Tissue- and stage-specific expression of a fatty acid binding protein-like gene from amphioxus Branchiostoma belcheri

A cDNA clone encoding an amphioxus fatty acid binding protein-like (AmphiFABPL) protein was isolated from a gut cDNA library of Branchiostoma belcheri. It contained a 423 bp open reading frame corresponding to a deduced protein of 140 amino acids with a predicted molecular mass of approximately 15.9 kDa. Phylogenetic analysis showed that AmphiFABPL fell outside the vertebrate clade of fatty acid binding proteins (FABPs), being positioned at the base of the chordate lineage, and was almost equally homologous to various vertebrate FABPs, suggesting that it may be the archetype of vertebrate FABPs. Both northern blotting and in situ hybridization analyses demonstrated that AmphiFABPL was expressed in the hepatic caecum and hind-gut, and although at a much lower level, it was also present in the endostyle, ovary and testis. In addition, whole-mount in situ hybridization revealed that AmphiFABPL was initially expressed in the posterior two thirds of the primitive gut, including the mid-gut where the hepatic caecum will form later, in 2-day larvae. The expression pattern is closely similar to that of the L-FABP and I-FABP genes in vertebrates, supporting the hypothesis that the hepatic caecum in the amphioxus is homologous to the vertebrate liver.     

Identification and expression of a novel class of glutathione-S-transferase from amphioxus Branchiostoma belcheri with implications to the origin of vertebrate liver

Glutathione-S-transferases have been identified in all the living species examined so far, yet little is known to date about them in amphioxus, a model organism for insights into the origin and evolution of vertebrates. We have isolated a cDNA encoding an amphioxus (Branchiostoma belcheri) glutathione-S-transferase with a predicted molecular mass of approximately 26 kDa, from the gut cDNA library. The glutathione-S-transferase had 43.7-51.8% identity to most glutathione-S-transferases identified from aquatic organisms including fish and green alga, but it was much less identical (<27%) to other cytosolic glutathione-S-transferase classes. The phylogenetic analysis revealed that the glutathione-S-transferase was grouped together with most piscine and algal glutathione-S-transferases, separating from other cytosolic glutathione-S-transferase classes. Moreover, the glutathione-S-transferase had an exon-intron organization typical of zebrafish putative GST, red sea bream GSTR1 and plaice GSTA1 genes. The recombinant glutathione-S-transferase has been successfully expressed and purified, which showed a relatively high catalytic activity (3.37+/-0.1 unit/mg) toward 1-chloro-2, 4-dinitrobenzene and a moderate activity toward ethacrynic acid (0.41+/-0.01 unit/mg), although it had no detectable activity toward 1, 2-dichloro-4-nitrobenzene, 4-hydroxynonenal, 4-nitrobenzyl chloride and cumene hydroperoxide. In addition, we have revealed a tissue-specific expression pattern of the glutathione-S-transferase gene in B. belcheri, with the most abundant expression in the hepatic caecum. All these indicate that the amphioxus glutathione-S-transferase belongs to a novel rho-class of glutathione-S-transferases with a tissue-specific expression pattern. The relation between the glutathione-S-transferase expression in amphioxus hepatic caecum and the origin of vertebrate liver is also discussed.     

Characterization and tissue-specific expression of phosphatidylcholine transfer protein gene from amphioxus Branchiostoma belcheri

An amphioxus cDNA, encoding phosphatidylcholine transfer protein (AmphiPCTP), was identified for the first time from the gut cDNA library of Branchiostoma belcheri. It contains a 660-bp open reading frame corresponding to a deduced protein of 219 amino acids. Phylogenetic tree analysis showed that AmphiPCTP clustered with PCTP subgroup of PCTP subfamily containing steroidogenic acute regulatory protein (StAR)-related lipid transfer (START) domains. AmphiPCTP had an exon-intron organization similar to that of human and rat PCTP genes in terms of both exon number and sequence homology of each exon, suggesting that PCTP has probably maintained a similar function in both amphioxus and mammalian species. Both in situ hybridization histochemistry and whole-mount in situ hybridization revealed a tissue-specific expression pattern of AmphiPCTP with the high levels in the hepatic caecum and primitive gut, including the region where the hepatic caecum will form later during development. This apparently agrees with the hypothesis that amphioxus hepatic caecum is equivalent to vertebrate liver. These results suggest a conserved role of PCTPs in amphioxus as well as mammalian species. This work was supported by National Science Foundation of China (NSFC; 30470203) and Ministry of Education of China (200404023014).     

