<b>STENOSTOMUM LEUCOPS</b> DUGÈS, 1828 (PLATYHELMINTHES, CATENULIDA): A PUTATIVE SPECIES COMPLEX WITH PHENOTYPIC PLASTICITY

ROSA, MARCOS T.; PEREIRA, CAMILA. M.; RAGAGNIN, GEOVANI. T.; LORETO, ELGION. L.S.

doi:10.1590/0031-1049.2015.55.27

ABSTRACT

Species of Stenostomum are small flatworms that live in freshwater and normally reproduce asexually by paratomy. They are basal in the phylogeny of Platyhelminthes. For more than a century, species of this genus, especially S. leucops, have been used in regeneration and other biological studies. However, some basic aspects of their biology are poorly known. Here, we characterized a strain of S. leucops that has been maintained in the laboratory for five years and a recent strain of S. grande. The time required for complete formation of zooids of S. leucops by asexual reproduction is approximately 42.5 hours at 28°C. The number of cells in the zooids, soon after paratomy, is approximately 2,500. The number of zooids formed in the chain is a plastic characteristic and is dependent on the conditions for cultivation. In some cultivation conditions of S. leucops, only worms with two zooids are formed. However, in other conditions, worms with up to five zooids are observed. Phylogenetic analyses of a fragment of the Cytochrome C Oxidase I (COI) sequence showed S. leucops and S. grande species constitute a species complex, the lineages of which having high intraspecific divergences.

KEY-WORDS:
Stenostomum grande; Paratomy; Zooids; Number of cells; Microturbellaria

RESUMO

Stenostomum são pequenos vermes que vivem em água doce e normalmente se reproduzem assexualmente por paratomia. Eles estão na base da filogenia dos platelmintes. Por mais de um século, espécies desse gênero, especialmente S. leucops, vêm sendo empregadas em estudos biológicos, principalmente sobre regeneração. Entretanto, alguns aspectos básicos da biologia destes vermes são ainda pobremente conhecidos. Neste estudo, caracterizamos uma linhagem que vem sendo mantida no laboratório por cinco anos. O tempo necessário para reprodução assexuada e completa formação de zoóides, a 28°C, é de aproximadamente 42,5 horas. O número de células nos zoóides, logo após a paratomia, é de aproximadamente 2.500. O número de zoóides presentes nos vermes é uma característica variável e depende das condições de cultivo. Em alguns procedimentos de cultivo de S. leucops, apenas cadeias com dois zoóides são formadas. No entanto, em outras condições de cultivo, cadeias de até cinco zoóides podem ser observadas. Análise filogenética empregando sequência do gene de Citocromo C Oxidase (COI) mostrou que S. leucops e S. grande constituem um complexo de espécies cujas linhagens mostram altas divergências intraespecíficas.

PALAVRAS-CHAVE:
Stenostomum grande; Paratomia; Zooides; Número de células; Microturbellaria

INTRODUCTION

The order Catenulida Meixner, 1924, is represented by small flatworms that generally range from 0.5 to 2 mm long. They have unpaired, dorsomedially located protonephridium, anterodorsal testes and male genital pore, and aciliary nonmobile sperm. Normally they are white in reflected light, and translucent in transmitted light. The intestine varies in color depending on their food content (Larsson, 2008LARSSON, K. 2008. Taxonomy and phylogeny of Catenulida (Platyhelminthes) with emphasis on the Swedish Fauna. Acta Universitatis Upsaliensis 2008: 1-48. (Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Science and Technology 395).). Approximately 100 species have been described worldwide, and the majority lives in freshwater. The sexually mature stage is rarely found because Catenulida normally reproduce by paratomy, an asexual form of reproduction in which structures typical of the anterior region develop followed by a fission perpendicular to the antero-posterior axis, which forms zooids (a movie of this process can be seen in http://w3.ufsm.br/labdros/permanente/paratomy.mp4). In some species, chains with up to nine zooids can occur (Hyman, 1951HYMAN, L.H. 1951. The invertebrates: Platyhelminthes and Rhynchocoela The acoelomate Bilateria New York, McGraw-Hill, v. 2.). One of the most studied Catenulida is Stenostomum leucops (Dugès, 1828DUGÈS, A. 1828. Recherches sur l'organisation et les moeurs des planariees. Annales des sciences naturelles 15: 139-182.), a cosmopolitan species exhibiting characteristics that make it an excellent experimental organism. For example, it can be easily maintained and reproduces quickly in culture, regenerates extensively and has internal organs that can be readily observed (Nuttycombe & Waters, 1938NUTTYCOMBE, J. & WATERS, A. 1938. The American species of the genus Stenostomum. Proceedings of the American Philosophical Society 79: 213-301.). For more than a century, Stenostomum, primarily S. leucops, have been used for several experimental biology studies, such as studies of fission and regeneration (Ritter & Congdon, 1900RITTER, W.E. & CONGDON, E.M. 1900. On the inhibition by artificial section of the normal fission plane in Stenostoma. Proceedings California Academy of Sciences 2: 365.; Child, 1990, 1902CHILD, C.M. 1902. Studies on regulation. Archiv für Entwicklungsmechanik der Organismen 15: 187-234.; Hartmann, 1922HARTMANN, M. 1922. Uber den dauernden Ersatz der ungeschlechtlichen Fortpflanzung durch fortgesetzte Regenerationen. Biologisches Zentralblatt 42: 364-381.; Ruhl, 1927RUHL, L. 1927. Regeneration in rhabdocoeles. Zoologischer Anzeiger 72: 160-175.; Van Cleave, 1929VAN CLEAVE, C.D. 1929. An experimental study of fission and reconstitution in Stenostomum. Physiological Zoology Chicago, 2: 18-58.), stem cells (Palmberg, 1990PALMBERG, I. 1990. Stem cells in microturbellarians an autoradiographic and immunocytochemical study. Protoplasma 158: 109-120.), ultrastructure of sensory organs (Reuter et al., 1993REUTER, M.; JOFFE, B. & PALMBERG, I. 1993. Sensory receptors in the head of Stenostomum leucops. II localization of catecholaminergic histofluorescence-ultrastructure of surface receptors. Acta Biologica Hungarica 44: 125-131.; Palmberg & Reuter, 1992PALMBERG, I. & REUTER, M. 1992. Sensory receptors in the head of Stenostomum leucops. 1. Presumptive photoreceptors. Acta Biologica Hungarica 43: 259-267.; Ruppert & Schreiner 1980RUPPERT, E.E. & SCHREINER, S.P. 1980. Ultrastructure and potential significance of cerebral light-refracting bodies of Stenostomum virginianum (Turbellaria, Catenulida). Zoomorphology 96: 21-31.), ultrastructure of the digestive tract (Antoniazzi & Silveira, 1996ANTONIAZZI, M.M. & SILVEIRA, M. 1996. Studies of Stenostomum grande Child, 1902 (Platyhelminthes, Catenulida): fine structure of the digestive tract and the endocytotic activity of the gastrodermis. Acta Zoologica Stockholm, 77: 25-32.), senescence (Martínez & Levinton, 1992MARTÍNEZ, D.E. & LEVINTON, J.S. 1992. Asexual metazoans undergo senescence. Proceedings of the National Academy of Sciences, United States of America 86: 9920-9923.), neuropeptides (Grahn et al., 1995GRAHN, M.; MAULE, A.G.; ELO, I.; SHAW, C.; REUTER, M. & HALTON, D.W. 1995. Antigenicity to neuropeptide-f (NPF) in Stenostomum leucops and Microstomum lineare. Hydrobiologia 305: 307-308.; Wikgren & Reuter, 1985WIKGREN, M.C. & REUTER, M. 1985. Neuropeptides in a microturbellarian-whole mount immunocytochemistry. Peptides 6: 471-5.) and ecology (Nandini & Sarma, 2013NANDINI, S. & SARMA, S.S.S. 2013. Demographic characteristic of cladocerans subject to predation by the flatworm Stenostomum leucopsHydrobiologia 715: 159-168.; Nandini et al., 2011NANDINI, S.; SARMA, S.S.S. & DUMONT, H.J. 2011. Predatory and toxic effects of the turbellarian (Stenostomum cf. leucops) on the population dynamics of Euchlanis dilatata, Plationus patulus (Rotifera) and Moina macrocopa (Cladocera). Hydrobiologia 662: 171-177.). However, some basic aspects of the biology of these worms, such as the time required for paratomy or the number of cells constituting the body, are not well known.

