E. N. Grigoryan

High regenerative ability of tailed amphibians (Urodela) as a result of the expression of juvenile traits by mature animals

The highest potencies of regeneration in tailed amphibians in comparison with the abilities of organ and tissue restoration in other vertebrates represent the goal of longstanding and intense studies. Accumulated information can half-open some mysteries of cellular and molecular fundamentals of regeneration in Urodela, but it does not explain the maintenance of regenerative abilities in mature, adult animals. The information summarized in the review suggests that the paedomorphosis inherent in this animal group determines the keeping of the juvenile state on all levels of organization—from organismic to molecular. This, in turn, permits and eases initiation and development of regenerative responses to trauma, right up to the epimorphic regeneration of whole organs. As an example, we have traced paedomorphosis-associated cellular and molecular specificities of urodelean eye and brain tissues, which could possibly play a permissive role in their complete regeneration.

Study of regeneration in amphibians in age of molecular-genetic approaches and methods

The results of molecular-genetic mechanisms of regeneration in amphibians are reviewed. Based on the examples of traditional and well-studied models of the restoration of the retinas and lenses of eyes, as well as limbs and tails in amphibians, we analyze the current state of regeneration problems and questions linked to cell reprogramming, growth, and morphogenesis. The development of the Kol’tsov school of thought in the age of molecular-genetic approaches and methods are monitored. The contemporary interpretation of organ regeneration in terms of molecular-genetic regulation and a new look at the definition of regeneration as repeated development is proposed. We also emphasize the current problems that exist in that field of developmental biology and are caused by the many difficulties of genome sequencing and the introduction of transgenesis in Urodela, the animal species with the highest regeneration abilities.

Somatostatin receptor immunoreactivity in the eye of the adult newt (Pleurodeles waltlii Michan)

The neuropeptide somatostatin is found in the retina of many species, yet its role in the visual process remains to be elucidated. The aim of the present study was to examine the expression and cellular localization of somatostatin receptor subtypes (sst; sst(2A), sst(2B) and sst(3)) in the eye of the adult newt Pleurodeles waltlii using immunohistochemistry. sst(2A) immunoreactivity was observed in bipolar cells, in the inner segments of cone photoreceptors, as well as in the region corresponding to connecting cilia of rods. sst(2B) immunoreactivity was not detected. sst(3) immunostaining was localized most intensely in the inner segments of cones, and in cilia of rods. These results suggest that somatostatin acting via sst(2A) and sst(3) receptors may play an important role in retinal physiology of the lower vertebrates.

A study of the localization and accumulation of S-phase cells in the retina of newt Pleurodeles waltl after experimental pigment epithelial detachment

This work continues the studies of the proliferative ability of cells in the adult newt retina. The model of experimental detachment of the retina from pigment epithelium and two techniques to saturate the ocular tissues in vivo with precursors of DNA synthesis were used: (1) the method of repeated [3H]-thymidine labeling and subsequent autoradiographic analysis of semithin sections and (2) an original method for continuous labeling of thymidine analog bromodeoxyuridine and subsequent immunochemical detection. The data obtained confirm and extend our previous data on the localization of DNA-synthesizing cells in the neural retina and expose the pattern of S-phase cell accumulation after retinal detachment for each proliferation-competent cell population. In addition to cells in the growth zone of the retina, Muller glia, microglia, and minor cell population in the vitreal part of interneurons, DNA-synthesizing cells included astrocytes of the optic nerve and cells of its vascular network. Four weeks after detachment, the number of S-phase cells in the growth zone could reach 15–20%, while the above-mentioned DNA-synthesizing cells in the differentiated retina have low reproductive rate and could produce only one generation within the same period.

Differentiation Markers of Retinal Cell Types in Studies on Vertebrate Eye Development and Regeneration

Data on the use of various immunochemical markers specifically indicating cell types of the neural retina and pigment epithelium are reviewed. It is demonstrated how this approach can be applied to the analysis of specific features of vertebrate retinal development, including the order and timing of differentiation of the main cell types, their interdependence in the course of this process, and factors controlling the latter. Problems concerning the state of differentiation and its change in the cells of retinal pigment epithelium and glial cells are discussed in respect to their analysis with the aid of specific protein markers. The current state of retina regeneration research involving the use of labeled cell sources and regenerated cells in lower vertebrates is analyzed. Problems in the search for new markers of retinal photoreceptor, macroglial, and microglial cells and their use in experiments are addressed.

Transcriptional factor Pitx2: Localization during triton retina regeneration

For the first time immune-chemical analysis of transcriptional factor Pitx2 localization during triton retina regeneration after its removal and also in tissues of a nonoperated eye of an adult triton has been carried out. Protein Pitx2 has been found in the nucleus of the earliest neuroblasts that form the germ of the retina. At a later stage of retina regeneration, Pitx2 was found in the nucleus of differentiating cells of ganglionic layers that correspond to Pitx2 protein localization in the native retina. Protein Ptix2 has also been found in the nucleus of less differentiated cells of the peripheral region of regenerative and native retina. It was demonstrated that protein Pitx2 is expressed not only in retina but also in other tissues of the posterior sector of the eye (pigment epithelium, choroid) using immune-histochemical and Western blot hybridization. It is supposed that transcriptional factor Pitx2 has been involved in the control of subsequent stages of retina regeneration from pigment epithelium cells.

