The planarian HOM/HOX homeobox genes (Plox) expressed along the anteroposterior axis.

In the freshwater planarian Dugesia japonica, five cDNAs for HOM/HOX homeobox genes were cloned and sequenced. Together with sequence data on HOM/HOX homeobox genes of platyhelminthes deposited in databases, comparison of the deduced amino acid sequences revealed that planarians have at least seven HOM/HOX homeobox genes, Plox1 to Plox7 (planarian HOM/HOX homeobox genes). Whole-mount in situ hybridization and RT-PCR revealed that Plox4 and Plox5 were increasingly expressed along a spatial gradient in the posterior region of intact animals. During regeneration, Plox5 was expressed only in the posterior region of regenerating body pieces, suggesting that the gene is involved in the anteroposterior patterning in planarians. Plox5 was not found to be expressed in a blastema-specific manner, which contradicts a previous report (J. R. Bayascas, E. Castillo, A. M. Mu?os-Mármol, and E. Saló. Development 124, 141-148, 1997). X-ray irradiation experiments showed that Plox5 was expressed at least in some cells other than neoblasts, but that the induction of Plox5 expression during regeneration might require neoblasts.     

Identification and characterization of a fibroblast growth factor gene in the planarian Dugesia japonica

Planarians belong to the phylum Platyhelminthes and can regenerate their missing body parts after injury via activation of somatic pluripotent stem cells called neoblasts. Previous studies suggested that fibroblast growth factor (FGF) signaling plays a crucial role in the regulation of head tissue differentiation during planarian regeneration. To date, however, no FGF homologues in the Platyhelminthes have been reported. Here, we used a planarian Dugesia japonica model and identified an fgf gene termed Djfgf, which encodes a putative secreted protein with a core FGF domain characteristic of the FGF8/17/18 subfamily in bilaterians. Using Xenopus embryos, we found that DjFGF has FGF activity as assayed by Xbra induction. We next examined Djfgf expression in non-regenerating intact and regenerating planarians. In intact planarians, Djfgf was expressed in the auricles in the head and the pharynx. In the early process of regeneration, Djfgf was transiently expressed in a subset of differentiated cells around wounds. Notably, Djfgf expression was highly induced in the process of head regeneration when compared to that in the tail regeneration. Furthermore, assays of head regeneration from tail fragments revealed that combinatorial actions of the anterior extracellular signal-regulated kinase (ERK) and posterior Wnt/ß-catenin signaling restricted Djfgf expression to a certain anterior body part. This is the region where neoblasts undergo active proliferation to give rise to their differentiating progeny in response to wounding. The data suggest the possibility that DjFGF may act as an anterior counterpart of posteriorly localized Wnt molecules and trigger neoblast responses involved in planarian head regeneration.     

What is the role of PIWI family proteins in adult pluripotent stem cells? Insights from asexually reproducing animals,planarians

Planarians have a remarkable regenerative ability owing to their adult pluripotent stem cells (aPSCs), which are called “neoblasts.” Planarians maintain a considerable number of neoblasts throughout their adulthood to supply differentiated cells for the maintenance of tissue homeostasis and asexual reproduction (fission followed by regeneration). Thus, planarians serve as a good model to study the regulatory mechanisms of in vivo aPSCs. In asexually reproducing invertebrates, such as sponge, Hydra, and planaria, piwi family genes are the markers most commonly expressed in aPSCs. While piwi family genes are known as guardians against transposable elements in the germline cells of animals that only sexually propagate, their functions in the aPSC system have remained elusive. In this review, we introduce recent knowledge on the PIWI family proteins in the aPSC system in planarians and other organisms and discuss how PIWI family proteins contribute to the regulation of the aPSC system.     

TINP1 homolog is required for planarian regeneration

The planarian flatworm is an ideal system for the study of regeneration in vivo. In this study, we focus on TINP1, which is one of the most conserved proteins in eukaryotic organisms. We found that TINP1 was expressed in parenchymal region through whole body as well as central nervous system (CNS) during the course of regeneration. RNA interference targeting DjTINP1 caused lysis defects in regenerating tissues and a decreased in cell division and expression levels of DjpiwiA and Djpcna. Furthermore, the expression levels of DjTINP1 were decreased when we inhibited the TGF-β signal by knockdown of smad4, which is the sole co-smad and has been proved to control the blastema patterning and central nervous system (CNS) regeneration in planarians. These findings suggest that DjTINP1 participate in the maintenance of neoblasts and be required for proper cell proliferation in planarians as a downstream gene of the TGF-β signal pathway.     

