Habitat selection by marine larvae in changing chemical environments

The replenishment and persistence of marine species is contingent on dispersing larvae locating suitable habitat and surviving to a reproductive stage. Pelagic larvae rely on environmental cues to make behavioural decisions with chemical information being important for habitat selection at settlement. We explored the sensory world of crustaceans and fishes focusing on the impact anthropogenic alterations (ocean acidification, red soil, pesticide) have on conspecific chemical signals used by larvae for habitat selection. Crustacean (Stenopus hispidus) and fish (Chromis viridis) larvae recognized their conspecifics via chemical signals under control conditions. In the presence of acidified water, red soil or pesticide, the ability of larvae to chemically recognize conspecific cues was altered. Our study highlights that recruitment potential on coral reefs may decrease due to anthropogenic stressors. If so, populations of fishes and crustaceans will continue their rapid decline; larval recruitment will not replace and sustain the adult populations on degraded reefs.

Fringing reefs exposed to different levels of eutrophication and sedimentation can support similar benthic communities

Benthic communities are sensitive to anthropogenic disturbances which can result in changes in species assemblages. A spatio-temporal survey of environmental parameters was conducted over an 18-month period on four different fringing reefs of Moorea, French Polynesia, with unusual vs. frequent human pressures. This survey included assessment of biological, chemical, and physical parameters. First, the results showed a surprising lack of a seasonal trend, which was likely obscured by short-term variability in lagoons. More frequent sampling periods would likely improve the evaluation of a seasonal effect on biological and ecological processes. Second, the three reef habitats studied that were dominated by corals were highly stable, despite displaying antagonistic environmental conditions through eutrophication and sedimentation gradients, whereas the reef dominated by macroalgae was relatively unstable. Altogether, our data challenge the paradigm of labelling environmental parameters such as turbidity, sedimentation, and nutrient-richness as stress indicators.

Mitochondrial upstream promoter sequences modulate in vivo the transcription of a gene in yeast mitochondria

An in vivo study of the importance of the length and/or structures of sequences upstream of a mitochondrial promoter was undertaken in Saccharomyces cerevisiae. Short tandem mtDNA repeats were introduced upstream of the COX2 gene. Our data show that its expression is modulated by the sequence located over 200 bp upstream of the promoter. A deletion decreases the level of transcripts to about 50%. The initial level can be recovered by a fill-in AT-rich sequence or partially by the presence of a long repeat tract; on the contrary, a smaller number of copies tends to intensify the effect of the deletion. These results show that the length and base composition upstream of mitochondrial promoter are involved in vivo in the modulation of the gene expression.

Expansion/contraction of mammalian mitochondrial DNA repeats in Escherichia coli mimics the mitochondrial heteroplasmy

Length polymorphism due to tandem repeats is a common feature in animal mitochondrial DNA. The rabbit mitochondrial genome contains a 20 bp repeat domain, which generates a general heteroplasmic state. The observed polymorphic patterns suggest a dynamic equilibrium between gain and loss of units that maintains the copy number in the range 3-19 repeat units. In the apparent absence of recombination, slipped-strand mispairing during replication appears to be the primary cause of additions and deletions. To investigate this hypothesis we have set up a plasmid assay in Escherichia coli. A variable number of repeat units was inserted into a plasmid in both orientations relative to the colE1 origin of replication. Our data show that (i) a minimum unit number (>3) is necessary to generate length polymorphs, (ii) the number of events increases with the length tract, (iii) an excess of additions over deletions is found when the copy number is less than 10 and the trend is reversed when it is over 10, (iv) the frequency of deletions-additions is dependent on the orientation, (v) the polymorphism patterns are different according to the orientation. The length polymorphic pattern generated in the bacteria, in one orientation, mimics that observed in the mitochondria, suggesting that slipped mispairing between repeated sequences during DNA replication is responsible for the mitochondrial heteroplasmic state.

Mitochondrial membrane potential and ageing in Podospora anserina

Some filamentous fungi exhibit a limited vegetative growth with modifications in the mitochondria, suggesting the involvement of mitochondria in the process of ageing. Nevertheless, the relationship between the ability to grow or the fate of these cells relative to their mitochondrial membrane potential (Psi(mt)) level has not been investigated. Using flow cytometric analysis, we have assessed Psi(mt) in young and senescent cultures of wild type strains and mitochondrial or nuclear mutant strains of Podospora anserina that present very long or brief life span. When we compared two distinct populations of cells obtained from the same strain, we can show a correlation not only between Psi(mt) and ageing, but also between Psi(mt) and the frequency of regeneration and/or the life span. However, this relationship is not observed when we compared the cells obtained from different physiological states or mutants strains. These results allow us to suggest that the Psi(mt) modifications during senescence could be only one of the possible consequences of the process and are not the factor driving towards death. We also show that the driving force of Psi(mt) is principally maintained by the alternative pathway during ageing, suggesting a role of the alternative oxidase pathway.

