Retinal stem cells and regeneration

The optic vesicle gives rise to several very different epithelial tissues, including the neural retina, the pigmented epithelium, the iris, the ciliary epithelium of the ciliary body and the optic stalk. Retinal regeneration can arise from several different cellular sources; in some species, the process involves interconversion, or transdifferentiation, among cells of the different tissue types. Therefore, prior to a discussion of retinal regeneration, we will briefly discuss current knowledge about the influence of signaling molecules in cell fate determination in ocular tissues. Next, we will detail the evidence for neurogenesis in the mature retina. Lastly, we will describe various types of regenerative phenomena that occur in the retina, from complete regeneration of functional retina in fish and amphibians, to the more limited neuronal production that occurs in avian and mammalian retinas.     

海鞘再生的细胞学过程及其调控机制研究进展与展望

再生现象在后生动物中普遍存在,但不同物种的再生能力存在显著差别。无脊椎动物如水螅和涡虫等再生能力较强,具有部分组织或细胞即可再生出一个完整个体的能力,被称为整体再生;而脊椎动物的再生能力相对较弱,局限在某些特定器官或身体结构,被称为部分再生,如蝾螈的附肢。海鞘作为进化上介于无脊椎动物与脊椎动物之间的尾索动物,既包括具备整体再生能力的群居类型,如拟菊海鞘(Botrylloides leachii),其可以利用部分血管残片即可再生出完整个体;也包括只具有部分再生能力的单体海鞘类型,如玻璃海鞘(Ciona robusta),其只有出入水管和神经复合体等器官才可再生。鉴于海鞘的进化地位及其具有的不同再生能力类群,近年来逐渐成为研究再生的理想模式动物。该文系统分析总结了海鞘不同类群所具备的整体再生和部分再生的各自细胞学过程及其调控机制,并比较归纳了导致海鞘不同群体具有不同再生能力差别的可能机制,展望了海鞘再生研究的未来方向,为理解后生动物再生能力的演化和调控机制提供参考。     

Quantitative analysis of cell types during growth,degrowth and regeneration in the planarians Dugesia mediterranea and Dugesia tigrina

A method of tissue maceration (dissociation) of planarian tissues into single cells was used to characterize the basic cell types in the planarians Dugesia mediterranea and Dugesia tigrina, and to determine the total cell number and distribution of cell types during growth, degrowth and regeneration.Using this method, 13 basic cell types have been determined for both species. The total number of cells increases with body length and volume whereas the distribution of cell types is only slightly affected. Growth and degrowth occur mainly through changes in total cell number leaving cell distribution only moderately affected. During regeneration, an increase in neoblast density in the blastema followed later on by increases in nerve cells are the more significant changes detected.These results are discussed in relation to mechanisms of cell renewal, blastema formation and maintenance of tissue polarity.Abbreviations nb neoblasts - nv nerve cells - ep epidermal cells - fp fixed parenchyma cells - g gastrodermal cells     

Constitutive gene expression and the specification of tissue identity in adult planarian biology

Planarians are flatworms that constitutively maintain adult tissues through cell turnover and can regenerate entire organisms from tiny body fragments. In addition to requiring new cells (from neoblasts), these feats require mechanisms that specify tissue identity in the adult. Crucial roles for Wnt and BMP signaling in the regeneration and maintenance of the body axes have been uncovered, among other regulatory factors. Available data indicate that genes involved in positional identity regulation at key embryonic stages in other animals display persisting regionalized expression in adult planarians. These expression patterns suggest that a constitutively active gene expression map exists for the maintenance of the planarian body. Planarians thus present a fertile ground for the identification of factors regulating the regionalization of the metazoan body plan and for the study of the attributes of these factors that can lead to the maintenance and regeneration of adult tissues.     

Two chloroplastic protein translocation components,Tic110 and Toc75, are conserved in different plastid types from multiple plant species

Most chloroplastic proteins are nuclear-encoded and must be transported into the organelle post-translationally. Proteinaceous components in the outer and inner envelope membranes of chloroplasts responsible for this import process were originally identified from pea seedlings. We sought to determine whether these proteins are conserved among different plant species other than pea and among different plastid types. We analyzed plant EST databases and found the presence of homologues to pea chloroplastic protein translocation components, Tic110 and Toc75, in both monocot and dicot species. Because these clones were obtained from various tissues, their presence in different types of plastids is proposed. Protein extracts were prepared from several plant species and from different plant tissues, and then probed with antisera raised against pea Tic110 and Toc75. The results support the idea that translocation components originally found in pea chloroplasts are conserved among different plant species and are present in various plastid types.     