The validity of S. leucops as a species has been questioned by Nuttycombe & Waters (1938)NUTTYCOMBE, J. & WATERS, A. 1938. The American species of the genus Stenostomum. Proceedings of the American Philosophical Society 79: 213-301. and Marcus (1945)MARCUS, E. 1945. Sobre Microturbelários do Brasil. Comunicaciones Zoologicas del Museo de Historia Natural de Montevideo 1: 1-74.. However, further studies by Noreña et al. (2005)NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58. have validated this species. More recently, Larsson et al. (2008)LARSSON, K.; AHMADZADEH, A. & JONDELIUS, U. 2008. DNA taxonomy of Swedish Catenulida (Platyhelminthes) and a phylogenetic framework for catenulid classification. Organisms, Diversity & Evolution 8: 399-412. used DNA sequences of 18 S rDNA and COI to show that S. leucops constitutes a monophyletic group. Yamazaki et al. (2012)YAMAZAKI, M.; ASAKAWA, S.; MURASE, J. & KIMURA, M. 2012. Phylogenetic diversity of microturbellarians in Japanese rice paddy fields, with special attention to the genus Stenostomum Soil Science and Plant Nutrition, 58: 11-23. used the same molecular markers and also included species collected in Japan; in their analysis, S. grande was placed in a cluster with representatives of S. leucops. Furthermore, the genetic divergences observed among the sequences of S. leucops collected in different places correspond to that expected for species, suggesting that it is a species complex. In order to solve the problem of whether S. leucops is one species or a species complex, it is necessary to morphologically and biologically characterize populations worldwide, and DNA barcoding can be useful for this task.

The basis for DNA barcoding is that short nucleotide sequences can be used to distinguish species, because the genetic variation between species is normally higher than that observed within species. For animals, the sequence used the most is a 650-base fragment of the 5' end of the mitochondrial gene Cytochrome C Oxidase I (COI, cox1) (Hebert et al., 2003HEBERT, P.D.N.; CYWINSKA, A.; BALL, S.L. & DE WAARD, J.R. 2003. Biological identifications through DNA barcodes. Proceedingsof the Royal Society of London. B, Biological Science 270: 313-321.). Although several shortcomings have been associated with DNA barcoding, the methodology is now well established and has been shown to be useful in various fields of biological research, including the identification of cryptic species or species complexes (Collins & Cruickshank, 2013COLLINS, R.A. & CRUIKSHANK, R.H. 2013. The seven deadly sins of DNA barcoding. Molecular Ecology Resources 13: 969-975.; Albu et al., 2010ALBU, M.; NIKBAKHT, H.; HAJIBABAEI, M. & HICKEY, D.A. 2010. The DNA Barcode Linker. Molecular Ecology Resources 11: 84-88.).

The aim of this study was to characterize some morphological and biological characteristics, such as the time required for paratomy and the number of cells in each zooid of a strain maintained in the laboratory for 5 years. A morphological plasticity was observed in the number of zooids formed, which depended on the growing conditions. We also performed a DNA barcoding and phylogenetic analysis. We found that S. leucops collected in Sweden, London and Brazil are paraphyletic with regard to S. grande, from Japan and Brazil, supporting the hypothesis that this taxon corresponds to a species complex.

MATERIALS AND METHODS

Animal sampling and cultures

The worms were collected in a pond at the Federal University of Santa Maria, Santa Maria, Brazil (53°17'W; 29°28'S). Stenostomum leucops was collected in March of 2009 and S. grandeChild, 1902CHILD, C.M. 1902. Studies on regulation. Archiv für Entwicklungsmechanik der Organismen 15: 187-234., in November of 2012. These specimens were identified following Noreña et al. (2005)NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58. and Damborenea et al. (2011)DAMBORENEA, C.; BRUSA, F.; ALMAGRO, I. & NOREÑA, C. 2011. A phylogenetic analysis of Stenostomum and its neotropical congeners, with a description of a new species from the Peruvian Amazon Basin. Invertebrate Systematics 25: 155-169.. The diagnostic characteristics of S. leucops are the light-refracting bodies with disc shaped, pharyngeal glands rounded shape, without a sphincter between pharynx and intestine, and the pharyngeal glands are on the entire surface of the pharynx. They present an elongated posterior end, free of intestine. Stenostomum grande have as characteristics the light-refracting bodies disc shaped with more than ten small spheres, pharyngeal glands small rounded shaped and only in the anterior half of the pharynx. They present sphincter between pharynx and intestine, oral pore circular. Culture, for both species, was initiated from a single worm, and the stocks were maintained in a 25 ml culture flask with 10 ml of reconstituted water (Knakievicz et al., 2006KNAKIEVICZ, T.; VIEIRA, S.M.; ERDTMANN, B. & FERREIRA, H.B. 2006. Reproduction modes and life cycle of freshwater planarians (Platyhelminthes, Tricladida, Palucida) from Southern Brazil. Invertebrate Biology 125: 212-221.). Two different culture conditions were used: i) Condition 1 - the worms were grown in a chamber with controlled temperature at 28 ± 2°C and constant luminosity of 33 cd. Every 3 days, half of the water volume was changed, and approximately 2 mg of powdered milk was added to the medium; ii) Condition 2 - the culture flasks were maintained at room temperature under indirect solar illumination. In these conditions, cyanobacteria belonging to the Chroococcales order become abundant in the medium and promote differential growth in the worms.

Vouchers of the used strains were deposited in UFSM Department of Biology collection under numbers SL01-sm01 and SL01-sm01.