The planarian <Emphasis Type="Italic">nanos</Emphasis>-like gene Smednos is expressed in germline and eye precursor cells during development and regeneration

Planarians are highly regenerative organisms with the ability to remake all their cell types, including the germ cells. The germ cells have been suggested to arise from totipotent neoblasts through epigenetic mechanisms. Nanos is a zinc-finger protein with a widely conserved role in the maintenance of germ cell identity. In this work, we describe the expression of a planarian nanos-like gene Smednos in two kinds of precursor cells namely, primordial germ cells and eye precursor cells, during both development and regeneration of the planarian Schmidtea mediterranea. In sexual planarians, Smednos is expressed in presumptive male primordial germ cells of embryos from stage 8 of embryogenesis and throughout development of the male gonads and in the female primordial germ cells of the ovary. Thus, upon hatching, juvenile planarians do possess primordial germ cells. In the asexual strain, Smednos is expressed in presumptive male and female primordial germ cells. During regeneration, Smednos expression is maintained in the primordial germ cells, and new clusters of Smednos-positive cells appear in the regenerated tissue. Remarkably, during the final stages of development (stage 8 of embryogenesis) and during regeneration of the planarian eye, Smednos is expressed in cells surrounding the differentiating eye cells, possibly corresponding to eye precursor cells. Our results suggest that similar genetic mechanisms might be used to control the differentiation of precursor cells during development and regeneration in planarians. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Specification of Primary Pigment Cell and Outer Photoreceptor Fates byBarH1Homeobox Gene in the DevelopingDrosophilaEye

In the developingDrosophilaeye,BarH1andBarH2, paired homeobox genes expressed in R1/R6 outer photoreceptors and primary pigment cells, are essential for normal eye morphogenesis. Here, we show evidence thatBarH1ectopically expressed under the control of thesevenlessenhancer (sev-BarH1) causes two types of cone cell transformation: transformation of anterior/posterior cone cells into outer photoreceptors and transformation of equatorial/polar cone cells into primary pigment cells.sev-BarH1repressed the endogenous expression of theroughhomeobox gene in R3/R4 photoreceptors, while theBarH2homeobox gene was activated bysev-BarH1in an appreciable fraction of extra outer photoreceptors. In primary pigment cells generated by cone cell transformation, the expression ofcut,a homeobox gene specific to cone cells, was completely replaced with that ofBarhomeobox genes. Extra outer photoreceptor formation was suppressed and enhanced, respectively, by reducing the activity of Ras/MAPK signaling and by dosage reduction ofyan,a negative regulator of the pathway, suggesting interactions betweenBarhomeobox genes (cell fate determinants) and Ras/MAPK signaling in eye development.     

Two msh/msx-related genes, Djmsh1 and Djmsh2, contribute to the early blastema growth during planarian head regeneration

Regeneration in planarians is an intriguing phenomenon, based on the presence of pluripotent stem cells, known as neoblasts. Following amputation, these cells activate mitotic divisions, migrate distally and undergo differentiation, giving rise to the regeneration blastema. We have identified two msh/msx-related genes, Djmsh1 and Djmsh2, which are expressed in distinct cell populations of the planarian Dugesia japonica and activated, with different patterns, during head regeneration. We demonstrate that RNA interference of Djmsh1 or Djmsh2 generates a delay in the growth of cephalic blastema, interfering with the dynamics of mitoses during its initial formation. Our data also reveal that the activity of the two planarian msh genes is required to regulate Djbmp expression during head regeneration. This study identifies, for the first time, a functional association between muscle segment homeobox (MSH) homeoproteins and BMP signaling during stem cell-based regeneration of the planarian head and provides a functional analysis of how msh genes may regulate in vivo the regenerative response of planarian stem cells.     

