Therapeutic peptides: Targeting the mitochondrion to modulate apoptosis

For many years, medical drug discovery has extensively exploited peptides as lead compounds. Currently, novel structures of therapeutic peptides are derived from active pre-existing peptides or from high-throughput screening, and optimized following a rational drug design approach. Molecules of interest may prove their ability to influence the disease outcome in animal models and must respond to a set of criteria based on toxicity studies, ease of administration, the cost of their synthesis, and logistic for clinical use to validate it as a good candidate in a therapeutic perspective. This applies to the potential use of peptides to target one central intracellular organelle, the mitochondrion, to modulate (i.e. activate or prevent) apoptosis. Putative mitochondrial protein targets and the strategies already elaborated to correct the defects linked to these proteins (overexpression, inactivation, mutation..., etc.) are described, and recent advances that led or may lead to the conception of therapeutic peptides via a specific action on these mitochondrial targets in the future are discussed.     

Interaction between Polo and BicD proteins links oocyte determination and meiosis control in Drosophila

Meiosis is a specialized cell cycle limited to the gametes in Metazoa. In Drosophila, oocyte determination and meiosis control are interdependent processes, and BicD appears to play a key role in both. However, the exact mechanism of how BicD-dependent polarized transport could influence meiosis and vice versa remains an open question. In this article, we report that the cell cycle regulatory kinase Polo binds to BicD protein during oogenesis. Polo is expressed in all cells during cyst formation before specifically localizing to the oocyte. This is the earliest known example of asymmetric localization of a cell-cycle regulator in this process. This localization is dependent on BicD and the Dynein complex. Loss- and gain-of-function experiments showed that Polo has two independent functions. On the one hand, it acts as a trigger for meiosis. On the other hand, it is independently required, in a cell-autonomous manner, for the activation of BicD-dependent transport. Moreover, we show that Polo overexpression can rescue a hypomorphic mutation of BicD by restoring its localization and its function, suggesting that the requirement for Polo in polarized transport acts through regulation of BicD. Taken together, our data indicate the existence of a positive feedback loop between BicD and Polo, and we propose that this loop represents a functional link between oocyte specification and the control of meiosis.     

Statistical Evidence for a More Than 800-Million-Year-Old Evolutionarily Conserved Genomic Region in Our Genome

Identification of conserved genomic regions between different species is crucial for the reconstruction of their last common ancestor. Indeed, such regions of conservation in todays species (if not due to chance) may either constitute stigmata of an ancestrally conserved region or result from a series of independent convergent events. The more phylogenetically distant the compared species are, the more we expect rearrangements and thus difficulties in finding regions of conservation. Here we decipher with strong evidence conserved genomic regions between vertebrates (human and zebrafish) and arthropods (Drosophila and Anopheles). This work includes a robust phylogenetic analysis in conjunction with a stringent statistical testing that allowed the significant rejection of a by chance conservation hypothesis. The conservation of gene clusters across four different species from two phylogenetically distant groups makes the hypothesis of an ancestral conservation more likely and parsimonious than the hypothesis of individual convergent events. This result shows that, in spite of more than 800 million years of divergence and evolution from their last common ancestor, we can still reveal stigmata of conservation between all these species. The last common ancestor of zebrafish, human, Drosophila, and Anopheles is the common ancestor of all protostomes and deuterostomes known as Urbilateria. This study reveals clusters of probably ancestrally conserved genes and constitutes an advance toward the reconstruction of the genome of Urbilateria. Thus this work allows a better understanding of the evolutionary history of metazoan genomes, including our genome.This article contains online supplementary text and tables.Reviewing Editor: Dr. Yves Van de Peer     

Discordance in Variation of the ITS Region and the Mitochondrial COI Gene in the Subterranean Amphipod Crangonyx islandicus

The amphipod Crangonyx islandicus is a recently discovered species endemic to Iceland. Populations of C. islandicus are highly structured geographically and genetically. The COI and 16S mitochondrial genes confine six monophyletic groups which have diverged for up to 5 million years within Iceland, and may present two cryptic species. To investigate the potential cryptic species status we analyse here the internal transcribed spacers (ITS1 and ITS2) and compare its variation with the patterns obtained with the mtDNA. The ITS regions present much less divergence among the geographic regions in comparison with the mtDNA, distances based on ITS1 are correlated with the COI distances as well as with geographic distances, but most of the variation is observed within individuals. The variation in the ITS region appears to have been shaped both by homogenization effect of concerted evolution and divergent evolution. A duplication of 269 base pairs is found in the ITS1 of all individuals from the southern populations, its divergence from its paralog appears to predate the split of the different groups within Iceland but some evidence point to rapid diversification after the split. This duplication does not affect the secondary structures found in the 3' and 5' ends of the sequence, suggested to have a role in the excision of the ITS1. Compensatory base changes within the ITS2 sequences which have been suggested to be a species indicator were not detected.     

