Interpreted gene expression of human dermal fibroblasts after adipo-, chondro- and osteogenic phenotype shifts

Autologous cell-based therapies promise important developments for reconstructive surgery. In vitro expansion as well as differentiation strategies could provide a substantial benefit to cellular therapies. Human dermal fibroblasts, considered ubiquitous connective tissue cells, can be coaxed towards different cellular fates, are readily available and may altogether be a suitable cell source for tissue engineering strategies. Global gene expression analysis was performed to investigate the changes of the fibroblast phenotype after four-week inductions toward adipocytic, osteoblastic and chondrocytic lineages. Differential gene regulation, interpreted through Gene Set Enrichment Analysis, highlight important similarities and differences of induced fibroblasts compared to control cultures of human fibroblasts, adipocytes, osteoblasts and articular chondrocytes. Fibroblasts show an inherent degree of phenotype plasticity that can be controlled to obtain cells supportive of multiple tissue types.     

The recessive phenotype of forked can be uncovered by heat shock in Drosophila

Heat shock uncovers the recessive forked phenotype when heterozygotes between f^36a and wild-type are heated during sensitive periods in pupal development. We call the phenocopy of a mutant in such a heterozygote a heterocopy. The heterocopy in f^36a/+ is virtually identical to the mutant phenotype; however, bristles on different parts of the body are affected during different sensitive periods. We discuss the hypothesis that the heat shock acts by affecting expression of the wild-type gene product corresponding to the mutant gene. The sensitive period for heterocopy induction in a specific tissue is proposed to correspond to the normal time of gene expression for the forked gene product in a particular tissue.     

Antisense technology in molecular and cellular bioengineering

Antisense technology is finding increasing application not only in clinical development, but also for cellular engineering. Several types of antisense methods (e.g. antisense oligonucleotides, antisense RNA and small interfering RNA) can be used to inhibit the expression of a target gene. These antisense methods are being used as part of metabolic engineering strategies to downregulate enzymes controlling undesired pathways with regard to product formation. In addition, they are beginning to be utilized to control cell phenotype in tissue engineering constructs. As improved methods for antisense effects that can be externally regulated emerge, these approaches are likely to find increased application in cellular engineering applications.     

Specific genetic interference with behavioral rhythms in Drosophila by expression of inverted repeats

We describe a new experimental technique that allows for a tissue-specific reduction of gene activity in the Drosophila nervous system. On the basis of the observation that certain gene functions can be ubiquitously blocked by injecting double-stranded RNA into Drosophila embryos, we employed a method to interfere with an individual gene function permanently in a predetermined cell type. This was achieved by the formation of an inverted-repeat RNA sequence in the tissue of interest under control of the GAL4/UAS binary expression system. As an example, we show that inverted-repeat-mediated interference with the period gene produces a hypomorphic period phenotype. A selective decrease of period RNA appears to be a component of the cellular response.     

Perspectives of gene combinations in phenotype presentation

Cells exhibit a variety of phenotypes in different stages and diseases. Although several markers for cellular phenotypes have been identified, gene combinations denoting cellular phenotypes have not been completely elucidated. Recent advances in gene analysis have revealed that various gene expression patterns are observed in each cell species and status. In this review, the perspectives of gene combinations in cellular phenotype presentation are discussed. Gene expression profiles change during cellular processes, such as cell proliferation, cell differentiation, and cell death. In addition, epigenetic regulation increases the complexity of the gene expression profile. The role of gene combinations and panels of gene combinations in each cellular condition are also discussed.     

Mechanotransduction from the ECM to the genome: Are the pieces now in place?

A multitude of biochemical signaling processes have been characterized that affect gene expression and cellular activity. However, living cells often need to integrate biochemical signals with mechanical information from their microenvironment as they respond. In fact, the signals received by shape alone can dictate cell fate. This mechanotrasduction of information is powerful, eliciting proliferation, differentiation, or apoptosis in a manner dependent upon the extent of physical deformation. The cells internal "prestressed" structure and its "hardwired" interaction with the extra-cellular matrix (ECM) appear to confer this ability to filter biochemical signals and decide between divergent cell functions influenced by the nature of signals from the mechanical environment. In some instances mechanical signaling through the tissue microenvironment has been shown to be dominant over genomic defects, imparting a normal phenotype on cells that otherwise have transforming genetic lesions. This mechanical control of phenotype is postulated to have a central role in embryogenesis, tissue physiology as well as the pathology of a wide variety of diseases, including cancer. We will briefly review studies showing physical continuity between the external cellular microenvironment and the interior of the cell nucleus. Newly characterized structures, termed nuclear envelope lamina spanning complexes (NELSC), and their interactions will be described as part of a model for mechanical transduction of extracellular cues from the ECM to the genome.     

