Project description:The transition from unicellular to multicellular life required the acquisition of coordinated and regulated cellular behaviors, including adhesion and migration. In metazoans, this relies on cell adhesion proteins, signaling systems, and an elaborate extracellular matrix (ECM) that contributes to cell adhesion and to the milieu in which signaling interactions occur. Innovations in these pathways that enabled complex multicellularity occurred at the level of new genes, new functions for existing genes, but also at the regulatory level. Gene regulation by microRNAs expanded with the evolution of multicellularity, but the functions of individual microRNAs in this context are largely unexplored. A single microRNA, miR-100, arose in the last common eumetazoan ancestor and is widely conserved across animals. Here, we reveal the molecular function of the homolog of miR-100 in C. elegans, the miR-51 family. The miR-51 family acts in a dose dependent manner to control morphogenesis by regulating several genes involved in cell signaling, adhesion and migration, including modifiers of the ECM, specifically heparan sulfate sulfotransferases (HSTs). Specific HSTs and signaling pathway components are also predicted conserved targets of miR-100 across vertebrates. Our work suggests that this miRNA provided an innovation in the regulation of cellular interactions early in metazoan evolution, as animals evolved to form more complex bodies.

Project description:Ηepatocellular carcinoma (HCC) accounts for the majority of primary liver cancers. Early de-tection/diagnosis is vital for the prognosis of HCC whereas diagnosis at late stages is associated with very low survival rate. Early diagnosis is based on patient’s 6 month surveillance and use of at least two imaging modalities. The aim of this study was to investigate diagnostic markers for the detection of early HCC based on proteome analysis, microRNAs (miRNAs) and circulat-ing tumor cells (CTCs) in the blood of patients with cirrhosis, early and advanced HCC. We studied 89 patients with HCC of whom 33 had early HCC and 28 cirrhotic patients. CTCs were detected by Real-Time Quantitative Reverse Transcription PCR and immunofluorescence using the markers Epithelial cell adhesion molecule (EPCAM), Vimentin, A Fetoprotein (AFP) and surface major Vault protein (sMVP). Expression of the five most commonly HCC-involved miRNAs (miR-122, miR-200a, miR-200b, miR-221, miR-222) was examined in the serum by qRT-PCR. Finally patient serum was analyzed by whole proteome analysis (LC/MS). Twenty seven out of 53 (51%) patients with advanced HCC had detectable CTCs. Among them, 10/27 (37%) presented evidence of mesenchymal or intermediate stage cells (vimentin and/or sMVP positive). Moreover, 5/17 (29%) patients with early HCC and 6/28 (21%) cirrhotic patients had detectable CTCs. Patients with early and advanced HCC exhibited a significant increase of miR-200b when compared to cirrhotic patients. Our proteome analysis indicated that early HCC patients present a significant upregulation of APOA2, APOC3 proteins when compared to cir-rhotic patients, that when used in combination, cover the 100% of the patients with early HCC. In conclusion, miR-200b, APOA2 and APOC3 proteins are sensitive markers and can be poten-tially useful in combination for the early diagnosis of HCC.

Project description:The evolution of complex multicellularity has been one of the major transitions in the history of life. In contrast to simple multicellular aggregates of cells, it has evolved only in a handful of lineages, including the animals, embryophytes, red and brown algae and fungi. Despite being a key step towards the evolution of complex organisms, the evolutionary origins and the genetic underpinnings of complex multicellularity are incompletely known. We constructed a reference atlas of mushroom formation based on developmental transcriptome data of six species and comparisons of >200 whole genomes, to elucidate the core genetic program of complex multicellularity and fruiting body development in mushroom-forming fungi (Agaricomycetes). Nearly 300 conserved gene families and >70 functional groups contained developmentally regulated genes from five to six species, covering functions related to fungal cell wall (FCW) remodeling, targeted protein degradation, signal transduction, adhesion and small secreted proteins (including effector-like orphan genes). Several of these families, including F-box proteins, expansin-like proteins, protein kinases, and transcription factors, showed expansions in Agaricomycetes, with from which many convergently expandedwere identified in multicellular plants and/or animals too, assuming convergent solutions to genetic hurdles imposed by complex multicellularity among independently evolved lineages. This study provides a novel entry point to studying mushroom development and complex multicellularity in one of the largest clades of complex eukaryotic organisms.

