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Transglutaminase activity determines nuclear localization of serotonin immunoreactivity in the early embryos of invertebrates and vertebrates Evgeny Ivashkin, Victoria Melnikova, Anastasia Kurtova, Nadja Brun, Alexandra Obukhova, Marina Yu. Khabarova, Alexander Yakusheff, Igor Adameyko, Kristin E. Gribble, and Elena E. Voronezhskaya ACS Chem. Neurosci., Just Accepted Manuscript • DOI: 10.1021/acschemneuro.9b00346 • Publication Date (Web): 10 Jul 2019 Downloaded from pubs.acs.org on July 17, 2019
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Transglutaminase activity determines nuclear localization of serotonin immunoreactivity in the early embryos of invertebrates and vertebrates
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Evgeny Ivashkin1,2,3,#, Victoria Melnikova1, Anastasia Kurtova1, Nadja R. Brun4, Alexandra Obukhova1, Marina Yu. Khabarova1, Alexander Yakusheff1, Igor Adameyko2,5, Kristin E. Gribble3, Elena E. Voronezhskaya1,#
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1Department
of Developmental and Comparative Physiology, Koltsov Institute of Developmental Biology, Russian Academy of Sciences, 119334 Moscow, Russia
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2Department
corresponding authors:
[email protected],
[email protected] 10 11
3Josephine
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4Department
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5Department
of Physiology and Pharmacology, Karolinska Institutet, 171 77 Stockholm, Sweden
Bay Paul Center for Comparative Molecular Biology and Evolution, Marine Biological Laboratory, 02543 Woods Hole, MA, USA of Biology, Woods Hole Oceanographic Institution, 02543 Woods Hole, MA, USA
of Molecular Neurosciences, Center of Brain Research, Medical University of Vienna, A-1090 Vienna, Austria
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Abstract
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Serotonin (5-HT) is a key player in many physiological processes both in the adult organism and developing embryo. One of the mechanisms for 5-HT-mediated effects is covalent binding of 5HT to the target proteins catalyzed by transglutaminases (serotonylation). Despite the implication in a variety of physiological processes, the involvement of serotonylation in embryonic development remains unclear. Here we tested the hypothesis that 5-HT serves as a substrate for transglutaminase-mediated transamidation of the nuclear proteins in the early embryos of both vertebrates and invertebrates.
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For this, we demonstrated that the level of serotonin immunoreactivity (5-HT-ir) in cell nuclei increases upon the elevation of 5-HT concentration in embryos of sea urchins, mollusks, and teleost fish. Consistently, pharmacological inhibition of transglutaminase activity resulted in the reduction of both brightness and nuclear localization of anti-5-HT staining.
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We identified specific and bright 5-HT-ir within nuclei attributed to a subset of different cell types: ectodermal and endodermal, macro- and micromeres, and blastoderm. Western blot and dot-blot confirmed the presence of 5-HT-ir epitopes in the normal embryos of all the species examined. The experimental elevation of 5-HT level led to the enhancement of 5-HT-ir-related signal on blots in a species-specific manner.
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The obtained results demonstrate that 5-HT is involved in transglutaminase-dependent monoaminylation of nuclear proteins and suggest nuclear serotonylation as a possible regulatory mechanism during early embryonic development. The results reveal that this pathway is conserved in the development of both vertebrates and invertebrates.
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Keywords: serotonylation, nucleus, early development, mollusks, sea urchins, zebrafish
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Introduction
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Serotonin (5-hydroxytryptamine, 5-HT),a neurotransmitter and neurohumoral (endo- and paracrine) substance, is involved in the regulation of a remarkable variety of biological processes throughout all animal phyla 1. During the individual development of animals, 5-HT participates in a number of neuronal and non-neuronal processes including cell proliferation and differentiation. 5-HT and 5-HT-related proteins are produced during cleavage and gastrula developmental stages of different animals ranging from a plethora of invertebrates to mammals.
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Previously, the efforts of different laboratories revealed that changes in the level of early 5-HT or pharmacological/genetic modulations of serotonin receptors and transporters lead to various developmental malformations including disturbances of cell divisions or even a complete cell cycle arrest 2–8. However, the intracellular molecular mechanisms of the observed effects remain mostly unknown. Antidepressants, many of which are serotonin-specific reuptake inhibitors, may result in teratogenic effects in pregnant women 9,10. Additionally, the ubiquitous distribution of many industrial chemicals is associated with neurotoxic effects in the developing embryo 11,12. While numerous studies have improved our understanding of the role of 5-HT in neural stages of development, the roles and mechanisms of pre-neural serotonin remain enigmatic. All this makes the early 5-HT of special interest in reproductive technologies and developmental biology.
