Abstract
A number of studies have suggested that olfaction plays an important role in fish migration. Fish use several distinct families of olfactory receptors to detect environmental odorants, including MORs (main olfactory receptors), V1Rs (vomeronasal type-1 receptors), V2Rs (vomeronasal type-2 receptors), TAARs (trace amine-associated receptors), and FPRs (formyl peptide receptors). The V1Rs have been reported to detect pheromones, and a pheromone hypothesis for the spawning migration of anadromous fish has been proposed. Examining whether Coilia nasus relies on V1R-mediated olfaction for spawning migration is important for understanding the molecular basis of spawning migration behavior. Here, we explored the V1R gene family in anadromous C. nasus. Six V1R genes previously reported in other teleost fish were successfully identified. Interestingly, we detected the largest V1R repertoire in teleost fish from C. nasus and identified a species-specific expansion event of V1R3 gene that has previously been detected as single-copy genes in other teleost fish. The V1R loci were found to be populated with repetitive sequences, especially in the expanded V1R3 genes. Additionally, the divergence of V1R3 genetic structures in different populations of C. nasus indicates the copy number variation (CNV) in V1R3 gene among individuals of C. nasus. Most of the putative C. nasus V1R genes were expressed primarily in the olfactory epithelium, consistent with the role of the gene products as functional olfactory receptors. Significant differences in the expression levels of V1R genes were detected between the anadromous and non-anadromous C. nasus. This study represents a first step in the elucidation of the olfactory communication system of C. nasus at the molecular level. Our results indicate that some V1R genes may be involved in the spawning migration of C. nasus, and the study provides new insights into the spawning migration and genome evolution of C. nasus.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
The Japanese grenadier anchovy Coilia nasus is a famous small-sized commercial fish that is widely distributed in the coastal waters of China, the middle and lower reaches of the Yangtze River, Ariake Bay of Japan, and the western coastal waters of the Korean Peninsula (Whitehead et al. 1998; Zhu et al. 2014; Yuan et al. 1980). Anadromous C. nasus lives in the sea until it reaches sexual maturity and then performs ocean–river migration behavior to the exorheic rivers through long-distance swimming to spawn (Whitehead et al. 1998; Zhu et al. 2014; Yuan et al. 1980). However, the molecular mechanisms of spawning migration of anadromous C. nasus have not been clarified yet.
Olfactory hypotheses in fish migration propose that the spawning migration of fish is mediated by olfactory cues. Indeed, migratory fish lose the ability to perform accurate migrations following alterations to their olfactory epithelia (McBride et al. 1964; Tarrant 1966; Jahn 1967; Doving et al. 1985; Yano and Nakamura 1992; Barbin et al. 1998). Strong olfactory responses to natal stream water have also been found in migratory sockeye salmon through blood oxygenation level-dependent functional magnetic resonance imaging (Bandoh et al. 2011). Some olfactory receptor genes have been demonstrated to be differentially expressed during the different life stages of the wild anadromous Atlantic salmon, but not in the non-anadromous population (Johnstone et al. 2011). Thus, a functional olfactory ability is essential for migration to their natal streams. Therefore, we hypothesized that olfaction also played an important role in the spawning migration of C. nasus.
Pheromones play essential roles in many intraspecies communications, such as mating preferences, individual recognition and aggression. Based on previous research, two different olfactory hypotheses have been proposed for salmon imprinting and homing: One imprinting hypothesis was developed in Coho salmon (Oncorhynchus kisutch) (Wisby and Hasler 1954), while the second is the pheromone hypothesis developed in Arctic char (Salvelinus alpinus) and Atlantic salmon (Salmo salar) (Nordeng 1971, 1977). The pheromone hypothesis states that juvenile salmon release population-specific odors in a stream to guide the homing adults in the return to their natal waters during their migration. Furthermore, a mixture of sulfated steroids has been shown to function as a migratory pheromone; these steroids are released by stream-dwelling larval lamprey to guide adults to spawning streams (Sorensen et al. 2005). Therefore, if olfaction plays an important role in the spawning migration of C. nasus, some pheromones may be used as the olfactory properties detected by C. nasus migrants to guide them during anadromous migration.
Vertebrate species distinguish a large number of chemical cues in the environment through the olfactory receptors (ORs) (Laberge and Hara 2001; Hino et al. 2009; Fuss and Ray 2009; Zhu et al. 2015). The ORs are G protein-coupled receptors with seven transmembrane domains that are encoded by corresponding chemosensory receptor genes (Kaupp 2010; Zhang and Firestein 2009; Korsching 2009). In mammals, two organs function as the main olfactory organ and the vomeronasal organ to perform olfactory functions. Five types of olfactory receptors derived from evolutionarily distinct multigene families to detect chemical cues in the outer environment have been detected in vertebrates, including the main olfactory receptors (MORs) (Buck and Axel 1991), vomeronasal type-1 receptors (V1Rs), vomeronasal type-2 receptors (V2Rs) (Ryba and Tirindelli 1997), trace amine-associated receptors (TAARs) (Liberles and Buck 2006), and formyl peptide receptors (Riviere et al. 2009). Because fish do not possess a vomeronasal system, their corresponding ORs are expressed in the olfactory epithelium of the nasal cavity (Pfister and Rodriguez 2005; Cao et al. 1998; Asano-Miyoshi et al. 2000). V1Rs and V2Rs in fish were named following mammalian nomenclature when they were first identified. Recently, the orthologous V1R genes in fish have been named ORAs (Saraiva and Korsching 2007; Johnstone et al. 2008), while the V2R orthologs have been named OlfCs (Alioto and Ngai 2006).
