Project description:Spinal cord injury leads to impaired motor and sensory functions. After spinal cord injury there is a an initial phase of hypo-reflexia followed by a developing hyper-reflexia, often termed spasticity. Previous studies have suggested a relationship between the reappearance of plateau potentials in motor neurons and the development of spasticity after spinalization. To understand the molecular mechanism behind this phenomena we examined the transcriptional response of the motor neurons after spinal cord injury as it progress over time. We used a rat tail injury model where a complete transection of the caudal (S2) rat spinal cord leads to an immediate flaccid paralysis of the tail and a subsequent appearance of spasticity 2-3 weeks post injury that develops into strong spasticity after 2 months. Gene expression changes were studied in motor neurones 0, 2, 7, 21 and 60 days after complete spinal transection. Tail MNs were retrogradely labelled with Fluoro-Gold injected into the muscle and intra peritoneally. 5-7 days after tracer injections the spinal cord was dissected out, snap-frozen in liquid nitrogen, sliced in 10 um thick slices and fluorescent motor neurons were laser dissected into a collector tube to a total of ca. 50-200 cells pr sample. RNA was then extracted, two round amplified and hybridized to Affymetrix rat 230 2.0 arays. 31 samples were hybridized onto chips, 4 Spi-0 (Control), 6 Spi-2, 5 Spi-7, 8 Spi-21 and 8 Spi-60.

Project description:A major virulence factor in S. enterica is the pathogenicity island Spi2. The goal of the experiment was to determine the impact of the toll-like receptor 4 (TLR-4) on expression of Spi2 in S. enterica wild type (WT) and triple mutant strain (TMS) with deletions in SPI-1 TTSS, SPI-2 TTSS, flagella. The stain 14028 was used for the experiment. Cells were grown in a TLR-4 wildtype (plus) or deleted (minus) macrophage background. Total RNA was extracted and processed by qRT-PCR. Two strains (WT and TMS) grown under 2 conditions (TLR-4 wildtype (plus) or TLR-4 deleted (minus)) - total 4 samples were analyzed in the study. All PCRs were done in quadruplicates, located on the same PCR plate. For each quadruplicates the median value was calculated and used as a data point for further normalization. A set of controls was selected for all data sets using the following criteria: the data points for the controls should have Cp <40 and be present in all the samples.

Project description:A major virulence factor in S. enterica is the pathogenicity island Spi2. The goal of the experiment was to determine the impact of the NRAMP-1 (natural resistance-associated macrophage protein-1) on expression of Spi2 in S. enterica wild type (WT) and triple mutant strain (TMS) with deletions in SPI-1 TTSS, SPI-2 TTSS, flagella. The stain 14028 was used for the experiment. Cells were grown in a NRAMP-1 wildtype (plus) or deleted (minus) macrophage background. Total RNA was extracted and processed by qRT-PCR. Two strains ( WT and TMS) grown under 2 conditions (NRAMP-1 wildtype (plus) or NRAMP-1 deleted (minus)) - total 4 samples were analyzed in the study. All PCRs were done in duplicates, located on the same PCR plate. For each duplicate the mean value was calculated and used as a data point for further normalization. We averaged the Cp values for all the data points in a sample and then subtracted this sample average Cp from all the data points of the sample. Only 192 primer pairs from 288 on the platform GPL11111 were used.

Project description:Saccharomyces cerevisiae yeast is a fungus presenting a peripheral organelle called the cell wall. The cell wall protects the yeast cell from stress and provides means for communication with the surrounding environment. It has a complex molecular structure, composed of an internal part of cross-linked polysaccharides and an external part of mannoproteins. These latter are very interesting owing to their functional properties, dependent of their molecular features with massive mannosylations. Therefore, the molecular characterization of mannoproteins is a must relying on the optimal isolation and preparation of the cell wall fraction. Multiple methods are well reported for yeast cell wall isolation. The most ap-plied one consists of yeast cell lysis by mechanical disruption. However, applying this classical approach to S288C yeast cells showed a considerable contamination with non-cell wall proteins, mainly comprising mitochondrial proteins. Here-in, we tried to further purify the yeast cell wall preparation by two means: ultracentrifugation and Triton X-100 addition. While the first strategy showed limited outcomes in mitochondrial proteins removal, the second strategy showed optimal results when Triton X-100 was added at 5%, allowing the identification of more mannoproteins and enriching significant-ly their amounts. This promising method could be reliably implemented in lab-scale and industrial processes for “pure” cell wall isolation.