Stem cells in asexual reproduction of Enchytraeus japonensis (Oligochaeta, Annelid): proliferation and migration of neoblasts

Enchytraeus japonensis is a small oligochaete that reproduces mainly asexually by fragmentation (autotomy) and regeneration. As sexual reproduction can also be induced, it is a good animal model for the study of both somatic and germline stem cells. To clarify the features of stem cells in regeneration, we investigated the proliferation and lineage of stem cells in E. japonensis. Neoblasts, which have the morphological characteristics of undifferentiated cells, were found to firmly adhere to the posterior surface of septa in each trunk segment. Also, smaller neoblast‐like cells, which are designated as N‐cells in this study, were located dorsal to the neoblasts on the septa. By conducting 5‐bromo‐2′‐deoxyuridine (BrdU)‐labeling‐experiments, we have shown that neoblasts are slow‐cycling (or quiescent) in intact growing worms, but proliferate rapidly in response to fragmentation. N‐cells proliferate more actively than do neoblasts in intact worms. The results of pulse‐chase experiments indicated that neoblast and N‐cell lineage mesodermal cells that incorporated BrdU early in regeneration migrated toward the autotomized site to form the mesodermal region of the blastema, while the epidermal and intestinal cells also contributed to the blastema locally near the autotomized site. We have also shown that neoblasts have stem cell characteristics by expressing Ej‐vlg2 and by the activity of telomerase during regeneration. Telomerase activity was high in the early stage of regeneration and correlated with the proliferation activity in the neoblast lineage of mesodermal stem cells. Taken together, our results indicate that neoblasts are mesodermal stem cells involved in the regeneration of E. japonensis.     

Position-specific and non-colinear expression of the planarian posterior (Abdominal-B-like) gene

Hox genes are pivotal molecules in the control of morphogenesis along the anterior-posterior (AP) axis in various bilaterians. Planarians are key animals for understanding the evolution of the bilaterian body plan. Furthermore, they are also known for their strong regeneration ability and are thought to use the Hox genes in the process of reconstruction of the AP axis. In the present paper, the identification and analysis of expression of two posterior (Abdominal-B-like) genes, DjAbd-Ba and DjAbd-Bb, is reported in the planarian Dugesia japonica. DjAbd-Ba is expressed in the entire tail region and its anterior boundary is the posterior pharyngeal region. In contrast, DjAbd-Bb is expressed in several types of cells throughout the body. During regeneration, the expression of DjAbd-Ba rapidly recovers a pattern similar to that in the normal worm. These findings suggest the possibility that DjAbd-Ba is involved in the specification of the tail region. The anterior boundary of the expression domain of the posterior gene DjAbd-Ba is anterior to the domains of the central genes Plox4-Dj and Plox5-Dj. These expression patterns of planarian Hox genes seem out of the rule of spatial colinearity and may reflect an ancestral feature of bilaterian Hox genes.     

Molecular analysis of stem cells and their descendants during cell turnover and regeneration in the planarian Schmidtea mediterranea

In adult planarians, the replacement of cells lost to physiological turnover or injury is sustained by the proliferation and differentiation of stem cells known as neoblasts. Neoblast lineage relationships and the molecular changes that take place during differentiation into the appropriate cell types are poorly understood. Here we report the identification and characterization of a cohort of genes specifically expressed in neoblasts and their descendants. We find that genes with severely downregulated expression after irradiation molecularly define at least three discrete subpopulations of cells. Simultaneous BrdU labeling and in situ hybridization experiments in intact and regenerating animals indicate that these cell subpopulations are related by lineage. Our data demonstrate not only the ability to measure and study the in vivo population dynamics of adult stem cells during tissue homeostasis and regeneration, but also the utility of studies in planarians to broadly inform stem cell biology in adult organisms.     

The freshwater planarian Dugesia (G.) tigrina contains a great diversity of homeobox genes

To identify potential pattern control and cell determination and/or differentiation genes in the freshwater planarian Dugesial (G.) tigrina, we searched for homeobox genes of different types in the genome of this primitive metazoan. We applied two basic approaches: 1) Screening the cDNA library with degenerate oligonucleotides corresponding to the most conserved amino acid sequence from helix-3 of the homeodomain of each family; and 2) PCR amplification of genomic DNA or cDNA, using two sets of degenerated oligonucleotides corresponding to helices 1 and 3 of the homeodomain or two specific domains of the POU family. Using the first strategy we have identified and characterized two tissue-specific cell determination and/or differentiation NK-type homeobox genes. Using the second strategy we have identified several homeobox genes that belong to the HOM/Hox, paired (prd) or POU families.     