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Growing evidence suggests that the canonical effects of monoamines via extracellular ligand-receptor interactions are accompanied by the wide involvement of monoamines in intracellular regulation via posttranslational modifications of proteins. Unlike in a classical scenario of 5-HT action, the latter process requires 5-HT to be inside of the cells and includes the transglutaminase-mediated binding of monoamines to glutamine residues in target peptides (transamidation) 1.
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In some cases, protein serotonylation (or generally monoaminylation) may lead to the formation of an active or inactive molecule that remains stable until its proteolytic degradation 13. The described pathway has been confirmed to be important for regulating various physiological functions, including activation of platelet aggregation, insulin release, long term smooth muscle contraction, reorganization of dendritic spines in neurons, and many other processes 14. Recently, we have shown that monoaminylation occurs not only in an adult organism but also during embryonic development. Serotonylation of proteins in the early embryo mediates 5-HT-dependent maternal effects during the development of a freshwater snail Lymnaea stagnalis 15.
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Consistent with the fact that nuclei contain thousands of regulatory proteins, the tissue transglutaminase (also known as transglutaminase 2, TG2) appears to be localized and active in the nuclei of different cells. Nuclear TG2 promotes post-translational modifications of transcriptional factors and other related proteins, which has a direct impact on gene expression 16. At the same time, an enigmatic presence of 5-HT within the cell nuclei has been registered in a number of early works using electron-microscopy and autoradiography techniques. Moreover, application of the radioactively marked 5-HT or its biochemical precursor 5-hydroxytryptophan (5HTP) revealed strong localization of the signal within the cell nuclei, perinuclear space or even in condensed chromosomes 17–22. Later, the immunochemical techniques also demonstrated the presence of 5-HT-immunoreactivity in adult neuronal and immune cell nuclei. These observations were confirmed by both fluorescent immunohistochemistry (IHC) and immunogold IHC combined with electron microscopy 23–25 as well as by direct identification of histone serotonylation in a recent study 26.
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In this study, we addressed the evolutionarily conserved role of transglutaminase activity in the nuclear localization of serotonin during early embryonic development of sea urchins, mollusks and teleost fish embryos. The regulated activity of transglutaminase might be important for specific developmental transitions and epigenetically defined adaptations to postnatal life15.
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Results
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Sea Urchins. Echinoderms and particularly sea urchins are known as a classical model system widely used for investigating the early pre-neural neurotransmitter functions 27,7. We analyzed embryos of sea urchins Mesocentrotus nudus, Scaphechinus mirabilis and Paracentrotus lividus at blastula and gastrula stages to assay localization of 5-HT immunoreactivity (5-HT-ir). Sea urchin blastula represents a hollow sphere made of ciliated monolayer epithelium. M. nudus and P. lividus blastula cells exhibited positive 5-HT-ir within the nuclei of all epithelial cells (Fig. 1A1, A4; Fig 1N, O, P). Application of the 5-HT precursor 5-HTP to the embryo medium significantly enhanced the brightness of staining (Fig. 1B1, B4, D) but did not change its pattern (Fig. 1B1- B4), whereas inhibition of the transglutaminase activity by monodansylcadaverine (MDC) diminished brightness of staining (Fig. 1C1, C4, D). Colocalization analysis of 5-HT-ir and a nuclear marker confirmed that most anti-5-HT staining is associated with nuclear material (Fig. 1A2-A4). The level of colocalization was noticeably higher after 5-HTP application (Fig. 3 B2- B4) and decreased after MDC treatment (Fig. 1C2- C4).
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In intact M. nudus gastrula, no bright positive 5-HT-ir was associated with nuclei of any cells (Fig. 1E, G, H), while bright 5-HT-ir spots appear at the apical region of all ectodermal cells (Fig. 1E, G). Incubation with 5-HTP resulted in an increased level of 5-HT-ir in all cells (Fig. 1F). The ectodermal cells, however, demonstrated the maximal brightness with a positive 5-HT-ir signal in nuclei (Fig. 1I), while the cells of developing archenteron (endoderm) were overall less extensively stained (Fig. 1J). Primary mesodermal cells demonstrate 5-HT-ir negative signal (Fig. 1K). A similar pattern of 5-HT-ir occurred in normal and 5-HTP-treated gastrula of S. mirabilis (Fig. 1L, M).
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We applied a set of various commercial antibodies produced in different animals: rabbit (from two different suppliers), goat polyclonal and rat monoclonal antibodies to test the specificity of 5-HT-ir labeling. Staining of P. lividus blastula revealed a similar staining pattern for all polyclonal antibodies. In all cases, the positive signal was associated with the nuclear region (Fig. 1N, O, P). Rat monoclonal antibody revealed no bright signal in nuclei (Fig. 1Q). The omission of the primary antibody, as well as pre-adsorption with BSA-5-HT conjugate, eliminated the positive signal (Fig 1R, R’).
