The complexification of cell to cell interactions along metazoan evolution has led to the development of a molecular network specialized in intercellular communication. Receptor tyrosine kinases (RTKs) are among the most ancient and important proteins that emerged in multicellular organisms. RTKs form a superfamily of transmembrane receptors that bind a large panel of ligands including hormones, growth factors and cytokines, and trigger different signalling cascades inside the cell for the control and regulation of key cellular processes. In eumetazoan organisms, RTK mediation is essential for embryogenesis [1,2], growth [3] and metabolic regulations [4]. RTK diversity increased along with speciation, possibly due to the acquisition of new regulatory processes in cell function, so that conserved and original classes of RTK could be found in different metazoan organisms [5][6][7]. RTKs possess a unique transmembrane domain and their capacity to transduce signals inside the cell is dependent on their autophosphorylation and requires vicinity of two tyrosine kinase (TK) domains. Members of the insulin receptor (IR) family belong to the very well conserved RTK class II, and were probably present in the most ancient metazoans because they have been identified in diploblastic organisms like sponge [8]. Although most of the RTK are monomeric and dimerize upon ligand binding, IR are constitutively assembled in a 2 b 2 heterotetramers [9,10]. Binding of insulin peptides
BackgroundTyrosine kinase receptors (RTKs) comprise a large family of membrane receptors that regulate various cellular processes in cell biology of diverse organisms. We previously described an atypical RTK in the platyhelminth parasite Schistosoma mansoni, composed of an extracellular Venus flytrap module (VFT) linked through a single transmembrane domain to an intracellular tyrosine kinase domain similar to that of the insulin receptor.Methods and FindingsHere we show that this receptor is a member of a new family of RTKs found in invertebrates, and particularly in insects. Sixteen new members of this family, named Venus Kinase Receptor (VKR), were identified in many insects. Structural and phylogenetic studies performed on VFT and TK domains showed that VKR sequences formed monophyletic groups, the VFT group being close to that of GABAB receptors and the TK one being close to that of insulin receptors. We show that a recombinant VKR is able to autophosphorylate on tyrosine residues, and report that it can be activated by L-arginine. This is in agreement with the high degree of conservation of the alpha amino acid binding residues found in many amino acid binding VFTs. The presence of high levels of vkr transcripts in larval forms and in female gonads indicates a putative function of VKR in reproduction and/or development.ConclusionThe identification of RTKs specific for parasites and insect vectors raises new perspectives for the control of human parasitic and infectious diseases.
Differentiated cells can be forced to change identity, either to directly adopt another differentiated identity or to revert to a pluripotent state. Direct reprogramming events can also occur naturally. We recently characterized such an event in Caenorhabditis elegans, in which a rectal cell switches to a neuronal cell. Here we have used this single-cell paradigm to investigate the molecular requirements of direct cell-type conversion, with a focus on the early steps. Our genetic analyses revealed the requirement of sem-4/Sall, egl-27/ Mta, and ceh-6/Oct, members of the NODE complex recently identified in embryonic stem (ES) cells, and of the OCT4 partner sox-2, for the initiation of this natural direct reprogramming event. These four factors have been shown to individually impact on ES cell pluripotency; however, whether they act together to control cellular potential during development remained an open question. We further found that, in addition to acting at the same time, these factors physically associate, suggesting that they could act together as a NODE-like complex during this in vivo process. Finally, we have elucidated the functional domains in EGL-27/MTA that mediate its reprogramming activity in this system and have found that modulation of the posterior HOX protein EGL-5 is a downstream event to allow the initiation of Y identity change. Our data reveal unique in vivo functions in a natural direct reprogramming event for these genes that impact on ES cells pluripotency and suggest that conserved nuclear events could be shared between different cell plasticity phenomena across phyla.transdifferentiation | regenerative medicine | metaplasia | SANT H ow differentiated cells can switch their identity is a fascinating question that has attracted much attention in the last decade. A number of studies have shown how strikingly easily a differentiated cell can be experimentally reprogrammed not only into an embryonic stem cell-like state (1) but also into another, different, differentiated identity (2). Remarkably, this process, called direct cell-type conversion or transdifferentiation, also occurs naturally (2).The molecular mechanisms underlying these events are still unclear and it remains to be determined whether key elements are shared between natural and induced reprogramming events. Factors used to reprogram differentiated cells to a stem cell-like state are important for embryonic stem (ES) cell self-renewal (1). Several studies have shed light on the molecular networks that maintain ES cell pluripotency (3). Key factors have been identified, such as Nanog (3) or SOX2 and OCT4 that are required for ES cell pluripotency and that, together with additional factors, can force fibroblasts into embryonic-like stem cells (1, 3). Besides these pluripotency factors, transcriptional repression complexes have been found necessary for ES cell self-renewal, but whether and how these complexes act together to control cellular potential during development remain to be determined. Among them, the NODE (Nanog and O...
