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- Volume 30, 2014
Annual Review of Cell and Developmental Biology - Volume 30, 2014
Volume 30, 2014
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Myelination of the Nervous System: Mechanisms and Functions
Vol. 30 (2014), pp. 503–533More LessMyelination of axons in the nervous system of vertebrates enables fast, saltatory impulse propagation, one of the best-understood concepts in neurophysiology. However, it took a long while to recognize the mechanistic complexity both of myelination by oligodendrocytes and Schwann cells and of their cellular interactions. In this review, we highlight recent advances in our understanding of myelin biogenesis, its lifelong plasticity, and the reciprocal interactions of myelinating glia with the axons they ensheath. In the central nervous system, myelination is also stimulated by axonal activity and astrocytes, whereas myelin clearance involves microglia/macrophages. Once myelinated, the long-term integrity of axons depends on glial supply of metabolites and neurotrophic factors. The relevance of this axoglial symbiosis is illustrated in normal brain aging and human myelin diseases, which can be studied in corresponding mouse models. Thus, myelinating cells serve a key role in preserving the connectivity and functions of a healthy nervous system.
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Insights into Morphology and Disease from the Dog Genome Project
Vol. 30 (2014), pp. 535–560More LessAlthough most modern dog breeds are less than 200 years old, the symbiosis between man and dog is ancient. Since prehistoric times, repeated selection events have transformed the wolf into man's guardians, laborers, athletes, and companions. The rapid transformation from pack predator to loyal companion is a feat that is arguably unique among domesticated animals. How this transformation came to pass remained a biological mystery until recently: Within the past decade, the deployment of genomic approaches to study population structure, detect signatures of selection, and identify genetic variants that underlie canine phenotypes is ushering into focus novel biological mechanisms that make dogs remarkable. Ironically, the very practices responsible for breed formation also spurned morbidity; today, many diseases are correlated with breed identity. In this review, we discuss man's best friend in the context of a genetic model to understand paradigms of heritable phenotypes, both desirable and disadvantageous.
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Noncoding RNAs and Epigenetic Mechanisms During X-Chromosome Inactivation
Vol. 30 (2014), pp. 561–580More LessIn mammals, the process of X-chromosome inactivation ensures equivalent levels of X-linked gene expression between males and females through the silencing of one of the two X chromosomes in female cells. The process is established early in development and is initiated by a unique locus, which produces a long noncoding RNA, Xist. The Xist transcript triggers gene silencing in cis by coating the future inactive X chromosome. It also induces a cascade of chromatin changes, including posttranslational histone modifications and DNA methylation, and leads to the stable repression of all X-linked genes throughout development and adult life. We review here recent progress in our understanding of the molecular mechanisms involved in the initiation of Xist expression, the propagation of the Xist RNA along the chromosome, and the cis-elements and trans-acting factors involved in the maintenance of the repressed state. We also describe the diverse strategies used by nonplacental mammals for X-chromosome dosage compensation and highlight the common features and differences between eutherians and metatherians, in particular regarding the involvement of long noncoding RNAs.
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Zygotic Genome Activation During the Maternal-to-Zygotic Transition
Vol. 30 (2014), pp. 581–613More LessEmbryogenesis depends on a highly coordinated cascade of genetically encoded events. In animals, maternal factors contributed by the egg cytoplasm initially control development, whereas the zygotic nuclear genome is quiescent. Subsequently, the genome is activated, embryonic gene products are mobilized, and maternal factors are cleared. This transfer of developmental control is called the maternal-to-zygotic transition (MZT). In this review, we discuss recent advances toward understanding the scope, timing, and mechanisms that underlie zygotic genome activation at the MZT in animals. We describe high-throughput techniques to measure the embryonic transcriptome and explore how regulation of the cell cycle, chromatin, and transcription factors together elicits specific patterns of embryonic gene expression. Finally, we illustrate the interplay between zygotic transcription and maternal clearance and show how these two activities combine to reprogram two terminally differentiated gametes into a totipotent embryo.
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Histone H3 Variants and Their Chaperones During Development and Disease: Contributing to Epigenetic Control
Vol. 30 (2014), pp. 615–646More LessWithin the nucleus, the interplay between lineage-specific transcription factors and chromatin dynamics defines cellular identity. Control of this interplay is necessary to properly balance stability and plasticity during the development and entire life span of multicellular organisms. Here, we present our current knowledge of the contribution of histone H3 variants to chromatin dynamics during development. We review the network of histone chaperones that governs their deposition timing and sites of incorporation and highlight how their distinct distribution impacts genome organization and function. We integrate the importance of H3 variants in the context of nuclear reprogramming and cell differentiation, and, using the centromere as a paradigm, we describe a case in which the identity of a given genomic locus is propagated across different cell types. Finally, we compare development to changes in stress and disease. Both physiological and pathological settings underline the importance of H3 dynamics for genome and chromatin integrity.