Project description:Genetic engineering of filamentous fungi has promise for accelerating the transition to a more sustainable food system and enhancing the nutritional value, sensory appeal, and scalability of microbial foods. However, genetic tools and demonstrated use cases for bioengineered food production by edible strains are lacking. Here, we developed a synthetic biology toolkit for Aspergillus oryzae, an edible fungus traditionally used in fermented foods and currently used in protein production and meat alternatives. Our toolkit includes a CRISPR-Cas9 method for genome integration, neutral loci, and new promoters. We use these tools to enhance the elevate levels of the nutraceutical ergothioneine and intracellular heme in the edible biomass. The biomass overproducing heme is red in color and is readily formulated into imitation meat patties with minimal processing. These findings highlight the promise of genetic approaches to enhance fungal meat alternatives and provide useful engineering tools for diverse applications in fungal food production and beyond.

Project description:The expression profile of an S. Typhimurium hfq mutant-strain was compared to the parental strain under 2 different growth conditions; early stationary phase and SPI-1 (Salmonella pathogenicity island 1) inducing condition. Keywords: Genetic modification This study comprises two separate experiments performed under different growth conditions, were the gene expression profile was compared to that of the parental strain. Three biological replicates were performed for each strain and condition. For this study, we used Salmonella genomic DNA as the comparator which also acted as the control for spot quality.

Project description:Although mammalian cloning by somatic cell nuclear transfer (SCNT) has been established in various species, the low developmental efficiency has hampered its practical applications. Treatment of SCNT-derived embryos with histone deacetylase (HDAC) inhibitors can improve their development, but the underlying mechanism is still unclear. To address this question, we analysed gene expression profiles of SCNT-derived 2-cell mouse embryos treated with trichostatin A (TSA), a potent HDAC inhibitor that is best used for mouse cloning. Unexpectedly, TSA had no effect on the numbers of aberrantly expressed genes or the overall gene expression pattern in the embryos. However, in-depth investigation by gene ontology and functional analyses revealed that TSA treatment specifically improved the expression of a small subset of genes encoding transcription factors and their regulatory factors, suggesting their positive involvement in de novo RNA synthesis. Indeed, introduction of one of such transcription factors, Spi-C, into the embryos at least partially mimicked the TSA-induced improvement in embryonic development by activating gene networks associated with transcriptional regulation. Thus, the effects of TSA treatment on embryonic gene expression did not seem to be stochastic, but more specific than expected, targeting genes that direct development and trigger zygotic genome activation at the 2-cell stage. Gene expression were measured in mouse unfertilized oocytes, in vitro fertilized, somatic cell cloned embryos and cumulus cells. Somatic cell cloned embryos were treated with/without TSA or Spi-C mRNA and subjected at 2-cell stage. More than four biological replicates were performed in each group.

Project description:Cultured meat is an emergent technology with the potential for significant environmental and animal welfare benefits. Accurate mimicry of traditional meat requires fat tissue; a key contributor to both the flavour and texture of meat. Here, we show that fibro-adipogenic progenitor cells (FAPs) are present in bovine muscle, and are transcriptionally and immunophenotypically distinct from satellite cells. These two cell types can be purified from a single muscle sample using a simple fluorescence-activated cell sorting (FACS) strategy. FAPs demonstrate high levels of adipogenic potential, as measured by gene expression changes and lipid accumulation, and can be proliferated for a large number of population doublings, demonstrating their suitability for a scalable cultured meat production process. Crucially, FAPs reach a mature level of adipogenic differentiation in three-dimensional, edible hydrogels. The resultant tissue accurately mimics traditional beef fat in terms of lipid profile and taste, and FAPs thus represent a promising candidate cell type for the production of cultured fat.

Project description:The use of an animal component-free scaffold to culture muscle cells on is a potential approach for producing (hybrid) cultured meat. However, to develop a plant-based scaffold with optimal mechanical characteristics for muscle cell growth, differentiation and maturation, it is essential to characterize the natural extracellular matrix (ECM) found in conventional meat. Therefore, this research initially involved isolating the ECM by removing muscle cells through 0.5 % SDS decellularization. Subsequently, various structural parameters of both fresh meat (representing the upper limit) and decellularized meat (representing the lower limit) were measured. Effective removal of cells and adequate preservation of the ECM's main structure and components were confirmed through Picogreen assay, proteomic analysis, and determination of glycosaminoglycan (GAG) content. Samples underwent amplitude sweeps, texture analyses and internal structure visualization. The conditions resembling the natural ECM of muscle cells lie between the determined upper and lower limits for each parameter.

Project description:Bacterial type III secretion systems are able to secrete membrane proteins. In this project we could show that cognate T3SS chaperones are able to bind to the transmembrane segments of T3SS substrates to avoid erroneous targeting to the bacterial inner membrane. Here, we studied the Salmonella SPI-2 T3SS secreted protein SseF and the interaction with its chaperone SscB by in vivo photocrosslinking. LC-MS/MS analysis was done to provide additional evidence that SscB is the interaction partner leading to the upshift of the SseF band in an SDS-PAGE analysis.