V1R (ORA) is a fish olfactory receptor gene family that was recently identified (Saraiva and Korsching 2007). The fish V1R gene family is small, with only six members; all of them are highly conserved in the analyzed teleost fish species, with the exception of Takifugu rubripes and Tetraodon nigroviridis in which V1R2 is absent (Pfister and Rodriguez 2005; Saraiva and Korsching 2007; Shi and Zhang 2007; Pfister et al. 2007). Studies have demonstrated the sequence conservation of orthologous V1R genes among salmonid species and between distantly related rockfish species (Johansson and Banks 2011; Johnson and Banks 2011). Therefore, the V1R gene family is unique compared with the MOR, V2R, and TAAR gene families, which have experienced extensive lineage-specific expansions (Saraiva and Korsching 2007; Niimura and Nei 2005; Hashiguchi et al. 2008; Hussain et al. 2009; Nei et al. 2008). The existence of the orthologous fish V1R1 gene in elephant sharks (Callorhinchus milii) and an orthologous gene of the fish V1R2 in frogs (Xenopus tropicalis) indicates that the V1R genes have been maintained throughout the evolutionary history of aquatic vertebrates (Grus and Zhang 2009). The strong sequence conservation of V1Rs suggests their functional significance and implies that they can distinguish evolutionarily conserved chemicals, such as reproductive pheromones (Saraiva and Korsching 2007; Johnson and Banks 2011). Indeed, V1Rs in mammals can detect low molecular weight molecules such as steroids (Boschat et al. 2002; Del Punta et al. 2002; Isogai et al. 2011). V1R1 (ORA1), which is a zebrafish olfactory receptor that is ancestral to all mammalian V1R genes (Saraiva and Korsching 2007), has been proven to recognize 4-hydroxyphenylacetic acid, which is a putative reproductive pheromone used to elicit increases in oviposition frequency in zebrafish mating pairs, with high specificity and sensitivity (Behrens et al. 2014). Therefore, the V1Rs are the putative pheromone receptors.
In order to understand the feasible relationship between olfaction and spawning migration behavior, it is worthwhile to investigate the putative pheromone V1R receptors in C. nasus. Previously, we have reported the de novo transcriptomes of the olfactory epithelium in C. nasus (Zhu et al. 2014) and that work will be helpful for this study.
In this study, we described the V1R gene family of C. nasus through data mining and phylogenetic analysis. Six intact V1R gene members that are orthologous to the known V1R genes were identified. Additionally, we identified a species-specific expansion event of V1R3 gene subfamily, which have previously been reported to exist as a single copy in other teleost fish. We used real-time relative quantitative PCR to detect the expression profiles in the tissues of all the members of the V1R gene family in C. nasus. Furthermore, we investigated this gene family’s potential role in the migratory behavior of the anadromous and non-anadromous forms of C. nasus by analyzing the expression levels of all the V1R genes in olfactory rosettes in both forms. Based on our results, we propose that some V1R genes play an important role in the spawning migration behavior of C. nasus.
Materials and methods
Ethics statement
This work was approved by the Institutional Animal Care and Use Committee of Shanghai Ocean University and was performed following the Guidelines on the Care and Use of Animals for Scientific Purposes set by the Institutional Animal Care and Use Committee of Shanghai Ocean University.
Fish and tissue samples
The anadromous C. nasus migrants used in this study were captured in early May 2014 from the Jingjiang section of the Yangtze River in Jingjiang, Jiangsu Province, on the east coast of China when the fish were migrating upstream along the river. The fish were captured with the help of fisherman with fishing license No. SuChuanBu (2011) JMF217 and a special fishing license for C. nasus in the Yangtze River (No. SuChuanBu 2014 ZX-M025) permitted by the Jiangsu Provincial Oceanic and Fishery Bureau. Non-anadromous C. nasus individuals from Poyanghu Lake in Jiujiang, Jiangxi Province, in the southeast of China were captured in late March 2014, before the anadromous C. nasus migrated to the lake. These fish were also captured with the assistance of fisherman owning a fishing license (No. 0400051) permitted by the Jiangxi Provincial Department of Agriculture.
Immediately after capture, live fish from the wild waters were buried in medical ice bags with a temperature of −20 °C until loss of consciousness was achieved. The average time to loss of consciousness for the fish was estimated to be 3 min. Then, the captured fish were rapidly dissected on ice and examined for anatomical characteristics of the gonadal development phase (Xu et al. 2011, 2012). The olfactory rosettes of C. nasus in phase III and other tissues used in this work were collected. To prevent RNA degradation, all of the operations on C. nasus were finished within 10 min of loss of consciousness. All efforts were made to minimize suffering. The sampled tissues for RNA experiments were stored in RNALater (Ambion, USA), kept at 4 °C overnight and transported to Shanghai Ocean University at −20 °C.
Muscle tissue for DNA experiments from the fresh-caught fish was fixed in 100 % ethanol and stored at 4 °C. The muscle tissue from C. nasus from the waters of Zhoushan and Taihu Lakes was transported to the fish specimen room in Shanghai Ocean University, and the muscle tissue from the C. nasus of Dongtinghu Lake was provided by Dr. Dong Liu from Shanghai Ocean University. Genomic DNA from the muscle tissue of one C. nasus was extracted using the Genomic DNA Purification Kit (Lifefeng, China) and subsequently stored at −20 °C in water.
PCR and DNA sequencing
The primers used to amplify the complete open reading frame of the V1R1 and V1R2 genes from the genomic DNA of anadromous C. nasus from the Jingjiang section of the Yangtze River were designed according to the transcripts produced by transcriptome sequencing (Zhu et al. 2014) (Fig. 1; Supplementary Table S1; Supplementary Text S2). The internal regions of the V1R3 and V1R6 genes were amplified with primers from the literature (Ota et al. 2012). PCR was performed in an Eppendorf Mastercycler (Eppendorf, Germany) with approximately 50 ng of genomic DNA, 1U of DNA Taq plus polymerase (including dNTP and buffer, Tiangen, Shanghai), and 5 pmol of each primer in a total volume of 25 µl. The PCRs were performed as follows: initial denaturation for 5 min at 95 °C, then 30 cycles of denaturation for 45 s at 95 °C, annealing for 45 s at the corresponding temperature, and extension for 1 min 30 s at 72 °C, followed by a 10-min additional extension at 72 °C and storage at 4 °C. The PCR products were subjected to electrophoresis, the target DNA bands were isolated and purified, and then the obtained DNA fragments were ligated into T-vectors and transformed into Escherichia coli (DH5α). The clones were identified by PCR with primers M13-34 and RV-M, and the positive clones were sequenced. V1R4 and V1R5 sequences (not intact) were obtained directly from the transcriptome data.