青岛文昌鱼S-腺苷高半胱氨酸水解酶基因的组织特异性表达

为了探索文昌鱼S-腺苷高半胱氨酸水解酶AdoHcyase基因在文昌鱼组织中的表达分布情况,利用组织原位杂交技术,以地高辛标记的反义RNA为探针,检测了文昌鱼AdoHcyase基因在组织中的表达分布特点.结果表明,AdoHcyase基因在雌性文昌鱼的卵巢、肝盲囊和后肠杂交信号十分强烈,在内柱、鳃等组织中也有微弱信号表达,...     

Characterization and expression profile of AmphiCD63 encoding a novel member of TM4SF proteins from amphioxus Branchiostoma belcheri tsingtauense.

The study on CD antigen genes remains lacking in the cephalochordate amphioxus to date. In this report, the cDNA encoding CD63 was identified for the first time from the gut cDNA library of amphioxus Branchiostoma belcheri tsingtauense. Primary structural examination showed that the protein encoded by the cDNA contained four potential transmembrane domains characteristic of transmembrane 4 superfamily (TM4SF) proteins and a conserved CCG motif in the putative major extracellular loop. BLAST search revealed that the cDNA is closely associated with other known CD63 antigen genes, and it was thus designated AmphiCD63. Phylogenetic analysis indicated that AmphiCD63 is extremely close to vertebrate CD63, CD151 and CD53, suggesting they may have been evolved from a common ancestral gene. RT-PCR analysis exhibited that AmphiCD63 mRNA was abundant in muscle, ovary, foregut including hepatic caecum and hindgut, while it was present at considerably lower levels in notochord and gill and absent in testis.     

Molecular and biochemical characterization of galectin from amphioxus: primitive galectin of chordates participated in the infection processes

A novel F4-carbohydrate recognition domain (CRD)-linker-F3-CRD-type bi-CRD Branchiostoma belcheri tsingtauense galectin (BbtGal)-L together with its alternatively spliced mono-CRD isoform BbtGal-S from amphioxus intestine was encoded by a 9488-bp unique gene with eight exons and seven introns. The recombinant proteins of BbtGal were found to have beta-galactoside-binding activity, indicating that BbtGal was a member of the galectin family. Phylogenetic analysis of this gene along with its splicing form and genome structure suggested that the BbtGal gene was the primitive form of the chordate galectin family. Real-time polymerase chain reaction analyses (PCR) indicated that BbtGal mRNA was expressed during all stages of embryonic development. In terms of tissue distribution, BbtGal-L mRNA was mainly expressed in the immunity-related organs, such as hepatic diverticulum, intestine, and gill, but BbtGal-S was ubiquitously expressed in all tissues. The expression of BbtGal-L mRNA was elevated after acute challenge with various microorganisms, but BbtGal-L only bound to specific bacteria. The immune function of BbtGal was consistent with its localization both outside and inside the cell. Our study on amphioxus galectin may help further understanding of the evolution of chordate galectin in terms of host-pathogen interaction in the immune system.     

Verification and tissue-specific expression of nifU-like gene from the amphioxus Branchiostoma belcheri

A nifU-like gene exhibiting similarity to nifU of nitrogen fixation gene cluster was identified for the first time from the gut cDNA library of amphioxus Branchiostoma belcheri. Both RT-PCR and Northern blotting as well as in situ hybridization histochemistry verified that the cDNA represents an amphioxus nifU-like gene rather than a microbial contaminant. The nifU-like gene encodes a protein of 164 amino acid residues including a highly conserved U-type motif (C-X26-C-X43-C), and shares 66-86% identity to NifU-like proteins from a variety of species including vertebrates, invertebrates and microbes. It is expressed in a tissue-specific manner in the digestive system including epipharyngeal groove, endostyle, hepatic caecum and hind-gut and in the gill, ovary and testis. Taken together, it is highly likely that NifU-like protein plays some tissue-dependent and critical role in amphioxus.     

Verification and tissue-specific expression of nifU-like gene from the amphioxus Branchiostoma belcheri.

