Cholinesterasen mit Nebenjobs

Moonlighting cholinesterases in non-synaptic cholinergic mechanisms The early phylogenetic and ontogenetic appearance of acetylcholine (ACh) and its cholinergic protein components render their possible functionalities, apart from purely neuronal ones, most likely. The capacities of cholinesterases (ChEs) to form large protein complexes opened wide functional fields for them. Already existent in stem cells, ChEs in cooperation with components of the cell matrix (ECM) promote cell differentiation, whereby their enzymatic activity is (at least partially) dispensable. This is independently supported by effects of inactive AChE protein exerted in non-neuronal cells, as well as the discovery of cholinesterase-like adhesion molecules (CLAMs). Therefore, much evidence supports the conclusion that the original functionalities of cholinesterases, and, more generally of cholinergic systems, are to be sought in cell-cell-communication. Here, these views were exemplified by some in vitro and in vivo model studies. In the vertebrate retina early differentiating amacrine cells co-regulate network formation. Similarly potent are cholinergic mechanisms during skeletogenesis. ACh accelerates bone formation, and ChEs not only regulate its concentration, but exert additional structural functions. As much convincing, a study on tadpoles documented that gut formation in Xenopus laevis depends strictly on the AChE protein, but not on its enzymatic activity. A full elucidation of ChE functionalities is essential, since a multitude of anticholinesterases (ChE inhibitors) are widely applied in public life (agriculture, health, security). It is timely that cholinergic research focuses on elucidation of non-synaptic ChEs, and on analyzing non-neuronal cholinergic systems (NNCS) in general.     

Cholinesterases in development and disease

Cholinesterases (ChEs) including acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) are abundant in the nervous system and other tissues. Here we describe two different aspects of ChEs and the cholinergic system. The first aspect concerns the role of cholinergic transmission in central pattern generation in the neonatal rat spinal cord and the second one describes the involvement of ChEs in the pathologies of dystrophin-deficient mutant (mdx) mice, the animal model of Duchenne muscular dystrophy. Thus, this study is divided into two distinct parts. In the first part we show that AChE is abundant in ventral horn neurons, central canal-adjacent and partition neurons in all the observed segments (L2, L5, S1, and S2). AChE was also found in the intermediolateral and sacral parasympathetic nuclei of L2 and S1, respectively. Blocking the AChE by edrophonium produced non-stationary bursting in spinal cord preparations of developing rats. Cross-wavelet/coherence analyses of the data revealed epochs of locomotor-like activity (left-right and flexor-extensor alternation) followed by other rhythmic or non-rhythmic bursting patterns. Addition of exogenous ACh stabilized the rhythm and increased the incidence of locomotor-like pattern in the preparations. Thus, the cholinergic system in the spinal cord is capable of producing and modulating functional rhythmic bursts. Moreover, bath-applied edrophonium and exogenous ACh were found as potent means of modulation of the locomotor rhythm produced by stimulation of sacrocaudal afferents (SCAs). We show that a subclass of sacral neurons with contralateral funicular projections to the thoracolumbar cord is associated with the cholinergic system. This group of neurons may play a major role in the observed enhancement of the SCA-induced motor rhythm. In the second part we show that adult mdx-muscles are malformed with distorted neuromuscular junctions (nmjs) and impaired regulation of acetylcholine receptors. Examination of circulating ChE levels revealed that in mdx-sera, while AChE activity was elevated, BuChE activity was markedly lower than in wild-type (wt) sera. Thus, BuChE to AChE ratio in mouse sera decreased from 6:1 in wt control to 3:1 in mdx. Because serum ChE levels may be modulated by gonadal steroids, it is possible that lack of dystrophin in mdx-mice may affect this regulation. Further studies are in progress to determine the potential endocrine regulation of ChEs in circulation and at the nmjs of mdx- and wt-mice. These studies will help clarify whether the hormonal regulation is impaired in the mdx mutant, and whether changes in circulating ChE reflect or influence the functional deficits observed in excitable tissues of diseased states.     