Estimation of the time required for asexual reproduction of S. leucops

To assess the time required for asexual reproduction by paratomy, a total of 98 worms under Condition 1 were analyzed. They were put in a drop of water in Kline concavity slides with one worm per concavity. The slides were maintained in a wet chamber, and the water was replenished every day. The worms were observed through a stereo microscope every 12 hours. After fission, each "new" worm was transferred to a new well, and the time for the process was registered.

Estimating the number of cells of S. leucops

Worms soon after paratomy or showing the constriction between zooids, which characterize that the fission will occur shortly, were put on a slide with a drop of distilled water and 2.5 µl of ethidium bromide (0.5 mg/ml). For each preparation, one worm was put on the slide, covered with a coverslip and squashed, and they were observed through an Olympus BX41 fluorescence microscope. Pictures were taken using a 518 nm absorption filter and a 605 nm emission filter. Additionally, estimates were performed for worms with two, three and four zooids. The nuclei were counted directly from a computer screen, which marked the nuclei that had already been counted.

A second procedure was performed using an acetic orcein (2%) stain. The worms were photographed, and the number of cells was estimated as previously described.

DNA barcoding

Genomic DNA was isolated from approximately 100 worms of each strain following the method described by Oliveira et al. (2009)OLIVEIRA, L.F.V.; WALLAU, G.L. & LORETO, E.L.S. 2009. Isolation of high quality DNA: a protocol combining rennet and glass milk. Electronic Journal of Biotechnology 12: 1-6.. As previously highlighted, the strains were made from a single worm. Thus, as only asexual reproduction has been observed, the worms in each culture are clones, therefore, homogeneous mitochondrial sequences are expected. The primers and PCR conditions used to amplify Cytochrome C Oxidase I (COI) were described by Telford et al. (2000)TELFORD, M.J.; HERNIOU, E.A.; RUSSELL, R.B. & LITTLEWOOD, T.J. 2000. Changes in mitochondrial genetic codes as phylogenetic characters: two examples from the flatworms. Proceedings of the National Academy of Sciences, United States of America 97: 11359-11364.. A fragment of 497 bp was sequenced using a MegaBace 500 automatic sequencer. The dideoxy chain-termination reaction was performed using the DYEnamicET kit (GE Healthcare). The sequences obtained were deposited in GenBank (accession numbers: S. leucops KJ476143 and S. grande KM056359).

For the phylogenetic analyses, other Stenostomum COI sequences were obtained from GenBank (accession numbers: AB665116 to AB665124, FJ384873 to FJ38910, AJ405975, and AJ405976). These nucleotide sequences were aligned using Clustal W (Thompson et al., 1994THOMPSON, J.D.; HIGGINS, D.G. & GIBSON, T.J. 1994. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Research 22(22): 4673-4680.) according to the default program parameters. The phylogenetic analyses were implemented in Mega 5.0 software (Tamura et al., 2011TAMURA, K.; PETERSON, D.; PETERSON, N.; STECHER, G.; NEI, M. & KUMAR, S. 2011. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Molecular Biology and Evolution 28(10): 2731-2739.) by neighbor-joining and maximum likelihood with 1,000 bootstrap replications. The genetic distances among different taxa were estimated by P distance also using Mega 5.0 software.

RESULTS

Life cycle and biological characterization of S. leucops

The morphological characteristics of S. leucops here studied correspond to those described by Noreña et al. (2005)NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58. and Damborenea et al. (2011)DAMBORENEA, C.; BRUSA, F.; ALMAGRO, I. & NOREÑA, C. 2011. A phylogenetic analysis of Stenostomum and its neotropical congeners, with a description of a new species from the Peruvian Amazon Basin. Invertebrate Systematics 25: 155-169.. The same occurs for S. grande.

During the five years that we maintained the culture of S. leucops, the sexually mature form was not observed. In cultures maintained under the Condition 1, paratomy occurred after an average time of 42.5 hours. However, 45% of the individuals evaluated (n = 98) reproduced in 24 hours, while 4% required 96 hours to proceed to fission (Fig. 1). During the time that the cultures were maintained in Condition 1, only worms with two zooids were observed. The average size of worms with two zooids preceding paratomy was 0.98 ± 0.09 mm and 0.49 ± 0.07 mm after fission (Fig. 2, I and II). In culture using the Condition 2, maintained under indirect solar illumination, some cyanobacteria grew and the worms developed three, four or five zooids (Fig. 2, III and IV). In this analysis, a total of 53 specimens were observed. Following this observation, we also characterized the development of this strain in a medium supplemented with cyanobacteria. The larger worms were those with five zooids and an average size of 1.03 ± 0.05 mm. After paratomy, the size of the worms with one zooid, which were formed from chains of multiple zooids, was 0.45 ± 0.03. An absence of perturbation in the culture flasks is a necessary condition for the growth of more than two zooids. When the culture is agitated, such as when collecting worms using a pipette, the development of multiple zooids is interrupted, and as a consequence the two zooid pattern of paratomy returns. For this reason, we were not able to determine the time necessary for paratomy with multiple zooids, once the transferring to a Kline slide promotes a change of the reproduction pattern of multiple zooids to two zooids.

FIGURE 1: The
frequency of fission in Stenostomum leucops under Conditions 1. The percentage of zooids formed is shown on the Y-axis. The X-axis shows the time (in hours) required for fission to occur.

FIGURE 2:
General view of Stenostomum leucops showing one zooid (I), two zooids (II), three zooids (III) and five zooids (IV). cp = ciliated pits; cg = cerebral ganglia; pg = pharyngeal glands.

The cell number estimate for worms with one zooid growing in Condition 1, soon after paratomy, is approximately 2,500. The number of cells in two zooid worms preceding the fission is approximately 5,000. As seen in Table 1, for worms growing in medium supplemented with cyanobacteria (Condition 2), the number of cells in animals with one, two, three and four zooids increases by 2,000 cells for each zooid formed. This suggests that the number of cells necessary to form one zooid is approximately 2,000.

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TABLE 1:
Estimates of cell number in worms with 1, 2, 3 and 4 zooids growing in cultivation Procedure 1 and Procedure 2 (average ± standard deviation).

DNA Barcoding

Using the available Stenostomum COI sequences, the phylogenetic analysis conducted through neighbor-joining showed that both S. leucops and S. grande, constitute a complex of species sincespecimens of S. leucops, from Sweden, grouped with a specimen of S. grande, from Japan, while specimens of S. leucops, from Brazil and London, grouped in a clade including a representative of S. grande, from Brazil (Fig. 3). A similar tree was obtained by maximum likelihood (data not shown). These analyses indicate that the two nominal species S. leucops and S. grande are polyphyletic. The estimates of evolutionary divergence using P distance were very small within the sequences of S. leucops from Sweden (zero to 0.004). However, larger distances were observed between these sequences and those collected in Sweden and the south of Brazil (approximately 0.14) as well as between the samples from Brazil and London (0.127) (Table 2). The distance found between the S. grande from Brazil and Japan is remarkable (0.154), but the distance observed between S. grande from Brazil and S. leucops from London is lower (0.110). Similar distances were observed between S. grande from Japan and the S. leucops samples from Sweden. The P distances observed among the twelve species here studied ranged from 0.076 to 0.213.