A nifU-like gene exhibiting similarity to nifU of nitrogen fixation gene cluster was identified for the first time from the gut cDNA library of amphioxus Branchiostoma belcheri. Both RT-PCR and Northern blotting as well as in situ hybridization histochemistry verified that the cDNA represents an amphioxus nifU-like gene rather than a microbial contaminant. The nifU-like gene encodes a protein of 164 amino acid residues including a highly-conserved U-type motif (C-X(26)-C-X(43)-C), and shares 66-86% identity to NifU-like proteins from a variety of species including vertebrates, invertebrates and microbes. It is expressed in a tissue-specific manner in the digestive system including epipharyngeal groove, endostyle, hepatic caecum and hindgut and in the gill, ovary and testis. Taken together, it is highly likely that NifU-like protein plays some tissue-dependent and critical role in amphioxus.     

Characterization, expression and localization of S-adenosylhomocysteine hydrolase from amphioxus Branchiostoma belcheri tsingtaunese

A cDNA clone encoding AmphiSAHH [amphioxus SAHH (S-adenosylhomocysteine hydrolase)] protein was isolated from a cDNA library from the gut of Branchiostoma belcheri tsingtaunese. It contained a 1305 bp open reading frame corresponding to a deduced protein of 434 amino acid residues, with a predicted molecular mass of approx. 47.8 kDa. Phylogenetic analysis showed that AmphiSAHH and sea-urchin SAHH joined together and positioned at the base of the vertebrate SAHH clade, suggesting that both AmphiSAHH and sea-urchin SAHH might share some characteristics of the archetype of vertebrate SAHH proteins. The genomic DNA sequence of AmphiSAHH contained eight exons and seven introns, which was similar to B. floridae and sea-urchin SAHH exon/intron organization. Sequence comparison suggested the evolutionary appearance of the ten exon/nine intron organization of SAHH genes after the split of invertebrates and vertebrates, after which it has been highly conserved. AmphiSAHH has been successfully expressed in Escherichia coli and purified. Western blotting confirmed that the enzyme has a native molecular mass of approx. 48 kDa, and the catalytic activities and NAD(+)/NADH binding affinity of recombinant AmphiSAHH were measured. Immunohistochemistry analysis showed that SAHH was strongly expressed in hepatic caecum, gill, spermary and ovary of amphioxus.     

A trypsin homolog in amphioxus: expression, enzymatic activity and evolution

Trypsin has been documented in a variety of species including both vertebrates and invertebrates, but little is known about it in amphioxus, a model organism for insights into the origin and evolution of vertebrates. Here we identified a trypsin gene in Branchiostoma japonicum. The cDNA was 978 bp long with an ORF encoding a deduced protein of 272 amino acids. The deduced protein had an N-terminal signal peptide of 15 amino acids, a 16 activation peptide with the typical cleavage site Arg/Ile, a Tryp_SPc domain with the catalytic triad His⁷²-Asp¹¹⁸-Ser²¹⁵ and the S1 substrate binding residue Asp²⁰⁹, which are all characteristic of trypsinogens. The recombinant trypsin protein was able to hydrolyse the trypsin prototypic substrate BAEE, which was inhibited by the trypsin-specific inhibitor soybean trypsin inhibitor. Both northern blotting and tissue-section in situ hybridization demonstrated that trypsin gene was expressed in a tissue-specific manner, with most abundant levels in the hepatic caecum, mid-gut and ovary. And the whole mount in situ hybridization showed that it began to express in the middle third of the full-length primitive gut in 2-day larvae, where the hepatic caecum will form later during development. Phylogenetic analysis indicated that both amphioxus and ascidian trypsins are more closer to each other than to vertebrate trypsins, suggesting a continuous evolutionary divergence of vertebrate trypsins after split from protochordate/vertebrate common ancestor.     