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The Nature of Embryonic Stem Cells
Vol. 30 (2014), pp. 647–675More LessMouse embryonic stem (ES) cells perpetuate in vitro the broad developmental potential of naïve founder cells in the preimplantation embryo. ES cells self-renew relentlessly in culture but can reenter embryonic development seamlessly, differentiating on schedule to form all elements of the fetus. Here we review the properties of these remarkable cells. Arising from the stability, homogeneity, and equipotency of ES cells, we consider the concept of a pluripotent ground state. We evaluate the authenticity of ES cells in relation to cells in the embryo and examine their utility for dissecting mechanisms that confer pluripotency and that execute fate choice. We summarize current knowledge of the transcription factor circuitry that governs the ES cell state and discuss the opportunity to expose molecular logic further through iterative computational modeling and experimentation. Finally, we present a perspective on unresolved questions, including the challenge of deriving ground state pluripotent stem cells from non-rodent species.
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“Mesenchymal” Stem Cells
Vol. 30 (2014), pp. 677–704More LessTwo opposing descriptions of so-called mesenchymal stem cells (MSCs) exist at this time. One sees MSCs as the postnatal, self-renewing, and multipotent stem cells for the skeleton. This cell coincides with a specific type of bone marrow perivascular cell. In skeletal physiology, this skeletal stem cell is pivotal to the growth and lifelong turnover of bone and to its native regeneration capacity. In hematopoietic physiology, its role as a key player in maintaining hematopoietic stem cells in their niche and in regulating the hematopoietic microenvironment is emerging. In the alternative description, MSCs are ubiquitous in connective tissues and are defined by in vitro characteristics and by their use in therapy, which rests on their ability to modulate the function of host tissues rather than on stem cell properties. Here, I discuss how the two views developed, conceptually and experimentally, and attempt to clarify the confusion arising from their collision.
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Haploid Mouse Embryonic Stem Cells: Rapid Genetic Screening and Germline Transmission
Vol. 30 (2014), pp. 705–722More LessMost animal genomes are diploid, and mammalian development depends on specific adaptations that have evolved secondary to diploidy. Genomic imprinting and dosage compensation restrict haploid development to early embryos. Recently, haploid mammalian development has been reinvestigated since the establishment of haploid embryonic stem cells (ESCs) from mouse embryos. Haploid cells possess one copy of each gene, facilitating the generation of loss-of-function mutations in a single step. Recessive mutations can then be assessed in forward genetic screens. Applications of haploid mammalian cell systems in screens have been illustrated in several recent publications. Haploid ESCs are characterized by a wide developmental potential and can contribute to chimeric embryos and mice. Different strategies for introducing genetic modifications from haploid ESCs into the mouse germline have been further developed. Haploid ESCs therefore introduce new possibilities in mammalian genetics and could offer an unprecedented tool for genome exploration in the future.
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Previous Volumes
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Volume 40 (2024)
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Volume 39 (2023)
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Volume 38 (2022)
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Volume 37 (2021)
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Volume 36 (2020)
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Volume 35 (2019)
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Volume 34 (2018)
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Volume 33 (2017)
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Volume 32 (2016)
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Volume 31 (2015)
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Volume 30 (2014)
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Volume 29 (2013)
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Volume 28 (2012)
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Volume 27 (2011)
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Volume 26 (2010)
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Volume 25 (2009)
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Volume 24 (2008)
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Volume 23 (2007)
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Volume 22 (2006)
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Volume 21 (2005)
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Volume 20 (2004)
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Volume 19 (2003)
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Volume 18 (2002)
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Volume 17 (2001)
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Volume 16 (2000)
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Volume 15 (1999)
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Volume 14 (1998)
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Volume 13 (1997)
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Volume 12 (1996)
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Volume 11 (1995)
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Volume 10 (1994)
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Volume 9 (1993)
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Volume 8 (1992)
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Volume 7 (1991)
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Volume 6 (1990)
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Volume 5 (1989)
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Volume 4 (1988)
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Volume 3 (1987)
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Volume 2 (1986)
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Volume 1 (1985)
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Volume 0 (1932)