FIGURE 3:
Molecular phylogenetic analysis by the neighbor-joining method for Cytochrome C Oxidase (COI) gene using P distance. Bootstrap values for 1000 replications are shown in the branches. Gap/missing data treatment: complete deletion. Sites analyzed: 474.

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TABLE 2:
Estimates of Evolutionary divergence between sequences, using P distance, conducted in MEGA 5.0. The number of base differences per site between sequences are shown. The analysis involved 20 nucleotidesequences. All positions containing gaps and missing data were eliminated. There were a total of 473 positions in thefinal dataset. The number after the species name correspond the last three number, of GenBank accession number, informed in Materials and Methods.

DISCUSSION

The easy cultivation, fast asexual reproduction, and regeneration are characteristics that make Stenostomum, particularly S. leucops, a potential model organism for studies of regeneration, stem cells, aging and other biological topics. However, there are very few records in the literature that describe the time necessary for the worms to proceed the natural fission. Hyman (1951)HYMAN, L.H. 1951. The invertebrates: Platyhelminthes and Rhynchocoela The acoelomate Bilateria New York, McGraw-Hill, v. 2. described the time necessary for Stenostomum to undergo paratomy as around two days. Reuter & Kuusisto (1992)REUTER, M. & KUUSISTO, A. 1992. Growth factors in asexually reproducing Catenulida and Macrostomida (Plathelminthes): A confocal, immunocytochemical and experimental study. Zoomorphology 112: 155-166. noted that the time required for a new zooid development in both S. leucops and Microstomum lineare Müller OF, 1773 varied from 20 to 45 h owing to environmental factors. These studies do not describe the conditions under which the time required for paratomy was determined. Our results showed that the worms required 42.5 hours to carry out the fission at 28°C.

No records were found in the literature for the number of cells that make up Stenostomum. For Catenulida, Simanow et al. (2012)SIMANOW, D.; MELLAART-STRAVER, I.; SORMACHEVA, I. & BERIZIKOV, E. 2012. The flatworm Macrostomum lignano is a powerful model organism for ion channel and stem cell research. Stem Cells International (2012): 1-10, ID 167265, doi: 10.1155/2012/167265.
https://doi.org/10.1155/2012/167265... reported that Macrostomum lignano consists of approximately 25,000 cells. This worm is approximately 1.5 mm long, which is about three times larger than the worms used in our study. The number of cells found in S. leucops soon after paratomy is approximately 2.500 and, if an adjustment to the length of the body is applied between S. leucops and M. lignano, it can be estimated that S. leucops has 30% of the cells found in M. lignano. Nevertheless, Caenorhabditis elegans, a nematode similar in size to S. leucops, has fewer cells, 959 in the adult hermaphrodite and 1031 in the adult male (Sulston & Horvitz, 1977SULSTON, J.E. & HORVITZ, H.R. 1977. Post-embryonic cell lineages of the nematode, Caenorhabditis elegans. Developmental Biology 56: 110-56.). A small number of cells was a useful characteristic for transforming C. elegans into one of the most prestigious animal models, as it allows precise descriptions of development; for example, it was the first organism to have its connectome (neural wiring diagram) completed (White et al., 1986WHITE, J.G.; SOUTHGATE, E.; THOMSON, J.N. & BRENNER, S. 1986. The structure of the nervous system of the nematode Caenorhabditis elegans. Philosophical Transations of the Royal Society of London, B Biological Sciences 314: 1-340.). The small number of cells observed in Stenostomum may also be important to the usefulness of these worms as models for biological studies.

Although the number of zooids is not a diagnostic characteristic for Stenostomum species identification, this characteristic is always cited in the descriptions of species of this genus (Van Cleave, 1929VAN CLEAVE, C.D. 1929. An experimental study of fission and reconstitution in Stenostomum. Physiological Zoology Chicago, 2: 18-58.; Nuttycombe & Waters 1938NUTTYCOMBE, J. & WATERS, A. 1938. The American species of the genus Stenostomum. Proceedings of the American Philosophical Society 79: 213-301.; Noreña et al., 2005NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58.; Damborenea et al., 2011DAMBORENEA, C.; BRUSA, F.; ALMAGRO, I. & NOREÑA, C. 2011. A phylogenetic analysis of Stenostomum and its neotropical congeners, with a description of a new species from the Peruvian Amazon Basin. Invertebrate Systematics 25: 155-169.; Gamo & Leal-Zanchet, 2004GAMO, J. & LEAL-ZANCHET, A.M. 2004. Freshwater microturbellarians (Platyhelminthes) from Rio Grande do Sul, Brazil. Revista Brasileira de Zoologia 21: 897-903.). Van Der Land (1965)VAN DER LAND, J. 1965. Notes on microturbellaria from freshwater habitats in the Netherlands. Zooologische Mededelingen 40: 235-251., Gamo & Leal-Zanchet (2004)GAMO, J. & LEAL-ZANCHET, A.M. 2004. Freshwater microturbellarians (Platyhelminthes) from Rio Grande do Sul, Brazil. Revista Brasileira de Zoologia 21: 897-903. and Noreña et al. (2005)NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58. describe S. leucops as having only two zooids. On the other hand, Van Claeve (1929) and Palmberg (1990)PALMBERG, I. 1990. Stem cells in microturbellarians an autoradiographic and immunocytochemical study. Protoplasma 158: 109-120. report that the worms they studied showed multiple zooids (up to five), but do not described the conditions under which these animals were cultivated. Our data show that zooid number is a plastic phenotype and is highly dependent on environmental conditions. We have maintained our cultures for four years and have only observed two zooids. During this time, we were led to think that it was a characteristic of the species, but along the fifth year, the alteration of culture conditions resulted in worms with multiple zooids. This phenotypic plasticity could explain the differences in the descriptions from various authors. Our results suggest that the reproductive pattern with multiple zooids occurs only when the worms are in Condition 2 of maintenance. Even in this condition, disturbance in the cultures, as pipetting the worms, promote the changes of reproductive patterns from multiple for two zooids.

The number of cells in each zooid in worms with multiple zooids is smaller than that observed in animals with only two zooids, approximately 2,000 for the former and 2,500 for the latter on average. Furthermore, the size of worms with two zooids, originated from the fission process of two zooids, is similar to that observed in worms with four or five zooids produced, approximately 1 mm long. Nevertheless, the number of cells in these animals is very different. The two-zooid worms have approximately 5,000 cells compared to 7,000 cells in animals with four zooids. It is likely that some of the cells present in the four or five zooid worms are smaller. This could indicate a faster reproductive process in animals producing multiple zooids. However, as we are not able to measure the time required in paratomy in multiple zooids process, this hypothesis needs additional assays to be clarified.

