Generation of two iPSC lines from healthy donor with a heterozygous mutation in the VPS13B gene.

The human induced pluripotent stem cell (iPSC) lines, iCS-MAF1-1 and iCS-MAF1-11, were generated from fibroblasts. The donor has a heterozygous mutation in the VPS13B gene, which manifests in her child as Cohen syndrome. It is a Golgi pathology, characterized by postnatal microcephaly and delayed growth and mental development. However, the process underlying pathological changes leading to the onset of the disease is still unknown. The use of iPSC will allow describing the early stages of neurogenesis, which is undoubtedly relevant for identifying key stages of development, at which phenotypic manifestations of mutations in the VPS13B gene are found.

Complex biology of constitutional ring chromosomes structure and (in)stability revealed by somatic cell reprogramming.

Human ring chromosomes are often unstable during mitosis, and daughter cells can be partially or completely aneuploid. We studied the mitotic stability of four ring chromosomes, 8, 13, 18, and 22, in long-term cultures of skin fibroblasts and induced pluripotent stem cells (iPSCs) by GTG karyotyping and aCGH. Ring chromosome loss and secondary aberrations were observed in all fibroblast cultures except for r(18). We found monosomy, fragmentation, and translocation of indexed chromosomes. In iPSCs, aCGH revealed striking differences in mitotic stability both between iPSC lines with different rings and, in some cases, between cell lines with the same ring chromosome. We registered the spontaneous rescue of karyotype 46,XY,r(8) to 46,XY in all six iPSC lines through ring chromosome loss and intact homologue duplication with isoUPD(8)pat occurrence, as proven by SNP genotype distribution analysis. In iPSCs with other ring chromosomes, karyotype correction was not observed. Our results suggest that spontaneous correction of the karyotype with ring chromosomes in iPSCs is not universal and that pluripotency is compatible with a wide range of derivative karyotypes. We conclude that marked variability in the frequency of secondary rearrangements exists in both fibroblast and iPSC cultures, expanding the clinical significance of the constitutional ring chromosome.

CLARITY and Light-Sheet microscopy sample preparation in application to human cerebral organoids.

Cerebral organoids are three-dimensional cell-culture systems that represent a unique experimental model reconstructing early events of human neurogenesis in vitro in health and various pathologies. The most commonly used approach to studying the morphological parameters of organoids is immunohistochemical analysis; therefore, the three-dimensional cytoarchitecture of organoids, such as neural networks or asymmetric internal organization, is difficult to reconstruct using routine approaches. Immunohistochemical analysis of biological objects is a universal method in biological research. One of the key stages of this method is the production of cryo- or paraffin serial sections of samples, which is a very laborious and time-consuming process. In addition, slices represent only a tiny part of the object under study; three-dimensional reconstruction from the obtained serial images is an extremely complex process and often requires expensive special programs for image processing. Unfortunately, staining and microscopic examination of samples are difficult due to their low permeability and a high level of autofluorescence. Tissue cleaning technologies combined with Light-Sheet microscopy allows these challenges to be overcome. CLARITY is one of the tissue preparation techniques that makes it possible to obtain opaque biological objects transparent while maintaining the integrity of their internal structures. This method is based on a special sample preparation, during which lipids are removed from cells and replaced with hydrogel compounds such as acrylamide, while proteins and nucleic acids remain intact. CLARITY provides researchers with a unique opportunity to study three-dimensional biological structures while preserving their internal organization, including whole animals or embryos, individual organs and artificially grown organoids, in particular cerebral organoids. This protocol summarizes an optimization of CLARITY conditions for human brain organoids and the preparation of Light-Sheet microscopy samples.

Generation of iPSC line ICGi024-A from human skin fibroblasts of a patient with ring chromosome 18.

Ring chromosome 18 is a rare chromosomal disorders that usually originate de novo and correlate with clinical manifestation: developmental delay as well as microcephaly, brain and ocular malformations, hypotonia and skeletal abnormalities. We generate iPSC clonal cell line ICGi024-A with pluripotency properties which were demonstrated in vitro by three germ layer differentiation capacity. ICGi024-A can be used for disease modeling and fundamental investigation of ring chromosome instability.

Generation of four iPSC lines from two siblings with a microdeletion at the CNTN6 gene and intellectual disability.

The human induced pluripotent stem cell (iPSC) lines, ICGi009-A, ICGi009-B, ICGi013-A and ICGi013-B, were generated from skin fibroblasts of two siblings with intellectual disability. Both patients were carriers of CNTN6 gene microdeletion (Kashevarova et al., 2014). iPSC lines have normal karyotype, express pluripotency markers, are able to differentiate in vitro into derivatives of all three germ layers and represent a unique tool to study neurodevelopmental disorders.

Generation of the induced pluripotent stem cell line, ICAGi002-A, from unaffected carrier megabase scaled duplication involving the CNTN6 gene.

The 3p26.3 microduplication involving the CNTN6 gene cause developmental delay and the intellectual disability. However, the incomplete penetrance is described for this copy number variation (CNV). Here we describe ICAGi002-A line, which is supposed to use as a model for studying of the penetrance of the CNV in 3p26.3. The ICAGi002-A iPSCs line was obtained by the reprogramming of the skin fibroblasts from a healthy donor with 3p26.3 microduplication involving the CNTN6 gene. The ICAGi002-A cells was pluripotent as it was shown by the expression of the pluripotency-associated markers and in vitro differentiation into the cells of three germ layers.

Induced pluripotent stem cell line, ICAGi001-A, derived from human skin fibroblasts of a patient with 2p25.3 deletion and 2p25.3-p23.3 inverted duplication.

Skin fibroblasts from a patient with developmental delay and chromosome 2p25.3 deletion syndrome were reprogrammed into induced pluripotent stem cells (iPSCs) and the clonal stem cell line ICAGi001-A (iTAF9-11) was established. ICAGi001-A pluripotency was demonstrated in vitro by three germ layer differentiation capacity. This line is a good model for studying of the developmental delay and brain disorder.

Induced pluripotent stem cell line, IMGTi003-A, derived from skin fibroblasts of an intellectually disabled patient with ring chromosome 13.

Skin fibroblasts from a patient with neurodevelopmental and speech delay, anxiety disorder, macrocephaly, microorchidism, multiple anomalies of internal organs and ring chromosome 13 were reprogrammed into induced pluripotent stem cells (iPSCs) to generate a clonal stem cell line IMGTi003-A (iTAF6-6). IMGTi003-A pluripotency was demonstrated by three germ layer differentiation capacity in vitro, and this cell line had a mosaic karyotype with 46,XY,r(13) as a predominant cell subpopulation. IMGTi003-A line is a good model for studying of the mitotic instability of the ring chromosome 13.