Competence factors of retinal pigment epithelium cells for reprogramming in the neuronal direction during retinal regeneration in newts

Retinal pigment epithelium (RPE) cells that have the unique ability to reprogram retinal cells in vivo were analyzed in the adult newt. Our own data and that available in the literature on the peculiarities of the biology of these cells (from morphology to molecular profile, which can be associated with the capability of phenotype change) were summarized. It was established that the molecular traits of specialized and poorly differentiated cells are combined in RPE of the adult newt. It was registered that persistent (at a low level) proliferation and rapid change of specific cytoskeleton proteins can contribute to the success of RPE cell reprogramming in the neuronal direction. Each of the considered factors of competence for reprogramming can be found for animal RPE, whose cells are not able in vivo to change the phenotype to a neuronal one; however, their totality (supported by the epigenetic state permissive for conversion) is probably an internal property of only newt RPE.

The retinal pigment epithelial cells of the adult newt and rat under conditions of in vitro organotypic culture

To understand why the retinal pigment epithelium (RPE) has different potentials for neural differentiation in lower and higher vertebrates, the RPEs of adult newts and rats were compared under similar in vitro cultivation conditions. The RPEs of both animal species were organotypically cultivated within the posterior eye wall under constant rotation in the serum medium free of growth factors. Comparison of the cell morphology, proliferation, and expression of pan-neural markers demonstrated that the RPE cells of adult newts and rats under similar in vitro conditions displayed both similarities and differemces. They were able to synthesize DNA but rarely divided mitotically. In addition, part of the RPE cells of both the newt and the rat were dislodged from the layer, migrated, and acquired a macrophage phenotype. However, the majority of the cells retained the initial morphology and remained within the layer. In several cases, these cells displayed the initial characteristics of neural differentiation, namely, expression of pan-neural proteins. The difference between the newt and rat RPE cells was in the ability of the former to generate in vitro an additional row of dedifferentiated NF-200-positive cells, characteristic of in vivo newt retinal regeneration. These data demonstrate that the RPE cells of the adult newt and rat retain the potential of manifesting neural cell traits; however, more advanced changes towards differentiation are characteristic of only the newt RPE.

FGF2 signaling pathway components in tissues of the posterior eye sector in the adult newt Pleurodeles waltl

The FGF2 signaling pathway components in tissues of the posterior wall in the normal and regenerating eye of the adult Pleurodeles waltl newt were detected for the first time. The fgf2 gene expression was found in the retina, retinal pigment epithelium, and choroid using polymerase chain reaction (PCR). A high homology of the mRNA nucleotide sequence of the most conservative fgf2 gene region in the P. waltl with the fgf2 orthologs in other vertebrates was proved. The Fgf2 protein amino acid sequence of the P. waltl newt demonstrates even more homology with this growth factor in other vertebrates. The Fgf2 protein with a molecular weight 35 kDa was found in the studied eye tissues using Western blot hybridization. Localization of the Fgf2 protein and its Fgfr receptors was immunohistochemically studied in the pigment epithelium, choroid, central and growth retina regions of the newt native eye, and in the connective cilium of photoreceptors. Using real-time PCR and immunohistochemistry methods, it was found that the fgf2 gene down-regulation and a decrease in the intensity of the immunochemical reaction of its protein product (Fgf2) occur in the early period after the retina removal (in 4–8 days) (as compared with those in the same department of the unoperated eye).

Morphogenetic changes during newt tail regeneration under changed gravity conditions

Gravity-dependent shape alterations in newt tail regenerates are described, which were previously noticed in experiments onboard satellites Foton M2, M3 and in corresponding laboratory controls. Laboratory conditions were developed that allow reproducing this phenomenon persistently in the adult newts Pleurodeles waltl (Michahelles, 1830). The newts kept in an aquarium (in partial weightlessness) after 1/3 tail amputation developed normal lanceolate regenerates, while those that stayed on a moist mat (exposed to greater gravity than in aquarium) developed curved tail regenerates. Dynamics of the shape alterations were described using computer morphometric analysis. The curve was shown to develop at stage III of regeneration and to be caused by bending of the developing axial structures: the ependymal tube and the cartilage rode. Cellular processes were described that accompany the tail shape changes, such as cell migration and formation of dense aggregates. Unequal proliferation throughout the wound epidermis and blastema was revealed using BrdU assay. Proliferation increased within dorsal and apical regions of the regenerates in the newts kept on the mat cell compared with the aquarian animals.