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Brn3/POU-IV-type POU homeobox genes-Paradigmatic regulators of neuronal identity across phylogeny. Brn3/POU- iv型POU同源盒基因-跨系统发育神经元同一性的范式调节因子
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-07-01 Epub Date: 2020-02-03 DOI: 10.1002/wdev.374
Eduardo Leyva-Díaz, Neda Masoudi, Esther Serrano-Saiz, Lori Glenwinkel, Oliver Hobert

One approach to understand the construction of complex systems is to investigate whether there are simple design principles that are commonly used in building such a system. In the context of nervous system development, one may ask whether the generation of its highly diverse sets of constituents, that is, distinct neuronal cell types, relies on genetic mechanisms that share specific common features. Specifically, are there common patterns in the function of regulatory genes across different neuron types and are those regulatory mechanisms not only used in different parts of one nervous system, but are they conserved across animal phylogeny? We address these questions here by focusing on one specific, highly conserved and well-studied regulatory factor, the POU homeodomain transcription factor UNC-86. Work over the last 30 years has revealed a common and paradigmatic theme of unc-86 function throughout most of the neuron types in which Caenorhabditis elegans unc-86 is expressed. Apart from its role in preventing lineage reiterations during development, UNC-86 operates in combination with distinct partner proteins to initiate and maintain terminal differentiation programs, by coregulating a vast array of functionally distinct identity determinants of specific neuron types. Mouse orthologs of unc-86, the Brn3 genes, have been shown to fulfill a similar function in initiating and maintaining neuronal identity in specific parts of the mouse brain and similar functions appear to be carried out by the sole Drosophila ortholog, Acj6. The terminal selector function of UNC-86 in many different neuron types provides a paradigm for neuronal identity regulation across phylogeny. This article is categorized under: Gene Expression and Transcriptional Hierarchies > Regulatory Mechanisms Invertebrate Organogenesis > Worms Nervous System Development > Vertebrates: Regional Development.

理解复杂系统构造的一种方法是调查在构建这样一个系统时是否存在通常使用的简单设计原则。在神经系统发育的背景下,人们可能会问,其高度多样化的组成部分(即不同的神经元细胞类型)的产生是否依赖于具有特定共同特征的遗传机制。具体来说,在不同的神经元类型中,调节基因的功能是否存在共同的模式?这些调节机制是否不仅在一个神经系统的不同部分中使用,而且在动物的系统发育中是否都是保守的?我们在这里通过关注一个特定的,高度保守的和被充分研究的调控因子,POU同源域转录因子UNC-86来解决这些问题。过去30年的工作揭示了unc-86在秀丽隐杆线虫unc-86表达的大多数神经元类型中的共同和典型的功能主题。除了在发育过程中防止谱系重复的作用外,UNC-86还通过协同调节特定神经元类型的大量功能不同的身份决定因素,与不同的伴侣蛋白结合,启动和维持终端分化程序。unc-86的小鼠同源基因Brn3已被证明在启动和维持小鼠大脑特定部位的神经元身份方面具有类似的功能,而果蝇的唯一同源基因Acj6似乎也具有类似的功能。UNC-86在许多不同神经元类型中的终端选择功能为跨系统发育的神经元身份调节提供了一个范例。本文分类如下:基因表达和转录层次>无脊椎动物器官发生>蠕虫神经系统发育>脊椎动物:区域发育。
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引用次数: 22
Regulation of rhythmic behaviors by astrocytes. 星形胶质细胞对节律行为的调节
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-07-01 Epub Date: 2019-12-15 DOI: 10.1002/wdev.372
F Rob Jackson, Samantha You, Lauren B Crowe

Glial astrocytes of vertebrates and invertebrates are important modulators of nervous system development, physiology, and behavior. In all species examined, astrocytes of the adult brain contain conserved circadian clocks, and multiple studies have shown that these glial cells participate in the regulation of circadian behavior and sleep. This short review summarizes recent work, using fruit fly (Drosophila) and mouse models, that document participation of astrocytes and their endogenous circadian clocks in the control of rhythmic behavior. This article is categorized under: Gene Expression and Transcriptional Hierarchies > Regulatory Mechanisms Nervous System Development > Flies.

