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Skin color is highly variable in Africans, but the underlying molecular mechanisms remain poorly understood. Using population genetics and functional genomics, we identified key genetic variants, regulatory elements and genes that affect skin pigmentation, an adaptive trait, which provides valuable insights into the mechanisms underlying human skin color diversity and evolution.
The genetic background of pediatric acute myeloid leukemia (AML) does not fit with classification systems developed for adult AML. This study investigates the genetic background of pediatric AML and proposes a genomic framework for improved classification and risk stratification based on the driver alterations.
The spatial biology revolution promises deep insights into tissue organization, but deriving this knowledge from diverse, complex data remains a major obstacle. Data-driven discovery of the multicellular organization of tissues is now achieved by transforming multimodal spatial imaging data using deep learning.
A new study combining experimental treatments of human blood cells from thousands of individuals with flow-cytometry-based phenotyping and then genome-wide association analyses identifies genetic loci associated with non-resting cell states. Integrating the results with disease association signals yields insights into the underlying biology.
Polymorphisms in the non-coding genome affect genetic circuits and result in variable immune responses across individuals. Here we report a genetic circuit involving a long non-coding RNA (lncRNA) that spatially coordinates chromatin contacts to control pro- and anti-inflammatory gene expression and shape immune responses of healthy individuals to pathogens or vaccination.
New research reports that paused RNA polymerase II (RNAPII) enhances the targeting and activity of BAF chromatin remodelers. These findings suggest a new paradigm for understanding how the collaborative action of chromatin remodelers and the transcriptional machinery govern cell-type-specific chromatin accessibility.
CX-5461 (also known as pidnarulex), currently in phase 1/2 trials, induces selective killing of homologous-recombination-deficient or BRCA1- or BRCA2-mutated tumors in preclinical models. New work confirms these findings but shows it to be a remarkably potent mutagen that induces extensive genetic changes in cultured human cells with or without BRCA1/2 mutations, raising substantial safety issues.
Long segments of the genome that are shared ‘identical by descent’ (IBD) demonstrate recent relatedness between individuals. A new computational method robustly identifies shared IBD segments in human ancient DNA data, providing insights into the mobility and demography of prehistoric human societies.
EasySci, a scalable single-cell profiling technique, uncovered over 300 mammalian brain cell states, revealing molecular features and dynamics of rare cell states linked to aging and Alzheimer’s disease. This work offers insights into cell states that expand (rare astrocytes and vascular leptomeningeal cells in the olfactory bulb, reactive microglia, and oligodendrocytes) or are depleted (neuronal progenitors, neuroblasts and committed oligodendrocyte precursors) during normal and pathological aging.
Combined analysis of genome-wide association studies and epigenetic data has identified certain immune cell types as drivers of autoimmune disease, but current methods have not been able to pinpoint key effector immune cell states. Using single-cell data from inflammatory tissues, we identified effector cell states embedded within inflammatory tissues — including T peripheral helper cells and tissue regulatory T cells — that capture disproportionate disease heritability.
We present a model to predict the chance of each possible de novo mutation in the human genome informed by recent insights into determinants of mutagenesis. Predictions were applied to refine demographic models, identify constrained genes, and uncover mutagenic effects of polymerase III transcription and transcription factor binding in testis.
Deep learning shows promise for predicting gene expression levels from DNA sequences. However, recent studies show that current state-of-the-art models struggle to accurately characterize expression variation from personal genomes, limiting their usefulness in personalized medicine.
Variants in the HLA region on chromosome 6 are strongly associated with many immune-related diseases. A method to construct personalized HLA genomes from single-cell RNA sequencing data, coupled with single-cell HLA expression quantitative trait loci modeling, identifies how genetic variants influence HLA gene expression across cell states.
This Perspective article explores complex synthetic lethal relationships in cancer, which can involve several partners. Understanding this complexity presents challenges and opportunities for the development of therapeutics that target these interactions.
Whole-genome sequencing data of individuals from the UK Biobank and Iceland and a somatic mutation barcoding strategy enabled detection of clonal hematopoiesis at scale. This comprehensive study provides insights into the epidemiology, somatic and germline genetics, and disease associations of clonal hematopoiesis.
Previous studies reported an effect of N6-methyladenosine (m6A) of super-enhancer RNAs (seRNAs) on chromatin accessibility and gene transcription. We investigated seRNA m6A levels in pancreatic ductal adenocarcinoma (PDAC) and found that aberrantly increased m6A methylation promoted local chromatin accessibility, resulting in increased transcription of oncogenes acting in PDAC progression.
We present an analysis that shows that although nearly half of the human genome comprises repetitive sequences, recombination between homologous repeats has a minor role in cancer chromosomal evolution.
The pancreas is an essential organ present in all vertebrates, and human pancreatic agenesis is an extremely rare disorder of largely unknown genetic determinants. A study now demonstrates that a primate-specific regulatory network controlled by the KRAB zinc-finger protein ZNF808 is essential for pancreas development.
Whole-exome and genome sequencing in consanguineous families with unsolved lipodystrophy identified biallelic pathogenic loss-of-function variants in the phospholipase gene PLAAT3. Multi-omics and functional analyses in human and mouse PLAAT3-deficient adipose tissue and adipose stem cells revealed an adipocyte differentiation defect that is mediated by an altered gene network downstream of the adipogenesis master regulator PPARγ.
This Review discusses how embryonic transcriptional programs, such as epithelial–mesenchymal plasticity and stemness, may be harnessed in adult tissues to drive processes and diseases such as regeneration and cancer.