Stem cells by the shore: Meeting summary of the 2008 MDI Stem Cell Symposium

A diverse group of stem cell biologists converged on the Mount Desert Island Biological Laboratory (MDIBL) on August 8th and 9th, 2008 for the seventh annual Mount Desert Island Stem Cell Symposium co-hosted by the Mount Desert Island Biological Laboratory and the Jackson Laboratory. The focus of this year’s meeting was epigenetics, a timely topic given the remarkable progress in the area of nuclear reprogramming.     

Growth cone inhibition – an important mechanism in neural development?

Since the growth cone was first described a century ago by Cajal, considerable effort has been directed towards understanding the mechanisms responsible for its guidance. Traditionally, attention has focussed on the role of adhesive molecules in determining neural development. Recently, it has become apparent that inhibitory interactions may play a crucial part in axonal navigation. A common feature of inhibition seen in three model systems (peripheral nerve segmentation, retinotectal mapping and CNS/PNS segregation) is a collapse of the motile structures of the growth cone. It is increasingly clear that the identification of molecular mechanisms of inhibition, as well as those of adhesion, will be of fundamental importance to understanding neural development.     

Jak2 tyrosine kinase

Discovered roughly 10 yr ago, Jak2 tyrosine kinase has emerged as a critical molecule in mammalian development, physiology, and disease. Here, we review the early history of Jak2 and its role in health and disease. We will also review, its critical role in mediating cytokine-dependent signal transduction. Additionally, more recent work demonstrating the importance of Jak2 in G protein-coupled receptor and tyrosine kinase growth factor receptor signal transduction will be discussed. The cellular and biochemical mechanisms by which Jak2 tyrosine kinase is activated and regulated within the cell also will be reviewed. Finally, structure-function and pharmacological-based studies that identified structural motifs and amino acids within Jak2 that are critical for its function will be examined. By reviewing the biology of Jak2 tyrosine kinase at the molecular. cellular, and physiological levels, we hope to advance the understanding of how a single gene can have such a profound impact on development, physiology, and disease.     

Jak2 tyrosine kinase: a true jak of all trades?

Discovered roughly 10 yr ago, Jak2 tyrosine kinase has emerged as a critical molecule in mammalian development, physiology, and disease. Here, we review the early history of Jak2 and its role in health and disease. We will also review its critical role in mediating cytokine-dependent signal transduction. Additionally, more recent work demonstrating the importance of Jak2 in G protein-coupled receptor and tyrosine kinase growth factor receptor signal transduction will be discussed. The cellular and biochemical mechanisms by which Jak2 tyrosine kinase is activated and regulated within the cell also will be reviewed. Finally, structure-function and pharmacological-based studies that identified structural motifs and amino acids within Jak2 that are critical for its function will be examined. By reviewing the biology of Jak2 tyrosine kinase at the molecular, cellular, and physiological levels, we hope to advance the understanding of how a single gene can have such a profound impact on development, physiology, and disease.     

Towards understanding the multifaceted role of SUMOylation in plant growth and development

Post‐translational modifications (PTMs) play a critical role in regulating plant growth and development through the modulation of protein functionality and its interaction with its partners. Analysis of the functional implication of PTMs on plant cellular signalling presents grand challenges in understanding their significance. Proteins decorated or modified with another chemical group or polypeptide play a significant role in regulating physiological processes as compared with non‐decorated or non‐modified proteins. In the past decade, SUMOylation has been emerging as a potent PTM influencing the adaptability of plants to growth, in response to various environmental cues. Deciphering the SUMO‐mediated regulation of plant stress responses and its consequences is required to understand the mechanism underneath. Here, we will discuss the recent advances in the role and significance of SUMOylation in plant growth, development and stress response.     

To curve for survival: Apical hook development

Apical hook is a simple curved structure formed at the upper part of hypocotyls when dicot seeds germinate in darkness.The hook structure is transient but essential for seedlings’ survival during soil emergence due to its efficient protection of the delicate shoot apex from mechanical injury.As a superb model system for studying plant differential growth,apical hook has fascinated botanists as early as the Darwin age,and significant advances have been achieved at both the morphological and molec...     

Fibroblast growth factors and Hedgehogs: at the heart of the epicardial signaling center

Over the past several years, increasing attention has been focused on understanding signaling pathways that control key events during midgestational heart development. During this period of development, the heart tube transforms into a functioning organ that must maintain its own blood supply and grow and respond to the physiologic needs of the organism. A critical event that occurs during midgestational heart development is the formation of the epicardium, which functions as a source of cells and as a signaling center that regulates myocardial growth and coronary vascular development. This review will describe our understanding of the role and the mechanism by which the epicardium governs these developmental events, primarily as a result of studies in the mouse. We focus on two key growth factor pathways: fibroblast growth factor and Hedgehog signaling.     

