Regeneration in insects.

@9cIntroduction@21T issues exhibit an impressive ability to respond to a myriad of insults by repairing and regenerating complex structures. The elegant and orderly process of regeneration provides clues to the mechanisms of pattern formation but also offers the hope that the process might one day be manipulated to replace damaged body parts. To manipulate the process, it will be necessary to understand the genetic basis of the process. In the case of the insect leg, we are coming close to such a level of understanding and many of the lessons learned are relevant to vertebrate systems. A dynamic web of gene regulatory networks appears to create a robust self-organizing system that is at once extremely intricate but also perhaps simple in its reliance on a few key signaling pathways and a few simple processes, e.g. autoactivation and lateral inhibition. Here we will summarize what has been learned about the networks of gene regulation present in the Drosophila leg discs and then we will explore how the regenerative responses to different insults can be understood as predictable responses to these networks. Each of the regulatory networks could themselves serve as the subject of a detailed review and that is beyond the scope of this discussion. Here we will focus on the interplay between the regulatory networks in patterning the tissue.     

Regeneration and vegetative propagation. II

The Botanical Review - During the past decade remarkable strides have been made in the field of growth substances in general and in their practical application in various aspects of vegetative...     

Ueber Regeneration beiMonophyllaea Horsfieldii R. Br.

Ohne Zusammenfassung     

Regeneration in Gastrotricha—I. Light Microscopical Observations on the Regeneration in Turbanella sp.

For the first time, the phenomenon of regeneration is reported for the phylum Gastrotricha. Adult specimens of Turbanella sp. were transected transversely and events of regeneration were observed on the light microscopical level. In both anterior and posterior fragments the wound closure was completed I day after the operation, and in 3 days the epidermis was restored entirely. The dorsal commissure of the Y-organ was rebuilt soon after wound closure. In anterior fragments cut at any level of the intestine, caudal adhesive tubes were formed anew, following the species-specific pattern. In posterior fragments, and in both fragments if transected at a pharynx level, regeneration resulted in a complete wound healing, with no new adhesive tubes being observed.     

林隙（gap）更新动态研究进展

林隙（ｇａｐ）更新动态研究进展臧润国（中国林业科学研究院生态环境研究所,北京１０００９３）ＲｅｓｅａｒｃｈＡｄｖａｎｃｅｓｏｆＧａｐＲｅｇｅｎｅｒａｔｉｏｎＤｙｎａｍｉｃｓ．ＺａｎｇＲｕｎｇｕｏ（ＩｎｓｔｉｔｕｔｅｏｆＥｃｏｌｏｇｙａｎｄＥｎｖｉｒ...     

Regeneration after fire in Triodia R. Br.

Hummock grasses in the genus Triodia R. Br. were examined at 116 recently burned locations across mainland Australia, and were recorded as regenerating by resprouting, or by seed only. Prior to this survey it was known that the capacity to resprout varies considerably in Triodia, but it was unclear whether some species might be entirely resprouting and other species entirely fire-killed; whether this might be associated with particular traits of species or particular landscape types; or whether resprouting might be more common in particular regions such as the northern monsoonal grasslands. Seven species had both fire-killed and resprouting populations represented among the sites examined. Three species [T. basedowii E. Pritzel, T. marginata N.T. Burbidge and T. melvillei (C.E. Hubbard) Lazarides] were recorded as fire-killed at all sites examined, and five species [T. bynoei (C.E. Hubbard) Lazarides, T. bunicola (S.W.L. Jacobs) Lazarides, T. intermedia Cheel, T. molesta N.T. Burbidge and T. spicata N.T. Burbidge] were recorded as resprouting at all sites. Another seven species were recorded at one site only. There was no clear overall trend for fire-killed populations to be more prevalent in south rather than north, or east vs west, or coastal vs inland parts of the continent. No clear relationships were found between regeneration strategy and site attributes. Considered as a group, resprouting species were more likely to have an open growth form than a dense growth form, whereas the opposite was true for fire-killed species. Given that no trait either of species or of landscape was found to be a consistent correlate of resprouting, a likely inference is that resprouting might vary between different fires, even for a given population at a given site. Against this inference, fire-killed populations had substantial densities of seedlings much more often. Longitudinal studies would be needed to demonstrate directly whether resprouting varied between different fires at a site, and to investigate the implications of this for maintenance or extinction of local populations.     

Regeneration

Ohne Zusammenfassung     

Regeneration of dopaminergic neurons in goldfish retina.

The conditions necessary to trigger regeneration of dopaminergic neurons were investigated in the goldfish retina. Intraocular injection of 6-hydroxydopamine (6-OHDA) was used to destroy dopaminergic neurons, and neuronal regeneration was monitored by injections of the thymidine analog bromodeoxyuridine (BUdR). Regenerated dopaminergic neurons, (identified by double-labeling with anti-tyrosine hydroxylase and anti-BUdR antibodies) were found within 3 weeks after 2 injections of 0.6 mg/ml 6-OHDA (estimated intraocular concentration), but not after injection of lower doses. All retinas with regenerated dopaminergic neurons also contained other types of regenerated neurons, including cones and ganglion cells, consistent with nuclear counts which revealed non-selective cell loss (34-36%) in both the outer and inner nuclear layers after exposure to the high dose, but not lower doses of 6-OHDA. Regenerated neurons were produced by clusters of dividing neuroepithelial cells probably derived from rod precursors in the outer nuclear layer. These results demonstrate that dopaminergic neurons will not regenerate after they are selectively ablated but only as part of a developmental process that involves generation of multiple cell types.     

Regeneration of nasopharyngeal epithelium in Macaca fascicularis.

Regeneration of the nasopharyngeal epithelium in Macaca fascicularis occurs as a result of migration of epithelial cells from the margins of the lesions as well as from the neighbouring glandular ducts and epithelial crypts. The study further reveals that the basal cells are the progenitors of both goblet and ciliated cells. The regenerating epithelium at first consists of mucus-containing cells which are finally converted into normal globlet and ciliated cells. The formation of centrioles and concurrent reduction in the amount of 'mucus' droplets, and rearrangement of centrioles towards the luminal surface of the cells along with simultaneous development of cilia in some of these mucus-containing cells are stages in the differentiation of ciliated cells. However, some cells which do not possess secretory droplets may also develop into ciliated cells directly.     

油松种群自然更新格局的研究

种群的空间格局系指某一种群个体在其生存空间内相对静止的散布形式。它是种群的重要属性之一,是种的生物学特性对其所生存的环境条件在特定时期适应和选择的结果。空间格局的阐明,无论在理论生态学的研究上抑或     

HUMAN WOUND REPAIR : I. Epidermal Regeneration

A series of linearly incised superficial skin wounds was made on the forearms of young adult male volunteers. Wounds were sampled at several intervals between 3 hr and 21 days after wounding, for study by light and electron microscopy. The light microscopic observations show that regeneration of epidermis in human wounds conforms chronologically to that reported for the epidermis in superficial wound repair in laboratory animals. It is further shown that "ruffling" of cell membranes characterizes the cells of the migrating epidermis in early wound healing. This study reveals that the basement lamina and hemidesmosomes are established by epidermis in contact with the fibrin net at the base of early wounds. Epidermal cells in the wound environment are shown to be phagocytic. Analysis of the submicroscopic cytology of differentiating and maturing regenerated epidermis reveals that, in the sequence of events, the formation of filaments, basal lamina, and desmosomes is followed chronologically by evolution of keratohyalin granules and, subsequently, by keratinization of the surface epidermal elements. The entire sequence of migration, differentiation, and ultimate keratinization in the superficial wounds studied requires 3–5 days for completion.