The 5′-and 3′-flanking sequences of the V1R1, V1R2, V1R3, V1R5, and V1R6 genes were obtained using the Genome Walking kit (Takara, Japan) with primers designed based on the obtained sequences. The V1R4 flanking sequence was obtained through a round of the genome walking reaction, followed by a PCR using the above product as the template and primers from the literature (Ota et al. 2012); then, genome walking and PCR were performed to gain the 3′- region of the V1R4 gene. Finally, the DNA bands produced were purified, cloned, and sequenced. The obtained sequences were edited using BIOEDIT 6.0.7 (Hall 1999) and annotated with TBLASTX in the NCBI database (http://www.ncbi.nlm.nih.gov/). The primers used are shown in Table 1.
5′ UTR sequence motif
A conserved sequence motif in the internal sequences of V1R1–V1R2 with the length of about 75 bp has been identified in the already investigated teleost fish (Pfister et al. 2007; Ota et al. 2012). The approximately 75-bp sequence of the V1R1 5′-UTR homology region of D. rerio, G. aculeatus, O. latipes, T. nigroviridis, T. rubripes, S. salar, H. chilotes and the corresponding sequence from C. nasus were aligned with the software Clustal X 2.0 for initial identification (Thompson et al. 1997). A logo was produced using the sequence logo software (http://weblogo.berkeley.edu/logo.cgi).
Phylogenetic analysis
The sequences of V1R genes from D. rerio, G. aculeatus, O. latipes, T. nigroviridis, and T. rubripes were downloaded from the published literature (Saraiva and Korsching 2007). Then, TBLASTN searches were conducted on the genomes of the above fish in the ENSEMBL genome browser (http://www.ensembl.org/index.html). The V1R sequences from S. salar and H. chilotes were collected from published papers (Ota et al. 2012; Johnstone et al. 2012). The MEGA 5.05 software was used to perform the alignment of amino acid sequences, calculation of distances, and construction of neighbor-joining trees (Tamura et al. 2011).
V1R genes in different populations of C. nasus
Following the amplification of the internal region of the V1R3 gene with degenerate oligos obtained from the published literature (Ota et al. 2012), we obtained a sequence with repeat sequences. Through blasting in NCBI, we found that these repeats were inserted into the second intron of the V1R3 gene. Therefore, we designed a pair of primers flanking the microsatellite to amplify the genomic DNA from the different populations of C. nasus (Supplementary Table S3) through PCR; the populations were collected from the Jingjiang section of the Yangtze River, the seawaters of Zhoushan, Taihu Lake, Poyanghu Lake, and Dongtinghu Lake. The population from Jingjiang represents the anadromous type of C. nasus, the population from Zhoushan represents the marine type of C. nasus, the population from Taihu Lake represents the landlocked type of C. nasus, and the populations from Poyanghuhu Lake and Dongtinghu Lake represent the non-anadromous type (freshwater resident) of C. nasus. Four fish from each population were used to represent their population in the study.
Relative real-time quantitative PCR
To investigate the expression profiles of the V1R genes in tissues, the following tissues were extracted from three anadromous adult C. nasus and pooled for RNA extraction, respectively: the olfactory sensory organ (including the female olfactory rosette and male olfactory rosette), liver, heart, gill, muscle, ovary, testis, eye, and stomach. To investigate the differential expression profiles of the V1R genes between anadromous and non-anadromous C. nasus, the olfactory rosettes from five wild female anadromous C. nasus captured from the Jingjiang section of the Yangtze River and five wild female non-anadromous C. nasus captured from Poyanghu Lake were dissected and, respectively, pooled for further RNA extraction.
Total RNA was extracted from the above tissues with the Trizol reagent (Invitrogen, USA) following the user manual. cDNA was produced with the First-Strand cDNA synthesis Kit (Takara, Japan). To prevent cross-amplification, the PCR primers were designed based on the regions of the V1R genes that did not possess any appreciable sequence identity to one another (Supplementary Table S4). From our transcriptome data, we identified three transcripts of the V1R3 gene and named them Unigene12966_All (V1R3-1), CL5470.Contig1_All (V1R3-2), and Unigene116116_All (V1R3-3). Two of them (V1R3-1 and V1R3-2) were used as templates to design qPCR primers.
Relative expression qPCR was performed using a Bio-Rad PTC-200 real-time PCR instrument (Bio-Rad, Germany) in a reaction mixture with a final volume of 50 μl including 25 μl SYBR Premix Ex Taq (Takara, Japan), 1 μl of each primer (10 μM), 4 μl template cDNA, and 19 μl DEPC water under the following conditions: 95 °C for 30 s and 40 cycles of 95 °C for 5 s, 60 °C for 30 s, and 72 °C for 32 s. Each gene was analyzed in triplicate. The GAPDH gene was used as the internal control for normalization (Wang et al. 2016). A no-template control sample with nuclease-free water was used to detect contamination and the degree of dimer formation; no contamination or dimer formation was detected. The relative transcript level in each tissue was calculated using the comparative 2−∆∆CT method (Livak and Schmittgen. 2001). All of the Ct values were normalized to the internal control gene in the same tissues. Then, in order to describe the relative expression levels of V1R genes in all the ten mentioned tissues of C. nasus more clearly and directly, the relative expression levels of V1R genes in different issues were presented as fold changes by comparing their normalized Ct values relative to the normalized Ct values of the same genes in the tissue with the lowest normalized Ct value. For investigation into the differential expression profiles of the V1R genes, the V1R genes in the olfactory rosettes of C. nasus from the Jingjiang section of the Yangtze River (JJOR) were presented as fold changes compared to the normalized Ct values of the same genes in the olfactory rosettes of C. nasus from Poyanghu Lake (PYOR). All of the target genes, the internal control gene, and the no-template control were evaluated in triplicate to prevent technical error. The Student’s t test was used to determine significant differences among the treatments at p < 0.05. All of the data were expressed as mean ± standard deviation (S.D.) in this study.
Results and discussion
Identification of six orthologous V1R-like genes from other teleost fish in C. nasus
According to the methods mentioned above, all the six V1R genes reported in other fish (Saraiva and Korsching 2007; Pfister et al. 2007; Ota et al. 2012; Johnstone et al. 2012) were identified in C. nasus (Supplementary Text S5, Supplementary Text S6 and Supplementary Fig. S7). The nucleotide sequences were deposited in GenBank (GenBank ID: KP260935–KP260940).
