Human Naive Pluripotent Stem Cells Model X Chromosome Dampening and X Inactivation

Naive human embryonic stem cells (hESCs) can be derived from primed hESCs or directly from blastocysts, but their X chromosome state has remained unresolved. Here, we show that the inactive X chromosome (Xi) of primed hESCs was reactivated in naive culture conditions. Like cells of the blastocyst, the resulting naive cells contained two active X chromosomes with XIST expression and chromosome-wide transcriptional dampening and initiated XIST-mediated X inactivation upon differentiation. Both establishment of and exit from the naive state (differentiation) happened via an XIST-negative XaXaintermediate. Together, these findings identify a cell culture system for functionally exploring the two X chromosome dosage compensation processes in early human development: X dampening and X inactivation. However, remaining differences between naive hESCs and embryonic cells related to mono-allelic XIST expression and non-random X inactivation highlight the need for further culture improvement. As the naive state resets Xiabnormalities seen in primed hESCs, it may provide cells better suited for downstream applications

Engineering HIV-1-resistant T-cells from short-hairpin RNA-expressing hematopoietic stem/progenitor cells in humanized BLT mice

Down-regulation of the HIV-1 coreceptor CCR5 holds significant potential for long-term protection against HIV-1 in patients. Using the humanized bone marrow/liver/thymus (hu-BLT) mouse model which allows investigation of human hematopoietic stem/progenitor cell (HSPC) transplant and immune system reconstitution as well as HIV-1 infection, we previously demonstrated stable inhibition of CCR5 expression in systemic lymphoid tissues via transplantation of HSPCs genetically modified by lentiviral vector transduction to express short hairpin RNA (shRNA). However, CCR5 down-regulation will not be effective against existing CXCR4-tropic HIV-1 and emergence of resistant viral strains. As such, combination approaches targeting additional steps in the virus lifecycle are required. We screened a panel of previously published shRNAs targeting highly conserved regions and identified a potent shRNA targeting the R-region of the HIV-1 long terminal repeat (LTR). Here, we report that human CD4+ T-cells derived from transplanted HSPC engineered to co-express shRNAs targeting CCR5 and HIV-1 LTR are resistant to CCR5- and CXCR4- tropic HIV-1-mediated depletion in vivo. Transduction with the combination vector suppressed CXCR4- and CCR5- tropic viral replication in cell lines and peripheral blood mononuclear cells in vitro. No obvious cytotoxicity or interferon response was observed. Transplantation of combination vector-transduced HSPC into hu-BLT mice resulted in efficient engraftment and subsequent stable gene marking and CCR5 down-regulation in human CD4+ T-cells within peripheral blood and systemic lymphoid tissues, including gut-associated lymphoid tissue, a major site of robust viral replication, for over twelve weeks. CXCR4- and CCR5- tropic HIV-1 infection was effectively inhibited in hu-BLT mouse spleen-derived human CD4+ T-cells ex vivo. Furthermore, levels of gene-marked CD4+ T-cells in peripheral blood increased despite systemic infection with either CXCR4- or CCR5- tropic HIV-1 in vivo. These results demonstrate that transplantation of HSPCs engineered with our combination shRNA vector may be a potential therapy against HIV disease.This work was supported by grants from the California Institute for Regenerative Medicine (CIRM grant DR1-01431 to ISYC), the National Institutes of Health (1RO1HL086409 and 3RO1HL086409-03S1 to DSA and 5T32AI060567), and the University of California Los Angeles AIDS Institute/Center for AIDS Research (5P30AI028697). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript

Uniparental Genetic Heritage of Belarusians: Encounter of Rare Middle Eastern Matrilineages with a Central European Mitochondrial DNA Pool

Ethnic Belarusians make up more than 80% of the nine and half million people inhabiting the Republic of Belarus. Belarusians together with Ukrainians and Russians represent the East Slavic linguistic group, largest both in numbers and territory, inhabiting East Europe alongside Baltic-, Finno-Permic- and Turkic-speaking people. Till date, only a limited number of low resolution genetic studies have been performed on this population. Therefore, with the phylogeographic analysis of 565 Y-chromosomes and 267 mitochondrial DNAs from six well covered geographic sub-regions of Belarus we strove to complement the existing genetic profile of eastern Europeans. Our results reveal that around 80% of the paternal Belarusian gene pool is composed of R1a, I2a and N1c Y-chromosome haplogroups – a profile which is very similar to the two other eastern European populations – Ukrainians and Russians. The maternal Belarusian gene pool encompasses a full range of West Eurasian haplogroups and agrees well with the genetic structure of central-east European populations. Our data attest that latitudinal gradients characterize the variation of the uniparentally transmitted gene pools of modern Belarusians. In particular, the Y-chromosome reflects movements of people in central-east Europe, starting probably as early as the beginning of the Holocene. Furthermore, the matrilineal legacy of Belarusians retains two rare mitochondrial DNA haplogroups, N1a3 and N3, whose phylogeographies were explored in detail after de novo sequencing of 20 and 13 complete mitogenomes, respectively, from all over Eurasia. Our phylogeographic analyses reveal that two mitochondrial DNA lineages, N3 and N1a3, both of Middle Eastern origin, might mark distinct events of matrilineal gene flow to Europe: during the mid-Holocene period and around the Pleistocene-Holocene transition, respectively