脊椎动物和无脊椎动物的胶质星形胶质细胞是神经系统发育、生理和行为的重要调节器。在所研究的所有物种中,成体大脑的星形胶质细胞都含有保守的昼夜节律钟,多项研究表明,这些胶质细胞参与了昼夜节律行为和睡眠的调控。这篇简短的综述总结了利用果蝇(果蝇)和小鼠模型进行的最新研究,这些研究记录了星形胶质细胞及其内源性昼夜节律钟参与节律行为控制的情况。本文归类于基因表达和转录层次结构 > 调控机制 神经系统发育 > 苍蝇。
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引用次数: 14
Endochondral ossification and the evolution of limb proportions. 软骨内成骨和肢体比例的演变。
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-07-01 Epub Date: 2020-01-29 DOI: 10.1002/wdev.373
Campbell Rolian

Mammals have remarkably diverse limb proportions hypothesized to have evolved adaptively in the context of locomotion and other behaviors. Mechanistically, evolutionary diversity in limb proportions is the result of differential limb bone growth. Longitudinal limb bone growth is driven by the process of endochondral ossification, under the control of the growth plates. In growth plates, chondrocytes undergo a tightly orchestrated life cycle of proliferation, matrix production, hypertrophy, and cell death/transdifferentiation. This life cycle is highly conserved, both among the long bones of an individual, and among homologous bones of distantly related taxa, leading to a finite number of complementary cell mechanisms that can generate heritable phenotype variation in limb bone size and shape. The most important of these mechanisms are chondrocyte population size in chondrogenesis and in individual growth plates, proliferation rates, and hypertrophic chondrocyte size. Comparative evidence in mammals and birds suggests the existence of developmental biases that favor evolutionary changes in some of these cellular mechanisms over others in driving limb allometry. Specifically, chondrocyte population size may evolve more readily in response to selection than hypertrophic chondrocyte size, and extreme hypertrophy may be a rarer evolutionary phenomenon associated with highly specialized modes of locomotion in mammals (e.g., powered flight, ricochetal bipedal hopping). Physical and physiological constraints at multiple levels of biological organization may also have influenced the cell developmental mechanisms that have evolved to produce the highly diverse limb proportions in extant mammals. This article is categorized under: Establishment of Spatial and Temporal Patterns > Regulation of Size, Proportion, and Timing Comparative Development and Evolution > Regulation of Organ Diversity Comparative Development and Evolution > Organ System Comparisons Between Species.

哺乳动物有非常不同的肢体比例,假设在运动和其他行为的背景下进化适应。从机械上讲,肢体比例的进化多样性是肢体骨生长差异的结果。纵肢骨生长受软骨内成骨过程驱动,受生长板控制。在生长板中,软骨细胞经历一个紧密协调的生命周期,包括增殖、基质生成、肥大和细胞死亡/转分化。这种生命周期在个体的长骨和远缘类群的同源骨中都是高度保守的,这导致有限数量的互补细胞机制可以产生肢体骨大小和形状的遗传表型变异。这些机制中最重要的是软骨形成和单个生长板中的软骨细胞群大小、增殖率和肥大软骨细胞大小。哺乳动物和鸟类的比较证据表明,在驱动肢体异速发育的过程中,某些细胞机制的进化变化比其他机制更有利于发育偏见的存在。具体来说,软骨细胞群的大小可能比肥大的软骨细胞大小更容易进化,而极端肥大可能是一种罕见的进化现象,与哺乳动物高度特化的运动模式相关(例如,动力飞行,弹跳两足跳跃)。在生物组织的多个层面上的物理和生理限制也可能影响细胞的发育机制,从而在现存哺乳动物中产生高度多样化的肢体比例。本文的分类为:时空格局的建立>大小、比例和时间的调控>器官多样性的调控>物种间器官系统的比较。
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引用次数: 22
Developmental dynamics of neurogenesis and gliogenesis in the postnatal mammalian brain in health and disease: Historical and future perspectives. 健康和疾病中出生后哺乳动物大脑中神经发生和胶质瘤发生的发育动力学:历史和未来的观点。
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-05-01 Epub Date: 2019-12-11 DOI: 10.1002/wdev.369
Masato Nakafuku, Ángela Del Águila