Identification,expression and bioactivity of hexokinase in amphioxus: Insights into evolution of vertebrate hexokinase genes

Hexokinase family includes hexokinases I, II, III and IV, that catalyze the phosphorylation of glucose to produce glucose 6-phosphate. Hexokinase IV, also known as glucokinase, is only half size of the other types of hexokinases that contain two hexokinase domains. Despite the enormous progress in the study of hexokinases, the evolutionary relationship between glucokinase and other hexokinases is still uncertain, and the molecular processes leading to the emergence of hexokinases in vertebrates remain controversial. Here we clearly demonstrated the presence of a single hexokinase-like gene in the amphioxus Branchiostoma japonicum, Bjhk, which shows a tissue-specific expression pattern, with the most abundant expression in the hepatic caecum, testis and ovary. The phylogenetic and synteny analyses both reveal that BjHK is the archetype of vertebrate hexokinases IV, i.e. glucokinases. We also found for the first time that recombinant BjHK showed functional enzyme activity resembling vertebrate hexokinases I, II, III and IV. In addition, a native glucokinase activity was detected in the hepatic caecum. Finally, glucokinase activity in the hepatic caecum was markedly reduced by fasting, whereas it was considerably increased by feeding. Altogether, these suggest that Bjhk represents the archetype of glucokinases, from which vertebrate hexokinase gene family was evolved by gene duplication, and that the hepatic caecum plays a role in the control of glucose homeostasis in amphioxus, in favor of the notion that the hepatic caecum is a tissue homologous to liver.     

文昌鱼sfy1基因的克隆及其在早期发育中的表达

文昌鱼是公认现存最接近于脊椎动物的一种头索动物,具有与脊椎动物相似但简单得多的身体图式[1],因而是研究脊椎动物发育机制起源和进化的宝贵材料,也是发育生物学的经典实验模型之一.近年来,人们在对果蝇和脊椎动物发育分子机制的研究取得了一系列重大突破之后,利用发育调控基     

The amphioxus rab GDP-dissociation inhibitor (GDI) gene is neural-specific: implications for the evolution of chordate rab GDI genes.

The rab GDP-dissociation inhibitor (rab GDI) proteins are involved in the regulation of vesicle-mediated cellular transport. We isolated the amphioxus rab GDI gene, analyzed its expression during amphioxus development, and performed a phylogenetic analysis of the rab GDI family. In contrast to the two major rab GDI forms in mammals, the alpha and beta forms, there is only one rab GDI isoform in amphioxus. Our analysis indicates that the occurrence of the alpha and beta forms of rab GDI preceded the divergence of lineages leading to birds and mammals, and that the amphioxus rab GDI may have evolved directly from the common ancestor of both forms. While the mammalian rab GDI beta-genes are ubiquitously expressed, the rab GDI alpha genes are predominantly expressed in neural tissues. The expression analysis of the amphioxus rab GDI gene shows predominantly neural expression similar to that of the mammalian rab GDI alpha form, suggesting that the ancestral expression pattern of chordate rab GDI was neural. In addition, the chicken rab GDI beta-like gene also shows neural-specific expression, which indicates that the neural expression was retained in both early postduplication alpha and beta isoforms and that a novel function associated with ubiquitous expression may have evolved uniquely in mammals. These results reveal a likely scenario of functional divergence of the rab GDI genes after duplication of the ancestral gene. A similar pattern of evolution, in which one of the duplicated genes retained a role similar to that of the ancestral one while other genes were recruited into novel roles, was also observed in the analysis of chordate Otx and hedgehog genes. In the rab GDI, hedgehog, and Otx gene families, the gene retaining the ancestral role shows a lower rate of sequence evolution than its counterpart, which was recruited for a novel function.     

Characterization of Amphioxus AmphiVent, an evolutionarily conserved marker for chordate ventral mesoderm

Structure and developmental expression are described for amphioxus AmphiVent, a homolog of vertebrate Vent genes. In amphioxus, AmphiVent-expressing ventral mesoderm arises at midneurula by outgrowth from the paraxial mesoderm, but in vertebrates, Vent-expressing ventral mesoderm originates earlier, at the gastrula stage. In other embryonic tissues (nascent paraxial mesoderm, neural plate, endoderm, and tailbud), AmphiVent and its vertebrate homologs are expressed in similar spatiotemporal domains, indicating conservation of many Vent gene functions during chordate evolution. The ventral mesoderm evidently develops precociously in vertebrates because their relatively large embryos probably require an early and extensive deployment of the mesoderm-derived circulatory system. The vertebrate ventral mesoderm, in spite of its strikingly early advent, still resembles the nascent ventral mesoderm of amphioxus in expressing Vent homologs. This coincidence may indicate that Vent homologs in vertebrates and amphioxus play comparable roles in ventral mesoderm specification.     