The roles of signaling pathways in liver repair and regeneration

The liver has remarkable regeneration potency that restores liver mass and sustains body hemostasis. Liver regeneration through signaling pathways following resection or moderate damages are well studied. Various cell signaling, growth factors, cytokines, receptors, and cell types implicated in liver regeneration undergo controlled hypertrophy and proliferation. Some aspects of liver regeneration have been discovered and many investigations have been carried out to identify its mechanisms. However, for optimizing liver regeneration more should be understood about mechanisms that control the growth of hepatocytes and other liver cell types in adults. The current paper deals with the possible applicability of liver regeneration signaling pathways as a target for therapeutic approaches and preventing various liver damages. Furthermore, the latest findings of spectrum-specific signaling pathway mechanisms that underlie liver regeneration are briefly described.     

CNS regeneration: a morphogen's tale

Tissue regeneration will soon become an avenue for repair of damaged or diseased tissues as stem cell niches have been found in almost every organ of the vertebrate body including the CNS. In addition, different animals display an array of regenerative capabilities that are currently being researched to dissect the molecular mechanisms involved. This review concentrates on the different ways in which CNS tissues such as brain, spinal cord and retina can regenerate or display neurogenic potential and how these abilities are modulated by morphogens.     

EvoRegen in animals: Time to uncover deep conservation or convergence of adult stem cell evolution and regenerative processes

How do animals regenerate specialised tissues or their entire body after a traumatic injury, how has this ability evolved and what are the genetic and cellular components underpinning this remarkable feat? While some progress has been made in understanding mechanisms, relatively little is known about the evolution of regenerative ability. Which elements of regeneration are due to lineage specific evolutionary novelties or have deeply conserved roots within the Metazoa remains an open question. The renaissance in regeneration research, fuelled by the development of modern functional and comparative genomics, now enable us to gain a detailed understanding of both the mechanisms and evolutionary forces underpinning regeneration in diverse animal phyla. Here we review existing and emerging model systems, with the focus on invertebrates, for studying regeneration. We summarize findings across these taxa that tell us something about the evolution of adult stem cell types that fuel regeneration and the growing evidence that many highly regenerative animals harbor adult stem cells with a gene expression profile that overlaps with germline stem cells. We propose a framework in which regenerative ability broadly evolves through changes in the extent to which stem cells generated through embryogenesis are maintained into the adult life history.     

The influence of fundamental traits on mechanisms controlling appendage regeneration

One of the most compelling questions in evolutionary biology is why some animals can regenerate injured structures while others cannot. Appendage regeneration appears to be common when viewed across the metazoan phylogeny, yet this ability has been lost in many taxa to varying degrees. Within species, the capacity for regeneration also can vary ontogenetically among individuals. Here we argue that appendage regeneration along the secondary body axis may be constrained by fundamental traits such as body size, aging, life stage, and growth pattern. Studies of the molecular mechanisms affecting regeneration have been conducted primarily with small organisms at early life stages. Such investigations disregard the dramatic shifts in morphology and physiology that organisms undergo as they age, grow, and mature. To help explain interspecific and intraspecific constraints on regeneration, we link particular fundamental traits to specific molecular mechanisms that control regeneration. We present a new synthesis for how these fundamental traits may affect the molecular mechanisms of regeneration at the tissue, cellular, and genomic levels of biological organization. Future studies that explore regeneration in organisms across a broad phylogenetic scale, and within an ontogenetic framework, will help elucidate the proximate mechanisms that modulate regeneration and may reveal new biomedical applications for use in regenerative medicine.     

Human regeneration: An achievable goal or a dream?

The main objective of regenerative medicine is to replenish cells or tissues or even to restore different body parts that are lost or damaged due to disease, injury and aging. Several avenues have been explored over many decades to address the fascinating problem of regeneration at the cell, tissue and organ levels. Here we discuss some of the primary approaches adopted by researchers in the context of enhancing the regenerating ability of mammals. Natural regeneration can occur in different animal species, and the underlying mechanism is highly relevant to regenerative medicine-based intervention. Significant progress has been achieved in understanding the endogenous regeneration in urodeles and fishes with the hope that they could help to reach our goal of designing future strategies for human regeneration.     