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We incubated P. lividus blastula in another well-known transglutaminase activity blocker, cystamine, alone and in combination with 5-HTP. The effect was similar in all experimental series regardless of the antibody used. In all cases, incubation with 5-HTP resulted in a significant increase of 5-HT-ir brightness within nuclei. This outcome was negated by application of cystamine prior to 5-HTP (Fig. 1S, T, U).
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Western blot with rabbit polyclonal anti-5-HT antibody (Immunostar) revealed several bands with the most prominent weight around ~20, ~50 and ~70 kDa in the samples of M. nudus embryos. An additional band of ~35 kDa occurred after 5-HTP treatment while bands of ~20 and ~70 kDa demonstrated a visible enhancement of signal (Fig. 2A). In the blots of P. lividus embryos ~30 kDa and ~50 kDa bands are visible with three different antibodies (Fig. 2B-D). Additional bands appear around ~15, ~30, ~32 and ~70 kDa with polyclonal rabbit anti-5-HT antibody (Fig. 2B), and additional bands with weight ~35 and ~45 kDa with polyclonal goat antibody (Fig. 2C). Despite the differences between species and antibodies applied, the selected bands ACS Paragon Plus Environment
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demonstrated consistent changes in relative density after 5-HTP and cystamine treatment. Thus, the density of ~30 kDa and ~50 kDa bands exceeded control level in 5-HTP-treated samples and were lower in cystamine-treated samples (Fig. 2E). The specificity of the visualized bands was confirmed by the decrease of the positive signal in all bands after pre-adsorption of the primary antibody with BSA-5-HT conjugate. The omission of the primary and secondary antibody also confirmed the specific character of staining (Fig. 2J).
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To estimate the total pool of serotonylated peptides, we used dot-blot of P. lividus blastula samples. Measurements of integrated spot density revealed a reduction of the positive 5-HT-ir signal after cystamine treatment and consistent increase after 5-HTP treatment. When 5-HTP was applied after cystamine, the signal remained at the control level (Fig. 2F). All three antibodies demonstrated high specificity: they were bound to BSA-5-HT conjugate in a concentrationdependent manner but not with BSA alone (Fig. 2G), and the intensity of the dot spots diminished after pre-adsorption of the primary antibody with soluble BSA-5-HT (Fig. 2H). Representative samples demonstrated a consistent concentration-dependent increase in positive signal density after 5- HTP application in case of all three anti-5HT antibodies used in this experiment (Fig. 2I).
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Ε-(γ-glutamyl)-lysine bond is a well-known marker for the transglutaminase activity 28. We stained blastula of M. nudus using antibody against ε-(γ-glutamyl)-lysine to estimate the subcellular pattern of transglutaminase activity. Positive staining occurred in vesicle-like granules in the cytoplasm (Fig. 2K1). Such a pattern can be associated with autophagosomes 29. We also observed a positive signal located in the nuclei and colocalized with the nuclear marker (Fig. 2K2, K3). Application of MDC considerably suppressed both brightness of the staining and colocalization of a specific signal with the nuclear marker (Fig. 2L1- L3).
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Mollusks. To determine the evolutionary conservation of nuclear serotonin during embryonic development of different animals, we carried out experiments on the representatives of other invertebrate and vertebrate groups. We chose the mollusks as one of the candidates for two reasons: first, 5-HT has been found previously within early embryos of gastropod mollusks to have a somewhat nuclear pattern 6; and second, serotonylation has already been described in the early development of a snail 15. Based on this, we experimentally analyzed the distribution of 5-HT-ir in early cleaving embryos of a fresh-water snail Lymnaea stagnalis. The signal from anti5-HT staining in control embryos was either distributed equally in cytoplasm and nuclear volumes (Fig. 3A), or nuclei and mitotic spindles were had lower levels of staining as compared to the cytoplasm of dividing cells (Fig. 3B, C). Incubation with 5-HTP increased the general level of 5HT-ir within the entire embryo and changed the staining pattern so that the greatest anti-5-HT staining became associated with the nuclear region (Fig. 3A’), condensing chromosomes, and the mitotic spindles (Fig. 3B’). This pattern of 5-HT-ir was similar in both macro- and micromeres (Fig. 3D, E). Notably, in the case of elevated serotonin, the association of bright anti-5-HT staining signal with nuclear structures was observed regardless of the phase of the cell cycle. Bright positive 5-HT-ir was located either within the nuclear region in interphase stage or around the condensing chromosomes and along with the spindles at prophase, metaphase, anaphase, and telophase phases during cell division (Fig. 3F). Colocalization analysis confirmed a positive correlation of 5-HT-ir and nuclear marker (Fig. 3G1-G3) as well as enhancement of such colocalization in 5-HTP-treated embryos (Fig. 3H1-H3).