Intronic GIY-YIG endonuclease gene in the mitochondrial genome of Podospora curvicolla: evidence for mobility

Endonuclease genes encoded in invasive introns are themselves supposed to be mobile elements which, during evolution, have colonized pre-existing introns converting them into invasive elements. This hypothesis is supported by numerous data concerning the LAGLI-DADG subclass of intronic endonucleases. Less is known about the GIY-YIG ORFs which constitute another family of endonucleases. In this paper we describe the presence of one optional GIY-YIG ORF in the second intron of the mitochondrial cytochrome b gene in the fungus Podospora curvicolla. We show that this GIY-YIG ORF is efficiently transferred from an ORF-containing intron to an ORF-less allele. We also show that the products of both the GIY-YIG ORF and the non-canonical LAGLI-DADG-GIY-YIG ORF, which is generated by its integration, have endonuclease activities which recognize and cut the insertion site of the optional sequence. This constitutes the first direct evidence for potential mobility of an intronic GIY-YIG endonuclease. We discuss the role that such a mobile sequence could have played during evolution.

Premature death in Podospora anserina: sporadic accumulation of the deleted mitochondrial genome, translational parameters and innocuity of the mating types

The Podospora anserina premature death syndrome was described as early growth arrest caused by a site-specific deletion of the mitochondrial genome (mtDNA) and occurring in strains displaying the genotype AS1-4 mat-. The AS1-4 mutation lies in a gene encoding a cytosolic ribosomal protein, while mat- is one of the two forms (mat- and mat+) of the mating-type locus. Here we show that, depending on culture conditions, death due to the accumulation of the deleted mtDNA molecule can occur in the AS1-4 mat+ context and can be delayed in the AS1-4 mat- background. Furthermore, we show that premature death and the classical senescence process are mutually exclusive. Several approaches permit the identification of the mat-linked gene involved in the appearance of premature death. This gene, rmp, exhibits two natural alleles, rmp- linked to mat- and rmp+ linked to mat+. The first is probably functional while the second probably carries a nonsense mutation and is sporadically expressed through natural suppression. A model is proposed that emphasizes the roles played by the AS1-4 mutation, the rmp gene, and environmental conditions in the accumulation of the deleted mitochondrial genome characteristic of this syndrome.

Rapid methods for nucleic acids extraction from Petri dish-grown mycelia

We have developed rapid and economic methods for the isolation of nucleic acids from filamentous fungi. The main advantages of these methods are: (1) the mycelium is directly recovered from a Petri-dish culture, (2) the complete experiment takes place in microfuge tubes, (3) it is very fast and allows for the processing of 24 samples in the same day, and (4) up to 100 micrograms of total DNA or RNA are recovered, both of which are sufficiently pure for most purposes. Of particular interest is the recovery of large amounts of mitochondrial DNA as visualised by electrophoresis in ethidium bromide-stained gels.

The mat- allele of Podospora anserina contains three regulatory genes required for the development of fertilized female organs

In the filamentous fungus Podospora anserina, mating type is specified by a single locus with two alternate alleles, termed mat- and mat+. A previous study has shown that the mat+ sequence consists of 3.7 kb and contains a single gene relevant to the sexual cycle. This gene, called FPR1, encodes a protein with a HMG DNA-binding domain and is required for fertilization and for the development of the fertilized fruiting body. The mat- sequence, which is 4.7 kb in length, displays a more complex structure. We present here the characterization of two genes, called SMR1 and SMR2, which are present in the mat- allele along with the FMR1 gene. FMR1, whose role in the sexual cycle has been already partially described, encodes a protein with an alpha 1-domain and was shown to control fertilization. We demonstrate that these three genes are required for the developmental events that occur in the female organ after fertilization. The additional role of FMR1 requires a region of unknown function that is distinct from the alpha 1-domain. SMR1 encodes a protein with a putative acidic/hydrophobic alpha-helix, which has been proposed to be a feature common to transcriptional activators. The protein sequence deduced from SMR2 contains an HMG motif suggesting that it is a transcription factor.

Transposition of a group II intron

Among mobile genetic elements, self-splicing introns are of particular interest. They belong to either group I or group II depending on their three-dimensional structure. Homing, the systematic intron invasion of an intronless gene when it encounters its homologous intron-bearing allele, is the only means for intron mobility so far demonstrated. It depends on the activity of the intron-encoded protein and is very specific for the acceptor site. Intron transposition, the transfer of an intron to a novel site, predicted on the basis of phylogenetic studies and in vitro reverse-splicing experiments, has been proposed to be responsible for evolutionary intron spreading. Here we present results from polymerase chain reaction experiments consistent with transposition of a group II intron. This event is proposed to account for the site-specific deletion in the mitochondrial chromosome of the fungus Podospora anserina that is associated with the premature death syndrome and might also be involved in the senescence process affecting this species.