Induction of acetylcholinesterase expression during apoptosis in various cell types

Acetylcholinesterase (AChE) plays a key role in terminating neurotransmission at cholinergic synapses. AChE is also found in tissues devoid of cholinergic responses, indicating potential functions beyond neurotransmission. It has been suggested that AChE may participate in development, differentiation, and pathogenic processes such as Alzheimer's disease and tumorigenesis. We examined AChE expression in a number of cell lines upon induction of apoptosis by various stimuli. AChE is induced in all apoptotic cells examined as determined by cytochemical staining, immunological analysis, affinity chromatography purification, and molecular cloning. The AChE protein was found in the cytoplasm at the initiation of apoptosis and then in the nucleus or apoptotic bodies upon commitment to cell death. Sequence analysis revealed that AChE expressed in apoptotic cells is identical to the synapse type AChE. Pharmacological inhibitors of AChE prevented apoptosis. Furthermore, blocking the expression of AChE with antisense inhibited apoptosis. Therefore, our studies demonstrate that AChE is potentially a marker and a regulator of apoptosis.     

Expression analysis of a novel p75(NTR) signaling protein,which regulates cell cycle progression and apoptosis

Neurotrophin receptor-interacting MAGE (NRAGE) is the most recently identified p75 neurotrophin receptor (p75(NTR)) intracellular binding protein. Previously, NRAGE over-expression was shown to mediate cell cycle arrest and facilitate nerve growth factor (NGF) dependent apoptosis of sympathetic neuroblasts in a p75(NTR) specific manner. Here we have examined the temporal and spatial expression patterns of NRAGE over the course of murine embryogenesis to determine whether NRAGE's expression is consistent with its proposed functions. We demonstrate that NRAGE mRNA and protein are expressed throughout embryonic and adult tissues. The mRNA is constitutively expressed within each tissue across development. However, expression of NRAGE protein displays a tight temporal tissue specific regulation. During early CNS development, NRAGE protein is expressed throughout the neural tube, but by later stages of neurogenesis, NRAGE protein is restricted within the ventricular zone, subplate and cortical plate. Moreover, NRAGE protein expression is limited to proliferative neural subpopulations as we fail to detect NRAGE expression co-localized with mature/differentiation associated neuronal markers. Interestingly, NRAGE's expression is not restricted solely to areas of p75(NTR) expression suggesting that NRAGE may mediate proliferation and/or apoptosis from other environmental signals in addition to NGF within the CNS. Our data support previously characterized roles for NRAGE as a mediator of precursor apoptosis and a repressor of cell cycle progression in neural development.     

Cross-Homologies and Structural Differences Between Human Cholinesterases Revealed by Antibodies Against cDNA-Produced Human Butyrylcholinesterase Peptides

To study the polymorphism of human cholinesterases (ChEs) at the levels of primary sequence and three-dimensional structure, a fragment of human butyrylcholinesterase (BuChE) cDNA was subcloned into the pEX bacterial expression vector and its polypeptide product analyzed. Immunoblot analysis revealed that the clone-produced BuChE peptides interact specifically with antibodies against human and Torpedo acetylcholinesterase (AChE). Rabbit polyclonal antibodies prepared against the purified clone-produced BuChE polypeptides interacted in immunoblots with denatured serum BuChE as well as with purified and denatured erythrocyte AChE. In contrast, native BuChE tetramers from human serum, but not AChE dimers from erythrocytes, interacted with these antibodies in solution to produce antibody-enzyme complexes that could be precipitated by second antibodies and that sedimented faster than the native enzyme in sucrose gradient centrifugation. Furthermore, both AChE and BuChE dimers from muscle extracts, but not BuChE tetramers from muscle, interacted with these antibodies. To reveal further whether the anti-cloned BuChE antibodies would interact in situ with ChEs in the neuromuscular junction, bundles of muscle fibers were microscopically dissected from the region in fetal human diaphragm that is innervated by the phrenic nerve. Muscle fibers incubated with the antibodies and with 125I-Protein A were subjected to emulsion autoradiography, followed by cytochemical ChE staining. The anti-cloned BuChE antibodies, as well as anti-Torpedo AChE antibodies, created patches of silver grains in the muscle endplate region stained for ChE, under conditions where control sera did not. These findings demonstrate that the various forms of human AChE and BuChE in blood and in neuromuscular junctions share sequence homologies, but also display structural differences between distinct molecular forms within particular tissues, as well as between similarly sedimenting molecular forms from different tissues.     