Stenostomum leucops is distributed worldwide, with registers for North America, Europe, Africa (Larsson, 2008LARSSON, K. 2008. Taxonomy and phylogeny of Catenulida (Platyhelminthes) with emphasis on the Swedish Fauna. Acta Universitatis Upsaliensis 2008: 1-48. (Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Science and Technology 395). and references therein) and Japan (Yamazaki et al., 2012YAMAZAKI, M.; ASAKAWA, S.; MURASE, J. & KIMURA, M. 2012. Phylogenetic diversity of microturbellarians in Japanese rice paddy fields, with special attention to the genus Stenostomum Soil Science and Plant Nutrition, 58: 11-23.). In South America, it has been recorded from Surinam (Van der Land, 1965VAN DER LAND, J. 1965. Notes on microturbellaria from freshwater habitats in the Netherlands. Zooologische Mededelingen 40: 235-251.), Argentina (Noreña et al., 1995NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58.), Peru (Damborenea et al., 2011DAMBORENEA, C.; BRUSA, F.; ALMAGRO, I. & NOREÑA, C. 2011. A phylogenetic analysis of Stenostomum and its neotropical congeners, with a description of a new species from the Peruvian Amazon Basin. Invertebrate Systematics 25: 155-169.) and the South Brazilian State Rio Grande do Sul (Gamo & Leal-Zanchet 2004GAMO, J. & LEAL-ZANCHET, A.M. 2004. Freshwater microturbellarians (Platyhelminthes) from Rio Grande do Sul, Brazil. Revista Brasileira de Zoologia 21: 897-903., Braccini & Leal-Zanchet, 2013BRACCINI, J.A.L. & LEAL-ZANCHET, A.M. 2013. Turbellarian assemblages in freshwater lagoons in southern Brazil. Invertebrate Biology 132: 305-314. and in this study). As mentioned previously, the validity of this species has been questioned by Nuttycombe & Waters (1938)NUTTYCOMBE, J. & WATERS, A. 1938. The American species of the genus Stenostomum. Proceedings of the American Philosophical Society 79: 213-301. and Marcus (1945)MARCUS, E. 1945. Sobre Microturbelários do Brasil. Comunicaciones Zoologicas del Museo de Historia Natural de Montevideo 1: 1-74. who consider the descriptions of this species ambiguous and broad to make its recognition difficult. Molecular analyses performed by Larsson et al. (2008)LARSSON, K.; AHMADZADEH, A. & JONDELIUS, U. 2008. DNA taxonomy of Swedish Catenulida (Platyhelminthes) and a phylogenetic framework for catenulid classification. Organisms, Diversity & Evolution 8: 399-412. for Swedish Catenulida showed that the nominal species S. leucops is strongly supported as monophyletic group. However, the authors noted that variation in the branch lengths may be evidence for ongoing cladogenesis of some S. leucops populations, which makes it a candidate for a species complex. Yamazaki et al. (2012)YAMAZAKI, M.; ASAKAWA, S.; MURASE, J. & KIMURA, M. 2012. Phylogenetic diversity of microturbellarians in Japanese rice paddy fields, with special attention to the genus Stenostomum Soil Science and Plant Nutrition, 58: 11-23. performed a phylogenetic analysis for Japanese Stenostomum and included sequences of S. leucops from Europe. They found that a sequence of S. grande from Japan was included in the cluster of S. leucops from Europe. Our phylogenetic analysis of the available Stenostomum COI sequences showed that S. leucops and S. grande constitute a species complex. This is supported by by the high genetic divergence observed among sequences from same species. In S. leucops, the P distance among samples from Sweden, London and Brazil have the same range as observed among the species here sampled, strongly suggesting it is a species complex, as previously noted by Larsson et al. (2008)LARSSON, K.; AHMADZADEH, A. & JONDELIUS, U. 2008. DNA taxonomy of Swedish Catenulida (Platyhelminthes) and a phylogenetic framework for catenulid classification. Organisms, Diversity & Evolution 8: 399-412.. Although the status of S. grande as a valid species has never been questioned, the results of our phylogenetic analyses and the large genetic distance observed between the COI sequences of S. grande from Japan and Brazil suggest that it may also be a candidate for a species complex.

Since it was proposed, DNA Barcoding has allowed the increase of cryptic species discovery, even for species that are not distinguishable morphologically. For some examples see Gill et al. (2014)GILL, B.A.; HARRINGTON, R.A.; KONDRATIEFF, B.C.; ZAMUDIO, K.R.; POFF; N.L. & FUNK, W.C. 2014. Morphological taxonomy, DNA barcoding, and species diversity in southern Rocky Mountain headwater streams. Freshwater Science 33: 288-301., Crawford et al. (2012)CRAWFORD, A.J.; CRUZ, C.; GRIFFTH, E.; ROSS, H.; IBÁÑEZ, R.; LIPS, K.R.; DRISKELL, A.C.; BERMINGHAM, E. & CRUMP, P. 2012. DNA barcoding applied to ex situ tropical amphibian conservation programme reveals cryptic diversity in captive populations. Molecular Ecology Resources 13: 1005-1018., Clare et al. (2011)CLARE, E.L.; LIM, B.K.; FENTON, M.B. & HEBERT, P.D.N. 2011. Neotropical Bats: estimating species diversity with DNA Barcodes. PLoS ONE 6: e22648., Hebert et al. (2004)HEBERT, P.D.N.; PENTON, E.H.; BURNS, J.M.; JANZEN, D.H. & HALLWACHS, W. 2004. Ten species in one: DNA barcoding reveals cryptic species in the neotropical skipper butterfly Astraptes fulgerator. Proceedings of the National Academy of Sciences, United States of America 101: 14812-14817..

We were not able to find morphological features distinguishing the internal groups in the species complex and thus we did not propose any taxonomic change for S. leucops and S. grande.

Stenostomum leucops, while putatively a species complex, has many characteristics that make it an excellent organism for these comparative studies, mainly with planarians. However, as these worms have a simple anatomy and few diagnostic characters to allow the species identification, DNA barcoding can be a good supplementary tool for the characterization of these species for those who are thinking in using these animals as experimental models.

ACKNOWLEDGEMENTS

We thank Dr. Sandro Santos for introducing us to the Catenulida's world, Dr. Lizandra Robe for critical comments on the manuscript, and the anonymous reviewer for valuable suggestions. This study was supported by research grants and fellowships from CNPq-Conselho Nacional de Desenvolvimento Científico e Tecnológico, Pq 303244/2010-0, PIBIC/UFSM and Fapergs (Probic/UFSM) and PRONEX FAPERGS (10/0028-7).