Genetic structures of the V1R genes
The genetic structures of the V1R genes in C. nasus were identified using TBLASTN search analysis in the NCBI database (http://www.ncbi.nlm.nih.gov/). The V1R1, V1R2, V1R5, and V1R6 genes possessed only one exon without an intron, the V1R3 gene had four exons with three introns, and the V1R4 gene had two exons with one intron between them; these results were in accordance with other published results(Saraiva and Korsching 2007; Pfister et al. 2007; Ota et al. 2012; Johnstone et al. 2012). However, the intron length of the V1R3 and V1R4 genes differed from the published results from other species (Fig. 2) (Saraiva and Korsching 2007; Pfister et al. 2007; Ota et al. 2012; Johnstone et al. 2012). The detection of highly conserved genetic structures may imply that the V1R genes play an important role in fish (Saraiva and Korsching 2007).
A conserved region in the internal sequences of V1R1–V1R2 in teleost fish
The V1R genes in mice are characterized by an unusual conservation in noncoding sequences between family members, including the transcribed and non-transcribed regions (Lane et al. 2002). In the 5′-UTR (untranslated region) of V1R1 and V1R2, we identified a conserved segment of 74 bp located approximately 270 bp upstream of the coding sequence of the V1R2 gene (Fig. 3). In the published results, the conserved region is usually located adjacent to the V1R1 genes in the V1R1 5′-UTR (Pfister et al. 2007; Ota et al. 2012). However, in C. nasus, the conserved region was located upstream of the V1R2 gene instead of V1R1. The conserved region may indicate the need for a transcriptional or translational regulatory element that acts on fish V1R1 genes and possibly also on V1R2 (Pfister et al. 2007). The genomic organization of the fish V1R1 and V1R2 genes is “head to head,” with an approximately 1- to 3-kb DNA sequence separating the coding sequences of the two genes (Saraiva and Korsching 2007; Pfister et al. 2007; Ota et al. 2012; Johnstone et al. 2012). This arrangement results in a short space between the two UTRs and two promoters whose transcriptional direction is inverted, rendering it easily amenable to genetic manipulation (Pfister et al. 2007). This conservation implies the importance of these two motifs for the transcription of V1R2 or V1R1 (Pfister et al. 2007) and will be an interesting topic for future research. Interestingly, TAATTG is the binding site of the LIM-homeodomain protein Lhx2 in mice, which regulates the expression of the olfactory receptor genes (Hirota and Mombaerts. 2004). The unique conserved motifs CATCTG and AATT may have occurred as a result of the difference in the structure of the LIM-homeodomain protein Lhx2 in C. nasus, thereby contributing to differences in the binding site sequences (Ota et al. 2012).
An expansion of the V1R gene repertoire in C. nasus
The V1R gene family is highly conserved in the analyzed teleost fish, where a maximum of seven members have been identified (Pfister and Rodriguez 2005; Saraiva and Korsching 2007; Shi and Zhang 2007; Pfister et al. 2007). However, an expansion event of V1R genes was detected in the genome of C. nasus.
Intriguingly, we identified four different sequences containing regions that were annotated as the 3′-regions of the V1R3 gene (V1R3-3000-7, V1R3-3000-12, V1R3-4000-33, and V1R3-4000-26) from amplification in this study (Supplementary Text S8). Using TBLASTN in the NCBI database (http://www.ncbi.nlm.nih.gov/), two sequences (V1R3-3000-7 and V1R3-3000-12) were identified that contained V1R3 genes (V1R3-a and V1R3-b in V1R3-3000-7 and V1R3-c and V1R3-d in V1R3-3000-12); these genes were arranged in a “tail-to-tail” genomic organization (Fig. 4). In contrast, one V1R3 copy (V1R3-g) was identified in VIR3-4000-26. No stop codon was found inside the CDS (coding sequence) region of the V1R3 fragments in these sequences. Therefore, we identified them as relaxed functional V1R3 genes. In the V1R3-4000-33 sequence, we found two V1R3 genes (V1R3-e and V1R3-f) arranged in a “tail-to-head” genomic organization (Fig. 4, Supplementary Text S8). V1R3-e was identified as a putative functional gene with no stop codon exists inside the CDS region, while the V1R3-f was identified as a pseudogene due to a premature stop codon in its CDS region.
One sequence containing regions that were annotated as the 5′-region of the V1R3 genes was identified from amplification (V1R3-2000-24) (Supplementary Text S8). The V1R3-2000-24, V1R3-Internal, and V1R3-3000-7 sequences were spliced together via sequence assembly with the BIOEDIT 6.0.7 software (Hall 1999).
Based on these results, six putative functional V1R3 genes and one putative pseudogene were identified (Table 1). Therefore, we may predict that some genomic clusters of V1R3 genes exist in pairs in the genome of C. nasus. We detected three transcripts of V1R3 through manual searching of the transcriptome data from the C. nasus epithelium (Zhu et al. 2014) (Supplementary Text S2); this finding was in accordance with the existence of multiple copies of the V1R3 genes in the genome of C. nasus. Moreover, the sequences with the names Unigene55097_All and Unigene18101_All from the transcriptome data were annotated as the 3′-regions of the V1R3 gene (Supplementary Text S2). By aligning these transcript sequences to the identified DNA sequences mentioned above, we found that Unigene55097_All was highly similar with V1R3-b and V1R3-d, while Unigene18101_All was highly similar with V1R3-a, V1R3-c, and V1R3-e.
A novel insight into fish migratory genes may be gained from this result. According to previous reports, there is only one copy of the V1R3 and V1R5 genes in the genome of species that have been examined to date, such as Danio rerio, Oryzias latipes, Gasterosteus aculeatus, T. rubripes, T. nigroviridis, and Haplochromis chilotes (Pfister and Rodriguez 2005; Saraiva and Korsching 2007; Pfister et al. 2007; Ota et al. 2012), which are non-migratory fish. However, the exception is the genome of S. salar, which contains two copies of the V1R3 and V1R5 genes. V1R3-a, V1R3-b, V1R5a, and V1R5b were identified through data mining from the genome (Johnstone et al. 2012). It is possible that the lack of known V1R3 paralogs in the examined species may be due to a lower experimental effort in those comparative studies. If the results are correct, however, species-specific gene expansions may be used in the study of species-specific recognition behavior.