The mature mammalian brain has long been thought to be a structurally rigid, static organ since the era of Ramón y Cajal in the early 20th century. Evidence accumulated over the past three decades, however, has completely overturned this long-held view. We now know that new neurons and glia are continuously added to the brain at postnatal stages, even in mature adults of various mammalian species, including humans. Moreover, these newly added cells contribute to structural plasticity and play important roles in higher order brain function, as well as repair after damage. A major source of these new neurons and glia is neural stem cells (NSCs) that persist in specialized niches in the brain throughout life. With this new view, our understanding of normal brain physiology and interventional approaches to various brain disorders has changed markedly in recent years. This article provides a brief overview on the historical changes in our understanding of the developmental dynamics of neurogenesis and gliogenesis in the postnatal and adult mammalian brain and discusses the roles of NSCs and other progenitor populations in such cellular dynamics in health and disease of the postnatal mammalian brain. This article is categorized under: Adult Stem Cells, Tissue Renewal, and Regeneration > Stem Cell Differentiation and Reversion Adult Stem Cells, Tissue Renewal, and Regeneration > Tissue Stem Cells and Niches Adult Stem Cells, Tissue Renewal, and Regeneration > Regeneration Adult Stem Cells, Tissue Renewal, and Regeneration > Stem Cells and Disease.

自20世纪初Ramón y Cajal时代以来,成熟哺乳动物的大脑一直被认为是一个结构僵化的静态器官。然而,过去三十年积累的证据完全推翻了这种长期持有的观点。我们现在知道,在出生后的阶段,新的神经元和神经胶质不断地添加到大脑中,甚至在各种哺乳动物物种(包括人类)的成年中也是如此。此外,这些新增加的细胞有助于结构可塑性,在高阶脑功能和损伤后修复中发挥重要作用。这些新神经元和胶质细胞的主要来源是神经干细胞(NSCs),它们一生都存在于大脑的特定壁龛中。有了这种新的观点,我们对正常脑生理学和各种脑疾病的介入方法的理解近年来发生了显著变化。本文简要概述了我们对出生后和成年哺乳动物大脑中神经发生和胶质瘤发生的发育动力学的理解的历史变化,并讨论了NSCs和其他祖细胞群体在出生后哺乳动物大脑健康和疾病的细胞动力学中的作用。本文分类如下:成体干细胞,组织更新和再生>干细胞分化和逆转成体干细胞,组织更新和再生>组织干细胞和壁龛成体干细胞,组织更新和再生>再生成体干细胞,组织更新和再生>干细胞和疾病。
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引用次数: 15
Hippo-Yap/Taz signaling: Complex network interactions and impact in epithelial cell behavior. Hippo-Yap/Taz信号:上皮细胞行为的复杂网络相互作用和影响。
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-05-01 Epub Date: 2019-12-11 DOI: 10.1002/wdev.371
Benjamin J van Soldt, Wellington V Cardoso

The Hippo pathway has emerged as a crucial integrator of signals in biological events from development to adulthood and in diseases. Although extensively studied in Drosophila and in cell cultures, major gaps of knowledge still remain on how this pathway functions in mammalian systems. The pathway consists of a growing number of components, including core kinases and adaptor proteins, which control the subcellular localization of the transcriptional co-activators Yap and Taz through phosphorylation of serines at key sites. When localized to the nucleus, Yap/Taz interact with TEAD transcription factors to induce transcriptional programs of proliferation, stemness, and growth. In the cytoplasm, Yap/Taz interact with multiple pathways to regulate a variety of cellular functions or are targeted for degradation. The Hippo pathway receives cues from diverse intracellular and extracellular inputs, including growth factor and integrin signaling, polarity complexes, and cell-cell junctions. This review highlights the mechanisms of regulation of Yap/Taz nucleocytoplasmic shuttling and their implications for epithelial cell behavior using the lung as an intriguing example of this paradigm. This article is categorized under: Gene Expression and Transcriptional Hierarchies > Regulatory Mechanisms Signaling Pathways > Cell Fate Signaling Establishment of Spatial and Temporal Patterns > Cytoplasmic Localization.

