Effect of vitamin A on wound epidermis during forelimb regeneration in adult newts.

The effects of vitamin A on blastemal epidermis were studied during the early postamputational period of forelimb regeneration in Triturus alpestris. Vitamin A was administered through oral intubation at a dose of 250 IU per gram of body weight per day. The results were evaluated by morphometry, histology, and autoradiography. After 7, 11 and 14 days of treatment, several alterations were observed in the wound epidermis: a) reversal of keratinization; fewer keratinized cells were counted in sections from vitamin A-treated limbs; b) decrease in the incorporation of tritiated thymidine, as judged by estimation of labeling indices; c) increased mitotic activity in the cells of the stratum germinativum, and in the middle layer of the epithelial cells, as well. The significance of these cellular effects is discussed against the relevant literature.     

Effect of vitamin E-deficiency on regeneration of the sciatic nerve

The regeneration of the sciatic nerve fibres was studied in both normal and vitamin E-deficient rats at 30 and 60 days after crush. The vitamin E is involved in one of the most important mechanisms of protection against peroxidation of plasma membrane lipids; the plasma membrane plays certainly a role in nerve regeneration. Both the diameter and the total number of myelinated nerve fibres was calculated at different times. The number of myelinated fibres in the undenervated deficient animals was lower than that found in the undenervated normals animals. Following the nerve crush, in normal animals after two months the number of myelinated fibres exceeded the number found in undenervated normal animals, whereas in the deficient rat nerves it was significantly lower than in the corresponding controls and moreover it did not even reach the number found in the nerves of undenervated deficient rats. Finally, the caliber distribution of myelinated fibres in undenervated and denervated deficient rats shows a relative percent increase in the number of greatest axons and a decrease in smaller axons. This result confirm the vitamin E to be an important factor of the normal process of nerve regeneration.     

A newt's eye view of lens regeneration

In this paper we describe the basic process of lens regeneration in adult newt and we pinpoint several issues in order to obtain a comprehensive understanding of this ability, which is restricted to only a few salamanders. The process is characterized by dynamic changes in the organization of the extracellular matrix in the eye, re-entering of the cell cycle and dedifferentiation of the dorsal iris pigment epithelial cells. The ability of the dorsal iris to contribute to lens regeneration is discussed in light of iris-specific gene expression as well as in relation to factors present in the eye.     

The effect of vitamin A on limb regeneration in Rana temporaria

Previous experiments in which vitamin A has been administered to developing or regenerating limbs have shown that different limb axes are affected. In regenerating axolotl limbs, serial reduplications in the proximodistal axis are produced. In the developing chick limb bud, mirror-imaged reduplications in the anteroposterior axis are produced. Results reported here on Rana temporaria limb buds reveal that vitamin A causes both effects to occur. That is, limbs are both serially reduplicated in the proximodistal axis and mirror imaged in the anteroposterior axis. Time and concentration effects are explored and the significance of these results for our current understanding of axial organisation in limbs is discussed.     

A critical role for thrombin in vertebrate lens regeneration

Lens regeneration in urodele amphibians such as the newt proceeds from the dorsal margin of the iris where pigment epithelial cells (PEC) re-enter the cell cycle and transdifferentiate into lens. A general problem in regeneration research is to understand how the events of tissue injury or removal are coupled to the activation of plasticity in residual differentiated cells or stem cells. Thrombin, a pivotal regulator of the injury response, has been implicated as a regulator of cell cycle re-entry in newt myotubes, and also in newt iris PEC. After removal of the lens, thrombin was activated on the dorsal margin for 5-7 days. Inactivation of thrombin by either of two different inhibitors essentially blocked S-phase re-entry by PEC at this location. The axolotl, a related species which can regenerate its limb but not its lens, can activate thrombin after amputation but not after lens removal. These data support the hypothesis that thrombin is a critical signal linking injury to regeneration, and offer a new perspective on the evolutionary and phylogenetic questions about regeneration.     

