Translation across the 5'-splice site interferes with autocatalytic splicing

Survey of chimeric IStron elements in bacterial genomes: multiple molecular symbioses between group I intron ribozymes and DNA transposons

IStrons are chimeric genetic elements composed of a group I intron associated with an insertion sequence (IS). The group I intron is a catalytic RNA providing the IStron with self-splicing ability, which renders IStron insertions harmless to the host genome. The IS element is a DNA transposon conferring mobility, and thus allowing the IStron to spread in genomes. IStrons are therefore a striking example of a molecular symbiosis between unrelated genetic elements endowed with different functions. In this study, we have conducted the first comprehensive survey of IStrons in sequenced genomes that provides insights into the distribution, diversity, origin and evolution of IStrons. We show that IStrons have a restricted phylogenetic distribution limited to two bacterial phyla, the Firmicutes and the Fusobacteria. Nevertheless, diverse IStrons representing two major groups targeting different insertion site motifs were identified. This taken with the finding that while the intron components of all IStrons belong to the same structural class, they are fused to different IS families, indicates that multiple intron–IS symbioses have occurred during evolution. In addition, introns and IS elements related to those that were at the origin of IStrons were also identified.

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.

Learning to live together: mutualism between self-splicing introns and their hosts

Group I and II introns can be considered as molecular parasites that interrupt protein-coding and structural RNA genes in all domains of life. They function as self-splicing ribozymes and thereby limit the phenotypic costs associated with disruption of a host gene while they act as mobile DNA elements to promote their spread within and between genomes. Once considered purely selfish DNA elements, they now seem, in the light of recent work on the molecular mechanisms regulating bacterial and phage group I and II intron dynamics, to show evidence of co-evolution with their hosts. These previously underappreciated relationships serve the co-evolving entities particularly well in times of environmental stress.

Mobile DNA elements in T4 and related phages

Mobile genetic elements are common inhabitants of virtually every genome where they can exert profound influences on genome structure and function in addition to promoting their own spread within and between genomes. Phage T4 and related phage have long served as a model system for understanding the molecular mechanisms by which a certain class of mobile DNA, homing endonucleases, promote their spread. Homing endonucleases are site-specific DNA endonucleases that initiate mobility by introducing double-strand breaks at defined positions in genomes lacking the endonuclease gene, stimulating repair and recombination pathways that mobilize the endonuclease coding region. In phage T4, homing endonucleases were first discovered as encoded within the self-splicing td, nrdB and nrdD introns of T4. Genomic data has revealed that homing endonucleases are extremely widespread in T-even-like phage, as evidenced by the astounding fact that ~11% of the T4 genome encodes homing endonuclease genes, with most of them located outside of self-splicing introns. Detailed studies of the mobile td intron and its encoded endonuclease, I-TevI, have laid the foundation for genetic, biochemical and structural aspects that regulate the mobility process, and more recently have provided insights into regulation of homing endonuclease function. Here, we summarize the current state of knowledge regarding T4-encoded homing endonucleases, with particular emphasis on the td/I-TevI model system. We also discuss recent progress in the biology of free-standing endonucleases, and present areas of future research for this fascinating class of mobile genetic elements.

Better late than early: delayed translation of intron-encoded endonuclease I-TevI is required for efficient splicing of its host group I intron

The td group I intron interrupting the thymidylate synthase (TS) gene of phage T4 is a mobile intron that encodes the homing endonuclease I-TevI. Efficient RNA splicing of the intron is required to restore function of the TS gene, while expression of I-TevI from within the intron is required to initiate intron mobility. Three distinct layers of regulation temporally limit I-TevI expression to late in the T4 infective cycle, yet the biological rationale for stringent regulation has not been tested. Here, we deleted key control elements to deregulate I-TevI expression at early and middle times post T4 infection. Strikingly, we found that deregulation of I-TevI, or of a catalytically inactive variant, generated a thymidine-dependent phenotype that is caused by a reduction in td intron splicing. Prematurely terminating I-TevI translation restores td splicing, full-length TS synthesis, and rescues the thymidine-dependent phenotype. We suggest that stringent translational control of I-TevI evolved to prevent the ribosome from disrupting key structural elements of the td intron that are required for splicing and TS function at early and middle times post T4 infection. Analogous translational regulatory mechanisms in unrelated intron-open reading frame arrangements may also function to limit deleterious consequences on splicing and host gene function.

Survey of group I and group II introns in 29 sequenced genomes of the Bacillus cereus group: insights into their spread and evolution

Group I and group II introns are different catalytic self-splicing and mobile RNA elements that contribute to genome dynamics. In this study, we have analyzed their distribution and evolution in 29 sequenced genomes from the Bacillus cereus group of bacteria. Introns were of different structural classes and evolutionary origins, and a large number of nearly identical elements are shared between multiple strains of different sources, suggesting recent lateral transfers and/or that introns are under a strong selection pressure. Altogether, 73 group I introns were identified, inserted in essential genes from the chromosome or newly described prophages, including the first elements found within phages in bacterial plasmids. Notably, bacteriophages are an important source for spreading group I introns between strains. Furthermore, 77 group II introns were found within a diverse set of chromosomal and plasmidic genes. Unusual findings include elements located within conserved DNA metabolism and repair genes and one intron inserted within a novel retroelement. Group II introns are mainly disseminated via plasmids and can subsequently invade the host genome, in particular by coupling mobility with host cell replication. This study reveals a very high diversity and variability of mobile introns in B. cereus group strains.