Hippo通路已成为从发育到成年和疾病的生物事件的关键信号整合者。尽管在果蝇和细胞培养中进行了广泛的研究,但关于这一途径在哺乳动物系统中如何发挥作用的知识仍然存在主要空白。该通路由越来越多的组分组成,包括核心激酶和接头蛋白,它们通过关键位点丝氨酸的磷酸化控制转录共激活因子Yap和Taz的亚细胞定位。当定位于细胞核时,Yap/Taz与TEAD转录因子相互作用,诱导增殖、干性和生长的转录程序。在细胞质中,Yap/Taz与多种途径相互作用,调节多种细胞功能或成为降解的目标。Hippo通路接收来自细胞内和细胞外各种输入的信号,包括生长因子和整合素信号、极性复合物和细胞-细胞连接。这篇综述强调了Yap/Taz核细胞质穿梭的调节机制及其对上皮细胞行为的影响,并将肺作为这一范式的一个有趣例子。本文分类如下:基因表达与转录层次>调控机制信号通路>细胞命运信号时空格局的建立>细胞质定位。
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引用次数: 18
The significance of sponges for comparative studies of developmental evolution 海绵对发育进化比较研究的意义
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-03-01 DOI: 10.1002/wdev.359
J. Colgren, S. Nichols
Sponges, ctenophores, placozoans, and cnidarians have key evolutionary significance in that they bracket the time interval during which organized animal tissues were first assembled, fundamental cell types originated (e.g., neurons and myocytes), and developmental patterning mechanisms evolved. Sponges in particular have often been viewed as living surrogates for early animal ancestors, largely due to similarities between their feeding cells (choanocytes) with choanoflagellates, the unicellular/colony‐forming sister group to animals. Here, we evaluate these claims and highlight aspects of sponge biology with comparative value for understanding developmental evolution, irrespective of the purported antiquity of their body plan. Specifically, we argue that sponges strike a different balance between patterning and plasticity than other animals, and that environmental inputs may have prominence over genetically regulated developmental mechanisms. We then present a case study to illustrate how contractile epithelia in sponges can help unravel the complex ancestry of an ancient animal cell type, myocytes, which sponges lack. Sponges represent hundreds of millions of years of largely unexamined evolutionary experimentation within animals. Their phylogenetic placement lends them key significance for learning about the past, and their divergent biology challenges current views about the scope of animal cell and developmental biology.
海绵类、栉水母类、扁壳类和刺突动物具有关键的进化意义,因为它们包含了有组织动物组织首次组装、基本细胞类型(如神经元和肌细胞)起源和发育模式机制进化的时间间隔。海绵通常被视为早期动物祖先的活体替代品,这主要是因为它们的喂养细胞(choanocytes)与choano鞭毛虫(动物的单细胞/集落形成姐妹群)之间存在相似性。在这里,我们评估了这些说法,并强调了海绵生物学在理解发育进化方面具有比较价值的方面,而不管它们的身体计划是否古老。具体而言,我们认为海绵在模式和可塑性之间的平衡与其他动物不同,环境投入可能比基因调控的发育机制更重要。然后,我们提出了一个案例研究,以说明海绵中的可收缩上皮如何帮助解开海绵所缺乏的一种古老动物细胞类型——肌细胞的复杂祖先。海绵代表了数亿年来动物内部基本上未经检验的进化实验。它们的系统发育位置为它们了解过去提供了关键意义,它们不同的生物学挑战了当前关于动物细胞和发育生物学范围的观点。
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引用次数: 9
Postnatal development of cerebrovascular structure and the neurogliovascular unit. 出生后脑血管结构和神经胶质血管单位的发育。
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-03-01 DOI: 10.1002/wdev.363
Vanessa Coelho-Santos, Andy Y Shih