Expression and subcellular localization of a novel nuclear acetylcholinesterase protein

Acetylcholine is found in the nervous system and also in other cell types (endothelium, lymphocytes, and epithelial and blood cells), which are globally termed the non-neuronal cholinergic system. In this study we investigated the expression and subcellular localization of acetylcholinesterase (AChE) in endothelial cells. Our results show the expression of the 70-kDa AChE in both cytoplasmic and nuclear compartments. We also describe, for the first time, a nuclear and cytoskeleton-bound AChE isoform with approximately 55 kDa detected in endothelial cells. This novel isoform is decreased in response to vascular endothelial growth factor via the proteosomes pathway, and it is down-regulated in human leukemic T-cells as compared with normal T-cells, suggesting that the decreased expression of the 55-kDa AChE protein may contribute to an angiogenic response and associate with tumorigenesis. Importantly, we show that its nuclear expression is not endothelial cell-specific but also evidenced in non-neuronal and neuronal cells. Concerning neuronal cells, we can distinguish an exclusively nuclear expression in postnatal neurons in contrast to a cytoplasmic and nuclear expression in embryonic neurons, suggesting that the cell compartmentalization of this new AChE isoform is changed during the development of nervous system. Overall, our studies suggest that the 55-kDa AChE may be involved in different biological processes such as neural development, tumor progression, and angiogenesis.     

Acetylcholinesterase of Schistosoma mansoni--functional correlates. Contributed in honor of Professor Hans Neurath's 90th birthday

Acetylcholinesterase (AChE) is an enzyme broadly distributed in many species, including parasites. It occurs in multiple molecular forms that differ in their quaternary structure and mode of anchoring to the cell surface. This review summarizes biochemical and immunological investigations carried out in our laboratories on AChE of the helmint, Schistosoma mansoni. AChE appears in S. mansoni in two principal molecular forms, both globular, with sedimentation coefficients of approximately 6.5 and 8 S. On the basis of their substrate specificity and sensitivity to inhibitors, both are "true" acetylcholinesterases. Approximately half of the AChE activity of S. mansoni is located on the outer surface of the parasite, attached to the tegumental membrane via a covalently attached glycosylphosphatidylinositol anchor. The remainder is located within the parasite, mainly associated with muscle tissue. Whereas the internal enzyme is most likely involved in termination of neurotransmission at cholinergic synapses, the role of the surface enzyme remains to be established; there are, however, indications that it is involved in signal transduction. The two forms of AChE differ in their heparin-binding properties, only the internal 8 S form of the AChE being retained on a heparin column. The two forms differ also in their immunological specificity, since they are selectively recognized by different monoclonal antibodies. Polyclonal antibodies raised against S. mansoni AChE purified by affinity chromatography are specific for the parasite AChE, reacting with both molecular forms, but do not recognize AChE from other species. They interact with the surface-localized enzyme on the intact organism, and produce almost total complement-dependent killing of the parasite. S. mansoni AChE is thus demonstrated to be a functional protein, involved in multifaceted activities, which can serve as a suitable candidate for diagnostic purposes, vaccine development, and drug design.     

High aryl acylamidase activity associated with cobra venom acetylcholinesterase: Biological significance

Investigation of the non-classical functions of cholinesterases (ChEs) has been the subject of interest in the past three decades. One of which is aryl acylamidase (AAA) activity associated with ChEs, but characterized in in vitro, as an enzyme, splitting the artificial substrate o-nitroacetanilide with unknown physiological function. In the present study, we have compared levels of AAA activity of AChE from different sources like goat brain, electric eel organ and from venoms of different snakes. Remarkably cobra venom showed the highest AAA activity and also high AAA/AChE ratio. Both serotonergenic and cholinergic inhibitors inhibited the cobra venom AAA activity in a concentration dependent manner, which also underlines the association of AAA with AChE of cobra venom. The study becomes interesting because of i) the cobra venom AChE exists in monomeric globular forms; ii) in Alzheimer's disease too the most abundant forms of cholinesterases are monomeric globular forms, thought to be involved in the pathogenesis of Alzheimer's disease; iii) the effect of Alzheimer's disease drugs on the AAA activity of cobra venom, indicated that AAA activity of cobra venom was more sensitive than AChE and iv) Huperzine and Tacrine showed more pronounced effect on AAA. Thus, this study elucidates the high AAA associated with cobra venom AChE may serve as one of the prominent activity to test the pharmacological effect of AD drugs, as other sources were found to have lower activity.     

