来自杂志 Nature reviews. Genetics 的文献。
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1.
Vincent
(2023-10-31 14:27):
#paper https://doi.org/10.1038/s41576-022-00477-6 Nat Rev Genet 2022 Making sense of the ageing methylome
衰老近些年引起了比较大的研究兴趣。这篇综述文章总结了近些年关于衰老的甲基化组学研究。文章介绍了寻找衰老关联位点的几种统计方法和对应的工具,例如最常见的使用线性模型寻找差异化位点,使用假设检验寻找变异位点,以及通过使用熵值和相关性网络等统计工具寻找更复杂的变化模式。此外文章还介绍了一些有趣的与衰老相关的甲基化证据,探讨了通过干预甲基化模式与机制来达到延长寿命的策略。最后文章还讨论了甲基化年龄机理的相关理论。
Abstract:
Over time, the human DNA methylation landscape accrues substantial damage, which has been associated with a broad range of age-related diseases, including cardiovascular disease and cancer. Various age-related DNA methylation …
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Over time, the human DNA methylation landscape accrues substantial damage, which has been associated with a broad range of age-related diseases, including cardiovascular disease and cancer. Various age-related DNA methylation changes have been described, including at the level of individual CpGs, such as differential and variable methylation, and at the level of the whole methylome, including entropy and correlation networks. Here, we review these changes in the ageing methylome as well as the statistical tools that can be used to quantify them. We detail the evidence linking DNA methylation to ageing phenotypes and the longevity strategies aimed at altering both DNA methylation patterns and machinery to extend healthspan and lifespan. Lastly, we discuss theories on the mechanistic causes of epigenetic ageing.
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2.
Vincent
(2023-04-30 15:13):
#paper doi: https://www.nature.com/articles/s41576-023-00586-w Best practices for single-cell analysis across modalities. Nature review genetics,2023. 这篇综述文章来自Fabian Theis组, 是一篇极好的单细胞分析指导文章。文章涵盖了几种不同的技术(scRNA-seq, scATAC-seq, scTCR/BCR, spatial transcriptomics), 对于每一种技术路线,介绍了完整的分析流程和目前最好的处理方法,例如scRNA, 介绍了原始数据处理、数据过滤和去杂,标准化和批次效应去除,降维聚类分型,拟时序分析和RNA速率分析,差异基因分析,细胞组成分析和细胞通讯分析等等。对于每一个步骤,文章会总结当前的最佳实践(如果有其他文章做过基准测试)或者给出分析建议(如果目前还没有基准测试的工作)。鉴于当前单细胞分析领域各种方法层出不穷,这篇文章提供了一个很好的指导总结,非常推荐做单细胞分析的朋友阅读。
Abstract:
Recent advances in single-cell technologies have enabled high-throughput molecular profiling of cells across modalities and locations. Single-cell transcriptomics data can now be complemented by chromatin accessibility, surface protein expression, adaptive …
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Recent advances in single-cell technologies have enabled high-throughput molecular profiling of cells across modalities and locations. Single-cell transcriptomics data can now be complemented by chromatin accessibility, surface protein expression, adaptive immune receptor repertoire profiling and spatial information. The increasing availability of single-cell data across modalities has motivated the development of novel computational methods to help analysts derive biological insights. As the field grows, it becomes increasingly difficult to navigate the vast landscape of tools and analysis steps. Here, we summarize independent benchmarking studies of unimodal and multimodal single-cell analysis across modalities to suggest comprehensive best-practice workflows for the most common analysis steps. Where independent benchmarks are not available, we review and contrast popular methods. Our article serves as an entry point for novices in the field of single-cell (multi-)omic analysis and guides advanced users to the most recent best practices.
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3.
小W
(2023-03-31 16:57):
#paper doi:https://doi.org/10.1038/s41576-022-00511-7 Measuring biological age using omics data.
生物老化是随着实际年龄的增长而发生的系统完整性进行性下降 ,最终导致疾病、残疾和死亡。本文是利用组学数据量化生物衰老方法(衰老时钟)研究的综述文章,介绍了表观遗传、转录组学、蛋白质组学、代谢组学等方面衰老时钟的研究原理、局限性和优化。比较有意思的一点,第一代表观时钟彼此之间只有轻微的相关性,增大样本量的情况下训练第一代甲基化时钟过拟合,又消除了年龄和生物学年龄之间的联系。这里提出对之后开发衰老时钟的展望,定义衰老时钟的应用场景,通过有目的的特征选择或通过开发复合训练指标,将衰老生物学的特定方面纳入其中的建模方法应有助于提高模型的可解释性,并指导它们识别衰老的因果特征。一个大胆的方法是在时钟的训练中排除年龄,从而更接近于测量老化生物学特征。
Abstract:
Age is the key risk factor for diseases and disabilities of the elderly. Efforts to tackle age-related diseases and increase healthspan have suggested targeting the ageing process itself to 'rejuvenate' …
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Age is the key risk factor for diseases and disabilities of the elderly. Efforts to tackle age-related diseases and increase healthspan have suggested targeting the ageing process itself to 'rejuvenate' physiological functioning. However, achieving this aim requires measures of biological age and rates of ageing at the molecular level. Spurred by recent advances in high-throughput omics technologies, a new generation of tools to measure biological ageing now enables the quantitative characterization of ageing at molecular resolution. Epigenomic, transcriptomic, proteomic and metabolomic data can be harnessed with machine learning to build 'ageing clocks' with demonstrated capacity to identify new biomarkers of biological ageing.