The role of some donor-host cell interactions in conditions of the regenerative process microenvironment

The review is devoted to the analysis of experimental data about possible mechanisms of transdifferentiation or plasticity of tissue specific stem cells. Considerable attention is focused on the mechanisms and genetic consequences of fusion of different types of donor cells with the cells of recipient tissues which investigated on the models of cellular therapy of liver and heart diseases. The role of various kinds of cell contacts and their role in stem cells integration, reparation and regeneration of injured tissue and horizontal genes transfer are considered.     

全身纤维结缔组织网络中的界面流体传输现象

纤维结缔组织在身体中的作用是支撑、连接和分隔不同的组织和器官。最近,人体断肢解剖研究证实,一种定向纤维结缔组织组成了一种长程液体传输通路。其解剖位置有两种:皮肤传输通路(包括真皮、皮下组织和脂肪小叶间隔)和血管周围传输通路(静脉和动脉周围纤维结缔组织)。这种纤维通路的三维空间内部结构是一种纵向分布、相互连接的纤维丝,在每一根纤维丝及其周围水凝胶之间形成了一种固液界面区;纤维结缔组织中的液体能够通过这种界面区传输,命名为"生物界面流体传输通路";存在于各种组织和器官纤维基质中的液体,很可能并没有被束缚在"组织凝胶"中,而是在尚未明确的某种物理机制的作用下,朝向一定的方向传输。这些研究结果为理解纤维结缔组织的功能提供了一个新的视角。     

Cell size is positively correlated between different tissues in passerine birds and amphibians,but not necessarily in mammals

We examined cell size correlations between tissues, and cell size to body mass relationships in passerine birds, amphibians and mammals. The size correlated highly between all cell types in birds and amphibians; mammalian tissues clustered by size correlation in three tissue groups. Erythrocyte size correlated well with the volume of other cell types in birds and amphibians, but poorly in mammals. In birds, body mass correlated positively with the size of all cell types including erythrocytes, and in mammals only with the sizes of some cell types. Size of mammalian erythrocytes correlated with body mass only within the most taxonomically uniform group of species (rodents and lagomorphs). Cell volume increased with body mass of birds and mammals to less than 0.3 power, indicating that body size evolved mostly by changes in cell number. Our evidence suggests that epigenetic mechanisms determining cell size relationships in tissues are conservative in birds and amphibians, but less stringent in mammals. The patterns of cell size to body mass relationships we obtained challenge some key assumptions of fractal and cellular models used by allometric theory to explain mass-scaling of metabolism. We suggest that the assumptions in both models are not universal, and that such models need reformulation.     

The role of multipotent marrow stromal cells (MSCs) in tissue regeneration

An extensive body of preclinical and clinical data has shown that administration of adult multipotent marrow stromal cells (MSCs) effectively ameliorates experimental and clinical conditions of many different organ systems. Differentiation into organ parenchymal cells, however, is very rare, and the main mechanism for organ protection and regeneration from different types of injury is the exertion of paracrine effects and stimulation of tissue repair. A large number of clinical trials have been conducted and are ongoing to investigate the safety and efficacy of MSCs in different organs after various types of organ injury. This article intends to give a brief overview about current applications of MSCs and mechanisms involved in organ protection and regeneration.     

The role of multipotent marrow stromal cells (MSCs) in tissue regeneration

An extensive body of preclinical and clinical data has shown that administration of adult multipotent marrow stromal cells (MSCs) effectively ameliorates experimental and clinical conditions of many different organ systems. Differentiation into organ parenchymal cells, however, is very rare, and the main mechanism for organ protection and regeneration from different types of injury is the exertion of paracrine effects and stimulation of tissue repair. A large number of clinical trials have been conducted and are ongoing to investigate the safety and efficacy of MSCs in different organs after various types of organ injury. This article intends to give a brief overview about current applications of MSCs and mechanisms involved in organ protection and regeneration.     