The level of butyrylcholinesterase activity increases and the content of the mRNA remains unaffected in brain of senescence-accelerated mouse SAMP8

Looking at cholinesterases (ChEs) changes in age-related mental impairment, the expression of ChEs in brain of senescence accelerated-resistant (SAMR1) and senescence accelerated-prone (SAMP8) mice was studied. Acetylcholinesterase (AChE) activity was unmodified and BuChE activity increased twofold in SAMP8 brain. SAMR1 brain contained many AChE-T mRNAs, less BuChE and PRiMA mRNAs and scant AChE-R and AChE-H mRNAs. Their content unchanged in SAMP8 brain. Amphiphilic (G(4)(A)) and hydrophilic (G(4)(H)) AChE and BuChE tetramers, besides amphiphilic dimers (G(2)(A)) and monomers (G(1)(A)) were identified in SAMR1 brain and their distribution was little modified in SAMP8 brain. Blood plasma does not seem to provide the excess of BuChE activity in SAMP8 brain; it probably arises from glial cell changes owing to astrocytosis.     

Heterologous expression of acetylcholinesterase affects proliferation and glial cytoskeleton of adherent chicken retinal cells

Besides its function at cholinergic synapses, acetylcholinesterase (AChE) exerts structural functions on neural differentiation, independent of its enzymatic activity. To elucidate such functions, we have previously heterologously expressed AChE in histotypic retinal reaggregates, revealing strong effects on their histogenesis, particularly on Müller glia processes. To further resolve these findings at a less complex cellular level, in this study we transfected adherent retinal cells of the chick embryo after 2 days i.c. with a sense pSVK3-AChErab-cDNA expression vector encoding for the entire rabbit AChE gene by calcium phosphate precipitation. Northern blots using digoxigenin (DIG)-labeled rabbit cDNA revealed a pronounced level of rabbit AChE mRNA in AChE-transfected cells. Western blot analysis established an increase in the endogenous AChE protein in transfected cells. Noticeably, AChE activity was not much affected, indicating a post-translational regulation of overall AChE activity. As a corollary, 5'-bromo-2'-deoxyuridine (BrdU) studies showed a decrease in cell proliferation. Exploring changes of the Müller glia, the cytoskeletal protein vimentin was found to be increased in transfected cells. Vimentin-stained processes are longer, thicker and more orderly arranged. In conclusion, exogenous expression of rabbit AChE in chicken retinal monolayers exerts a structural function on glial cytoskeletal organization, independent of AChE activity.     

Cholinesterases during development of the avian nervous system

1. Long before onset of synaptogenesis in the chicken neural tube, the closely related enzymes butyrylcholinesterase (BChE) and acetylcholinesterase (AChE) are expressed in a mutually exclusive manner. Accordingly, neuroblasts on the ventricular side of the neural tube transiently express BChE before they abruptly accumulate AChE while approaching the outer brain surface. 2. By exploiting AChE as a sensitive and early histochemical differentiation marker, we have demonstrated complex polycentric waves of differentiation spreading upon the cranial part of the chicken neural tube but a smooth rostrocaudal wave along the spinal cord. Shortly after expression of AChE, these cells extend long projecting neurites. In particular, segmented spinal motor axons originate from AChE-positive motoneurones; they navigate through a BChE-active zone within the rostral half of the sclerotomes before contacting BChE/AChE-positive myotome cells. At synaptogenetic stages, cholinesterases additionally are detectable in neurofibrillar laminae foreshadowing the establishment of cholinergic synapses. 3. In order to elucidate the functional significance of cholinesterases at early stages, we have investigated specific cholinesterase molecules and their mechanisms of action in vivo and in vitro. A developmental shift from the low molecular weight forms to the tetramers of both enzymes has been determined. In vitro, the addition of a selective BChE inhibitor leads to a reduction of AChE gene expression. Thus, in vivo and in vitro data suggest roles of cholinesterases in the regulation of cell proliferation and neurite growth. 4. Future research has to show whether neurogenetic functioning of cholinesterases can help to understand their reported alterations in neural tube defects, mental retardations, dementias and in some tumours.     

