symbiotic clade, suggesting that the symbiotic lifestyle has been lost at least once in this group. It has been hypothesized that rates of evolution within mutualistic endosymbioses should be reduced relative to free-living taxa. However, results indicate that rates of molecular, morphological, biochemical and behavioral change are similar among branches leading to symbiotic and free-living dinoflagellates.

Comparison of the large subunit ribosomal DNA of Neospora and toxoplasma and development of a new genetic marker for their differentiation based on the D2 domain

The latest release of the large subunit ribosomal database contains 429 sequences, yet only 10 (six nuclear and four mitochondrial) are derived from parasites of the phylum Apicomplexa. Three of these (all Toxoplasma gondii) were previously contained in the 1994 release of the database. As an initiative towards an understanding of ribosomal gene organization in the Apicomplexa, the primary sequence of the large subunit (LSU) rDNA of Neospora caninum is presented, and compared with a consensus sequence derived for the LSU rDNA of T. gondii. Nucleotide differences observed between these two taxa in the D2 expansion segment (or domain) (also called the C1/C1' region) of the LSU rDNA were incorporated into a primer that forms the basis of a species-specific polymerase chain reaction (PCR) for N. caninum. The D2 domain of the LSU rDNA, therefore, represents a new genetic marker that can be used for the differentiation and identification of Neospora from other cyst-forming coccidia.

Ribosomal RNA gene organization in Cryptosporidium parvum

The cytoplasmic ribosomal RNA (rRNA) genes of the Apicomplexan protozoan parasite Cryptosporidium parvum have been analyzed with respect to size, copy number, organization and structure. The small and large subunit rRNAs are 1.7 and 3.6 kb, respectively. A 151 bp putative 5.8S rRNA gene was identified. The rDNA unit is 5' small subunit rRNA internal transcribed spacer 1-5.8S rRNA-internal transcribed spacer 2-large subunit rRNA 3'. There are five copies of the rDNA unit per haploid genome and they are not organized in a conventional head to tail tandem array with a conserved external transcribed spacer. The rDNA units are dispersed through the genome to at least three chromosomes. At least two of the rDNA units are single unlinked copies on different chromosomes. There are two structurally distinct types of rDNA unit, Type A and B, with marked differences in the internal transcribed spacer regions. There are four copies of the Type A rDNA unit and one copy of the Type B rDNA unit.

Extrachromosomal DNA in the Apicomplexa

Malaria and related apicomplexan parasites have two highly conserved organellar genomes: one is of plastid (pl) origin, and the other is mitochondrial (mt). The organization of both organellar DNA molecules from the human malaria parasite Plasmodium falciparum has been determined, and they have been shown to be tightly packed with genes. The 35-kb circular DNA is the smallest known vestigial plastid genome and is presumed to be functional. All but two of its recognized genes are involved with genetic expression: one of the two encodes a member of the clp family of molecular chaperones, and the other encodes a conserved protein of unknown function found both in algal plastids and in eubacterial genomes. The possible evolutionary source and intracellular location of the plDNA are discussed. The 6-kb tandemly repeated mt genome is the smallest known and codes for only three proteins (cytochrome b and two subunits of cytochrome oxidase) as well as two bizarrely fragmented rRNAs. The organization of the mt genome differs somewhat among genera. The mtDNA sequence provides information not otherwise available about the structure of apicomplexan cytochrome b as well as the unusually fragmented rRNAs. The malarial mtDNA has a phage-like replication mechanism and undergoes extensive recombination like the mtDNA of some other lower eukaryotes.

Inhibition of Plasmodium falciparum protein synthesis. Targeting the plastid-like organelle with thiostrepton

The human malaria parasite Plasmodium falciparum has two extrachromosomal DNAs associated with organelles whose function is unclear. Both genomes encode ribosomal RNAs (rRNAs) that are distinct from the nuclear-encoded rRNAs. Secondary structure analysis of all the P. falciparum rRNAs indicates that only the large subunit (LSU) rRNA encoded by the plastid-like genome is the target for thiostrepton. Indeed we find that thiostrepton inhibits growth of the parasite in the micromolar range which is 10-fold below concentrations with observable effects on total protein synthesis. We have further examined selective effects of thiostrepton on the plastid function by comparing differential effects of the drug on cytoplasmic and organellar encoded transcripts. Treatment with either thiostrepton or rifampin, an inhibitor of organellar and eubacterial RNA polymerase, both showed disappearance of organellar-encoded RNA transcripts within 6 h of treatment while transcripts of a nuclear-encoded mRNA remained constant for at least 8 h of treatment. Hence, we show a selective effect on organelle function that is suggestive of interference in the protein synthesis apparatus of the plastid. Sensitivity of P. falciparum to thiostrepton confirms that the plastid-like genome is essential for the erythrocytic cycle and presents a novel therapeutic site for this class of antibiotics.