Caenorhabditis elegans is a powerful in vivo model in which transgenesis is highly developed. However, while the analysis of biological phenomena often require the expression of more than one protein of interest, no reliable tool exists to ensure efficient concomitant and equivalent expression of more than two polypeptides from a single promoter. We report the use of viral 2A peptides, which trigger a "ribosomal-skip" or "STOP&GO" mechanism during translation, to express multiple proteins from a single vector in C. elegans. Although none of the viruses known to infect C. elegans contain 2A-like sequences, our results show that 2A peptides allow the production of separate functional proteins in all cell types and at all developmental stages tested in the worm. In addition, we constructed a toolkit including a 2A-based polycistronic plasmid and reagents to generate 2A-tagged fosmids. 2A peptides constitute an important tool to ensure the delivery of multiple polypeptides in specific cells, enabling several novel applications such as the reconstitution of multi-subunit complexes.
Although mitochondria are ubiquitous organelles, they exhibit tissue-specific morphology, dynamics and function. Here, we describe a robust approach to isolate mitochondria from specific cells of diverse tissue systems in Caenorhabditis elegans. Cell-specific mitochondrial affinity purification (CS-MAP) yields intact and functional mitochondria with exceptional purity and sensitivity (>96% enrichment, >96% purity, and single-cell and single-animal resolution), enabling comparative analyses of protein and nucleic acid composition between organelles isolated from distinct cellular lineages. In animals harbouring a mixture of mutant and wild-type mitochondrial genomes, we use CS-MAP to reveal subtle mosaic patterns of cell-type-specific heteroplasmy across large populations of animals (>10,000 individuals). We demonstrate that the germline is more prone to propagating deleterious mitochondrial genomes than somatic lineages, which we propose is caused by enhanced mtDNA replication in this tissue.
Natural interconversions between distinct somatic cell types have been reported in species as diverse as jellyfish and mice. The efficiency and reproducibility of some reprogramming events represent unexploited avenues in which to probe mechanisms that ensure robust cell conversion. We report that a conserved H3K27me3/me2 demethylase, JMJD-3.1, and the H3K4 methyltransferase Set1 complex cooperate to ensure invariant transdifferentiation (Td) of postmitotic Caenorhabditis elegans hindgut cells into motor neurons. At single-cell resolution, robust conversion requires stepwise histone-modifying activities, functionally partitioned into discrete phases of Td through nuclear degradation of JMJD-3.1 and phase-specific interactions with transcription factors that have conserved roles in cell plasticity and terminal fate selection. Our results draw parallels between epigenetic mechanisms underlying robust Td in nature and efficient cell reprogramming in vitro.
BackgroundReceptor tyrosine kinases (RTK) form a family of transmembrane proteins widely conserved in Metazoa, with key functions in cell-to-cell communication and control of multiple cellular processes. A new family of RTK named Venus Kinase Receptor (VKR) has been described in invertebrates. The VKR receptor possesses a Venus Fly Trap (VFT) extracellular module, a bilobate structure that binds small ligands to induce receptor kinase activity. VKR was shown to be highly expressed in the larval stages and gonads of several invertebrates, suggesting that it could have functions in development and/or reproduction.ResultsAnalysis of recent genomic data has allowed us to extend the presence of VKR to five bilaterian phyla (Platyhelminthes, Arthropoda, Annelida, Mollusca, Echinodermata) as well as to the Cnidaria phylum. The presence of NveVKR in the early-branching metazoan Nematostella vectensis suggested that VKR arose before the bilaterian radiation. Phylogenetic and gene structure analyses showed that the 40 receptors identified in 36 animal species grouped monophyletically, and likely evolved from a common ancestor. Multiple alignments of tyrosine kinase (TK) and VFT domains indicated their important level of conservation in all VKRs identified up to date. We showed that VKRs had inducible activity upon binding of extracellular amino-acids and molecular modeling of the VFT domain confirmed the structure of the conserved amino-acid binding site.ConclusionsThis study highlights the presence of VKR in a large number of invertebrates, including primitive metazoans like cnidarians, but also its absence from nematodes and chordates. This little-known RTK family deserves to be further explored in order to determine its evolutionary origin, its possible interest for the emergence and specialization of Metazoa, and to understand its function in invertebrate development and/or reproductive biology.
In spite of the numerous efforts made to control their transmission, parasite schistosomes still represent a serious public health concern and a major economic problem in many developing countries. Praziquantel (PZQ) is the drug of choice for the treatment of schistosomiasis and the only one that is available for mass chemotherapy. However, its widespread use and its inefficacy on juvenile parasites raise fears that schistosomes will develop drug resistance, and make the development of alternative drugs highly desirable. Protein tyrosine kinases (PTKs) are key molecules that control cell differentiation and proliferation and they already represent important targets for molecular cancer therapy. The recent characterization in Schistosoma mansoni of several cytosolic and receptor PTKs, with properties similar but also divergent from their vertebrate counterparts, opens new perspectives for the development of novel strategies in chemotherapy of schistosomiasis, which could be based on the use of parasite-specific tyrosine phosphorylation inhibitors.
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