REFERENCES

ALBU, M.; NIKBAKHT, H.; HAJIBABAEI, M. & HICKEY, D.A. 2010. The DNA Barcode Linker. Molecular Ecology Resources 11: 84-88.
ANTONIAZZI, M.M. & SILVEIRA, M. 1996. Studies of Stenostomum grande Child, 1902 (Platyhelminthes, Catenulida): fine structure of the digestive tract and the endocytotic activity of the gastrodermis. Acta Zoologica Stockholm, 77: 25-32.
BRACCINI, J.A.L. & LEAL-ZANCHET, A.M. 2013. Turbellarian assemblages in freshwater lagoons in southern Brazil. Invertebrate Biology 132: 305-314.
CHILD, C.M. 1900. Fission and regulation in Stenostomum leucops. Biological Bulletin 2(6): 329-331, 1901. (Meeting of the American Morphological Society. Abstracts of Papers, 27-28 december, Baltimore).
CHILD, C.M. 1902. Studies on regulation. Archiv für Entwicklungsmechanik der Organismen 15: 187-234.
CLARE, E.L.; LIM, B.K.; FENTON, M.B. & HEBERT, P.D.N. 2011. Neotropical Bats: estimating species diversity with DNA Barcodes. PLoS ONE 6: e22648.
COLLINS, R.A. & CRUIKSHANK, R.H. 2013. The seven deadly sins of DNA barcoding. Molecular Ecology Resources 13: 969-975.
CRAWFORD, A.J.; CRUZ, C.; GRIFFTH, E.; ROSS, H.; IBÁÑEZ, R.; LIPS, K.R.; DRISKELL, A.C.; BERMINGHAM, E. & CRUMP, P. 2012. DNA barcoding applied to ex situ tropical amphibian conservation programme reveals cryptic diversity in captive populations. Molecular Ecology Resources 13: 1005-1018.
DAMBORENEA, C.; BRUSA, F.; ALMAGRO, I. & NOREÑA, C. 2011. A phylogenetic analysis of Stenostomum and its neotropical congeners, with a description of a new species from the Peruvian Amazon Basin. Invertebrate Systematics 25: 155-169.
DUGÈS, A. 1828. Recherches sur l'organisation et les moeurs des planariees. Annales des sciences naturelles 15: 139-182.
GAMO, J. & LEAL-ZANCHET, A.M. 2004. Freshwater microturbellarians (Platyhelminthes) from Rio Grande do Sul, Brazil. Revista Brasileira de Zoologia 21: 897-903.
GILL, B.A.; HARRINGTON, R.A.; KONDRATIEFF, B.C.; ZAMUDIO, K.R.; POFF; N.L. & FUNK, W.C. 2014. Morphological taxonomy, DNA barcoding, and species diversity in southern Rocky Mountain headwater streams. Freshwater Science 33: 288-301.
GRAHN, M.; MAULE, A.G.; ELO, I.; SHAW, C.; REUTER, M. & HALTON, D.W. 1995. Antigenicity to neuropeptide-f (NPF) in Stenostomum leucops and Microstomum lineare. Hydrobiologia 305: 307-308.
HARTMANN, M. 1922. Uber den dauernden Ersatz der ungeschlechtlichen Fortpflanzung durch fortgesetzte Regenerationen. Biologisches Zentralblatt 42: 364-381.
HEBERT, P.D.N.; CYWINSKA, A.; BALL, S.L. & DE WAARD, J.R. 2003. Biological identifications through DNA barcodes. Proceedingsof the Royal Society of London. B, Biological Science 270: 313-321.
HEBERT, P.D.N.; PENTON, E.H.; BURNS, J.M.; JANZEN, D.H. & HALLWACHS, W. 2004. Ten species in one: DNA barcoding reveals cryptic species in the neotropical skipper butterfly Astraptes fulgerator. Proceedings of the National Academy of Sciences, United States of America 101: 14812-14817.
HYMAN, L.H. 1951. The invertebrates: Platyhelminthes and Rhynchocoela The acoelomate Bilateria New York, McGraw-Hill, v. 2.
KNAKIEVICZ, T.; VIEIRA, S.M.; ERDTMANN, B. & FERREIRA, H.B. 2006. Reproduction modes and life cycle of freshwater planarians (Platyhelminthes, Tricladida, Palucida) from Southern Brazil. Invertebrate Biology 125: 212-221.
LARSSON, K. 2008. Taxonomy and phylogeny of Catenulida (Platyhelminthes) with emphasis on the Swedish Fauna. Acta Universitatis Upsaliensis 2008: 1-48. (Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Science and Technology 395).
LARSSON, K.; AHMADZADEH, A. & JONDELIUS, U. 2008. DNA taxonomy of Swedish Catenulida (Platyhelminthes) and a phylogenetic framework for catenulid classification. Organisms, Diversity & Evolution 8: 399-412.
MARCUS, E. 1945. Sobre Microturbelários do Brasil. Comunicaciones Zoologicas del Museo de Historia Natural de Montevideo 1: 1-74.
MARTÍNEZ, D.E. & LEVINTON, J.S. 1992. Asexual metazoans undergo senescence. Proceedings of the National Academy of Sciences, United States of America 86: 9920-9923.
NANDINI, S. & SARMA, S.S.S. 2013. Demographic characteristic of cladocerans subject to predation by the flatworm Stenostomum leucopsHydrobiologia 715: 159-168.
NANDINI, S.; SARMA, S.S.S. & DUMONT, H.J. 2011. Predatory and toxic effects of the turbellarian (Stenostomum cf. leucops) on the population dynamics of Euchlanis dilatata, Plationus patulus (Rotifera) and Moina macrocopa (Cladocera). Hydrobiologia 662: 171-177.
NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58.
NUTTYCOMBE, J. & WATERS, A. 1938. The American species of the genus Stenostomum. Proceedings of the American Philosophical Society 79: 213-301.
OLIVEIRA, L.F.V.; WALLAU, G.L. & LORETO, E.L.S. 2009. Isolation of high quality DNA: a protocol combining rennet and glass milk. Electronic Journal of Biotechnology 12: 1-6.
PALMBERG, I. 1990. Stem cells in microturbellarians an autoradiographic and immunocytochemical study. Protoplasma 158: 109-120.
PALMBERG, I. & REUTER, M. 1992. Sensory receptors in the head of Stenostomum leucops. 1. Presumptive photoreceptors. Acta Biologica Hungarica 43: 259-267.
REUTER, M. & KUUSISTO, A. 1992. Growth factors in asexually reproducing Catenulida and Macrostomida (Plathelminthes): A confocal, immunocytochemical and experimental study. Zoomorphology 112: 155-166.
REUTER, M.; JOFFE, B. & PALMBERG, I. 1993. Sensory receptors in the head of Stenostomum leucops. II localization of catecholaminergic histofluorescence-ultrastructure of surface receptors. Acta Biologica Hungarica 44: 125-131.
RITTER, W.E. & CONGDON, E.M. 1900. On the inhibition by artificial section of the normal fission plane in Stenostoma. Proceedings California Academy of Sciences 2: 365.
RUHL, L. 1927. Regeneration in rhabdocoeles. Zoologischer Anzeiger 72: 160-175.
RUPPERT, E.E. & SCHREINER, S.P. 1980. Ultrastructure and potential significance of cerebral light-refracting bodies of Stenostomum virginianum (Turbellaria, Catenulida). Zoomorphology 96: 21-31.
SIMANOW, D.; MELLAART-STRAVER, I.; SORMACHEVA, I. & BERIZIKOV, E. 2012. The flatworm Macrostomum lignano is a powerful model organism for ion channel and stem cell research. Stem Cells International (2012): 1-10, ID 167265, doi: 10.1155/2012/167265.
» https://doi.org/10.1155/2012/167265
SULSTON, J.E. & HORVITZ, H.R. 1977. Post-embryonic cell lineages of the nematode, Caenorhabditis elegans. Developmental Biology 56: 110-56.
TAMURA, K.; PETERSON, D.; PETERSON, N.; STECHER, G.; NEI, M. & KUMAR, S. 2011. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Molecular Biology and Evolution 28(10): 2731-2739.
TELFORD, M.J.; HERNIOU, E.A.; RUSSELL, R.B. & LITTLEWOOD, T.J. 2000. Changes in mitochondrial genetic codes as phylogenetic characters: two examples from the flatworms. Proceedings of the National Academy of Sciences, United States of America 97: 11359-11364.
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VAN CLEAVE, C.D. 1929. An experimental study of fission and reconstitution in Stenostomum. Physiological Zoology Chicago, 2: 18-58.
VAN DER LAND, J. 1965. Notes on microturbellaria from freshwater habitats in the Netherlands. Zooologische Mededelingen 40: 235-251.
WHITE, J.G.; SOUTHGATE, E.; THOMSON, J.N. & BRENNER, S. 1986. The structure of the nervous system of the nematode Caenorhabditis elegans. Philosophical Transations of the Royal Society of London, B Biological Sciences 314: 1-340.
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YAMAZAKI, M.; ASAKAWA, S.; MURASE, J. & KIMURA, M. 2012. Phylogenetic diversity of microturbellarians in Japanese rice paddy fields, with special attention to the genus Stenostomum Soil Science and Plant Nutrition, 58: 11-23.