Interestingly, both S. salar and C. nasus have the ability to perform spawning migration behavior. The presence of the same expansion allows us to predict that the V1R3 gene has a relationship with the orientating function during the spawning migration. Some members of the expanded V1R3 genes may have gained novel functions that facilitate the ability of C. nasus to adapt to the long-distance spawning migration.
Additionally, when aligning the sequences of V1R3-3000-7 (V1R3-3-a/V1R3-3-b) and V1R3-3000-12 (V1R3-3-c/V1R3-3-d), we found that the two sequences were similar with high identity (just 5-bp difference), with a indel of 1325-bp sequence in the UTR regions (Supplementary Fig. S9). Among the 5-bp differences, four were located in the UTR regions and one in the CDS region. Local gene duplications might have been occurred in the genome of C. nasus to give rise to V1R3-3-a/V1R3-3-b and V1R3-3-c/V1R3-3-d.
Based on these results, we may conclude that the ancestor of these fish harbored one V1R3 gene, because nearly all of the species that have been investigated possess only one V1R3 gene (Saraiva and Korsching 2007). Therefore, we hypothesized that expansion events of the V1R3 genes may have occurred during the evolutionary history of C. nasus. These events may have resulted from local genome duplications.
Phylogenetic analysis of orthologous V1R genes among teleost fish
To investigate the functions of the identified V1R genes, we aligned the putative amino acid sequences of all of the V1R receptors from the above-mentioned fish and all of the V1R genes identified in this study to construct a phylogenetic tree. Figure 5 shows an unrooted neighbor-joining tree constructed from all of the putatively functional teleost V1R genes.
Based on this phylogenetic tree, the V1R receptors from teleost fish were subdivided into three pairs: V1R1–V1R2, V1R3–V1R4, and V1R5–V1R6. The neighbor-joining tree suggested the monophyly of each V1R gene family through near-maximal bootstrap probabilities. Orthologs of the six V1R genes could be unambiguously identified (Saraiva and Korsching 2007; Ota et al. 2012). This result confirmed that the V1R genes of C. nasus isolated in the present work are all orthologs of the six corresponding known teleost V1R genes. From the tree, we can predict that the genesis of the three clades probably preceded the genesis of the V1R gene pairs (Saraiva and Korsching 2007).
Repetitive elements in the V1R Loci in C. nasus
By aligning the copies with the Repeatmasker online software (http://www.repeatmasker.org/), the simple repeat sequences (ACAC)n and (TGTTAA)n were detected between V1R3-a and V1R3-b. Moreover, the simple repeat sequences (ACAC)n and (TGTTAA)n and (AATAG)n were detected between V1R3-c and V1R3-d, while (ACAC)n, and (TGTTAA)n and (TCTC)n were detected in the flanking region of V1R3-e. Finally, the simple repeat sequence (AGCGGC)n was found in the flanking region of the V1R4 gene.
A copy of SINE (short interspersed nucleotide element), a type of retrotransposon widely distributed in various eukaryotic genomes (Kramerov and Vassetzky 2011), was found to be inserted into the 3′-flanking region of the V1R6 genes. Through the sequence annotation in the NCBI dataset, we found that the SINE copy belonged to the tRNA-derived Cn-SINEs, which are a SINE family that was previously isolated from C. nasus by our laboratory (Liu et al. 2012).
Polymorphism of V1R3 gene in different populations of C. nasus
Different products in the different populations of C. nasus described above were detected via PCR with the V1R3IF and V1R3IR primers (Supplementary Table S3; Supplementary Fig. S10; Supplementary Text S11). Interestingly, a deletion in the V1R3 genes was found in some of the individuals from the populations of Poyanghu Lake and Dongtinghu Lake.
When some of the bands were purified and ligated into vectors for sequencing, some interesting results were obtained (Supplementary Text S11). Several insertions were found in the DNA sequence alignments of the populations from Dongtinghu Lake and Poyanghu Lake, including (GAGTCACACTACCAGTGCTGCCAAGGT)n and (TACCAGTGCTGCTAAGGTGCGTCAC)n. The numbers of the repeats varied in different populations of C. nasus (Supplementary Text S11). However, Supplementary Fig. S10 shows that 75 % of the individuals from the marine and anadromous populations possessed two bands, while 70 % of the individuals from the landlocked and non-anadromous populations possessed a single band. While there is not enough evidence to definitively use this marker to discriminate between populations (Zhu et al. 2014), this finding represents an interesting trend that may be used to address this problem.
These above results may indicate that the degree of differentiation of the populations of Poyanghu Lake and Dongtinghu Lake from the Jingjiang population was higher compared to the Taihu Lake population and Zhoushan population. One explanation may be that the differentiation of the landlocked C. nasus and marine C. nasus from the anadromous C. nasus occurred later than the divergence of non-anadromous C. nasus from anadromous C. nasus.
In addition, copy number variation (CNV) in V1R3 gene among individuals of C. nasus is also indicated, given the polymorphism of V1R3 gene in the different populations of C. nasus (Supplementary Fig. S10; Supplementary Text S11). CNVs, which are interspersed widely in the genome, make great contribution to genome evolution and population-based genetic variation (Conrad et al. 2010; Redon et al. 2006; Reymond et al. 2007; Sebat et al. 2004; Iafrate et al. 2004; Nozawa et al. 2007). The variation in V1R3 gene copy number is likely to be accounted for by olfactory requirements for the C. nasus to adapt to their specific living environments. This result may suggest an interesting pattern of local adaptation by CNV of C. nasus.
Expression profiles of the putative C. nasus V1R genes in different tissues
Any functional olfactory receptor is expected to be specifically expressed in the olfactory receptor neurons situated in the olfactory epithelium (Buck and Axel 1991; Johnstone et al. 2009). To investigate the functions of the identified C. nasus V1Rs, we examined the expression profiles of the V1R transcripts in various adult tissues from anadromous C. nasus migrants collected from the Yangtze River in Jingjing, Jiangsu Province, through qPCR (Fig. 6, Supplementary Table S4).