Origin and spread of human mitochondrial DNA haplogroup U7

Human mitochondrial DNA haplogroup U is among the initial maternal founders in Southwest Asia and Europe and one that best indicates matrilineal genetic continuity between late Pleistocene hunter-gatherer groups and present-day populations of Europe. While most haplogroup U subclades are older than 30 thousand years, the comparatively recent coalescence time of the extant variation of haplogroup U7 (~16–19 thousand years ago) suggests that its current distribution is the consequence of more recent dispersal events, despite its wide geographical range across Europe, the Near East and South Asia. Here we report 267 new U7 mitogenomes that – analysed alongside 100 published ones – enable us to discern at least two distinct temporal phases of dispersal, both of which most likely emanated from the Near East. The earlier one began prior to the Holocene (~11.5 thousand years ago) towards South Asia, while the later dispersal took place more recently towards Mediterranean Europe during the Neolithic (~8 thousand years ago). These findings imply that the carriers of haplogroup U7 spread to South Asia and Europe before the suggested Bronze Age expansion of Indo-European languages from the Pontic-Caspian Steppe region

Mechanisms of X-chromosome Regulation During Mammalian Development

The mammalian blastocyst forms several days after one of the smallest cells - the sperm - fertilizes one of the largest cells -the egg. Depending on sex chromosome contribution from the sperm, either a female (XX genotype) or a male (XY genotype) embryo develops. To compensate for the X chromosome genetic imbalance between males and females, female cells transcriptionally silence one of their two X chromosomes. This phenomenon of X-chromosome inactivation (XCI) occurs in the blastocyst inner cell mass (ICM) cells – which form the embryo – as it implants to the uterine wall. The transition of the na�ve pluripotent ICM cells with two active X chromosomes to primed pluripotency with an active and an inactive X chromosome (Xa and Xi, respectively) is mediated by the lncRNA Xist. While both mouse and human cells arising after implantation have an Xist-expressing Xi and an Xist-negative Xa, the X-chromosome state in the na�ve pre-implantation development is rather different in the two species. In mice, Xist is not expressed in the ICM cells with two active X chromosomes since Xist expression invariably leads to XCI. Yet, human pre-implantation blastocysts, including cells of the ICM, express XIST from active X chromosomes. We demonstrate that the presence of an XIST-expressing Xa, which is unique to human pre-implantation development, is a robust marker of human na�ve pluripotency. We utilize this marker to identify a culture condition that, for the first time, allows detailed molecular studies of X-chromosome regulation of human pre-implantation development using cultured human pluripotent stem cells (hPSCs). We demonstrate that na�ve hPSCs, despite having two active X chromosomes, compensate expression of X-chromosome genes via chromosome- wide transcriptional dampening and mediate XIST-mediated XCI upon differentiation to a somatic lineage. Lastly, we determine that na�ve culture conditions obliterate the epigenetic abnormalities of the Xi characteristic to conventional hPSCs of developmentally advanced – primed – pluripotent state.Once established, the Xi is kept transcriptionally silent for the life of the cell and its progeny, namely due to the many epigenetic layers forming the facultative heterochromatin of the Xi. In addition to covalent modifications of histone proteins, CpG islands of X-chromosome genes are methylated at cytosine residues to keep this silent state. To uncover the mechanisms which work in synergy with DNA methylation to maintain the inactive state of the Xi, we performed an RNAi and small chemical screen using engineered mouse cells with a reporter gene on the silent X chromosome. Our screen identified a synergistic combination of two FDA-approved chemicals that together lead to increased DNA demethylation not only of the Xi, but genome-wide, and works in synergy to reduce viability of leukemic cells. Thus, understanding XCI at the molecular level can be used to optimize the epigenetic activity of drug combinations

Transcriptome Encyclopedia of Early Human Development

Our understanding of human pre-implantation development is limited by the availability of human embryos and cannot completely rely on mouse studies. Petropoulos et al. now provide an extensive transcriptome analysis of a large number of human pre-implantation embryos at single-cell resolution, revealing previously unrecognized features unique to early human development

Regulation of X-chromosome dosage compensation in human: mechanisms and model systems

The human blastocyst forms 5 days after one of the smallest human cells (the sperm) fertilizes one of the largest human cells (the egg). Depending on the sex-chromosome contribution from the sperm, the resulting embryo will either be female, with two X chromosomes (XX), or male, with an X and a Y chromosome (XY). In early development, one of the major differences between XX female and XY male embryos is the conserved process of X-chromosome inactivation (XCI), which compensates gene expression of the two female X chromosomes to match the dosage of the single X chromosome of males. Most of our understanding of the pre-XCI state and XCI establishment is based on mouse studies, but recent evidence from human pre-implantation embryo research suggests that many of the molecular steps defined in the mouse are not conserved in human. Here, we will discuss recent advances in understanding the control of X-chromosome dosage compensation in early human embryonic development and compare it to that of the mouse.This article is part of the themed issue 'X-chromosome inactivation: a tribute to Mary Lyon'