Publication Dates

Publication in this collection
Nov 2015

History

Accepted
24 Sept 2015

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ALBU, M.; NIKBAKHT, H.; HAJIBABAEI, M. & HICKEY, D.A. 2010. The DNA Barcode Linker. Molecular Ecology Resources 11: 84-88.

[2] ANTONIAZZI, M.M. & SILVEIRA, M. 1996. Studies of Stenostomum grande Child, 1902 (Platyhelminthes, Catenulida): fine structure of the digestive tract and the endocytotic activity of the gastrodermis. Acta Zoologica Stockholm, 77: 25-32.

[3] BRACCINI, J.A.L. & LEAL-ZANCHET, A.M. 2013. Turbellarian assemblages in freshwater lagoons in southern Brazil. Invertebrate Biology 132: 305-314.

[4] CHILD, C.M. 1900. Fission and regulation in Stenostomum leucops. Biological Bulletin 2(6): 329-331, 1901. (Meeting of the American Morphological Society. Abstracts of Papers, 27-28 december, Baltimore).

[5] CHILD, C.M. 1902. Studies on regulation. Archiv für Entwicklungsmechanik der Organismen 15: 187-234.

[6] CLARE, E.L.; LIM, B.K.; FENTON, M.B. & HEBERT, P.D.N. 2011. Neotropical Bats: estimating species diversity with DNA Barcodes. PLoS ONE 6: e22648.

[7] COLLINS, R.A. & CRUIKSHANK, R.H. 2013. The seven deadly sins of DNA barcoding. Molecular Ecology Resources 13: 969-975.

[8] CRAWFORD, A.J.; CRUZ, C.; GRIFFTH, E.; ROSS, H.; IBÁÑEZ, R.; LIPS, K.R.; DRISKELL, A.C.; BERMINGHAM, E. & CRUMP, P. 2012. DNA barcoding applied to ex situ tropical amphibian conservation programme reveals cryptic diversity in captive populations. Molecular Ecology Resources 13: 1005-1018.

[9] DAMBORENEA, C.; BRUSA, F.; ALMAGRO, I. & NOREÑA, C. 2011. A phylogenetic analysis of Stenostomum and its neotropical congeners, with a description of a new species from the Peruvian Amazon Basin. Invertebrate Systematics 25: 155-169.

[10] DUGÈS, A. 1828. Recherches sur l'organisation et les moeurs des planariees. Annales des sciences naturelles 15: 139-182.

[11] GAMO, J. & LEAL-ZANCHET, A.M. 2004. Freshwater microturbellarians (Platyhelminthes) from Rio Grande do Sul, Brazil. Revista Brasileira de Zoologia 21: 897-903.

[12] GILL, B.A.; HARRINGTON, R.A.; KONDRATIEFF, B.C.; ZAMUDIO, K.R.; POFF; N.L. & FUNK, W.C. 2014. Morphological taxonomy, DNA barcoding, and species diversity in southern Rocky Mountain headwater streams. Freshwater Science 33: 288-301.

[13] GRAHN, M.; MAULE, A.G.; ELO, I.; SHAW, C.; REUTER, M. & HALTON, D.W. 1995. Antigenicity to neuropeptide-f (NPF) in Stenostomum leucops and Microstomum lineare. Hydrobiologia 305: 307-308.

[14] HARTMANN, M. 1922. Uber den dauernden Ersatz der ungeschlechtlichen Fortpflanzung durch fortgesetzte Regenerationen. Biologisches Zentralblatt 42: 364-381.

[15] HEBERT, P.D.N.; CYWINSKA, A.; BALL, S.L. & DE WAARD, J.R. 2003. Biological identifications through DNA barcodes. Proceedingsof the Royal Society of London. B, Biological Science 270: 313-321.

[16] HEBERT, P.D.N.; PENTON, E.H.; BURNS, J.M.; JANZEN, D.H. & HALLWACHS, W. 2004. Ten species in one: DNA barcoding reveals cryptic species in the neotropical skipper butterfly Astraptes fulgerator. Proceedings of the National Academy of Sciences, United States of America 101: 14812-14817.

[17] HYMAN, L.H. 1951. The invertebrates: Platyhelminthes and Rhynchocoela The acoelomate Bilateria New York, McGraw-Hill, v. 2.

[18] KNAKIEVICZ, T.; VIEIRA, S.M.; ERDTMANN, B. & FERREIRA, H.B. 2006. Reproduction modes and life cycle of freshwater planarians (Platyhelminthes, Tricladida, Palucida) from Southern Brazil. Invertebrate Biology 125: 212-221.

[19] LARSSON, K. 2008. Taxonomy and phylogeny of Catenulida (Platyhelminthes) with emphasis on the Swedish Fauna. Acta Universitatis Upsaliensis 2008: 1-48. (Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Science and Technology 395).

[20] LARSSON, K.; AHMADZADEH, A. & JONDELIUS, U. 2008. DNA taxonomy of Swedish Catenulida (Platyhelminthes) and a phylogenetic framework for catenulid classification. Organisms, Diversity & Evolution 8: 399-412.

[21] MARCUS, E. 1945. Sobre Microturbelários do Brasil. Comunicaciones Zoologicas del Museo de Historia Natural de Montevideo 1: 1-74.