Spoltud-1 is a chromatoid body component required for planarian long-term stem cell self-renewal

Freshwater planarians exhibit a striking power of regeneration, based on a population of undifferentiated totipotent stem cells, called neoblasts. These somatic stem cells have several characteristics resembling those of germ line stem cells in other animals, such as the presence of perinuclear RNA granules (chromatoid bodies). We have isolated a Tudor domain-containing gene in the planarian species Schmidtea polychroa, Spoltud-1, and show that it is expressed in neoblast cells, germ line cells and central nervous system, and during embryonic development. Within the neoblasts, Spoltud-1 protein is enriched in chromatoid bodies. Spoltud-1 RNAi eliminates protein expression after 3 weeks, and abolishes the power of regeneration of planarians after 7 weeks. Neoblast cells are eliminated by the RNAi treatment, disappearing at the end rather than gradually during the process. Neoblasts with no detectable Spoltud-1 protein are able to proliferate and differentiate. These results suggest that Spoltud-1 is required for long term stem cell self renewal.     

Proliferative response of the stem cell system during regeneration of the rostrum in <Emphasis Type="Italic">Macrostomum lignano</Emphasis> (Platyhelminthes)

Macrostomum lignano (Platyhelminthes) possesses pluripotent stem cells, also called neoblasts, which power its extraordinary regeneration capacity. We have examined the cellular dynamics of neoblasts during regeneration of the rostrum in M. lignano. First, using live squeeze observations, the growth curve of the rostrum was determined. Second, neoblasts were labelled with 5-bromo-2'-deoxyuridine (BrdU) and an anti-phospho-histone H3 mitosis marker (anti-phos-H3) to analyze their proliferative response to amputation. During the regeneration process, both S- and M-phase cells were present anterior to the eyes, a region that is devoid of proliferating cells during homeostasis. Furthermore, BrdU pulse experiments revealed a biphasic S-phase pattern, different from the pattern known to occur during regeneration of the tail plate in M. lignano. During a first systemic phase, S-phase numbers significantly increased, both in the region adjacent to the wound (the anterior segment) and the region far from the wound (the posterior segment). During the second, spatially restricted phase, S-phase numbers in the anterior segment rose to a peak at 3 to 5 days post-amputation (p-a), while in the posterior segment, S-phase activity approached control values again. A blastema, characterized as a build-up of S- and M-phase cells, was formed 1 day p-a.     

Regeneration in <Emphasis Type="Italic">Macrostomum lignano</Emphasis> (Platyhelminthes): cellular dynamics in the neoblast stem cell system

Neoblasts are potentially totipotent stem cells and the only proliferating cells in adult Platyhelminthes. We have examined the cellular dynamics of neoblasts during the posterior regeneration of Macrostomum lignano. Double-labeling of neoblasts with bromodeoxyuridine and the anti-phospho histone H3 mitosis marker has revealed a complex cellular response in the first 48 h after amputation; this response is different from that known to occur during regeneration in triclad platyhelminths and in starvation/feeding experiments in M. lignano. Mitotic activity is reduced during the first 8 h of regeneration but, at 48 h after amputation, reaches almost twice the value of control animals. The total number of S-phase cells significantly increases after 1 day of regeneration. A subpopulation of fast-cycling neoblasts surprisingly shows the same dynamics during regeneration as those in control animals. Wound healing and regeneration are accompanied by the formation of a distinct blastema. These results present new insights, at the cellular level, into the early regeneration of rhabditophoran Platyhelminthes. This work was supported by FWF Grant (P16618; P.I. Rieger, Innsbruck).     

Distribution of the stem cells (neoblasts) in the planarian <Emphasis Type="Italic">Dugesia japonica</Emphasis>

It has been postulated that the high regeneration ability of planarians is supported by totipotent stem cells, called neoblasts. There have been a few reports showing the distribution of neoblasts in planarians. However, the findings were not completely consistent. To determine the distribution of neoblasts, we focused on proliferating cell nuclear antigen (PCNA), which is present in proliferative cells. We cloned and sequenced the cDNA of PCNA from the planarian Dugesia japonica and produced an antiserum recognizing the gene product. X-ray irradiation caused rapid loss of all PCNA-positive cells and loss of the neoblasts (which were morphologically defined by the presence of the chromatoid body), strongly suggesting that all PCNA-positive cells were true neoblasts. Using the antiserum, we were successful in identifying the neoblasts more clearly than any previous work. In addition to their dispersed distribution in the dorsal and ventral mesenchyme, the neoblasts were distributed as clusters along the midline and bilateral lines in the dorsal mesenchyme. We also examined the behavior of the neoblasts after decapitation. Decapitation did not seem to affect the migration of neoblasts far from the wound. We demonstrated here that DjPCNA is a powerful tool for identifying planarian neoblasts.Edited by D.A. Weisblat     

