Project description:Macaca fascicularis (long-tailed, cynomolgus, or crab-eating macaque) is a highly advantageous model in which to study human cochlea with regard to both evolutionary proximity and physiological similarity of the auditory system. To better understand the properties of primate cochlear function, we analyzed the genes predominantly expressed in M. fascicularis cochlea.

Project description:ATAC-seq samples from 2 species and 2 cell types were generated to study cis-regulatory element evolution. Briefly, previously generated urinary stem cell derived iPS-cells (Homo sapiens) of 2 human individuals and fibroblast derived cynomolgus macaque iPSCs (Macaca fascicularis) of 2 individuals (Geuder et al. 2021) were differentiated to neural progenitor cells via dual-SMAD inhibition as three-dimensional aggregation culture (Chambers et al. 2009; Ohnuki et al. 2014). The NPC lines were cultured in NPC proliferation medium and passaged 2 - 4 times until they were dissociated and subjected to ATAC-seq together with the respective iPSC clones. ATAC-seq libraries were generated using the Omni-ATAC protocol (Corces et al. 2017) with minor modifications.

Project description:RNA-seq samples from 3 species across a differentiation from induced pluripotent stem cells to neural progenitor cells were generated to study gene expression evolution. Briefly, previously generated urinary stem cell derived iPSCs of 3 human (Homo sapiens) individuals (3 clones), 1 gorilla (Gorilla gorilla) individual and fibroblast derived cynomolgus macaque (Macaca fascicularis) iPSCs of 2 individuals (4 clones) (Geuder et al. 2021) were differentiated to neural progenitor cells via dual-SMAD inhibition as three-dimensional aggregation culture (Chambers et al. 2009; Ohnuki et al. 2014). Bulk RNA-seq libraries of iPSCs and NPCs were generated using prime-seq protocol (Janjic et al. 2022).

Project description:The long-tailed macaque, also referred to as cynomolgus monkey (Macaca fascicularis), is one of the most important non-human primate animal models in basic and applied biomedical research. To improve the predictive power of primate experiments for humans, we determined the genome sequence of a Macaca fascicularis female of Mauritian origin using a whole-genome shotgun sequencing approach. We applied a template switch strategy which employs either the rhesus or the human genome to assemble sequence reads. The 6-fold sequence coverage of the draft genome sequence enabled discovery of about 2.1 million potential single-nucleotide polymorphisms based on occurrence of a dimorphic nucleotide at a given position in the genome sequence. Homology-based annotation allowed us to identify 17,387 orthologs of human protein-coding genes in the M. fascicularis draft genome and the predicted transcripts enabled the design of a M. fascicularis-specific gene expression microarray. Using liver samples from 36 individuals of different geographic origin, we identified 718 genes with highly variable expression in liver, whereas the majority of the transcriptome shows relatively stable and comparable expression. Knowledge of the M. fascicularis draft genome is an important contribution to both the use of this animal in disease models and the safety assessment of drugs and their metabolites. In particular, this information allows high-resolution genotyping and microarray-based gene expression profiling for animal stratification, thereby allowing the use of well-characterized animals for safety testing. Finally, the genome sequence presented here is a significant contribution to the global "3R" animal welfare initiative, which has the goal to reduce, refine and replace animal experiments. A 36-microarray study using total RNA recovered from liver samples of untreated Cynomolgus monkeys of good laboratory practice (GLP) drug safety studies. The monkeys were from the Philippines, a Chinese colony, and Mauritius. Each microarray measures the expression level of 16,896 genes using 20,047 probe sets with six 60-mer probes (PM) per probe set. Each probe set is represented once on the array. The Cynomolgus monkey gene expression results analyzed in this study are further described in Ebeling et al. (2011) (PMID 21862625).

Project description:Infinium 450K is a hybridization array designed for the human genome, but the relative conservation between the macaque and human genomes makes its use in macaques feasible. We used the Infinium450K array to assay twelve Cynomolgus macaque muscle biopsies and compared it to Reduced Representation Bisulphite Sequencing (RRBS) data generated on the same samples.

Project description:Infinium 450K is a hybridization array designed for the human genome, but the relative conservation between the macaque and human genomes makes its use in macaques feasible. We used the Infinium450K array to assay twelve Cynomolgus macaque muscle biopsies and compared it to Reduced Representation Bisulphite Sequencing (RRBS) data generated on the same samples.

Project description:Infinium 450K is a hybridization array designed for the human genome, but the relative conservation between the macaque and human genomes makes its use in macaques feasible. We used the Infinium450K array to assay twelve Cynomolgus macaque muscle biopsies and compared it to Reduced Representation Bisulphite Sequencing (RRBS) data generated on the same samples. Muscle biopsies were performed on eleven adult male cynomologus macaques

Project description:Infinium 450K is a hybridization array designed for the human genome, but the relative conservation between the macaque and human genomes makes its use in macaques feasible. We used the Infinium450K array to assay twelve Cynomolgus macaque muscle biopsies and compared it to Reduced Representation Bisulphite Sequencing (RRBS) data generated on the same samples. Muscle biopsies were performed on eleven adult male cynomologus macaques

Project description:The long-tailed macaque, also referred to as cynomolgus monkey (Macaca fascicularis), is one of the most important non-human primate animal models in basic and applied biomedical research. To improve the predictive power of primate experiments for humans, we determined the genome sequence of a Macaca fascicularis female of Mauritian origin using a whole-genome shotgun sequencing approach. We applied a template switch strategy which employs either the rhesus or the human genome to assemble sequence reads. The 6-fold sequence coverage of the draft genome sequence enabled discovery of about 2.1 million potential single-nucleotide polymorphisms based on occurrence of a dimorphic nucleotide at a given position in the genome sequence. Homology-based annotation allowed us to identify 17,387 orthologs of human protein-coding genes in the M. fascicularis draft genome and the predicted transcripts enabled the design of a M. fascicularis-specific gene expression microarray. Using liver samples from 36 individuals of different geographic origin, we identified 718 genes with highly variable expression in liver, whereas the majority of the transcriptome shows relatively stable and comparable expression. Knowledge of the M. fascicularis draft genome is an important contribution to both the use of this animal in disease models and the safety assessment of drugs and their metabolites. In particular, this information allows high-resolution genotyping and microarray-based gene expression profiling for animal stratification, thereby allowing the use of well-characterized animals for safety testing. Finally, the genome sequence presented here is a significant contribution to the global "3R" animal welfare initiative, which has the goal to reduce, refine and replace animal experiments.

Project description:In this study, we aim to establish the means to characterize macaque natural killer (NK) cells, and to investigate whether the CD27/CD11b NK maturation model proposed in human and murine models is applicable to Macaca fascicularis (cynomolgus macaque) NK cells. The NK development studies performed in mice models have demonstrated four functionally distinct subsets defined by CD27 and CD11b, however this has not yet been established in nonhuman primates. The expression data of these macaque NK subsets will be associated with the antibody-dependent cellular cytotoxicity and missing-self responses produce by each subset.