Heat shock protein expression analysis in canine osteosarcoma reveals HSP60 as a potentially relevant therapeutic target

Heat shock proteins (HSP) are highly conserved across eukaryotic and prokaryotic species. These proteins play a role in response to cellular stressors, protecting cells from damage and facilitating recovery. In tumor cells, HSPs can have cytoprotective effects and interfere with apoptotic cascades. This study was performed to assess the prognostic and predictive values of the gene expression of HSP family members in canine osteosarcoma (OS) and their potential for targeted therapy. Gene expressions for HSP were assessed using quantitative PCR (qPCR) on 58 snap-frozen primary canine OS tumors and related to clinic-pathological parameters. A significant increased expression of HSP60 was found in relation to shorter overall survival and an osteoblastic phenotype. Therefore, the function of HSP60 was investigated in more detail. Immunohistochemical analysis revealed heterogeneous staining for HSP60 in tumors. The highest immunoreactivity was found in tumors of short surviving dogs. Next HSP expression was shown in a variety of canine and human OS cell lines by qPCR and Western blot. In two highly metastatic cell lines HSP60 expression was silenced using siRNA resulting in decreased cell proliferation and induction of apoptosis in both cell lines. It is concluded that overexpression of HSP60 is associated with a poor prognosis of OS and should be evaluated as a new target for therapy.     

Infrared laser‐mediated local gene induction in medaka,zebrafish and Arabidopsis thaliana

Heat shock promoters are powerful tools for the precise control of exogenous gene induction in living organisms. In addition to the temporal control of gene expression, the analysis of gene function can also require spatial restriction. Recently, we reported a new method for in vivo, single‐cell gene induction using an infrared laser‐evoked gene operator (IR‐LEGO) system in living nematodes (Caenorhabditis elegans). It was demonstrated that infrared (IR) irradiation could induce gene expression in single cells without incurring cellular damage. Here, we report the application of IR‐LEGO to the small fish, medaka (Japanese killifish; Oryzias latipes) and zebrafish (Danio rerio), and a higher plant (Arabidopsis thaliana). Using easily observable reporter genes, we successfully induced gene expression in various tissues in these living organisms. IR‐LEGO has the potential to be a useful tool in extensive research fields for cell/tissue marking or targeted gene expression in local tissues of small fish and plants.     

Dose-response of two cellular proliferation phenotypes produced by simian virus 40 large T antigen

Abstract. A set of cell lines was constructed by infection of established murine fibroblasts with recombinant retroviruses encoding the simian virus 40 large T antigen (Tag) gene. By immunofluorescence flow cytometry, it was shown that these cell lines expressed Tag over at least a 20-fold concentration range. Using these cells, the dose-response relationship between Tag concentration and a phenotype detected by flow cytometry that measures the rate at which proliferating cells transit the cell cycle (i.e. cell-cycling phenotype) was determined. This relationship between Tag concentration and phenotype was not linear. Instead, the cell-cycling phenotype became saturated at relatively low Tag concentrations, i.e. a further increase in Tag concentration did not change the phenotype. The dose-response relationship between Tag and a second phenotype, colony formation in soft agar, was also determined. Colony formation in soft agar is a measurement of cell transformation. In contrast to the cell-cycling phenotype, transformation was linearly related to Tag over the entire 20-fold Tag concentration range. This phenotype did not saturate at high Tag concentrations. Therefore, the dose-response relationship between Tag concentration and the cell-cycling phenotype was different from that between Tag concentration and cellular transformation. Since the Tag gene is comprised of multiple genetic domains that independently affect cellular proliferation, one possibility is that the differences in dose-response of the two phenotypes indicate that different genetic domains of the gene are necessary for production of each phenotype.     