Cloning,characterization and expression of tyrosinase-like gene in amphioxus Branchiostoma japonicum

Prophenoloxidase (tyrosinase) widely distributed in invertebrates and vertebrates, and plays a crucial role in the innate immune. In the present study, the full-length cDNA of a tyrosinase-like (designated AmphiTYR) was cloned from amphioxus Branchiostoma japonicum by PCR techniques. The full-length cDNA of AmphiTYR is 2314 bp, and its predicted open-reading frame codes for a protein of 544 amino acids with a predicted molecular mass of approximately 60.9 kDa and an isoelectric point of 5.65. It has a conserved putative copper-binding domain with six histidines in tyrosinase proteins. Six potential N-linked glycosylation sites and 14 conserved cysteine residues were also predicted to be present in B. japonicum tyrosinase. Homology analysis revealed that AmphiTYR was higher similar to vertebrates tyrosinases (32.5–40.5%) than to invertebrates phenoloxidase (6.4–25.4%). In the adult, AmphiTYR mRNA was expressed in the muscle, epidermis, notochord, ovary, hepatic caecum, pharynx and gill, but not in the neural tube, intestines and testis. During the different development stages from unfertilized egg to larvae of amphioxus, AmphiTYR expressed during all the amphioxus development. These results indicated that AmphiTYR gene not only play a pivotal role in innate immune but also play an important role during embryonic development of cephalochordate amphioxus.     

文昌鱼肝盲囊与脊椎动物肝脏起源

早期形态和胚胎学研究结果表明, 文昌鱼哈氏窝、内柱和肝盲囊分别是脊椎动物脑垂体、甲状腺和肝脏的同源器官。文章总结了近年来有关文昌鱼肝盲囊与脊椎动物肝脏之间关系的研究成果, 揭示文昌鱼肝盲囊和脊椎动物肝脏具有同源性, 并证明文昌鱼中存在类似脊椎动物的GH/IGF (Growth hormone/insulin-like growth factor)和TH/THR (Thyroid hormone/thyroid hormone receptor)信号通路, 为脊椎动物肝脏起源于文昌鱼肝盲囊样结构提供了分子水平证据。     

Identification, expression, function and localization of a DUF985 domain-containing hypothetical gene from amphioxus Branchiostoma belcheri

The progress in genome sequencing has led to an increasing submission of uncharacterized hypothetical genes with the domain of unknown function, DUF985, in GenBank, and none of these genes is related to a known protein. We therefore underwent an experimental study to identify the function of a DUF985 domain-containing hypothetical gene BbDUF985 (GenBank Accession No. AY273818) isolated from amphioxus Branchiostoma belcheri (B. belcheri). BbDUF985 was successfully expressed in both prokaryotic and eukaryotic systems, and its recombinant proteins expressed in both systems definitely exhibited an activity of phosphoglucose isomerase (PGI). Both tissue-section in situ hybridization and immunohistochemistry demonstrated that BbDUF985 was expressed in a tissue-specific manner, with most abundant levels in the hepatic caecum and ovary. In CHO cells transfected with the expression plasmid pEGFP-N1/BbDUF985, the fusion protein was targeted in the cytoplasm of CHO cells, suggesting that BbDUF985 is a cytosolic protein. In contrast, Western blotting indicated that BbDUF985 was also present in amphioxus humoral fluids, suggesting that it exists as a secreted protein as well. Our study provided a framework for further understanding the biochemical properties and physiological function of DUF985-containing hypothetical proteins in other species.     

Demonstration of plasminogen-like protein in amphioxus with implications for the origin of vertebrate liver

Plasminogen, the proenzyme of serine protease plasmin, is a plasma glycoprotein synthesized primarily in the liver, and its evolutionary origin in chordates remains unclear. We demonstrated here that the humoral fluid in amphioxus is capable of cross‐reacting with anti‐human or anti‐mouse plasminogen antibodies, and the hepatic diverticulum in amphioxus is the site of plasminogen‐like protein synthesis. The presence of plasminogen‐like protein in amphioxus pushes the origin of plasminogen to before the last common ancestor of vertebrates. In addition, the localization of plasminogen‐like protein in the hepatic diverticulum suggests that the diverticulum in amphioxus is functionally homologous to the vertebrate liver in respect of plasminogen synthesis, supporting the hypothesis that the vertebrate liver evolved from the hepatic diverticulum of an amphioxus‐like ancestor during early chordate evolution.