Five V1R genes (V1R1, V1R2, V1R3-1, V1R4, and V1R5) were primarily expressed in the female and male olfactory rosettes compared to other tissues (Fig. 6); this result was consistent with their assignment as functional olfactory receptors (Buck and Axel 1991; Johnstone et al. 2009). The V1R gene expressions were also detected in other tissues, although most of them have a relatively lower expression level compared to olfactory rosettes, suggesting that these genes may also have non-olfactory functions in other tissues of C. nasus.
In addition, it is worth noting that five V1R genes (V1R2, V1R3-1, V1R4, V1R5, and V1R6) were expressed at a higher level in the male olfactory rosettes than in the female rosette, while two V1R genes (V1R1 and V1R3-2) showed a higher expression level in the female rosettes than in the male rosettes. The sex-biased expression differences suggest that such V1Rs may be putative receptors of chemical cues used for sex-specific behaviors.
Possible contribution of V1R-mediated olfaction to spawning migration behavior in C. nasus
In spring every year, mature anadromous C. nasus migrants undergo the long-distance migration from the ocean coast to the exorheic rivers to spawn in the affiliated lakes (Zhu et al. 2014; Yuan et al. 1980). A pheromone hypothesis has been proposed for S. alpinus and S. salar that assumes that the juvenile salmon in a stream releases population-specific odors that guide homing adults (Nordeng 1971, 1977). We hypothesized that pheromones might be used as odorant cues by the C. nasus migrants to guide their travels during anadromous migration. Therefore, we investigated gene expression levels between the anadromous fish collected from the Jingjiang section of the Yangtze River and the non-anadromous population of C. nasus collected from Poyanghu Lake using qPCR analysis.
Five genes (V1R1, V1R3-1, V1R3-2, V1R4, and V1R5) were upregulated in the olfactory rosettes of anadromous C. nasus compared to the non-anadromous C. nasus (Fig. 7), while two V1R genes (V1R2 and V1R6) were downregulated in anadromous C. nasus compared to non-anadromous C. nasus.
These expression patterns indicate the possibility of a physiological change in the olfactory system of anadromous fish compared with non-anadromous fish. During the spawning migration, anadromous fish may detect odorant cues in the river through their olfaction systems. The detection of these cues may demand an increase in the expression level of a certain set of receptors in order to bind and discriminate all of the odorants in the waters. In contrast, non-anadromous adults may not need it.
Thus, the upregulated V1R1, V1R3-1, V1R3-2, V1R4, and V1R5 genes may be involved in the spawning migration of C. nasus and should receive more attention in future investigations into migration-related genes.
The V1Rs were predicted to detect pheromones (Boschat et al. 2002; Del Punta et al. 2002; Isogai et al. 2011; Behrens et al. 2014). Therefore, the pheromone receptors may be involved in the spawning migration of C. nasus. Our present results on V1R evolution are thus compatible with the hypothesis that C. nasus larvae in the freshwater lakes adjacent to the Yangtze River release pheromones to guide anadromous C. nasus adults to those lakes to spawn via migration up the Yangtze River.
Based on these results, we propose that the larval C. nasus in the fresh lakes adjacent to the Yangtze River release pheromones to guide anadromous C. nasus adults to those lakes to spawn via migration up the Yangtze River.
Conclusion
This study represents a first step toward elucidating the olfactory communication system of C. nasus at the genetic and molecular levels. Altogether, we have identified the whole family of V1R olfactory receptor genes in C. nasus that are highly conserved in fish species. We also detected the expansion events of the V1R3 genes in C. nasus. To date, C. nasus, which has the ability to perform anadromous migration, possesses the largest V1R repertoire in teleost fish. The discovery of the same V1R3 gene expansion event in C. nasus and S. salar provides us with a novel insight into research of migratory fish. Moreover, the divergence of V1R3 genetic structures in different populations of C. nasus indicates the CNV in V1R3 gene among individuals of C. nasus. Besides, we identified three V1R genes that are differentially expressed between anadromous and non-anadromous C. nasus. Therefore, we hypothesize that these V1R genes play an important role in the detection of olfactory cues from river water during the spawning migration of anadromous C. nasus.
References
Alioto TS, Ngai J (2006) The repertoire of olfactory C family G protein-coupled receptors in zebrafish: candidate chemosensory receptors for amino acids. BMC Genom 7:309
Asano-Miyoshi M, Suda T, Yasuoka A, Osima S, Yamashita S, Abe K (2000) Random expression of main and vomeronasal olfactory receptor genes in immature and mature olfactory epithelia of Fugu rubripes. J Biochem 127(5):915–924
Bandoh H, Kida I, Ueda H (2011) Olfactory responses to natal stream water in sockeyesalmon by BOLD fMRI. PLoS ONE 6(1):e16051
Barbin GP, Parher SJ, McCleave JD (1998) Olfactory clues play a critical role in the estuarine migration of silver-phase American eels. Environ Biol Fish 53:283–291
Behrens M, Frank O, Rawel H, Ahuja G, Potting C, Hofmann T et al (2014) ORA1, a zebrafish olfactory receptor ancestral to all mammalian V1R genes, recognizes 4-hydroxyphenylacetic acid, a putative reproductive pheromone. J Biol Chem 289:19778–19788
Boschat C, Pélofi C, Randin O, Roppolo D, Lüscher C, Broillet M-C et al (2002) Pheromone detection mediated by a V1r vomeronasal receptor. Nat Neurosci 5:1261–1262
Buck L, Axel R (1991) A novel multigene family may encode odorant receptors a molecular basis for odor recognition. Cell 65:175–187