The unceasing metabolic demands of brain function are supported by an intricate three-dimensional network of arterioles, capillaries, and venules, designed to effectively distribute blood to all neurons and to provide shelter from harmful molecules in the blood. The development and maturation of this microvasculature involves a complex interplay between endothelial cells with nearly all other brain cell types (pericytes, astrocytes, microglia, and neurons), orchestrated throughout embryogenesis and the first few weeks after birth in mice. Both the expansion and regression of vascular networks occur during the postnatal period of cerebrovascular remodeling. Pial vascular networks on the brain surface are dense at birth and are then selectively pruned during the postnatal period, with the most dramatic changes occurring in the pial venular network. This is contrasted to an expansion of subsurface capillary networks through the induction of angiogenesis. Concurrent with changes in vascular structure, the integration and cross talk of neurovascular cells lead to establishment of blood-brain barrier integrity and neurovascular coupling to ensure precise control of macromolecular passage and metabolic supply. While we still possess a limited understanding of the rules that control cerebrovascular development, we can begin to assemble a view of how this complex process evolves, as well as identify gaps in knowledge for the next steps of research. This article is categorized under: Nervous System Development > Vertebrates: Regional Development Vertebrate Organogenesis > Musculoskeletal and Vascular Nervous System Development > Vertebrates: General Principles.

脑功能不断的代谢需求是由一个复杂的三维小动脉、毛细血管和小静脉网络支持的,该网络旨在有效地将血液分配到所有神经元,并为血液中的有害分子提供庇护。这种微血管系统的发育和成熟涉及内皮细胞与几乎所有其他脑细胞类型(周细胞、星形胶质细胞、小胶质细胞和神经元)之间复杂的相互作用,这种相互作用贯穿于胚胎发育和小鼠出生后的最初几周。出生后脑血管重构期间血管网络的扩张和收缩都有发生。脑表面的脑脊液静脉网络在出生时是致密的,然后在出生后有选择性地修剪,最显著的变化发生在脑脊液静脉网络。这与通过诱导血管生成而扩张的地下毛细血管网络形成对比。在血管结构改变的同时,神经血管细胞的整合和串扰导致血脑屏障完整性和神经血管耦合的建立,以确保大分子传递和代谢供应的精确控制。虽然我们对控制脑血管发育的规则的理解仍然有限,但我们可以开始对这个复杂的过程如何演变形成一个观点,并为下一步的研究确定知识上的空白。本文分类如下:神经系统发育>脊椎动物:区域发育脊椎动物器官发生>肌肉骨骼和血管神经系统发育>脊椎动物:一般原理。
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引用次数: 72
The mouse fetal‐placental arterial connection: A paradigm involving the primitive streak and visceral endoderm with implications for human development 小鼠胎儿-胎盘动脉连接:一种涉及原始条纹和内脏内胚层的范式,对人类发育有意义
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-03-01 DOI: 10.1002/wdev.362
K. Downs, Adriana M Rodriguez