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Application of two different primary antibodies raised in rabbit and goat demonstrated a similar nuclear pattern of 5-HT-ir expression (Fig. 3I). The specificity of the staining was confirmed both by pre-adsorption with BSA-5-HT (Fig. 3J) and omission of the primary antibody (Fig. 3J’). with the antibody against the serotonin precursor 5-HTP revealed signal within the cell volume
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and increased intensity in all cells after 5-HTP treatment, although we observed no nucleusassociated pattern in all cases (Fig. 3K, L).
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Inhibition of transglutaminase activity by cystamine or MDC generally diminished the 5HT-ir in all possible conditions. In contrast, application of 5-HTP resulted in general enhancement of positive staining with the bright contrasted nuclei. Combined application of cystamine and 5HTP never led to nuclear localization of 5-TH-ir (Fig. 3M). Evaluation of relative 5-HT-ir brightness within nuclei demonstrated a consistent decrease of the signal level in cystamine and MDC treated preparations and an increase of staining brightness in 5-HTP-treated preparations. Combined application of cystamine and 5-HTP resulted in negation of 5-HTP effect (Fig. 3M, N).
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Western blot revealed the characteristic major band with the weight of ~90 kDa (both for rabbit and goat antibodies) as well as minor bands of ~35 and ~250 kDa (rabbit polyclonal antibody, Immunostar) and 25, 55 and 60 kDa (goat antibody, Immunostar). Quantification showed a consistent increase in relative density of ~90 kDa band in samples after 5-HTP treatment (Fig. 3Q). Dot blot analysis confirmed a reduction of the positive 5-HT-ir signal after cystamine and MDC treatment and consistent increase after 5-HTP treatment. When 5-HTP was applied after cystamine and MDC, the signal remained at a level similar to that in the control (Fig. 3R, S).
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In addition to L. stagnalis, we analyzed early embryos of the marine bivalve mollusks bay mussel, Mytilus trossulus, and the Ezo giant scallop, Mizuhopecten yessoensis. In the intact embryo of both species, 5-HT-ir was either equally distributed throughout the cytoplasm and nuclear region (Fig. 4A, E) or the nuclear area was negative in contrast to the cytoplasm (Fig. 4B). Application of 5-HTP resulted in significant enhancement of staining and expression of bright 5-HT-ir in the nuclear region (Fig. 4A’, B’, F, G). In M. trossulus, this pattern was evident in an interphase nucleus while staining around the condensed chromosomes did not exceed the cytoplasm level (Fig. 4B’). In M. yessoensis, a bright signal was located around the condensing chromosomes of metaphase cells and the spindles of anaphase cells (Fig. 4G). The staining specificity was supported by omission (Fig. 4 I, J) and pre-adsorption of the primary antibody (Fig. 4I', J'). Quantification of 5-HT-ir brightness in the nuclear region confirmed the consistent increase after 5-HTP application for samples of both bivalve species (Fig. 4C, H). Western blotting of M. trossulus samples shows a characteristic band at ~40 kDa. The application of 5-HTP led to the appearance of additional bands of ~25 and ~60 kDa (Fig. 4D).
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Zebrafish. Finally, we turned to teleost zebrafish Danio rerio as an essential model of vertebrate development and analyzed 64-cell and oblong blastula stage embryos. We found that 5-HT-ir is brighter in the nuclei as compared with the cytoplasm in blastoderm cells but not in the yolk syncytial layer (YSL) of control embryos at both stages (Fig. 5A, C, D, E). 5-HTP application resulted in an enhancement of 5-HT-ir within all cells. The brightest 5-HT-ir was associated with nuclei of the blastoderm cells (Fig. 5B, F), whereas bright nuclei were never observed in YSL. The positively contrasted signal appeared in the nuclear region both in the interphase nuclei and in the cell at any phase of division (Fig. 5D-F, G). It is worth noting that we have observed neither positive nor negative contrast pattern of 5-HT-ir along with the mitotic spindles both in intact and 5-HTP treated zebrafish embryos.
