Mohamed Hafez

Bacterial group I introns: mobile RNA catalysts

Group I introns are intervening sequences that have invaded tRNA, rRNA and protein coding genes in bacteria and their phages. The ability of group I introns to self-splice from their host transcripts, by acting as ribozymes, potentially renders their insertion into genes phenotypically neutral. Some group I introns are mobile genetic elements due to encoded homing endonuclease genes that function in DNA-based mobility pathways to promote spread to intronless alleles. Group I introns have a limited distribution among bacteria and the current assumption is that they are benign selfish elements, although some introns and homing endonucleases are a source of genetic novelty as they have been co-opted by host genomes to provide regulatory functions. Questions regarding the origin and maintenance of group I introns among the bacteria and phages are also addressed.

Phylogenetic and coevolutionary analysis of the β-barrel protein family comprised of mitochondrial porin (VDAC) and Tom40 ☆

Beta-barrel proteins are the main transit points across the mitochondrial outer membrane. Mitochondrial porin, the voltage-dependent, anion-selective channel (VDAC), is responsible for the passage of small molecules between the mitochondrion and the cytosol. Through interactions with other mitochondrial and cellular proteins, it is involved in regulating organellar and cellular metabolism and likely contributes to mitochondrial structure. Tom40 is part of the translocase of the outer membrane, and acts as the channel for passage of preproteins during their import into the organelle. These proteins appear to share a common evolutionary origin and structure. In the current study, the evolutionary relationships between and within both proteins were investigated through phylogenetic analysis. The two groups have a common origin and have followed independent, complex evolutionary pathways, leading to the generation of paralogues in animals and plants. Structures of diverse representatives were modeled, revealing common themes rather than sites of high identity in both groups. Within each group, intramolecular coevolution was assessed, revealing a new set of sites potentially involved in structure-function relationships in these molecules. A weak link between Tom40 and proteins related to the mitochondrial distribution and morphology protein, Mdm10, was identified. This article is part of a Special Issue entitled: VDAC structure, function, and regulation of mitochondrial metabolism.

The mtDNA rns gene landscape in the Ophiostomatales and other fungal taxa: Twintrons, introns, and intron-encoded proteins

Comparative sequence analysis of the mitochondrial small subunit ribosomal RNA (rns) gene among species of Ophiostoma, Grosmannia, Ceratocystiopsis and related taxa provides an overview of the types of introns that have invaded this gene within the ophiostomatoid fungi. The rns gene appears to be a reservoir for a number of group I and group II introns along with intron-associated open reading frames such as homing endonucleases and reverse transcriptases. This study uncovered two twintrons, one at position mS917 where a group ID intron encoding a LAGLIDADG ORF invaded another ORF-less group ID intron. Another twintron complex was detected at position mS1247 here a group IIA1 intron invaded the open reading frame embedded within a group IC2 intron. Overall the distribution of the introns does not appear to follow evolutionary lineages suggesting the possibility of rare horizontal gains and frequent losses. Results of this study will make a significant contribution to the understanding of the complexity of the mitochondrial intron landscape, and offer a resource to those annotating mitochondrial genomes. It will also serve as a resource to those that bioprospect for ribozymes and homing endonucleases.

A 971-bp insertion in the rns gene is associated with mitochondrial hypovirulence in a strain of Cryphonectria parasitica isolated from nature

In the chestnut-blight fungus Cryphonectria parasitica, cytoplasmically transmissible hypovirulence phenotypes frequently are elicited by double-stranded RNA (dsRNA) virus infections. However, some strains manifest cytoplasmically transmissible hypovirulence traits without containing any mycovirus. In this study, we describe an altered form of mtDNA that is associated with hypovirulence and senescence in a virus-free strain of C. parasitica, KFC9, which was obtained from nature and has an elevated level of cyanide-resistant respiration. In this strain, a 971-bp DNA element, named InC9, has been inserted into the first exon of the mitochondrial small-subunit ribosomal RNA (rns) gene. Sequence analysis indicates that InC9 is a type A1 group II intron that lacks a maturase-encoding ORF. RT-PCR analyses showed that the InC9 sequence is spliced inefficiently from the rRNA precursor. The KFC9 strain had very low amounts of mitochondrial ribosomes relative to virulent strains, thus most likely is deficient in mitochondrial protein synthesis and lacks at least some of the components of the cyanide-sensitive, cytochrome-mediated respiratory pathway. The attenuated-virulence trait and the splicing-defective intron are transferred asexually and concordantly by hyphal contact from hypovirulent donor strains to virulent recipients, confirming that InC9 causes hypovirulence.