MetaHox gene clusters

Homeobox genes encode important developmental control proteins. The Drosophila fruit fly HOM complex genes are clustered in region 84-89 of chromosome 3. Probably due to large-scale genome duplication events, their human HOX orthologs belong to four paralogous regions. A series of 13 other homeobox genes are also clustered in region 88-94, on the same chromosome of Drosophila. We suggest that they also duplicated during vertebrate evolution and belong to paralogous regions in humans. These regions are on chromosome arms 4p, 5q, 10q, and 2p or 8p. We coined the term "paralogon" to designate paralogous regions in general. We propose to call these genes "meta Hox" genes. Like Hox genes, metaHox genes are present in one cluster in Drosophila and four clusters (metaHox A-D) in humans on the 4p/5q/10q paralogon.     

Expression ofHoxDGenes in Developing and Regenerating Axolotl Limbs

Hoxgenes play a critical role in the development of the vertebrate axis and limbs, and previous studies have implicated them in the specification of positional identity, the control of growth, and the timing of differentiation. Axolotl limbs offer an opportunity to distinguish these alternatives because the sequence of skeletal differentiation is reversed along the anterior–posterior axis relative to that of other tetrapods. We report that during early limb development, expression patterns ofHoxDgenes in axolotls resemble those in amniotes and anuran amphibians. At later stages, the anterior boundary ofHoxd-11expression is conserved with respect to morphological landmarks, but there is no anterior–distal expansion of the posterior domain ofHoxd-11expression similar to that observed in mice and chicks. Since axolotls do not form an expanded paddle-like handplate prior to digit differentiation, we suggest that anterior expansion of expression in higher vertebrates is linked to the formation of the handplate, but is clearly not necessary for digit differentiation. We also show that the 5′HoxDgenes are reexpressed during limb regeneration. The change in the expression pattern ofHoxd-11during the course of regeneration is consistent with the hypothesis that the distal tip of the regenerate is specified first, followed by intercalation of intermediate levels of the pattern. BothHoxd-8andHoxd-10are expressed in non-regenerating wounds, butHoxd-11is specific for regeneration. It is also expressed in the posterior half of nerve-induced supernumerary outgrowths.     

Retinoic acid as a regulator of planarian morphogenesis

The effect of retinoic acid on regeneration of two species of asexual planarian races, Girardia tigrina and Schmidtea mediterranea, was studied. It was established that retinoic acids at physiological concentrations (10⁻⁷–10⁻¹⁰ M) inhibit the regeneration of the head part of planarians but have no effect on tail blastema growth. It is shown that regeneration of the head part is inhibited as a result of arrest of the cell cycle of neoblasts, proliferating stem cells, during the transition from the G ₁/G ₀ to the S phase. Thus, the morphogenetic role of retinoic acids in planarians, primitive bilaterally symmetrical animals, has been demonstrated.     

Expression analysis of <Emphasis Type="Italic">Djsix-1</Emphasis> gene during regeneration of planarian eyespots

Djsix-1 gene is one of the important eyespots-regulating genes in planarians. In this experiment, the expression of Djsix-1 and morphogenesis of eyespots during planarians eyespots regeneration were investigated. The planarians were subjected to two rounds of transverse amputation. Nineteen time points in the first round and ten ones in the second one during the regeneration of the planarians post-auricle fragments were selected. At different time points, the quantitative expression of Djsix-1 and morphogenesis of eyespots during eyespots regeneration were examined by real-time RT-PCR and paraffin sections. Results showed that the optimal growth temperature for planarians regeneration was 22°C in dark. At this temperature, Djsix-1 gene was first up-regulated at the 30th min after the first round of transverse amputation and its expression level increased at the 24-h time point. The expression level reached peak on day 4 and then began to decrease thereafter. From day 6 to day 9, the expression level was maintained in a relatively stable level. In the second round, Djsix-1 expression reached the peak on the 2nd day after amputation, and then began to decrease and maintained in a relatively stable level from the 4th to the 9th day. Morphological and histological examinations showed that eyespots were observed on the 4th day after amputation in the first round and on the 3rd day in the second round. These results indicated that corresponding relationship existed between eyespots morphogenesis and Djsix-1 quantitative expression. It was also suggested that Djsix-1 promoted neoblasts proliferation at the early stage of eyespots regeneration and regulated morphogenesis of eyespots at the later stage.