A monoclonal antibody against synaptic AChE: a useful tool for detecting apoptotic cells

The classical function of acetylcholinesterase (AChE) is to terminate synaptic transmission at cholinergic synapses by rapidly hydrolyzing the neurotransmitter acetylcholine (ACh). Non-classical functions of AChE involve accelerating the assembly of Abeta peptide into amyloid fibrils and participating in haematopoiesis and neurite growth. Although numerous antibodies have been raised against AChE, many researchers have questioned their reliability to identify the AChE in situ, especially with the regard to its non-classical roles. Researchers attended the Ninth International Meeting on Cholinesterase raised this question by showing different Western blot patterns of AChE detected by different Abs. Producing more effective and reliable Abs for measuring AChE in vivo or in situ has become an important issue in many scientific fields. In this paper, we introduce a monoclonal antibody raised against synaptic AChE that we identified by Western blot assays, immunofluorescent staining and immunoprecipitation of AChE, and mass spectrometry. Our results strongly demonstrate the specificity of our monoclonal antibody to recognize synaptic AChE; hence our antibody can be used as an effective tool to study the various functions of AChE. Since the apoptosis-related AChE was its synaptic form, our antibody can be used as a tool to detect apoptotic cells.     

Development of specific synaptic network functions in organotypic central nervous system (CNS) cultures: implications for transplantation of CNS neural cells in vivo

This article provides a broad overview of the significant roles that morphophysiologic analyses of organotypic cultures of neural tissues explanted in vitro-initiated during the 1950s-have played in stimulating the more recent development of techniques for transplantation of neural cells and tissues into specific regions of the central nervous system (CNS) in vivo. The demonstrations by Crain and co-workers in the 1950s and 1960s that fetal rodent and human CNS neurons can continue to develop a remarkable degree of mature structure and function during many months of complete isolation in culture provided crucial evidence that development of many organotypic properties of nerve cells is regulated by epigenetic factors that ensure rather stereotyped expression despite wide variations in environmental conditions. These in vitro studies strongly suggested that fetal neural cells should, indeed, be capable of even more highly organotypic development after transplantation in vivo, as has been elegantly demonstrated by many of the successful CNS transplantation studies reviewed here.     

Non-classical actions of cholinesterases: Role in cellular differentiation, tumorigenesis and Alzheimer''s disease

The cholinesterases are members of the serine hydrolase family, which utilizes a serine residue at the active site. Acetylcholinesterase (AChE) is distinguished from butyrylcholinesterase (BChE) by its greater specificity for hydrolysing acetylcholine. The function of AChE at cholinergic synapses is to terminate cholinergic neurotransmission. However, AChE is expressed in tissues that are not directly innervated by cholinergic nerves. AChE and BChE are found in several types of haematopoietic cells. Transient expression of AChE in the brain during embryogenesis suggests that AChE may function in the regulation of neurite outgrowth. Overexpression of cholinesterases has also been correlated with tumorigenesis and abnormal megakaryocytopoiesis. Acetylcholine has been shown to influence cell proliferation and neurite outgrowth through nicotinic and muscarinic receptor-mediated mechanisms and thus, that the expression of AChE and BChE at non-synaptic sites may be associated with a cholinergic function. However, structural homologies between cholinesterases and adhesion proteins indicate that cholinesterases could also function as cell-cell or cell-substrate adhesion molecules. Abnormal expression of AChE and BChE has been detected around the amyloid plaques and neurofibrillary tangles in the brains of patients with Alzheimer's disease. The function of the cholinesterases in these regions of the Alzheimer brain is unknown, but this function is probably unrelated to cholinergic neurotransmission. The presence of abnormal cholinesterase expression in the Alzheimer brain has implications for the pathogenesis of Alzheimer's disease and for therapeutic strategies using cholinesterase inhibitors.     

N-linked glycosylation of dimeric acetylcholinesterase in erythrocytes is essential for enzyme maturation and membrane targeting