Evo-Devo: evolutionary developmental mechanisms

Evolutionary developmental biology (Evo-Devo) as a discipline is concerned, among other things, with discovering and understanding the role of changes in developmental mechanisms in the evolutionary origin of aspects of the phenotype. In a very real sense, Evo-Devo opens the black box between genotype and phenotype, or more properly, phenotypes as multiple life history stages arise in many organisms from a single genotype. Changes in the timing or positioning of an aspect of development in a descendant relative to an ancestor (heterochrony and heterotopy) were two evolutionary developmental mechanisms identified by Ernst Haeckel in the 1870s. Many more have since been identified, in large part because of our enhanced understanding of development and because new mechanisms emerge as development proceeds: the transfer from maternal to zygotic genomic control; cell-to-cell interactions; cell differentiation and cell migration; embryonic inductions; functional interactions at the tissue and organ levels; growth. Within these emergent processes, gene networks and gene cascades (genetic modules) link the genotype with morphogenetic units (cellular modules, namely germ layers, embryonic fields or cellular condensations), while epigenetic processes such as embryonic inductions, tissue interactions and functional integration, link morphogenetic units to the phenotype. Evolutionary developmental mechanisms also include interactions between individuals of the same species, individuals of different species, and species and their biotic and/or abiotic environment. Such interactions link ecological communities. Importantly, there is little to distinguish the causality that underlies these interactions from that which underlies inductive interactions within embryos.     

Transduced endothelial cells expressing high levels of tissue plasminogen activator have an unaltered phenotype in vitro

Elevated cellular plasminogen activator activity has been associated with significant alterations in the in vitro phenotype of both malignant cell lines and nonmalignant endothelial cells. To examine the role of elevated cellular plasminogen activator activity in the production of altered endothelial cell behavior, bovine coronary artery endothelial cells were transduced with a retroviral vector expressing large amounts of tissue plasminogen activator. Cells transduced with the tissue plasminogen activator vector were compared with both untransduced cells and cells transduced with a control vector in a series of in vitro assays of cellular attachment, proliferation, migration, and invasion. The morphology of the 2 transduced populations was unchanged. There was a small decrease (5–15%) in the horizontal migration rate of both transduced cell populations, as compared with that of untransduced cells. No significant differences were detected among the three cell populations in any of the other assays. We conclude that expression of high levels of tissue plasminogen activator does not specifically affect endothelial cell phenotype in vitro. These data lend support to the hypothesis that elevated plasminogen activator activity is necessary but not sufficient to produce alterations in endothelial cell behavior. © 1993 Wiley-Liss, Inc.     

How might replicative senescence contribute to human ageing?

Cell senescence is the limited ability of primary human cells to divide when cultured in vitro. This eventual cessation of division is accompanied by a specific set of changes in cell physiology, morphology, and gene expression. Such changes in phenotype have the potential to contribute to human ageing and age-related diseases. Until now, senescence has largely been studied as an in vitro phenomenon, but recent data have for the first time directly demonstrated the presence of senescent cells in aged human tissues. Although a direct causal link between the ageing of whole organisms and the senescence of cells in culture remains elusive, a large body of data is consistent with cell senescence contributing to a variety of pathological changes seen in the aged. This review considers the in vitro phenotype of cellular senescence and speculates on the various possible routes whereby the presence of senescent cells in old bodies may affect different tissue systems.     

Genetic dissection of the initiation of the infection process and nodule tissue development in the Rhizobium-pea (Pisum sativum L.) symbiosis

Twelve non-nodulating pea (Pisum sativum L.) mutants were studied to identify the blocks in nodule tissue development. In nine, the reason for the lack of infection thread (IT) development was studied; this had been characterized previously in the other three mutants. With respect to IT development, mutants in gene sym7 are interrupted at the stage of colonization of the pocket in the curled root hair (Crh- phenotype), mutants in genes sym37 and sym38 are blocked at the stage of IT growth in the root hair cell (Ith- phenotype) and mutants in gene sym34 at the stage of IT growth inside root cortex cells (Itr- phenotype). With respect to nodule tissue development, mutants in genes sym7, sym14 and sym35 were shown to be blocked at the stage of cortical cell divisions (Ccd- phenotype), mutants in gene sym34 are halted at the stage of nodule primordium (NP) development (Npd- phenotype) and mutants in genes sym37 and sym38 are arrested at the stage of nodule meristem development (Nmd- phenotype). Thus, the sequential functioning of the genes Sym37, Sym38 and the gene Sym34 apparently differs in the infection process and during nodule tissue development. Based on these data, a scheme is suggested for the sequential functioning of early pea symbiotic genes in the two developmental processes: infection and nodule tissue formation.     

