Project description:According to Mendel's laws, each parent makes an equal genetic contribution to an offspring in sexually reproducing organisms. The bipolar mitotic spindle controls the equal segregation of paternal and maternal chromosomes during the first cell division. By overexpression of a single protein, GPR-1, in the maternal strain we changed the structure of the mitotic spindle from bipolar to two monopolar spindles to segregate maternal and paternal chromosomes into different cell lineages, resulting in non-mendelian segregation for entire genomes. To follow maternal and paternal segregation of the chromosomes we used red and green histone markers respectively. By mating gpr-1-overexpressing hermaphrodites with wild-type males, mendelian F1 worms that express both markers simultaneously in all tissues and non-mendelian F1 worms that express red and green markers in different tissues will be produced representing embryos with bipolar and embryos with two monopolar spindles. Thus, we show that the rules of genetic inheritance can be changed, which may inspire the formation of a new field of synthetic zoology. Transcriptional profiling was done to investigate the differences in gene expression between mendelian and non-mendelian offspring. Approximately 60 adult worms were used per sample. Four conditions were collected: hermaphrodites of the paternal strain, hermaphrodites of the maternal strain, co-segregating (mendelian) F1 after crossing of parental strains, and (non-mendelian) F1 that segregates the paternal genotype to body wall muscle, intestine + germline and the maternal genotype to the nervous system after crossing of parental strains.
Project description:According to Mendel's laws, each parent makes an equal genetic contribution to an offspring in sexually reproducing organisms. The bipolar mitotic spindle controls the equal segregation of paternal and maternal chromosomes during the first cell division. By overexpression of a single protein, GPR-1, in the maternal strain we changed the structure of the mitotic spindle from bipolar to two monopolar spindles to segregate maternal and paternal chromosomes into different cell lineages, resulting in non-mendelian segregation for entire genomes. To follow maternal and paternal segregation of the chromosomes we used red and green histone markers respectively. By mating gpr-1-overexpressing hermaphrodites with wild-type males, mendelian F1 worms that express both markers simultaneously in all tissues and non-mendelian F1 worms that express red and green markers in different tissues will be produced representing embryos with bipolar and embryos with two monopolar spindles. Thus, we show that the rules of genetic inheritance can be changed, which may inspire the formation of a new field of synthetic zoology. Transcriptional profiling was done to investigate the differences in gene expression between mendelian and non-mendelian offspring.
Project description:Comprehensive list of SUMO targets from the nematode Caenorhabditis elegans. SUMO conjugates isolated from transgenic worms carrying 8His and GFP tagged SUMO. The constructs rescues the lethal knock-out of a single SUMO gene, smo-1. SUMO conjugates where isolated from heat shock, arsenite exposure, and UV treated SUMO-GFP worms as well as from control non treated animals. In parallel identical purification procedure was performed with non-transgenic worms and proteins identified with this control where excluded.
Project description:Transcriptional profiling of heat-shocked worms was compared to non-heat-shocked worms to determine genes that are induced upon heat shock in each species; heat-shock-induced genes in each species were compared
Project description:Transcriptional profiling of N2 vs. mir-243 worms, aiming to identify direct and indirect targets of the microRNA. N2 and mir-243 young-adult worms grown at 20C were analyzed. Three biological replicates with dye-swaps were performed.
Project description:To investigate the effect of increased population density on gene expression in the nematode Caenorhabditis elegans we grew worms as solitary animals or in a ten animals population. We then performed gene expression profiling analysis using data obtained from RNA-seq of worms grown in both types of conditions (3 biological replications per condition)