Multiple controls regulate the expression of mobE, an HNH homing endonuclease gene embedded within a ribonucleotide reductase gene of phage Aeh1

Mobile genetic elements have the potential to influence the expression of genes surrounding their insertion site upon invasion of a genome. Here, we examine the transcriptional organization of a ribonucleotide reductase operon (nrd) that has been invaded by an HNH family homing endonuclease, mobE. In Aeromonas hydrophila phage Aeh1, mobE has inserted into the large-subunit gene (nrdA) of aerobic ribonucleotide reductase (RNR), splitting it into two smaller genes, nrdA-a and nrdA-b. This gene organization differs from that in phages T4, T6, RB2, RB3, RB15, and LZ7, where mobE is inserted in the nrdA-nrdB intergenic region. We present evidence that the expression of Aeh1 mobE is regulated by transcriptional, posttranscriptional, and translational controls. An Aeh1-specific late promoter drives expression of mobE, but strikingly the mobE transcript is processed internally at an RNase E-like site. We also identified a putative stem-loop structure upstream of mobE that sequesters the mobE ribosome binding site, presumably acting to down regulate MobE translation. Moreover, our transcriptional analyses indicate that the surrounding nrd genes of phage Aeh1 are expressed by a different strategy than are the corresponding phage T4 genes and that transcriptional readthrough is the only mechanism by which the promoterless Aeh1 nrdB gene is expressed. We suggest that the occurrence of multiple layers of control to limit the expression of mobE to late in the Aeh1 infection cycle is an adaptation of Aeh1 to reduce any effects on expression of the surrounding nrd genes early in phage infection when RNR function is critical.

Specialized lineages of bacterial group II introns

The Avi.groEL intron of Azotobacter vinelandii, which interrupts the termination codon of the groEL gene, is shown to belong to a monophyletic subset of bacterial group II introns that share a large insertion at their 5' extremity and a peculiar genetic localization. Some of these introns are inserted within, right next to, or very close to, a stop codon while others are located immediately 3' of, or close to, an initiation codon. After subgroup IIC introns, which target rho-independent transcription terminators, this is the second instance of a genetically specialized lineage of bacterial group II introns. Both the members of subgroup IIC and the relatives of Avi.groEL stand in contrast against the rest of group II retrotransposons in that features other than sequence must be used in target recognition. Among other specialized characters that could unite the two subgroups are: (i) the presence, next to the 5' splice site, of conserved RNA structures incompatible with the active fold of the group II ribozyme; and (ii) the likely involvement of the ribosome in the facilitation of the splicing process.

Rare group I intron with insertion sequence element in a bacterial ribonucleotide reductase gene

A rare group I intron in a cyanobacterial ribonucleotide reductase gene has been characterized. It contains a mobile insertion sequence element not required for RNA splicing. Ribonucleotide reductase genes were found to be hot spots for all three types of self-splicing intervening sequences, including group I and II introns and inteins.

Self-splicing of the bacteriophage T4 group I introns requires efficient translation of the pre-mRNA in vivo and correlates with the growth state of the infected bacterium

Bacteriophage T4 contains three self-splicing group I introns in genes in de novo deoxyribonucleotide biosynthesis (in td, coding for thymidylate synthase and in nrdB and nrdD, coding for ribonucleotide reductase). Their presence in these genes has fueled speculations that the introns are retained within the phage genome due to a possible regulatory role in the control of de novo deoxyribonucleotide synthesis. To study whether sequences in the upstream exon interfere with proper intron folding and splicing, we inhibited translation in T4-infected bacteria as well as in bacteria containing recombinant plasmids carrying the nrdB intron. Splicing was strongly reduced for all three T4 introns after the addition of chloramphenicol during phage infection, suggesting that the need for translating ribosomes is a general trait for unperturbed splicing. The splicing of the cloned nrdB intron was markedly reduced in the presence of chloramphenicol or when translation was hindered by stop codons inserted in the upstream exon. Several exon regions capable of forming putative interactions with nrdB intron sequences were identified, and the removal or mutation of these exon regions restored splicing efficiency in the absence of translation. Interestingly, splicing of the cloned nrdB intron was also reduced as cells entered stationary phase and splicing of all three introns was reduced upon the T4 infection of stationary-phase bacteria. Our results imply that conditions likely to be frequently encountered by natural phage populations may limit the self-splicing efficiency of group I introns. This is the first time that environmental effects on bacterial growth have been linked to the regulation of splicing of phage introns.