Project description:The evolution of complex multicellularity has been one of the major transitions in the history of life. In contrast to simple multicellular aggregates of cells, it has evolved only in a handful of lineages, including the animals, embryophytes, red and brown algae and fungi. Despite being a key step towards the evolution of complex organisms, the evolutionary origins and the genetic underpinnings of complex multicellularity are incompletely known. We constructed a reference atlas of mushroom formation based on developmental transcriptome data of six species and comparisons of >200 whole genomes, to elucidate the core genetic program of complex multicellularity and fruiting body development in mushroom-forming fungi (Agaricomycetes). Nearly 300 conserved gene families and >70 functional groups contained developmentally regulated genes from five to six species, covering functions related to fungal cell wall (FCW) remodeling, targeted protein degradation, signal transduction, adhesion and small secreted proteins (including effector-like orphan genes). Several of these families, including F-box proteins, expansin-like proteins, protein kinases, and transcription factors, showed expansions in Agaricomycetes, with from which many convergently expandedwere identified in multicellular plants and/or animals too, assuming convergent solutions to genetic hurdles imposed by complex multicellularity among independently evolved lineages. This study provides a novel entry point to studying mushroom development and complex multicellularity in one of the largest clades of complex eukaryotic organisms.

Project description:The evolution of complex multicellularity has been one of the major transitions in the history of life. In contrast to simple multicellular aggregates of cells, it has evolved only in a handful of lineages, including the animals, embryophytes, red and brown algae and fungi. Despite being a key step towards the evolution of complex organisms, the evolutionary origins and the genetic underpinnings of complex multicellularity are incompletely known. We constructed a reference atlas of mushroom formation based on developmental transcriptome data of six species and comparisons of >200 whole genomes, to elucidate the core genetic program of complex multicellularity and fruiting body development in mushroom-forming fungi (Agaricomycetes). Nearly 300 conserved gene families and >70 functional groups contained developmentally regulated genes from five to six species, covering functions related to fungal cell wall (FCW) remodeling, targeted protein degradation, signal transduction, adhesion and small secreted proteins (including effector-like orphan genes). Several of these families, including F-box proteins, expansin-like proteins, protein kinases, and transcription factors, showed expansions in Agaricomycetes, with from which many convergently expandedwere identified in multicellular plants and/or animals too, assuming convergent solutions to genetic hurdles imposed by complex multicellularity among independently evolved lineages. This study provides a novel entry point to studying mushroom development and complex multicellularity in one of the largest clades of complex eukaryotic organisms.

Project description:The evolution of complex multicellularity has been one of the major transitions in the history of life. In contrast to simple multicellular aggregates of cells, it has evolved only in a handful of lineages, including the animals, embryophytes, red and brown algae and fungi. Despite being a key step towards the evolution of complex organisms, the evolutionary origins and the genetic underpinnings of complex multicellularity are incompletely known. We constructed a reference atlas of mushroom formation based on developmental transcriptome data of six species and comparisons of >200 whole genomes, to elucidate the core genetic program of complex multicellularity and fruiting body development in mushroom-forming fungi (Agaricomycetes). Nearly 300 conserved gene families and >70 functional groups contained developmentally regulated genes from five to six species, covering functions related to fungal cell wall (FCW) remodeling, targeted protein degradation, signal transduction, adhesion and small secreted proteins (including effector-like orphan genes). Several of these families, including F-box proteins, expansin-like proteins, protein kinases, and transcription factors, showed expansions in Agaricomycetes, with from which many convergently expandedwere identified in multicellular plants and/or animals too, assuming convergent solutions to genetic hurdles imposed by complex multicellularity among independently evolved lineages. This study provides a novel entry point to studying mushroom development and complex multicellularity in one of the largest clades of complex eukaryotic organisms.

Project description:The evolution of complex multicellularity has been one of the major transitions in the history of life. In contrast to simple multicellular aggregates of cells, it has evolved only in a handful of lineages, including the animals, embryophytes, red and brown algae and fungi. Despite being a key step towards the evolution of complex organisms, the evolutionary origins and the genetic underpinnings of complex multicellularity are incompletely known. We constructed a reference atlas of mushroom formation based on developmental transcriptome data of six species and comparisons of >200 whole genomes, to elucidate the core genetic program of complex multicellularity and fruiting body development in mushroom-forming fungi (Agaricomycetes). Nearly 300 conserved gene families and >70 functional groups contained developmentally regulated genes from five to six species, covering functions related to fungal cell wall (FCW) remodeling, targeted protein degradation, signal transduction, adhesion and small secreted proteins (including effector-like orphan genes). Several of these families, including F-box proteins, expansin-like proteins, protein kinases, and transcription factors, showed expansions in Agaricomycetes, with from which many convergently expandedwere identified in multicellular plants and/or animals too, assuming convergent solutions to genetic hurdles imposed by complex multicellularity among independently evolved lineages. This study provides a novel entry point to studying mushroom development and complex multicellularity in one of the largest clades of complex eukaryotic organisms.