A novel role of the hedgehog pathway in lens regeneration

Lens regeneration in the adult newt is a classic example of replacing a lost organ by the process of transdifferentiation. After lens removal, the pigmented epithelial cells of the dorsal iris proliferate and dedifferentiate to form a lens vesicle, which subsequently differentiates to form a new lens. In searching for factors that control this remarkable process, we investigated the expression and role of hedgehog pathway members. These molecules are known to affect retina and pigment epithelium morphogenesis and have been recently shown to be involved in repair processes. Here we show that Shh, Ihh, ptc-1, and ptc-2 are expressed during lens regeneration. The expression of Shh and Ihh is quite unique since these genes have never been detected in lens. Interestingly, both Shh and Ihh are only expressed in the regenerating and developing lens, but not in the intact lens. Interfering with the hedgehog pathway results in considerable inhibition of the process of lens regeneration, including decreased cell proliferation as well as interference with lens fiber differentiation in the regenerating lens vesicle. Down-regulation of ptc-1 was also observed when inhibiting the pathway. These results provide the first evidence of a novel role for the hedgehog pathway in specific regulation of the regenerating lens.     

Signaling during lens regeneration

The newt is one of the few organisms that is able to undergo lens regeneration as an adult. This review will examine the signaling pathways that are involved in this amazing phenomenon. In addition to outlining the current research involved in elucidating the key signaling molecules in lens regeneration, we will also highlight some of the similarities and differences between lens regeneration and development.     

A comparative proteomic analysis during urodele lens regeneration

To examine underlying mechanisms of urodele lens regeneration we have employed a proteomic analysis of 650 proteins involved in several signaling pathways. We compared expression of these proteins between the regeneration-competent dorsal iris and the regeneration-incompetent ventral iris in the newt. After a series of screenings we selected several proteins to evaluate their expression quantitatively on immunoblots. We then used these selected proteins to compare their expression between the dorsal iris of the newt and the iris of the axolotl, another urodele, which does not regenerate the lens. In the newt we find that most proteins are expressed in both dorsal and ventral iris, even though there is differential regulation. Moreover, several of these proteins are expressed in the axolotl iris as well and for some of them their expression is consistent with the regeneration potential.     

Lens regeneration in mice under the influence of vitamin A

The effect of vitamin A has been studied on lens regeneration in young (7 days old) as well as adult mice. A longitudinal slit was made under local anesthesia in the cornea over the lens. The lens was extracted intact through the incision. Intraperitonial injection of vitamin A (0.05 ml of 30 IU/ml in young and 0.05 ml of 50 IU/ml in adult) was given to the operated animals. Vitamin A was found to induce lens regeneration in not only young but also in adult mice. Regenerated lenses were similar in shape, size, transparency and histological features to normal intact lenses.     

Macrophage activity in Wolffian lens regeneration

The cell type mainly involved in the phagocytic uptake of melanosomes from iris epithelial cells during Wolffian lens regeneration in the adult newt is identified on the basis of electron and light microscopic evidence as a macrophage of monocytic origin. Appearance of macrophages in iris and ciliary epithelia following lentectomy is a part of leucocytic infiltration of the area, in which granulocytes, mast cells, and other cell types also participate. The general pattern of leucocytic infiltration was studied as a function of time after lentectomy. Infiltration of the iris epithelium by macrophages is reduced when most of the melanosomes have been removed from the cytoplasm of the epithelial cells and finally ceases when depigmentation has been completed. The possibility that an immune mechanism mediated by macrophages is involved in dedifferentiation of iris epithelial cells is discussed.     