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Consistently, the incubation with cystamine reduced the positive 5-HT-ir staining in the nuclei of blastoderm cells, while 5-HT application increased signal intensity as expected. Combined application of cystamine and 5-HT resulted in the diminishing of the nuclear staining pattern (Fig. 5H, I). No positive signal occurred in control preparations after omission (Fig. 5J2) or pre-adsorption of the primary antibody (Fig. 5J3). ACS Paragon Plus Environment
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Discussion
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The role of serotonin during early embryogenesis remains largely unexplored yet is of a broad interest in general developmental biology and toxicology. To summarize, our results demonstrate the presence of 5-HT-ir within the nuclear region of early embryonic cells of both invertebrate and vertebrate animals. According to our observations, the level of 5-HT-ir colocalization with nuclear material increases after elevation of 5-HT within the cytoplasm, while inhibition of transglutaminase activity reduces this nuclear-specific pattern. The nuclear localization of 5-HT-ir is prominent in all examined animals: sea urchin, mollusk and teleost fish. Distribution of nuclear 5-HT-ir is specific for different cells and tissues. In some cases, it is attributed to certain nucleus-related compartments (condensed chromosomes, perinuclear area, mitotic spindles).
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Commercially available anti-5-HT antibodies were shown to recognize other small molecules similar to 5-HT 30 and serotonylated proteins in parallel with their primary target – 5-HT itself. Such anti-5-HT antibodies are typically produced using 5-HT linked to BSA by formaldehyde fixation as an antigen. The NH2- group in the side chain of glutamine residues and primarily amine group in the molecule of 5-HT represent sites for the crosslinking during formaldehyde fixation. The resulting structure is similar to 5-HT bound to the glutamine, with transamidation in the serotonylated peptide chains. The specificity of such epitope recognition by polyclonal anti-5-HT antibodies was previously confirmed by both inhibiting and knocking out the catalyzing enzyme TG2 31,32. However, in previous studies, anti-5-HT antibody was used to assess serotonylation in blots only. In our study, we applied in vivo pharmacological inhibition of TGases activity in a combination with both IHC and blotting. The similarity of the results obtained via different methods suggests that serotonylation of proteins may have a significant impact on the brightness and pattern of anti-5-HT staining in tissues. This fact is not usually considered by the researchers who apply anti-5-HT (and highly likely other monoamines) IHC staining.
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The increased level of 5-HT in nuclei was described in different 5-HT-expressing cells in the 1970s. In hagfish and rat, 5-HT is localized in fibroblast nuclei after incubation with tritiated 5HT 18. Later, the presence of serotonin and other monoamines was shown in the nuclei of various cells such as immune cells, peritoneal mast cells, and adrenal medulla cells of mammals 22–24. These studies have also highlighted the role of serotonin synthesis, transport and catabolism on the nuclear pattern of 5-HT subcellular localization. In addition to differentiated tissues, 5-HT-ir expression was noted in the nuclei of early embryos as well. For example, the electronmicroscope autoradiographs have shown nuclear localization of serotonin in the 2-4-cell embryos of a polychaete supplied with 3H-5-HTP 17. However, despite the descriptive evidence of the nuclear localization of serotonin and its association with intranuclear structures in early embryos, the possible mechanisms of such patterns have not been previously extensively investigated. Our results clearly indicate that TGase activity has a large impact on the nuclear localization of 5HT-ir. Nevertheless, despite presence of 5-HT in early embryos of a wide range of animal taxa, the nuclear localization pattern of 5-HT has some exceptions. In normal mouse cleaving embryos, 5-HT preferentially occupies cytoplasm. A ring-like 5-HT positive staining was observed around the nucleus in some embryos only 33, while after the elevation of intracellular 5-HT, anti-5-HT immunostaining was distributed uniformly both within cytoplasm and nucleus 34. We also could see obvious diversity in the level and pattern of nuclear transglutaminase-dependent 5-HT-ir both among our objects and between different cells of the same embryo. The meaning and origination of these differences require further study.
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Nuclear localization of TG2 itself was reported for a number of cell types in mammals. Soon after the first description, the capability of transglutaminase activity to mediate nuclear conjugation of polyamines was found in the cells of regenerating liver 35. The authors performed isolation of nuclei from rat livers and described increased incorporation of polyamines after partial hepatectomy. In later works, nuclear localization of transamidation activity was directly demonstrated by using in situ technique 36. In the following years, numerous works confirmed that up to 10% of TG2 activity is localized within nucleus volume in the TG2 expressing cells 16. For the case of invertebrates, it is known that immunohistochemistry reveals a strong nuclear pattern of TG2 localization in sea urchin embryonic cells. A variety of nuclear proteins such as E2F1, hypoxia-inducible factor 1 and Sp1 are the targets for transglutaminases 16. Other important nuclear substrates for transglutaminases are histones. TG2 is involved in the crosslinking of the H2A, H2B, H3 and H4 histones in vertebrates 37 and invertebrates 38,39. Histone crosslinking affects chromatin condensation in vitro and indicates the onset of apoptosis 40. Our experiments revealed a strong colocalization of 5-HT-ir with condensed chromosomes, suggesting histones are probable candidates for serotonylation in early embryos. Such a mechanism may directly contribute to pro- and antiapoptotic action of 5-HT in addition to the earlier described action via activating specific 5-HT receptors 41. Finally, in very recent work published during the revision of the current paper, serotonylation of histone H3 was described as a modification that can modulate transcription factor II D binding to H3K4me3 thus affecting permissive gene expression in serotonergic neurons 26. In our experiments, the increase of intracellular 5-HT level led to a very high brightness of anti-5-HT staining in nuclei. While the application of TGase blockers, almost completely vanished this pattern. On the other hand, in some cases, we observed transglutaminase-dependent 5-HT-ir both in the nuclei and along with the mitotic spindles during cell division. Such a high amplitude of brightness variation and the apparent variety of affected nuclear structures, suggests considerable diversity and abundance of proteins in nuclei which may be serotonylated.