In Placentalia, the fetus depends upon an organized vascular connection with its mother for survival and development. Yet, this connection was, until recently, obscure. Here, we summarize how two unrelated tissues, the primitive streak, or body axis, and extraembryonic visceral endoderm collaborate to create and organize the fetal‐placental arterial connection in the mouse gastrula. The primitive streak reaches into the extraembryonic space, where it marks the site of arterial union and creates a progenitor cell pool. Through contact with the streak, associated visceral endoderm undergoes an epithelial‐to‐mesenchymal transition, contributing extraembryonic mesoderm to the placental arterial vasculature, and to the allantois, or pre‐umbilical tissue. In addition, visceral endoderm bifurcates into the allantois where, with the primitive streak, it organizes the nascent umbilical artery and promotes allantoic elongation to the chorion, the site of fetal‐maternal exchange. Brachyury mediates streak extension and vascular patterning, while Hedgehog is involved in visceral endoderm's conversion to mesoderm. A unique CASPASE‐3‐positive cell separates streak‐ and non‐streak‐associated domains in visceral endoderm. Based on these new insights at the posterior embryonic‐extraembryonic interface, we conclude by asking whether so‐called primordial germ cells are truly antecedents to the germ line that segregate within the allantois, or whether they are placental progenitor cells. Incorporating these new working hypotheses into mutational analyses in which the placentae are affected will aid understanding a spectrum of disorders, including orphan diseases, which often include abnormalities of the umbilical cord, yolk sac, and hindgut, whose developmental relationship to each other has, until now, been poorly understood.
在胎盘中,胎儿依靠与母亲有组织的血管连接来生存和发育。然而,直到最近,这种联系还很模糊。在这里,我们总结了两种不相关的组织,即原始条纹或体轴和胚胎外内脏内胚层,是如何在小鼠原肠胚中协同创建和组织胎儿-胎盘动脉连接的。原始条纹延伸到胚胎外空间,在那里它标志着动脉结合的部位,并形成祖细胞池。通过与条纹的接触,相关的内脏内胚层经历上皮到间充质的转变,为胎盘动脉血管系统、尿囊或脐前组织提供胚胎外中胚层。此外,内脏内胚层分叉为尿囊,在那里,通过原始条纹,它组织新生的脐动脉,并促进尿囊向绒毛膜的延伸,绒毛膜是胎母交换的部位。Brachyunry介导条纹延伸和血管模式,而Hedgehog参与内脏内胚层向中胚层的转化。一种独特的CASPASE‐3阳性细胞在内脏内胚层中分离条纹和非条纹相关结构域。基于对胚胎后-胚胎外界面的这些新见解,我们通过询问所谓的原始生殖细胞是否真的是在尿囊内分离的生殖系的前身,或者它们是否是胎盘祖细胞来得出结论。将这些新的工作假设纳入胎盘受影响的突变分析中,将有助于理解一系列疾病,包括孤儿疾病,这些疾病通常包括脐带、卵黄囊和后肠的异常,迄今为止,人们对它们之间的发育关系知之甚少。
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引用次数: 8
Signatures of sex: Sex differences in gene expression in the vertebrate brain. 性别特征:脊椎动物大脑中基因表达的性别差异。
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-01-01 Epub Date: 2019-05-20 DOI: 10.1002/wdev.348
Bruno Gegenhuber, Jessica Tollkuhn