病理性瘢痕形成中VEGF 表达及调控的研究进展*

病理性瘢痕一直是整形外科乃至整个外科界研究的热点,由于其发病机制十分复杂,迄今尚无明确的病因学诊断和有效的治疗方法.VEGF作为目前活性最强的血管生长因子,与病理性瘢痕的发生、发展关系密切.研究病理性瘢痕形成过程中VEGF的表达及调控机制,有助于阐明病理性瘢痕的发病机制,为预防和治疗病理性瘢痕提供依据.     

中期因子在肿瘤发生和组织再生中的作用

中期因子(midkine,MK）是一种肝素结合性生长因子.在胚胎期,MK在组织中广泛分布.在成人体内其表达降低,仅局限于某些特定部位.MK受体种类繁多,信号通路复杂多样,这就决定了MK功能的多样化,它能促进很多种类细胞的生长、存活、分化和迁移,具有抗细胞凋亡的作用,不仅与肿瘤发生密切相关,而且在很多组织的发育形成及损伤后的修复再生过程均有参与.MK已成为恶性肿瘤在内的多种疾病治疗中颇具前景的分子靶点.本文中对MK的基因及蛋白结构、受体及相关信号通路、分子功能及作用机制等进行了全面的综述,并对其在肿瘤发生和发育与组织再生等方面的生物学功能及研究意义进行了深入的探讨.     

The problems associated with high biomass levels in plant cell suspensions

The development of plant cell cultures as an alternative supply of phytochemicals has been difficult. Although there has been some very suitable targets, the yields of these compounds has remained low despite considerable efforts. One of the main constituents of a process is its productivity which is the sum of the process run time (growth rate), yield, and biomass levels. The effect of changes in all three of these components on productivity has been demonstrated.Of the three components making up productivity, biomass is perhaps the easiest to increase. However, high biomass levels will increase the viscosity, which will affect both mixing and oxygen supply. Therefore, this will require more vigorous mixing which may increase the shear within the bioreactor. All these parameters need further investigation at high biomass concentrations.     

Mitogenic factors of corpora lutea

The mammalian corpus luteum (CL), which plays a central role in the reproductive process because of its production of hormones such as progesterone, appears to be an exceptionally dynamic organ. Its rate of growth and development are extremely rapid and, even when the CL is functionally mature, its rate of cell turnover remains relatively high. Associated with this high rate of cell turnover, the mature CL receives the greatest blood supply per unit tissue of any organ, and also exhibits a relatively high metabolic rate. Although numerous growth factors have been identified in luteal tissue, their role in growth and differentiation of this dynamic organ remains unclear. Recently, while attempting to identify mitogenic factors of ovine and bovine CL, we have found that they produce several mitogens during the estrous cycle as well as pregnancy. The majority of these luteal-derived mitogenic factors are heparin-binding, and although some may represent previously identified factors, several appear to be novel heparin-binding growth factors. Isolation and purification of mitogenic factors produced by the CL will enable us to determine their roles in luteal growth, development and differentiated function, which will contribute to our understanding not only of the regulation of fertility but also of tissue growth and development in general.     

The androgen receptor: a potential target for therapy of prostate cancer

The androgen receptor plays a pivotal role in the prostate. Its primary function is to provide responsive gene products for differentiation and growth, but under abnormal conditions it contributes to the development of prostate cancer. The goal of this review is to elucidate the molecular functions of the androgen receptor and its role in prostate cancer. Initially the function of the androgen receptor will be described. Next, the clinical diagnosis, epidemiological impact, and treatments of androgen-dependent and -independent prostate cancer will be discussed. Finally we will examine how the mechanism of androgen action has played a role in the translation of new therapies and how this may influence future treatment modalities of prostate cancer.     