Quantitative analysis of group II intron expression and splicing in Lactococcus lactis

The group II intron Ll.ltrB is found within the ltrB relaxase gene of the conjugative element pRS01 in Lactococcus lactis. Precise splicing of the intron is essential for pRS01 transfer. The transcription regulation and in vivo splicing activity of Ll.ltrB have not been investigated thoroughly in L. lactis in the natural pRS01 context. We developed absolute quantitative real-time reverse transcription-PCR assays to quantify RNA levels of the 5' exon (ltrBE1) and the spliced relaxase (ltrB) and intron-encoded protein (ltrA) genes, as well as Ll.ltrB splicing activity under different physiological conditions. The mRNA levels for the ATP-binding protein OppD were assayed for comparison to the ltrB transcripts. The oppD mRNA ranged from 10- to 10,000-fold higher than ltrB region genes. ltrBE1 expression was growth-phase dependent. The mRNA level of ltrA was almost constant during all growth phases and in all media tested. Ll.ltrB in vivo splicing activity ranged from (6.5 +/- 2.1)% to (22.1 +/- 8.0)%. Acid challenge significantly decreased both ltrB region mRNA levels and intron splicing activity. The presence of recipient cells, different mating environments, and temperature stress had no significant effects on expression and splicing. Western blotting showed that the level of LtrB protein expressed from an intronless ltrB gene was much higher (about 20-fold) than the level of protein expressed from an intron-containing construct. Interestingly, LtrB protein showed a tendency to function in cis on its oriT target. The low level of ltrB transcript and relatively inefficient splicing of the intron may limit Ll.ltrB mobility and dissemination in nature.

Four inteins and three group II introns encoded in a bacterial ribonucleotide reductase gene

A bacterial ribonucleotide reductase gene was found to encode four inteins and three group II introns in the oceanic N2-fixing cyanobacterium Trichodesmium erythraeum. The 13,650-bp ribonucleotide reductase gene is divided into eight extein- or exon-coding sequences that together encode a 768-amino acid mature ribonucleotide reductase protein, with 83% of the gene sequence encoding introns and inteins. The four inteins are encoded on the second half of the gene, and each has conserved sequence motifs for a protein-splicing domain and an endonuclease domain. These four inteins, together with known inteins, define five intein insertion sites in ribonucleotide reductase homologues. Two of the insertion sites are 10 amino acids apart and next to key catalytic residues of the enzyme. Protein-splicing activities of all four inteins were demonstrated in Escherichia coli. The four inteins coexist with three group II introns encoded on the first half of the same gene, which suggests a breakdown of the presumed barrier against intron insertion in this bacterial conserved protein-coding gene.

A ribosomal function is necessary for efficient splicing of the T4 phage thymidylate synthase intron in vivo

Splicing of the group I intron of the T4 thymidylate synthase (td) gene was uncoupled from translation by introducing stop codons in the upstream exon. This resulted in severe splicing deficiency in vivo. Overexpression of a UGA suppressor tRNA partially rescued splicing, suggesting that this in vitro self-splicing intron requires translation for splicing in vivo. Inhibition of translation by the antibiotics chloramphenicol and spectinomycin also resulted in splicing deficiency. Ribosomal protein S12, a protein with RNA chaperone activity, and CYT-18, a protein that stabilizes the three-dimensional structure of group I introns, efficiently rescued the stop codon mutants. We identified a region in the upstream exon that interferes with splicing. Point mutations in this region efficiently alleviate the effect of a nonsense codon. We infer from these results that the ribosome acts as an RNA chaperone to facilitate proper folding of the intron.

pH dependence of self-splicing by the group IA2 intron in a pre-mRNA derived from the nrdB gene of bacteriophage T4

The nrdB gene of bacteriophage T4 contains a group IA2 intron. We have investigated the kinetics of self-splicing by a shortened variant of nrdB pre-mRNA in the presence of the co-substrates guanosine and 2'-amino-2'-deoxyguanosine. The pH dependence of the first transesterification step displayed parallel linear correlations for the two different co-substrates up to pH 7, above which the reaction with guanosine levels off to become pH independent. The plot for the 30-fold slower reaction with 2'-aminoguanosine is linear up to pH 8-8.5 and then levels off. The linear correlations with slopes close to unity suggest that a deprotonation event accelerates the transesterification reaction and that a change in rate limiting step occurs at a first order rate constant of approximately 1 min-1(i.e. for our system k cat/ K m approximately 10(5) M-1 min-1). The pH dependence of observed rate constants in different divalent metal ion mixtures, where the 2'-aminoguanosine-dependent reaction is enhanced 6- and 35-fold compared with that in magnesium, strongly supports this conclusion. This is, to our knowledge, the first report on an intact self-splicing group I intron where use of different co-substrates and divalent metal ions shows that a deprotonation enhances the rate and verifies that the transitions occurring during splicing of group I introns are all part of a common reaction sequence.