Women and men differ in disease prevalence, symptoms, and progression rates for many psychiatric and neurological disorders. As more preclinical studies include both sexes in experimental design, an increasing number of sex differences in physiology and behavior have been reported. In the brain, sex-typical behaviors are thought to result from sex-specific patterns of neural activity in response to the same sensory stimulus or context. These differential firing patterns likely arise as a consequence of underlying anatomic or molecular sex differences. Accordingly, gene expression in the brains of females and males has been extensively investigated, with the goal of identifying biological pathways that specify or modulate sex differences in brain function. However, there is surprisingly little consensus on sex-biased genes across studies and only a handful of robust candidates have been pursued in the follow-up experiments. Furthermore, it is not known how or when sex-biased gene expression originates, as few studies have been performed in the developing brain. Here we integrate molecular genetic and neural circuit perspectives to provide a conceptual framework of how sex differences in gene expression can arise in the brain. We detail mechanisms of gene regulation by steroid hormones, highlight landmark studies in rodents and humans, identify emerging themes, and offer recommendations for future research. This article is categorized under: Nervous System Development > Vertebrates: General Principles Gene Expression and Transcriptional Hierarchies > Regulatory Mechanisms Gene Expression and Transcriptional Hierarchies > Sex Determination.

女性和男性在许多精神和神经疾病的患病率、症状和进展率方面存在差异。随着越来越多的临床前研究将两性纳入实验设计,生理和行为方面的性别差异越来越多。在大脑中,典型的性别行为被认为是对相同感觉刺激或环境做出反应的特定性别的神经活动模式的结果。这些不同的发射模式可能是潜在的解剖学或分子性别差异的结果。因此,对女性和男性大脑中的基因表达进行了广泛的研究,目的是确定指定或调节大脑功能性别差异的生物途径。然而,令人惊讶的是,在各个研究中,对性别偏见基因的共识很少,在后续实验中,只有少数强有力的候选基因被追求。此外,尚不清楚性别偏见基因表达是如何或何时产生的,因为对发育中的大脑进行的研究很少。在这里,我们整合了分子遗传学和神经回路的观点,为基因表达的性别差异如何在大脑中产生提供了一个概念框架。我们详细介绍了类固醇激素的基因调控机制,重点介绍了啮齿类动物和人类的里程碑式研究,确定了新出现的主题,并为未来的研究提供了建议。本文分类如下:神经系统发育>脊椎动物:一般原理基因表达和转录层次>调控机制基因表达和翻译层次>性别决定。
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引用次数: 41
Using brain organoids to study human neurodevelopment, evolution and disease. 利用脑类器官研究人类神经发育、进化和疾病。
Q1 Biochemistry, Genetics and Molecular Biology Pub Date : 2020-01-01 Epub Date: 2019-05-09 DOI: 10.1002/wdev.347
Christina Kyrousi, Silvia Cappello

The brain is one of the most complex organs, responsible for the advanced intellectual and cognitive ability of humans. Although primates are to some extent capable of performing cognitive tasks, their abilities are less evolved. One of the reasons for this is the vast differences in the brain of humans compared to other mammals, in terms of shape, size and complexity. Such differences make the study of human brain development fascinating. Interestingly, the cerebral cortex is by far the most complex brain region resulting from its selective evolution within mammals over millions of years. Unraveling the molecular and cellular mechanisms regulating brain development, as well as the evolutionary differences seen across species and the need to understand human brain disorders, are some of the reasons why scientists are interested in improving their current knowledge on human corticogenesis. Toward this end, several animal models including primates have been used, however, these models are limited in their extent to recapitulate human-specific features. Recent technological achievements in the field of stem cell research, which have enabled the generation of human models of corticogenesis, called brain or cerebral organoids, are of great importance. This review focuses on the main cellular and molecular features of human corticogenesis and the use of brain organoids to study it. We will discuss the key differences between cortical development in human and nonhuman mammals, the technological applications of brain organoids and the different aspects of cortical development in normal and pathological conditions, which can be modeled using brain organoids. This article is categorized under: Comparative Development and Evolution > Regulation of Organ Diversity Nervous System Development > Vertebrates: General Principles.

大脑是最复杂的器官之一,负责人类先进的智力和认知能力。虽然灵长类动物在某种程度上有能力执行认知任务,但它们的能力进化程度较低。其中一个原因是人类大脑在形状、大小和复杂性方面与其他哺乳动物相比存在巨大差异。这些差异使得对人类大脑发育的研究引人入胜。有趣的是,大脑皮层是迄今为止最复杂的大脑区域,这是哺乳动物数百万年来选择性进化的结果。解开调节大脑发育的分子和细胞机制,以及不同物种之间的进化差异,以及了解人类大脑疾病的需要,是科学家们对改善他们目前对人类皮质生成的了解感兴趣的一些原因。为此,包括灵长类动物在内的几种动物模型被使用,然而,这些模型在概括人类特定特征的程度上是有限的。干细胞研究领域的最新技术成果非常重要,这些成果使人类皮质生成模型(称为脑或脑类器官)的产生成为可能。本文综述了人类皮质发生的主要细胞和分子特征,并利用脑类器官对其进行研究。我们将讨论人类和非人类哺乳动物皮质发育的关键差异,脑类器官的技术应用以及正常和病理条件下皮质发育的不同方面,这些可以用脑类器官来建模。本文分类为:比较发育与进化>器官多样性调节神经系统发育>脊椎动物:一般原理。
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引用次数: 23
期刊
Wiley Interdisciplinary Reviews: Developmental Biology
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