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4.
Vincent
(2022-10-31 15:22):
#paper Obtaining genetics insights from deep learning via explainable artificial intelligence, Nature Reviews Genetics https://doi.org/10.1038/ s41576-022-00532-2 基于深度学习的人工智能模型在基因组功能预测中发挥重要作用,被认为是当下表现最好的模型(state of the art)。但是由于深度学习模型的复杂性, 它们往往被认为是黑箱模型,其预测效果/机制往往很难被解释,但是基因组的研究中很多时候作用机制(过程)比预测效果(结果)更有价值。这篇review paper总结了近年来新兴的可解释性机器学习(xAI)技术在基因组领域的研究进展,展望了该技术在揭示生物机理方面的潜能。这篇文章主要以regulatory genomics 作为例子, 总结归纳了4种解释机器学习模型的技术:基于模型的解释(检查隐含层的神经元活动,注意力机制),影响的数学传播(前向传播/后向传播), 特征相互作用的鉴别,和基于先验知识的透明模型,以及这几种技术在高通量测序技术中的潜在假设和相应的局限性。
Abstract:
Artificial intelligence (AI) models based on deep learning now represent the state of the art for making functional predictions in genomics research. However, the underlying basis on which predictive models …
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Artificial intelligence (AI) models based on deep learning now represent the state of the art for making functional predictions in genomics research. However, the underlying basis on which predictive models make such predictions is often unknown. For genomics researchers, this missing explanatory information would frequently be of greater value than the predictions themselves, as it can enable new insights into genetic processes. We review progress in the emerging area of explainable AI (xAI), a field with the potential to empower life science researchers to gain mechanistic insights into complex deep learning models. We discuss and categorize approaches for model interpretation, including an intuitive understanding of how each approach works and their underlying assumptions and limitations in the context of typical high-throughput biological datasets.
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5.
na na na
(2022-09-26 22:58):
#paper doi: 10.1038/nrg.2016.67 Nat Rev Genet, 2016, Computational genomics tools for dissecting tumour-immune cell interactions. 分享一篇比较早的16年综述,本文全方面收录了研究肿瘤免疫中各个环节涉及到的热点软件工具和数据库,描述了基于基因表达谱、DNA甲基化谱和免疫组织化学等分子信息的多种来源和可用于研究肿瘤免疫表型的生信算法,并且深入浅出的讲述了肿瘤免疫相关的技术发展现况、面临的挑战、现今研究重点、未来发展,既可帮助入门学习肿瘤免疫,也可用于深入肿瘤免疫相关研究。虽然时间有点久了,但其中讲述的观点和算法工具至今依然受用。
Abstract:
Recent breakthroughs in cancer immunotherapy and decreasing costs of high-throughput technologies have sparked intensive research into tumour-immune cell interactions using genomic tools. The wealth of the generated data and the …
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Recent breakthroughs in cancer immunotherapy and decreasing costs of high-throughput technologies have sparked intensive research into tumour-immune cell interactions using genomic tools. The wealth of the generated data and the added complexity pose considerable challenges and require computational tools to process, to analyse and to visualize the data. Recently, various tools have been developed and used to mine tumour immunologic and genomic data effectively and to provide novel mechanistic insights. Here, we review computational genomics tools for cancer immunology and provide information on the requirements and functionality in order to assist in the selection of tools and assembly of analytical pipelines.
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6.
张贝
(2022-02-28 16:37):
#paper doi: 10.1038/s41576-019-0150-2 Nat Rev Genet
. 2019. RNA sequencing: the teenage years
本文是一篇关于RNA-seq的综述。文章从RNA-seq技术的发展、RNA-seq建库方法改良、RNA-seq实验方案设计、RNA-seq数据分析、其他非bulk RNA分析、非稳态RNA分析和非基因表达分析这7个方面进行介绍。
Abstract:
Over the past decade, RNA sequencing (RNA-seq) has become an indispensable tool for transcriptome-wide analysis of differential gene expression and differential splicing of mRNAs. However, as next-generation sequencing technologies have …
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Over the past decade, RNA sequencing (RNA-seq) has become an indispensable tool for transcriptome-wide analysis of differential gene expression and differential splicing of mRNAs. However, as next-generation sequencing technologies have developed, so too has RNA-seq. Now, RNA-seq methods are available for studying many different aspects of RNA biology, including single-cell gene expression, translation (the translatome) and RNA structure (the structurome). Exciting new applications are being explored, such as spatial transcriptomics (spatialomics). Together with new long-read and direct RNA-seq technologies and better computational tools for data analysis, innovations in RNA-seq are contributing to a fuller understanding of RNA biology, from questions such as when and where transcription occurs to the folding and intermolecular interactions that govern RNA function.
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