Influence of the pituitary on Wolffian lens regeneration

Removal of the pituitary 3 days before lentectomy retards Wolffian lens regeneration in the adult newt, Notophthalmus viridescens, by two stages over a 21-day period. Hypophysectomy 5 or 10 days after lentectomy does not alter the progress of regeneration during the subsequent 10-day period. Hypophysectomy 3 days before lentectomy also significantly decreases the incorporation of [³H]thymidine by iris epithelial nuclei 5 days after lentectomy but has no statistically significant effect on the incorporation 7 days after lentectomy.Pituitary tissue from newts or frogs enhances the regenerative activity of newt iris epithelial cells in vitro and in many cases promotes lens fiber formation. To a lesser extent, other tissues, such as nerve ganglion, also enhance the production of lens fiber cells from iris epithelium in vitro, whereas muscle tissue does not; and under certain conditions iris epithelial cells were found to depigment and redifferentiate into lens cells in the absence of other tissues in vitro.     

干细胞与晶状体再生

白内障摘除联合人工晶状体植入术是目前治疗白内障的唯一有效措施。然而,人工晶状体作为替代材料,仍然存在一些如屈光调节力差以及术后眩光等未能克服的缺陷。寻找更理想的晶状体替代物及低等两栖类动物（如蝾螈）强大的晶状体再生能力,为晶状体再生的研究提供了原动力和依据。近年来,人们已探索出将胚胎干细胞/诱导的多能干细胞在体外诱导分化为类晶状体样结构的培养方法,为白内障的治疗开辟了新的思路。晶状体再生的研究为探索晶状体正常发育机制及晶状体疾病的发生和防治提供了新的平台。晶状体再生的成功也将为白内障的防治带来里程碑性的突破。本文拟总结晶状体正常发育过程及其调控机制,回顾国内外对晶状体体内再生能力的研究成果,并对目前人们探索利用胚胎干细胞和诱导的多能干细胞再造晶状体的研究进展作一概述,希望对干细胞与晶状体再生的后续相关研究提供一定的借鉴。     

Effect of bovine pituitary hormone preparations on newt lens regeneration in vitro: stimulation by thyrotropin

The anterior lobe of the pituitary gland can stimulate lens regeneration from the dorsal iris in the newt Notophthalmus viridescens. We have studied the effect of pituitary hormone preparations on this process. Dorsal irises were cultured for 20 days in diluted Medium 199 supplemented with 10% fetal calf serum. Bovine thyrotropin TSH-B8 at concentrations of 30 to 3000 μg/ml significantly stimulated lens regeneration in these dorsal irises. Well-developed lenses, up to stage 9, were formed, in which γ-crystallin, a protein specific for lens fibers of young lenses, was detected by immunofluorescence. Additionally, the mitotic index was 5.5 times elevated in these explants when compared to their controls. Lutropin LH-B10 at concentrations of 30 to 3000 μg/ml, prolactin PRL-B4 at concentrations of 23 to 1600 μg/ml, and porcine adrenocorticotropin ACTH-6002 at concentrations of 3 to 300 μg/ml did not stimulate lens regeneration. A weak stimulation of lens formation was observed in iris cultures with 2700 μg/ml of follitropin FSH-B1 or 3000 μg/ml somatotropin GH-B18, but not at concentrations of 30 μg/ml. Our results suggest that the inherent ability of the dorsal iris to form lens can be activated by the bovine thyrotropin preparation TSH-B8.     

Retina and lens regeneration in anuran amphibians

Anuran amphibians can regenerate the retina through differentiation of stem cells in the ciliary marginal zone and through transdifferentiation of the retinal pigmented epithelium. By contrast, the regeneration of the lens has been demonstrated only in larvae of species belonging to the Xenopus genus, where the lens regenerates through transdifferentiation of the outer cornea. Retinal pigmented epithelium to neural retina and outer cornea to lens transdifferentiation processes are triggered and sustained by signaling molecules belonging to the family of the fibroblast growth factor. Both during retina and lens regeneration there is a re-activation of many of the genes which are activated during development of the eye, even though the spatial and temporal pattern of gene expression is not a simple repetition of that found in development.