The highly variable mitochondrial small-subunit ribosomal RNA gene of Ophiostoma minus

Mitochondrial genomes in the true fungi are highly variable both in size and organization. Most of this size variation is due to the presence of introns and intron-encoded open reading frames (ORFs). The objectives for this work were to examine the mitochondrial small-subunit ribosomal RNA (rns) gene of strains of Ophiostoma minus for the presence of introns and to characterize such introns and their encoded ORFs. DNA sequence analysis showed that among different strains of O. minus various rns gene exon/intron configurations can be observed. Based on comparative sequence analysis and RNA secondary structure modeling group I introns with LAGLIDADG ORFs were uncovered at positions mS569 and mS1224 and group II introns were present at positions mS379 and mS952. The mS379 group II intron encoded a fragmented reverse transcriptase (RT)-like ORF and the mS952 group II intron encoded a LAGLIDADG-type ORF. Examples of intron ORF degeneration due to frameshift mutations were observed. The mS379 group II intron is the first mitochondrial group II intron to have an ORF inserted within domain II, typically RT-like ORFs are inserted in domain IV. The evolutionary dynamics of the intron-encoded ORFs have also been examined.

Identification of group I introns within the SSU rDNA gene in species of Ceratocystiopsis and related taxa

During a recent phylogenetic study, group I introns were noted that interrupt the nuclear small subunit ribosomal RNA (SSU rDNA) gene in species of Ceratocystiopsis. Group I introns were found to be inserted at the following rDNA positions: S943, S989, and S1199. The introns have been characterized and phylogenetic analysis of the host gene and the corresponding intron data suggest that for S943 vertical transfer and frequent loss appear to be the most parsimonious explanation for the distribution of nuclear SSU rDNA introns among species of Ceratocystiopsis. The SSU rDNA data do suggest that a recent proposal of segregating the genus Ophiostoma sensu lato into Ophiostoma sensu stricto, Grosmannia, and Ceratocystiopsis has some merit but may need further amendments, as the SSU rDNA suggests that Ophiostoma s. str. may now represent a paraphyletic grouping.

A second eukaryotic group with mitochondrion-encoded tmRNA: in silico identification and experimental confirmation.

In bacteria, stalled ribosomes are rescued by transfer-mRNA (tmRNA) that catalyzes two steps. First, a non-encoded alanine is added to the incomplete polypeptide chain by the tRNAAla-like portion of tmRNA, and second, the ribosome switches to the mRNA-like domain of tmRNA, thus resuming protein synthesis. Mitochondrial DNA (mtDNA)-encoded mt-tmRNA is so far only known from jakobid protists, but we posit that the corresponding ssrA gene may also reside in other mtDNAs. Here we present a highly sensitive covariance model built from jakobid ssrA genes that identifies previously unrecognized ssrA homologs in mtDNAs of oomycetes. These genes, located in previously unassigned genomic regions, are circular permuted as in α-Protobacteria, implying that pre-tmRNA is processed and the two pieces are held together by non-covalent interactions. RNA-Seq data from Phytophthora sojae confirm predicted processing sites as well as post-transcriptional addition of 3′ CCA, a prerequisite for tmRNAs to be charged with alanine by alanyl-tRNA synthetase. Structure modeling of oomycete tmRNAs infers that the mRNA-like domain is lacking as in jakobids. Features of mitochondrial tmRNAs include the G-U pair at position three of the acceptor stem, a hallmark of bacterial tmRNAs, and a T-loop sequence that differs from that of standard tRNAs and most bacterial tmRNAs, forming alternative, virtually isosteric tertiary interactions with the D-loop. The anticodon stem has two additional G-A base pairs formed between the D-loop and the variable region, shortening the length of the variable region to a single nucleotide.

Convergent evolution of twintron-like configurations: One is never enough

Introns inserted within introns are commonly referred to as twintrons, however the original definition for twintron implied that splicing of the external member of the twintron could only proceed upon splicing of the internal member. This review examines the various types of twintron-like arrangements that have been reported and assigns them to either nested or twintron categories that are subdivided further into subtypes based on differences of their mode of splicing. Twintron-like arrangements evolved independently by fortuitous events among different types of introns but once formed they offer opportunities for the evolution of new regulatory strategies and/or novel genetic elements.

Evolutionary dynamics of introns and their open reading frames in the U7 region of the mitochondrial rnl gene in species of Ceratocystis

The mtDNA rnl-U7 region has been examined for the presence of introns in selected species of the genus Ceratocystis. Comparative sequence analysis identified group I and group II introns encoding single and double motif LAGLIDADG open reading frames (ORFs) at the following positions L1671, L1787, and L1923. In addition downstream of the rnl-U7 region group I introns were detected at positions L1971 and L2231, and a group II intron at L2059. A GIY-YIG type ORF was located within one mL1923 LAGLIDADG type ORF and a degenerated GIY-YIG ORF fused to a nad2 gene fragment was found in association with the mL1971 group I intron. The diversity of composite elements that appear to be sporadically distributed among closely related species of Ceratocystis illustrates the potential for homing endonucleases and their associated introns to invade new sites. Phylogenetic analysis showed that single motif LADGLIDADG ORFs related to the mL1923 ORFs have invaded the L1787 group II intron and the L1671 group I intron. Phylogenetic analysis of intron encoded single and double motif LAGLIDADG ORFs also showed that these ORFs transferred four times from group I into group II B1 type introns.