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According to the existing data, TG2 has low specificity requirements to the amino acid components adjusting to glutamine in the transamidation site 42. Thus, nearly any glutamine residues can be either be (i) bound to the lysine residues, (ii) transamidated utilizing any of monoamines available, or (iii) deamidated and turned into glutamate (in cases where other substrates are lacking) if it is available for the enzyme, according to the predicted protein structure. That means the substrates for transamidation may serve as concurrent inhibitors for each other. An example of such inhibition can be represented by antagonizing action of 5-HT to Factor XIII-A-mediated plasma fibronectin matrix assembly and crosslinking in osteoblast cultures via direct competition to glutamine-lysine transamidation 43. It is also worth mentioning that enzymes with opposite activity to transamidation have not been found in eukaryotes to date. Moreover, there is abundant evidence that protein complexes generated by transamidation are highly stable. Thrombus formation during blood coagulation 44 or egg envelope formation soon after the fertilization in echinoderm, teleost and amphibian 45–47 are characteristic examples of such highly stable complexes based on the TGases’ activity. In the cases of thrombus and egg envelope, the peptides undergo degradation via proteolysis without previous glutamine-lysine unlinking 48. This is consistent with the fact that monoaminylated proteins remain stable upon ubiquitin-dependent degradation 13. Thus, the target glutamine residue in the monoaminylated protein appears locked for transamidation with other protein’s lysine. And, vice versa, the proteins crosslinked through transamidation cannot be exposed to the monoaminylation at the target site. This alternative mode of transamidation renders the monoamines as an important regulatory component of the transglutaminase-dependent molecular processes in the nucleus.
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TG2 is known to take part in a variety of processes during embryonic development. For instance, it contributes to the regulation of germinal vesicle breakdown in mouse and amphibian oocytes 49,50. Moreover, TG2 and its activity can be targeted to the germinal vesicle nucleoplasm but not to the nucleolus. This feature closely matches our observation of 5-HT-ir intranuclear distribution, especially when the 5-HT positive signal is attributed to the nuclei but is absent in nucleolus-like structures of the interphase cell (Fig.3 F, H1). Little is known about TGases functions in developmental processes during the period between oocyte maturation and later cell differentiation/organogenesis. In our previous work, we hypothesized that TGases in the zygote and pre-neural stages take part in the serotonin-mediated maternal effects 15. In mammals, TG2 is involved in the regulation of adhesion and cell migration, which play an important role in establishing the embryo-maternal interface in the trophoblasts of implanting blastocyst 51. In our previous work on L. stagnalis, we have found that increasing but not decreasing of early preneural serotonin led to delayed developmental effects. Moreover, the exogenous elevation of the 5-HT level at a certain developmental stage resulted in gastrulation abnormalities prevented by the application of transglutaminase inhibitors 15. 5-HT was found to have an important role in the establishment of left-right polarity in the early embryo of chicken and frog 52,53. This mechanism includes gradient distribution of 5-HT between blastomeres and involves 5-HT binding to histone deacetylase partner protein Mad3 54. Serotonylation of nuclear proteins also depends on the intracellular level of 5-HT within cells and can act in conjunction with this process. However, neither in mollusks 55,15 nor in echinoderms or teleost fish (unpublished data of the authors), did the treatment of zygotes, cleaving embryos or gastrulae with inhibitors of TGases demonstrate any significant disturbances of development (including violation of left-right polarity). These results reveal an overall moderating rather than a master-regulating role of serotonylation and TGases activity during early development. In line with that, serotonylation of nuclear proteins might serve as a precise and accurate regulatory mechanism interlinking any of the serotonylation-related processes in organogenesis and tissue differentiation 56–58 with early events in the development and external factors such as mother’s physiology or embryonic environment. The fact that we found serotonylation in such diverse taxa suggests this process is highly conserved among animals and underlines the important role of serotonylation in the regulation of development.