Cao Y, Oh BC, Stryer L (1998) Cloning and localization of two multigene receptor families in goldfish olfactory epithelium. Proc Natl Acad Sci USA 95:11987–11992
Conrad DF, Pinto D, Redon R, Feuk L, Gokcumen O, Zhang Y et al (2010) Origins and functional impact of copy number variation in the human genome. Nature 464(7289):704–712
Del Punta K, Leinders-Zufall T, Rodriguez I, Jukam D, Wysocki CJ, Ogawa S et al (2002) Deficient pheromone responses in mice lacking a cluster of vomeronasal receptor genes. Nature 419:70–74
Doving KB, Westerberg H, Johnsen PB (1985) Role of olfaction in the behavior and neural responses of Atlantic salmon, Salmo salar, to hydrographic stratification. Can J Fish Aquat Sci 42:1658–1667
Fuss SH, Ray A (2009) Mechanisms of odorant receptor gene choice in Drosophila and vertebrates. Mol Cell Neurosci 41(2):101–112
Grus WE, Zhang J (2009) Origin of the genetic components of the vomeronasal system in the common ancestor of all extant vertebrates. Mol Biol Evol 26(2):407–419
Hall TA (1999) BioEdit: a user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. Nucleic Acids Symp Ser (Oxf). 41:95–98
Hashiguchi Y, Furuta Y, Nishida M (2008) Evolutionary patterns and selective pressures of odorant/pheromone receptor gene families in teleost fishes. PLoS ONE 3(12):e4083
Hino H, Miles NG, Bandoh H, Ueda H (2009) Molecular biological research on olfactory chemoreception in fishes. J Fish Biol 75(5):945–959
Hirota J, Mombaerts P (2004) The LIM-homeodomain protein Lhx2 is required for complete development of mouse olfactory sensory neurons. Proc Natl Acad Sci USA 101(23):8751–8755
Hussain A, Saraiva LR, Korsching SI (2009) Positive Darwinian selection and the birth of an olfactory receptor clade in teleosts. Proc Natl Acad Sci USA 106(11):4313–4318
Iafrate AJ, Feuk L, Rivera MN, Listewnik ML, Donahoe PK, Qi Y et al (2004) Detection of large-scale variation in the human genome. Nat Genet 36(9):949–951
Isogai Y, Si S, Pont-Lezica L, Tan T, Kapoor V, Murthy VN et al (2011) Molecular organization of vomeronasal chemoreception. Nature 478(7368):241–245
Jahn LA (1967) Responses to odors by fingerling cutthroat trout from Yellowstone Lake. Progress Fish-Culturist 38:207–210
Johansson ML, Banks MA (2011) Olfactory receptor related to class A, type 2 (V1r-like Ora2) genes are conserved between distantly related rockfishes (genus Sebastes). J Hered 102(1):113–117
Johnson MA, Banks MA (2011) Sequence conservation among orthologous vomeronasal type 1 receptor-like (ora) genes does not support the differential tuning hypothesis in Salmonidae. Gene 485(1):16–21
Johnstone KA, Lubieniecki KP, Chow W, Phillips RB, Koop BF, Davidson WS (2008) Genomic organization and characterization of two vomeronasal 1 receptor-like genes (ora1 and ora2) in Atlantic salmon Salmo salar. Mar Genom 1:23–31
Johnstone KA, Ciborowski KL, Lubieniecki KP, Chow W, Phillips RB, Koop BF et al (2009) Genomic organization and evolution of the vomeronasal type 2 receptor-like (OlfC) gene clusters in Atlanticsalmon, Salmo salar. Mol Biol Evol 26(5):1117–1125
Johnstone KA, Lubieniecki KP, Koop BF, Davidson WS (2011) Expression of olfactory receptors in different life stages and life histories of wild Atlantic salmon (Salmo salar). Mol Ecol 20(19):4059–4069
Johnstone KA, Lubieniecki KP, Koop BF, Davidson WS (2012) Identification of olfactory receptor genes in Atlantic salmon Salmo salar. J Fish Biol 81(2):559–575
Kaupp UB (2010) Olfactory signalling in vertebrates and insects: differences and commonalities. Nat Rev Neurosci 11(3):188–200
Korsching S (2009) The molecular evolution of teleost olfactory receptor gene families. Results Probl Cell Differ 47:37–55
Kramerov DA, Vassetzky NS (2011) Origin and evolution of SINEs in eukaryotic genomes. Heredity 107(6):487–495
Laberge F, Hara TJ (2001) Neurobiology of fish olfaction: a review. Brain Res Rev 36(1):46–59
Lane RP, Cutforth T, Axel R, Hood L, Trask BJ (2002) Sequence analysis of mouse vomeronasal receptor gene clusters reveals common promoter motifs and a history of recent expansion. Proc Natl Acad Sci USA 102:5489–5494
Liberles SD, Buck LB (2006) A second class of chemosensory receptors in the olfactory epithelium. Nature 442(7103):645–650
Liu D, Zhu G, Tang W, Yang J, Guo H (2012) PCR and magnetic bead-mediated target capture for the isolation of short interspersed nucleotide elements in fishes. Int J Mol Sci 13(2):2048–2062
Livak KJ, Schmittgen TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2-ΔΔCT method. Methods 25:402–408
McBride JR, Fagerlund UHM, Smith M, Tomlinson N (1964) Olfactory perception in juvenile salmon: II. Conditioned response of juvenile sockeye salmon (Oncorhynchus neeka) to lake waters. Can J Zool 42:245–248
Nei M, Niimura Y, Nozawa M (2008) The evolution of animal chemosensory receptor gene repertoires: roles of chance and necessity. Nat Rev Genet 9:951–963
Niimura Y, Nei M (2005) Evolutionary dynamics of olfactory receptor genes in fishes and tetrapods. Proc Natl Acad Sci USA 102(17):6039–6044
Nordeng H (1971) Is the local orientation of anadromous fishes determined by pheromones ? Nature 233:411–413
Nordeng H (1977) A pheromone hypothesis for homeward migration in anadromous salmonids. Oikos 28:155–159
Nozawa M, Kawahara Y, Nei M (2007) Genomic drift and copy number variation of sensory receptor genes in humans. Proc Natl Acad Sci USA 104(51):20421–20426
Ota T, Nikaido M, Suzuki H, Hagino-Yamagishi K, Okada N (2012) Characterization of V1R receptor (ora) genes in Lake Victoria cichlids. Gene 499(2):273–279
Pfister P, Rodriguez I (2005) Olfactory expression of a single and highly variable V1r pheromone receptor-like gene in fish species. Proc Natl Acad Sci USA. 102(15):5489–5494
Pfister P, Randall J, Montoya-Burgos JI, Rodriguez I (2007) Divergent evolution among teleost V1r receptor genes. PLoS ONE 2(4):e379