Morphological comparison of the regeneration process in Sabella spallanzanii and Branchiomma luctuosum (Annelida,Sabellida)

Within Annelida, the family Sabellidae is a particularly interesting clade in which to carry out comparative studies of regeneration, as its members vary in regeneration potential, with some even lacking this ability completely. However, data on the regenerative potential of sabellids are available only for a few species investigated early in the last century, and even for those, many aspects of regenerative ability are yet to be determined. In the present study, we compared the morphology of the regeneration process of anterior and posterior ends in Sabella spallanzanii and Branchiomma luctuosum, two sabellids that belong to closely related genera. Members of S. spallanzanii exhibited lower mortality in response to wounding and greater regenerative ability, with amputees able to complete the regeneration process more rapidly than in B. luctuosum. Moreover, results from this study suggest that adults of S. spallanzanii and B. luctuosum use different mechanisms to restore lost anterior body parts. In S. spallanzanii, both morphallaxis and epimorphosis appear to be important in anterior end regeneration, but in B. luctuosum, only epimorphosis appears to be important. Such variation among closely related taxa sharing similar body plans has rarely been reported, but might be profitably examined using molecular approaches in these and other species of sabellids. Results of such studies interpreted in the context of phylogeny may ultimately provide insight into the evolution of regeneration.     

Mechanisms for species differences in receptor-mediated carcinogenesis

Species differences resulting from a number of mechanisms are common in receptor-mediated chemical carcinogenesis. In this review, examples of possible mechanisms underlying these differences are discussed, including ligand metabolism, receptor polymorphisms, receptor isoforms, receptor levels, and crosstalk between signal transduction pathways. In addition, a number of other mechanisms also are likely to be important. The developmental state of the animal will determine the expression of receptors in different tissues. The regulatory pathways for cell proliferation and cell death and cell cycle check point controls can vary among species and tissues. Adaptation or potentiation of responses during chronic exposures to chemicals can greatly influence species differences. The mechanisms of adaptive processes are poorly understood but probably highly important for chronic toxicities such as cancer. Finally, different species may have different stem cell populations that are the targets for neoplastic transformation, and this will influence receptor-mediated carcinogenic responses. The implications of species differences in receptor-mediated responses for risk assessment are discussed.     

Distribution of segment regeneration ability in the Annelida

The annelids are an excellent group in which to investigatethe evolution of regeneration abilities. They exhibit qualitativeand quantitative variation in regeneration ability, includingamong closely related species, and their segmental body organizationmakes comparing results among species relatively straightforward.Here, I compile information on the presence/absence of segmentregeneration ability across the annelids. The ability to regenerateposteriorly appears to be nearly universal in the annelids.It is almost certainly ancestral for the phylum and may havebeen lost only a few times. The ability to regenerate anteriorlyis common but less widespread. It is absent in about a dozengroups, almost surely representing multiple independent lossesof this ability. Several non-regenerating species are closelyrelated to regenerating species, indicating very recent losses(or gains). Despite the fact that lack of this ability is unusual,there is a publication bias against reporting the lack of regenerationability, and in many cases the judgment that a particular speciesis unable to regenerate is based on incomplete or unpublisheddata. Thus, in order to build rigorous frameworks for futurecomparative studies of annelid regeneration, there is a needfor published studies clearly documenting the lack of regenerationabilities in annelid species. The review of regeneration datapresented here is especially useful in highlighting annelidgroups that possess both regenerating and non-regenerating representatives.Investigations of these groups may be particularly useful forelucidating the mechanisms leading to the loss (or perhaps gain)of segment regeneration ability.     

大兴安岭次生林空间分布格局及其尺度效应

研究大兴安岭落叶松林、白桦林和落叶松+白桦混交林3种次生林中,不同树种(落叶松、白桦和其他)和不同大小级(Ⅰ～Ⅴ级)树木的空间分布格局及其尺度效应。结果表明:3个林型中,仅落叶松林的更新数量达到良好状态,其余2种林型均为更新不良;各林型中,更新层幼苗、幼树的数量组成均与乔木层存在显著差异,且各林型中树木的直径(落叶松林和落叶松+白桦混交林除外)和树高分布也不够合理,3个林型均属于不稳定群落。各林型内林木空间分布整体以聚集分布为主,但方差/均值比率、负二项指数、Green指数、平均拥挤度和Morisita指数5个判别指数随尺度的变化显著不同,并以线性递增(40%)、幂函数递增(22%)和负二次多项式(20%)趋势为主。Ⅰ～Ⅲ级的更新层林木在不同尺度上以聚集分布为主,而乔木层(Ⅳ～Ⅴ级)在多种分布格局间波动,其对尺度的响应同样以线性递增(44%)、幂函数递增(15%)和负二次多项式(12%)为主。同一林型和取样尺度下,林木空间聚集程度整体随着林木大小级的增加呈线性下降趋势。各林型中,非优势树种的种群格局规模往往大于优势树种,而更新层林木空间格局规模大于乔木层。