[22] MARTÍNEZ, D.E. & LEVINTON, J.S. 1992. Asexual metazoans undergo senescence. Proceedings of the National Academy of Sciences, United States of America 86: 9920-9923.

[23] NANDINI, S. & SARMA, S.S.S. 2013. Demographic characteristic of cladocerans subject to predation by the flatworm Stenostomum leucopsHydrobiologia 715: 159-168.

[24] NANDINI, S.; SARMA, S.S.S. & DUMONT, H.J. 2011. Predatory and toxic effects of the turbellarian (Stenostomum cf. leucops) on the population dynamics of Euchlanis dilatata, Plationus patulus (Rotifera) and Moina macrocopa (Cladocera). Hydrobiologia 662: 171-177.

[25] NOREÑA, C.; DAMBORENEA, C. & BRUSA, F. 2005. A taxonomic revision of South American species of the genus Stenostomum O. Schmidt (Platyhelminthes: Catenulida) based on morphological characters. Zoological Journal of the Linnean Society 144: 37-58.

[26] NUTTYCOMBE, J. & WATERS, A. 1938. The American species of the genus Stenostomum. Proceedings of the American Philosophical Society 79: 213-301.

[27] OLIVEIRA, L.F.V.; WALLAU, G.L. & LORETO, E.L.S. 2009. Isolation of high quality DNA: a protocol combining rennet and glass milk. Electronic Journal of Biotechnology 12: 1-6.

[28] PALMBERG, I. 1990. Stem cells in microturbellarians an autoradiographic and immunocytochemical study. Protoplasma 158: 109-120.

[29] PALMBERG, I. & REUTER, M. 1992. Sensory receptors in the head of Stenostomum leucops. 1. Presumptive photoreceptors. Acta Biologica Hungarica 43: 259-267.

[30] REUTER, M. & KUUSISTO, A. 1992. Growth factors in asexually reproducing Catenulida and Macrostomida (Plathelminthes): A confocal, immunocytochemical and experimental study. Zoomorphology 112: 155-166.

[31] REUTER, M.; JOFFE, B. & PALMBERG, I. 1993. Sensory receptors in the head of Stenostomum leucops. II localization of catecholaminergic histofluorescence-ultrastructure of surface receptors. Acta Biologica Hungarica 44: 125-131.

[32] RITTER, W.E. & CONGDON, E.M. 1900. On the inhibition by artificial section of the normal fission plane in Stenostoma. Proceedings California Academy of Sciences 2: 365.

[33] RUHL, L. 1927. Regeneration in rhabdocoeles. Zoologischer Anzeiger 72: 160-175.

[34] RUPPERT, E.E. & SCHREINER, S.P. 1980. Ultrastructure and potential significance of cerebral light-refracting bodies of Stenostomum virginianum (Turbellaria, Catenulida). Zoomorphology 96: 21-31.

[35] SIMANOW, D.; MELLAART-STRAVER, I.; SORMACHEVA, I. & BERIZIKOV, E. 2012. The flatworm Macrostomum lignano is a powerful model organism for ion channel and stem cell research. Stem Cells International (2012): 1-10, ID 167265, doi: 10.1155/2012/167265.
» https://doi.org/10.1155/2012/167265

[36] SULSTON, J.E. & HORVITZ, H.R. 1977. Post-embryonic cell lineages of the nematode, Caenorhabditis elegans. Developmental Biology 56: 110-56.

[37] TAMURA, K.; PETERSON, D.; PETERSON, N.; STECHER, G.; NEI, M. & KUMAR, S. 2011. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Molecular Biology and Evolution 28(10): 2731-2739.

[38] TELFORD, M.J.; HERNIOU, E.A.; RUSSELL, R.B. & LITTLEWOOD, T.J. 2000. Changes in mitochondrial genetic codes as phylogenetic characters: two examples from the flatworms. Proceedings of the National Academy of Sciences, United States of America 97: 11359-11364.

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Number of Zooids	Procedure 1	Procedure 2
1	2.400 ± 280	2.158 ± 112
2	4.850 ± 325	3.964 ± 365
3	-	5.166 ± 91
4	-	7.003 ± 207

	1	2	3	4	5	6	7	8	9	10	11	12	13	14	15	16	17	18	19	20
1 S. sphagnetorum 904 Sweden
2 S. sphagnetorum 873 Sweden	0,002
3 S. simplex 120 Japan	0,076	0,078
4 S. island 901 Sweden	0,114	0,116	0,122
5 S. simplex 117 Japan	0,139	0,141	0,148	0,133
6 S. saliens 124 Japan	0,190	0,190	0,207	0,188	0,194
7 S. saliens 123 Japan	0,186	0,186	0,198	0,188	0,181	0,030
8 S. tuberculosum 122 Japan	0,175	0,177	0,188	0,173	0,188	0,105	0,108
9 S. longpich 906 Sweden	0,179	0,179	0,177	0,186	0,194	0,148	0,143	0,137
10 S. leucops SM Brazil	0,181	0,184	0,181	0,184	0,198	0,173	0,165	0,181	0,190
11 S. leucops 976 London	0,156	0,158	0,152	0,167	0,177	0,169	0,162	0,171	0,152	0,127
12 S. leucops 909 Sweden	0,184	0,186	0,173	0,181	0,177	0,196	0,192	0,196	0,175	0,143	0,124
13 S. leucops 908 Sweden	0,186	0,188	0,175	0,184	0,179	0,198	0,194	0,198	0,177	0,146	0,127	0,002
14 S. leucops 899 Sweden	0,184	0,186	0,173	0,181	0,177	0,194	0,192	0,196	0,175	0,143	0,124	0,002	0,004
15 S. leucops 898 Sweden	0,184	0,186	0,173	0,181	0,177	0,194	0,192	0,196	0,175	0,143	0,124	0,002	0,004	0,000
16 S. grande 116 Japan	0,181	0,184	0,184	0,177	0,184	0,186	0,184	0,171	0,173	0,150	0,133	0,118	0,120	0,116	0,116
17 S. grande SM Brazil	0,179	0,181	0,169	0,188	0,175	0,179	0,171	0,192	0,175	0,135	0,110	0,146	0,148	0,143	0,143	0,154
18 S. bryophilum 874 Sweden	0,184	0,181	0,177	0,181	0,213	0,194	0,196	0,190	0,181	0,177	0,171	0,186	0,188	0,186	0,186	0,190	0,194
19 S. grabbskogense 880 Sweden	0,184	0,181	0,177	0,181	0,213	0,194	0,196	0,190	0,181	0,177	0,171	0,186	0,188	0,186	0,186	0,190	0,194	0,000
20 S. grabbskogense 907 Sweden	0,184	0,181	0,177	0,181	0,213	0,194	0,196	0,190	0,181	0,177	0,171	0,186	0,188	0,186	0,186	0,190	0,1994	0,000	0,000
21 S. averaloi 910 Sweden	0,179	0,161	0,196	0,207	0,179	0,192	0,198	0,181	0,186	0,203	0,177	0,188	0,190	0,186	0,186	0,181	0,184	0,190	0,190	0,190

Brasil