Redon R, Ishikawa S, Fitch KR, Perry GH, Andrews TD et al (2006) Global variation in copy number in the human genome. Nature 444(7118):444–454
Reymond A, Henrichsen CN, Harewood L, Merla G (2007) Side effects of genome structural changes. Curr Opin Gene Dev 17(5):381–386
Riviere S, Challet L, Fluegge D, Spehr M, Rodriguez I (2009) Formyl peptide receptor-like proteins are a novel family of vomeronasal chemosensors. Nature 459(7246):574–577
Ryba NJP, Tirindelli R (1997) A new multigene family of putative pheromone receptors. Neuron 19:371–379
Saraiva LR, Korsching SI (2007) A novel olfactory receptor gene family in teleost fish. Genome Res 17(10):1448–1457
Sebat J, Lakshmi B, Troge J, Alexander J, Young J, Lundin P et al (2004) Large-scale copy number polymorphism in the human genome. Science 305(5683):525–528
Shi P, Zhang J (2007) Comparative genomic analysis identifies an evolutionary shift of vomeronasal receptor gene repertoires in the vertebrate transition from water to land. Genome Res 17(2):166–174
Sorensen PW, Fine JM, Dvornikovs V, Jeffrey CS, Shao F, Wang J et al (2005) Mixture of new sulfated steroids functions as a migratory pheromone in the sea lamprey. Nat Chem Biol 1:324–328
Tamura K, Peterson D, Peterson N, Stecher G, Nei M, Kumar S (2011) MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol Biol Evol 28(10):2731–2739
Tarrant RM (1966) Threshold of perception of eugenol in juvenile sockeye salmon. Trans Am Fish Soc 95:112–115
Thompson JD, Gibson TJ, Plewniak F, Jeanmougin F, Higgins DG (1997) The CLUSTAL_X windows interface: flexible strategies for multiple sequence alignment aided by quality analysis tools. Nucleic Acids Res 25:4876–4882
Wang C, Zhu G, Tang W, Liu D, Yang J (2016) Cloning, sequence analysis and tissue expression of Coilia nasus olfactory receptor gene MOR-2AK2. J Fish China 40(1):11–23 (In Chinese with English abstract)
Whitehead PJP, Nelson GJ, Wongratana T (1998) FAO species catalogue. Clupeoid fishes of the world (Suborder Clupeoidei). Part 2. Engraulididae. FAO Fish Synop 125(7):460–475
Wisby WJ, Hasler AD (1954) Effect of olfactory occlusion on migrating silver salmon (Oncorhynchus kisutch). J Fish Res Bd Can. 11:472–478
Xu GC, Wan JJ, Gu RB, Zhang CX, Xu P (2011) Morphological and histological studies on ovary development of Coilia nasus under artificial farming conditions. J Fish Sci China. 18(3):537–546 (In Chinese with English abstract)
Xu GC, Nie ZJ, Zhang CX, Wei GL, Xu P, Gu RB (2012) Histological studies on testis development of Coilia nasus under artificial farming conditions. J Huazhong Agric Univ 31(2):247–252 (In Chinese with English abstract)
Yano K, Nakamura A (1992) Observations on the effect of visual and olfactory ablation on the swimming behavior of migrating adult chum salmon, Oncorhynchus keta. Ichthyol Res 39:67–83
Yuan CM, Qin AL, Liu RH (1980) Discussion on subspecific taxonomy of the genus Coilia in middle and lower reaches of Yangtze River and southeast coastal China Sea. J Nanjing Univ (Nat Sci). 3:67–82 (In Chinese)
Zhang X, Firestein S (2009) Genomics of olfactory receptors. Results Probl Cell Differ 47:25–36
Zhu G, Wang L, Tang W, Liu D, Yang J (2014) De novo transcriptomes of olfactory epithelium reveal the genes and pathways for spawning migration in Japanese grenadier anchovy (Coilia nasus). PLoS ONE 9(8):e103832
Zhu G, Tang W, Liu D (2015) Research progress of olfactory receptor genes in fishes. J Fish China 39(6):916–927 (In Chinese with English abstract)
Acknowledgments
This study was supported by the Special Fund for Agro-Scientific Research in the Public Interest (No. 201203065), the National Natural Science Foundation of China (No. 31172407), the Ministry of Education’s Doctoral Discipline Foundation (No. 20123104110006), and Shanghai Universities First-class Disciplines Project of Fisheries. This research was supported by the Shanghai Outstanding Undergraduate Scholarship for Interdisciplinary Training. This manuscript copy has been edited by American Journal Experts (AJE) who specializes in scientific papers.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: T. Reusch.
Reviewed by Undisclosed experts.
Electronic supplementary material
Below is the link to the electronic supplementary material.
227_2016_2896_MOESM3_ESM.pdf
Supplementary Table S3. PCR primers used to detect polymorphisms in the V1R genes in different populations of Coilia nasus (PDF 315 kb)
227_2016_2896_MOESM4_ESM.pdf
Supplementary Table S4. Primers used for real-time quantitative PCR of the V1R genes of the anadromous and non-anadromous forms of Coilia nasus (PDF 354 kb)
227_2016_2896_MOESM9_ESM.pdf
Supplementary Fig. S9. The alignment of V1R3-3000-7 (V1R3-3-a/V1R3-3-b) and V1R3-3000-12 (V1R3-3-c/V1R3-3-d) (PDF 1309 kb)
227_2016_2896_MOESM10_ESM.pdf
Supplementary Fig. S10. Polymorphism in V1R genes from different populations of Coilia nasus collected from the Jingjiang section of the Yangtze River, the waters of Zhoushan, the Taihu Lake, the Poyanghu Lake, and the Dongtinghu Lake. The M represents the DNA marker. Lanes 1–10 are from the Jingjiang population, 11–20 are from the Zhoushan population, 21–30 are from the Taihu Lake population, 31–40 are from the Poyanghu Lake population, and 41–50 are from the Dongtinghu lake population. Lane 0 is the negative control with sterile water used as the template (PDF 479 kb)
227_2016_2896_MOESM11_ESM.pdf
Supplementary Text S11. Nucleotide sequences of the internal region of the V1R3 gene in the populations from Jingjiang, Zhoushan, Taihu Lake, Poyanghu Lake, and Dongtinghu Lake (PDF 302 kb)
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Zhu, G., Tang, W., Wang, L. et al. Identification of a uniquely expanded V1R (ORA) gene family in the Japanese grenadier anchovy (Coilia nasus). Mar Biol 163, 126 (2016). https://doi.org/10.1007/s00227-016-2896-9
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s00227-016-2896-9