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Serotonylation-related processes largely depend on intracellular 5-HT and are known to be sensitive to the blockade of 5-HT transport activity13. In humans, treatment with serotoninspecific reuptake inhibitor antidepressants during the earliest period of pregnancy affects the expression of proteins related to cell growth, survival, proliferation, and inflammatory response 9, and additionally, may show teratogenic effects 10. Our results suggest that serotonylation of proteins in early embryos must be carefully studied in order to expand our knowledge about the action of antidepressants during early development.
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Materials & Methods
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Animals maintenance and embryos production. Adult individuals of sea urchins (Mesocentrotus nudus and Scaphechinus mirabilis) and bivalve mollusks (bay mussel Mytilus trossulus and the giant Ezo scallop Mizuhopecten yessoensis) were collected in Vostok Bay, the Sea of Japan and maintained in the laboratory conditions. Embryos of Paracentrotus lividus were obtained from the adult specimens maintained in the Resource Center for Ecological Safety Observatory, St. Petersburg University. Gastropod mollusk (Lymnaea stagnalis) and teleost fish (Danio rerio) were from laboratory culture. All animals were maintained in conditions optimal for reproduction and eggs were obtained according to standard protocols described elsewhere 59– 61,15. All the animals’ maintenance and manipulation procedures were done according to the local rules and regulations acting at the territory of the Russian Federation (for mollusks and sea urchins) or Sweden (for zebrafish).
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Pharmacological treatments. Serotonin hydrochloride (5-HT), 5-HT precursor 5-hydroxy-Ltryptophan (5-HTP) and the inhibitors of transglutaminases monodansylcadaverine (MDC) and cystamine hydrochloride (cystamine) were obtained from Sigma-Aldrich. Final concentrations were 0.25 mM for MDC, 2.5 mM for cystamine, 0.01 mM for 5-HT and 0.1 mM for 5-HTP. Incubation solutions were made from 10 mM stock solutions freshly prepared in distilled water (5HT, 5-HTP, cystamine) or DMSO (MDC). Respective DMSO concentration was used as a control and was found not to affect normal development.
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For pharmacological treatments, eggs or embryos at the respective developmental stage were transferred into 2 ml of medium and held in a dark humid chamber for 1 hour at 18±0,2 °C for bivalve mollusks, 20±0,5 °C for sea urchins, 25±0,5 °C for gastropod mollusk and 27±0,5 °C for zebrafish. Embryos from the same egg mass or fertilization event were used for every experimental trial. At least three replicates were done for each species. Embryos were washed from the incubation solutions with respective fresh medium prior fixation and proceeded to the IHC and WB protocol.
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Immunohistochemistry. IHC staining was performed according to the standard protocol for whole mount staining described earlier15. 5-HT-ir was visualized using polyclonal rabbit antibody against 5-HT (Immunostar, Hudson, USA, #20080, dilution 1:1000), polyclonal goat antibody against 5-HT (Immunostar, Hudson, USA, #20079, dilution 1:500, 1:300), polyclonal rabbit antibody against 5-HT (Sigma, USA, # S 5545, dilution 1:500), monoclonal rat antibody against 5-HT (Chemicon, USA, # MAB 352, dilution 1:300), polyclonal rabbit antibody against 5-HTP (Immunostar, Hudson, USA, # 24446, dilution 1:1000). The activity of TGases in sea urchin embryos was identified with primary antibodies against ε-(γ-glutamyl)-lysine (Abcam, # ab424, dilution 1:1000). Primary antibodies were detected with goat-anti-rabbit, donkey-anti-goat or goatanti-rat Alexa 488 or Alexa 555 conjugated IgG (Molecular Probes, USA, diluted 1:800 in PBS). Cell nuclei were stained with DAPI, Hoechst 33342 or TOTO-3 Iodide (ToTo, Thermofisher, # T3604) dye.
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The omission of primary antibodies and, alternatively, pre-adsorption of primary antibodies with BSA-5-HT conjugate (Immunostar # 20081) were used as controls. We detected no positive signals in the first case and a significant reduction of brightness in the second one.
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Imaging and analysis. For imaging, embryos were cleared in 2,2’-thiodiethanol. Imaging was performed using Zeiss LSM 510 Meta, LSM 700, LSM 780 and Leica TCS SP5 confocal systems. Z-stack projections, optical sections, fluorograms, and colocalization channel images were built using Imaris software (Bitplane).