Syntaxin 5 is required for copper homeostasis in Drosophila and mammals

Copper is essential for aerobic life, but many aspects of its cellular uptake and distribution remain to be fully elucidated. A genome-wide screen for copper homeostasis genes in Drosophila melanogaster identified the SNARE gene Syntaxin 5 (Syx5) as playing an important role in copper regulation; flies heterozygous for a null mutation in Syx5 display increased tolerance to high dietary copper. The phenotype is shown here to be due to a decrease in copper accumulation, a mechanism also observed in both Drosophila and human cell lines. Studies in adult Drosophila tissue suggest that very low levels of Syx5 result in neuronal defects and lethality, and increased levels also generate neuronal defects. In contrast, mild suppression generates a phenotype typical of copper-deficiency in viable, fertile flies and is exacerbated by co-suppression of the copper uptake gene Ctr1A. Reduced copper uptake appears to be due to reduced levels at the plasma membrane of the copper uptake transporter, Ctr1. Thus Syx5 plays an essential role in copper homeostasis and is a candidate gene for copper-related disease in humans.     

Fibroblasts retain their tissue phenotype when grown in three-dimensional collagen gels

Fibroblasts are responsible for the synthesis, assembly, deposition, and organization of extracellular matrix molecules, and thus determine the morphology of connective tissues. Deposition of matrix molecules occurs in extracellular compartments, where the sequential stages are under cellular control. Cell orientation/polarity is important in determining how the cell orients these extracytoplasmic compartments and therefore how the matrix is assembled and oriented. However, the control of cell orientation is not understood. Fibroblasts from three tissues with different morphologies were studied to determine whether cells maintained their characteristic phenotype. Fibroblasts from cornea, which in vivo are oriented in orthogonal layers along with their matrix; from tendon, a uniaxial connective tissue, where cells orient parallel to each other; and from dermis, a connective tissue with no apparent cellular orientation, were used to study cell morphology and orientation in three-dimensional collagen gels. The different cells were grown for 3 and 7 days in identical three-dimensional collagen gels with a nonoriented matrix. Confocal fluorescence microscopy demonstrated that corneal fibroblasts oriented perpendicular to one another at 3 days, and after 7 days in hydrated gels these cells formed orthogonal sheets. Tendon fibroblasts were shown by the same methods to orient parallel to one another in bundles at both 3 and 7 days, throughout the depth of the gel. Dermal fibroblasts showed no apparent orientation throughout the hydrated gels at either time point examined. The organization of these different cell types was consistent with their tissue of origin as was the cell structure and polarity. These studies imply that cellular and tissue phenotype is innate to differentiated fibroblasts and that these cells will orient in a tissue-specific manner regardless of the extracellular matrix present.     

Dedifferentiation alters chondrocyte nuclear mechanics during in vitro culture and expansion

The biophysical features of a cell can provide global insights into diverse molecular changes, especially in processes like the dedifferentiation of chondrocytes. Key biophysical markers of chondrocyte dedifferentiation include flattened cellular morphology and increased stress-fiber formation. During cartilage regeneration procedures, dedifferentiation of chondrocytes during in vitro expansion presents a critical limitation to the successful repair of cartilage tissue. Our study investigates how biophysical changes of chondrocytes during dedifferentiation influence the nuclear mechanics and gene expression of structural proteins located at the nuclear envelope. Through an experimental model of cell stretching and a detailed spatial intranuclear strain quantification, we identified that strain is amplified and the distribution of strain within the chromatin is altered under tensile loading in the dedifferentiated state. Further, using a confocal microscopy image-based finite element model and simulation of cell stretching, we found that the cell shape is the primary determinant of the strain amplification inside the chondrocyte nucleus in the dedifferentiated state. Additionally, we found that nuclear envelope proteins have lower gene expression in the dedifferentiated state. This study highlights the role of cell shape in nuclear mechanics and lays the groundwork to design biophysical strategies for the maintenance and enhancement of the chondrocyte phenotype during cell expansion with a goal of successful cartilage tissue engineering.