Acetylcholinesterase (AChE) is well-known for its cholinergic functions in the nervous system; however, this enzyme is also found in other tissues where its function is still not understood. AChE is synthesized through alternative splicing as splicing variants, with isoforms including read-through (AChE(R) ), tailed (AChE(T) ) and hydrophobic (AChE(H) ). In human erythrocytes, AChE(H) is a glycophosphatidylinositol-linked dimer on the plasma membrane. Three N-linked glycosylation sites have been identified in the catalytic domain of human AChE. Here, we investigate the roles of glycosylation in assembly and trafficking of human AChE(H) . In transfected fibroblasts, expression of AChE(H) was able to mimic the function of the dimeric form of AChE on the erythrocyte membrane. A glycan-depleted form was constructed by site-directed mutagenesis. By comparison with the wild-type AChE(H) , the mutant had a much lower enzymatic activity and a much higher K(m) value. In addition, the mutant was dimerized in the endoplasmic reticulum, but was not trafficked to the Golgi apparatus. The results suggest that the glycosylation may affect AChE(H) enzymatic activity and trafficking, but not dimer formation. The present findings indicate the significance of N-glycosylation in controlling the biosynthesis of the AChE(H) dimer form. Structured digital abstract ? AChE-H?and?GM130?colocalize?by?cosedimentation through density gradient?(View interaction) ? AChE-H?and?Calnexin?colocalize?by?cosedimentation through density gradient?(View interaction).     

Molecular properties of acetylcholinesterase in mouse spleen

The presence of acetylcholinesterase (AChE) mRNA and activity in the tissues and cells involved in immune responses prompted us to investigate the level and pattern of AChE components in spleen. AChE activity was higher in mouse spleen (0.46 +/- 0.13 micromol of acetylthiocholine split per hour and per mg protein) than in muscle or heart, but lower than in brain. The spleen was essentially free of butyrylcholinesterase (BuChE) activity. About 40% of spleen AChE was extracted with a saline buffer, and a further 40% with 1% Triton X-100. Sedimentation analyses, the splitting of subunits in AChE dimers, phosphatidylinositol-specific phospholipase C (PIPLC) exposure, and phenyl-agarose chromatography showed that hydrophilic (G1H, 43%) and amphiphilic AChE monomers (G1A, 36%), as well as amphiphilic dimers (G2A, 21%), occurred in spleen. All these molecules bound to fasciculin-2-Sepharose, although the extent of binding was higher for G1H (77%) than for G1A (63%) or G2A (48%) forms. Differences in the extent to which wheat germ lectin (WGA) adsorbed with AChE of mouse spleen and of erythrocyte allowed us to discard the blood origin of spleen AChE activity. A 62 kDa protein was labeled in spleen samples using antibodies against human AChE. The protein was attributed to AChE monomers since its size was the same, regardless of whether disulfide bonds were reduced or not. Since cholinergic stimulation modulates proliferation/maturation of lymphoid cells, AChE may be important for regulating the level of acetylcholine (ACh) in the neighborhood of cholinergic receptors (AChR) in spleen and other lymphoid tissues.     

Cranial nerve growth in birds is preceded by cholinesterase expression during neural crest cell migration and the formation of an HNK-1 scaffold

Summary The expression of the neural crest cell (NCC) markers acetylcholinesterase (AChE) and the HNK-1-epitope is compared from the emigration of cephalic NCC until the formation of the cranial nerves V-X in chicken and quail hindbrain. We show that NCC transiently express acetylcholinesterase (AChE) activity during their emigration; NCC migrate into butyrylcholinesterase (BChE)-positive areas of the cranial mesenchyme. Along these migratory tracks that foreshadow the course of later projecting cranial nerves, BChE increases strongly in cells that may represent immature Schwann cells. Both AChE and BChE, but not HNK-1, are expressed in the ectodermal placodes. In NCC, HNK-1 is expressed strongly only when they approach their destination sites. Their intense expression of HNK-1 then leads to the establishment of tunnel-shaped HNK-1 matrices, within which G4-positive cranial neurites begin to extend. We conclude that AChE and HNK-1 expression in cephalic NCC serve different functions, since AChE is related to their migration, and HNK-1 to their aggregation and the formation of an extracellular neurite scaffold.     

A novel neural-specific BMP antagonist, Brorin-like, of the Chordin family

We identified a gene encoding a novel secreted protein in mice, humans, and zebrafish. As the protein of 222 amino acids is similar to Brorin, a secreted BMP antagonist, which is a member of the Chordin family, we named it Brorin-like. Recombinant Brorin-like protein weakly but significantly inhibited the activity of BMP in mouse preosteoblastic cells and promoted neurogenesis in mouse neural precursor cells. Brorin-like was predominantly expressed in the adult brain and embryonic neural tissues. The inhibition of Brorin-like functions in zebrafish resulted in the impairment of neural development. Brorin-like potentially plays roles in neural development and functions.