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Western and dot-blot analysis. Western blotting was performed according to the protocol described earlier 15. In brief, the same anti-5-HT antibodies as used for IHC were applied (Immunostar, Hudson, USA, #20080, dilution 1:2500; #20079, dilution 1:1000; Sigma, USA, # S 5545, dilution 1:2000). Staining of blots with antibodies against acetylated α-tubulin (SigmaAldrich, T-6793, dilution 1:4000) was used for normalization. The secondary antibody conjugated with horseradish peroxidase to mouse or rabbit IgG (1:10000; Jackson Immunoresearch, USA) followed by detection using an ECL detection kit (Amersham Biosciences, UK) were applied for signal visualization.
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Dot-blots were made using standard protocol 62. Pieces of properly sized nitrocellulose membrane were positioned on top of a 96-well microtiter plate and placed on a light box. The round well boundaries were easily discernible on the membrane and provided a guide when applying the samples at regular distances. Two-microliter aliquots of homogenates were spotted into the centers of individual circles, membranes were dried for 10–15 min. Homogenates were diluted to the final solutions with Tris buffer. Samples were loaded in triplicate. Immunodetection was performed the same way as in Western blot analysis (described above).
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Measurements and statistical analysis. Measurement of nuclei brightness was made with Bitplane Imaris software. We used the signal of nuclear marker staining as a mask to build isosurface volumes and measured the mean brightness of 5-HT-ir signal inside of them. FIJI (ImageJ) software was used to calculate relative density of Western blot bands and the integrated density of dot-blots. Statistical analysis was performed with GraphPad Prism software. See Figure legends for the details.
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Acknowledgements
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The authors are grateful to the staff of the Vostok Biological Station of NSCMB FEB RAS, Resource Center for ESO (St. Petersburg University) and Zebrafish Core Facility of Karolinska Institutet (Stockholm, Sweden). We also thank Dr. Vyacheslav Dyachuk for the help with bivalve Western blotting. The research was done using the equipment of the Core Centrum of IDB RAS and Far East Center of Electron Microscopy of NSCMB FEB RAS. The work was supported by the Russian Science Foundation grant No. 17-14-01353.
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Author Contributions
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EI and EEV conceived and planned the experiments. EI, VM, AK, NB, and EEV carried out the experiments. AO, MYK and AY contributed to sample preparation. EI analyzed data. EI and EEV wrote the manuscript in consultation with KEG, IA and NB. EEV, IA and KEG obtained the funding. All authors provided critical feedback.
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A, E, G, H, N-Q, L – intact embryo; B, F, I-K, M – 5-HTP-treated embryo, C – embryo after application of monodansylcadaverine (MDC).
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A-C– Representative image of normal (A1, A4), 5-HTP-treated (B1, B4) and MDC-treated (C1, C4) M. nudus blastula. A2, B2, C2 –Fluorogram showing brightness of green (5-HT-ir) and blue (DAPI) channels. Dots within rectangles were selected to build colocalization images shown in A3, B3. C3. Note a higher level of colocalization within the nuclei after 5-HTP-treatment and negation of colocalization after MDC-treatment.
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D – Relative estimation of nuclear 5-HT-ir level after incubation in 5-HTP and MDC.
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E-K – Sagittal optical section of normal and 5-HTP-treated M. nudus early gastrula. Ectodermal (arrows), endodermal (double arrows) and primary mesodermal (arrowhead) cells are marked. In intact gastrula, 5-HT-ir both in ectodermal and endodermal cell nuclei does not prevail over cytoplasmic level. Note strong positive 5-HT-ir signal within ectodermal cell nuclei, unlike in endodermal and mesodermal cells of 5-HTP-treated embryos. Bright 5-HT-ir spots occur in E, F, G and I located apically to the nuclei of ectoderm cells.
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L-M – Sagittal optical section of intact and 5-HTP-treated S. mirabilis gastrula. Bright 5-HT-ir occurs in ectoderm (arrow) and endoderm (double arrows) as well as in primary mesenchyme (arrowhead) nuclei. After 5-HTP application, brightness of 5-HT-ir is more pronounced in ectodermal cell nuclei (arrow) than in endodermal (double arrows) and primary mesenchyme cells (arrowhead) nuclei.
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N-Q – Comparison of 5-HT-ir pattern in P. lividus blastula revealed by different antibody staining. All polyclonal antibodies (N-P) demonstrate positive signal in nuclei unlike monoclonal one (Q).
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R, R’ – Controls of staining specificity (rabbit polyclonal antibody, Immunostar); primary antibody omission (R) and pre-adsorption with BSA-5HT (R’).
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S-U – Relative estimation of nuclear 5-HT-ir level visualized with various antibodies after incubation in 5-HTP and cystamine.
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an – animal pole, ae – archenteron.
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D, S-U – Mean is given, box represents 25th and 75th quartile, whiskers show min and max; n=9001600 nuclei; Mann-Whitney U test; *** - p