Project description:Interactions with the extracellular matrix (ECM) through integrin adhesion receptors provide cancer cells with physical and chemical cues that act in concert with growth factors to support survival and proliferation. Preclinical studies testing beta1 integrin antagonists in (breast) cancer models have shown inhibition of tumor growth and sensitization to radio- or chemotherapy and these strategies are currently evaluated in clinical trials. Here, we show that disruption of beta1 integrin-mediated ECM adhesion attenuates breast tumor growth but dissemination to the lungs from such small tumors can be markedly enhanced. beta1 integrin downregulation induces compensatory upregulation of beta3 integrins, but increased beta3 expression does not lead to enhanced lung metastasis. Instead, beta1 integrin downregulation in human and mouse triple negative, E-cadherin positive breast cancer cells elicits a switch from collective invasion to individual cell migration in 3D ECM. This involves alterations in the TGFbeta-BMP signaling network shifting the balance between miR-200 and ZEB, which causes a block in E-cadherin transcription. The switch is fully reversible: restored beta1 expression reinstates E-cadherin expression and cell cohesion. Moreover, restoring the network at the level of TGFbetaR, ZEB/miR-200 balance, or E-cadherin, restores cohesion and prevents the induction of lung metastasis without affecting tumor growth. These findings reveal that integrin-mediated ECM-attachments regulate a signaling network in control of epithelial characteristics that suppress metastatic spread. This raises concerns with respect to the use of beta1 integrins as cancer drug targets

Project description:miR-493-5p, miR-3662, and miR-589-3p were estimated as working microRNAs in bleomycin- and methotrexate-induced phenotypic changes in A549 cells via microRNAs-Proteins Analysis of Integrative Relationship (miR-PAIR). To verify the effect of these miRNAs on the their target protein expression levels, comprehensive expression of proteins in A549 cells treated with miR-493-59, miR-3662, and miR-589-3p mimic was examined by SWATH-MS method. As expected by a miR-PAIR mehtod, almost target proteins were succesfully regulated by miR-493-5p and miR-589-3p mimics.

Project description:The immunomodulatory potential of mesenchymal stromal cells (MSCs) has led to their widespread exploration in treating various inflammatory conditions. MSCs sourced from adult tissues such as bone marrow, Wharton’s jelly, and adipose tissue are multipotent and exhibit strong stemness characteristics. According to the International Society for Cell and Gene Therapy, MSCs are defined by their plastic-adherent, fibroblast-like morphology, expression of surface markers CD90, CD105, and CD73 (positive), absence of markers like CD34, CD45, and HLA-DR (negative), and their ability to differentiate into multiple lineages in vitro. Despite promising therapeutic outcomes, the clinical application of MSCs faces several obstacles. These include limitations associated with autologous stem cell efficiency, the invasiveness of administration procedures, risks of immune rejection, and the high costs associated with cell isolation, maintenance, and storage. Additionally, ensuring consistent cell viability, preventing spontaneous differentiation, and maintaining quality control contribute further to the financial and logistical challenges, limiting broader clinical accessibility. In recent years, the MSC-derived secretome has emerged as a compelling alternative in regenerative medicine. As MSCs exert many of their therapeutic effects via paracrine signaling rather than direct tissue integration, the secretome—a complex mix of cytokines, growth factors, extracellular vesicles (EVs), and microRNAs—offers a cell-free therapeutic option. However, the composition of the secretome is highly variable and influenced by factors such as tissue source, donor variability, culture conditions, passage number, and environmental cues. The MSC secretome contains a diverse range of biologically active molecules, including anti-inflammatory, pro-angiogenic, and signaling factors. Key components include growth factors like VEGF, TGF, FGF, HGF, and IGF; chemokines such as CCL-2, CCL-5, CCL-10, and CCL-20; and microRNAs like miR-27a, miR-133, miR-196a, miR-206, miR-15a/b, and miR-125b-5p. Additionally, anti-apoptotic and immunoregulatory molecules such as Indoleamine 2,3-dioxygenase (IDO) and Interleukin-10 (IL-10), as well as ECM-related proteins, are present. The functional plasticity of the MSC secretome can be enhanced by altering culture conditions—for instance, hypoxic environments, 3D culture systems, or exposure to specific stimulants. These strategies influence the secretome’s role in immunomodulation, extracellular matrix (ECM) remodeling, and angiogenesis. Notably, MSCs exposed to inflammatory stimuli adopt a more immunosuppressive phenotype, promoting the release of anti-inflammatory factors. Our study investigates the impact of priming MSCs with a defined protein cocktail on the composition of their secretome.