The unified neutral theory of biodiversity and biogeography at age ten

A decade has now passed since Hubbell published The Unified Neutral Theory of Biodiversity and Biogeography. Neutral theory highlights the importance of dispersal limitation, speciation and ecological drift in the natural world and provides quantitative null models for assessing the role of adaptation and natural selection. Significant advances have been made in providing methods for understanding neutral predictions and comparing them with empirical data. In this review, we describe the current state-of-the-art techniques and ideas in neutral theory and how these are of relevance to ecology. The future of neutral theory is promising, but its concepts must be applied more broadly beyond the current focus on species-abundance distributions.     

A complex of catalytically inactive protein phosphatase-1 sandwiched between Sds22 and inhibitor-3

Protein Ser/Thr phosphatase-1 (PP1) associates with a host of proteins to form substrate-specific holoenzymes. Sds22 and Inhibitor-3 (I3) are two independently described ancient interactors of PP1. We show here by various approaches that Sds22 and I3 form a heterotrimeric complex with PP1, both in cell lysates and after purification. The stability of the complex depended on functional PP1 interaction sites in Sds22 and I3, indicating that PP1 is sandwiched between Sds22 and I3. Intriguingly, I3 could not be replaced in this complex by another PP1 interactor with the same PP1 binding motif. In vitro, Sds22 and I3 were potent inhibitors of PP1, but with only some substrates. The inhibition by Sds22 could be reproduced with synthetic Sds22 fragments comprising leucine-rich repeats (LRR) 2 and 5. Sds22 and LRR5 also slowly converted PP1 into a conformation that was inactive with all tested substrates. Cell lysates that were prepared under conditions that prevented the Sds22-induced inactivation of PP1 contained a catalytically inactive complex of Sds22, PP1, and I3, indicating that this complex exists in vivo. Therefore, our studies show that a pool of PP1 is complexly controlled by both Sds22 and I3.     

The heritage of pathogen pressures and ancient demography in the human innate-immunity CD209/CD209L region

The innate immunity system constitutes the first line of host defense against pathogens. Two closely related innate immunity genes, CD209 and CD209L, are particularly interesting because they directly recognize a plethora of pathogens, including bacteria, viruses, and parasites. Both genes, which result from an ancient duplication, possess a neck region, made up of seven repeats of 23 amino acids each, known to play a major role in the pathogen-binding properties of these proteins. To explore the extent to which pathogens have exerted selective pressures on these innate immunity genes, we resequenced them in a group of samples from sub-Saharan Africa, Europe, and East Asia. Moreover, variation in the number of repeats of the neck region was defined in the entire Human Genome Diversity Panel for both genes. Our results, which are based on diversity levels, neutrality tests, population genetic distances, and neck-region length variation, provide genetic evidence that CD209 has been under a strong selective constraint that prevents accumulation of any amino acid changes, whereas CD209L variability has most likely been shaped by the action of balancing selection in non-African populations. In addition, our data point to the neck region as the functional target of such selective pressures: CD209 presents a constant size in the neck region populationwide, whereas CD209L presents an excess of length variation, particularly in non-African populations. An additional interesting observation came from the coalescent-based CD209 gene tree, whose binary topology and time depth (approximately 2.8 million years ago) are compatible with an ancestral population structure in Africa. Altogether, our study has revealed that even a short segment of the human genome can uncover an extraordinarily complex evolutionary history, including different pathogen pressures on host genes as well as traces of admixture among archaic hominid populations.     

In vivo activation of blood and arterial prophospholipase by an activator of blood platelet origin]

When partially purified platelet-rat lysate is injected in the rat aorta, transformation of prophospholipase into phospholipase is observed. Blood prophospholipases are activated almost entirely during about 15 minutes; aortic phospholipase are entirely activated for a longer time.