落叶松树种的体细胞胚胎发生与规模化技术体系

植物体细胞胚胎发生技术是植物体细胞在人为可控条件下通过与合子胚胎发生类似的途径 ,发育出新个体的再生技术 ,自问世以来 ,已被广泛用于生命科学领域。对落叶松及其杂种胚性细胞系的大规模增殖培养、原胚发育状态、体细胞胚成苗和专用生物反应器技术体系的建立以及其应用、展望等方面进行了探讨 ,表明落叶松体细胞胚胎发生过程中专用生物反应器技术体系的完善与建立迫在眉睫 ,并将为现代林木育种与繁殖工程及生命科学相关学科的发展带来重要影响 。     

Wnt/planar cell polarity signaling: an important mechanism to coordinate growth and patterning in the limb

The limb is one of the premier models for studying how a simple embryonic anlage develops into complex three-dimensional form. One of the key issues in the limb field has been to determine how the limb becomes patterned along its proximal (shoulder/hip) to distal (digits) axis. For decades it has been known that the apical ectodermal ridge (AER) plays a crucial role in distal outgrowth and patterning of the vertebrate embryonic limb. Most studies have explored the relationship between the AER and the progressive assignment of cell fates to mesenchyme along the proximal to distal (PD) axis. Comparatively few, however, have examined the additional role of the AER to regulate distal outgrowth of the limb and how this growth may also influence pattern along the PD axis. Here, I will review key studies that explore the role of growth in limb development. In particular, I will focus on a recent flurry of papers that examine the role of the Wnt/planar cell polarity (PCP) pathway in regulating directed growth of the limb mesenchyme. Finally, I will discuss a potential mechanism that relates the AER to the Wnt/PCP pathway and how directed growth can play a role in shaping the limb along the PD axis.     

VEGF in biological control

Vascular endothelial growth factor A (VEGF-A) belongs to a family of heparin binding growth factors that include VEGF-B, VEGF-C, VEGF-D, and placental-like growth factor (PLGF). First discovered for its ability to regulate vascular endothelial cell permeability, VEGF is a well-known angiogenic factor that is important for vascular development and maintenance in all mammalian organs. The development of molecular tools and pharmacological agents to selectively inhibit VEGF function and block angiogenesis and/or vascular permeability has led to great promise in the treatment of various cancers, macular degeneration, and wound healing. However, VEGF is also important in animals for the regulation of angiogenesis, stem cell and monocyte/macrophage recruitment, maintenance of kidney and lung barrier functions and neuroprotection. In addition to its role in regulating endothelial cell proliferation, migration, and cell survival, VEGF receptors are also located on many non-endothelial cells and act through autrocrine pathways to regulate cell survival and function. The following review will discuss the role of VEGF in physiological angiogenesis as well as its role in non-angiogenic processes that take place in adult organs.     

Wnt/planar cell polarity signaling

The limb is one of the premier models for studying how a simple embryonic anlage develops into complex three-dimensional form. One of the key issues in the limb field has been to determine how the limb becomes patterned along its proximal (shoulder/hip) to distal (digits) axis. For decades it has been known that the apical ectodermal ridge (AER) plays a crucial role in distal outgrowth and patterning of the vertebrate embryonic limb. Most studies have explored the relationship between the AER and the progressive assignment of cell fates to mesenchyme along the proximal to distal (PD) axis. Comparatively few, however, have examined the additional role of the AER to regulate distal outgrowth of the limb and how this growth may also influence pattern along the PD axis. Here, I will review key studies that explore the role of growth in limb development. In particular, I will focus on a recent flurry of papers that examine the role of the Wnt/planar cell polarity (PCP) pathway in regulating directed growth of the limb mesenchyme. Finally, I will discuss a potential mechanism that relates the AER to the Wnt/PCP pathway and how directed growth can play a role in shaping the limb along the PD axis.     

Cancer stem cells in solid tumors: is 'evading apoptosis' a hallmark of cancer?

Conventional wisdom has long held that once a cancer cell has developed it will inevitably progress to clinical disease. Updating this paradigm, it has more recently become apparent that the tumor interacts with its microenvironment and that some environmental bottlenecks, such as the angiogenic switch, must be overcome for the tumor to progress. In parallel, attraction has been drawn to the concept that there is a minority population of cells - the cancer stem cells - bestowed with the exclusive ability to self-renew and regenerate the tumor. With therapeutic targeting issues at stake, much attention has shifted to the identification of cancer stem cells, the thinking being that the remaining non-stem population, already fated to die, will play a negligible role in tumor development.In fact, the newly appreciated importance of intercellular interactions in cancer development also extends in a unique and unexpected way to interactions between the stem and non-stem compartments of the tumor. Here we discuss recent findings drawn from a hybrid mathematical-cellular automaton model that simulates growth of a heterogeneous solid tumor comprised of cancer stem cells and non-stem cancer cells. The model shows how the introduction of cell fate heterogeneity paradoxically influences the tumor growth dynamic in response to apoptosis, to reveal yet another bottleneck to tumor progression potentially exploitable for disease control.