Differential expression of two novel odorant receptors in the locust (Locusta migratoria)
© Xu et al.; licensee BioMed Central Ltd. 2013
Received: 12 March 2013
Accepted: 16 April 2013
Published: 22 April 2013
Olfaction in animals is important for host localization, mating and reproduction in heterogeneous chemical environments. Studying the molecular basis of olfactory receptor neurons (ORNs) systems can elucidate the evolution of olfaction and associated behaviours. Odorant receptors (ORs) in insects have been identified, particularly in the holometabolous model Drosophila, and some of them have been functionally studied. However, ORs in the locust—a hemimetabolous model insect and the most important insect crop pest—have not yet been identified, hindering our understanding of locust olfaction. Here, we report for the first time four putative ORs in Locusta migratoria: LmigOR1, LmigOR2, LmigOR3 and LmigOR4.
These four putative OR genes encoded proteins with amino acids of 478, 436, 413 and 403 respectively. Sequence identity among them ranged from 19.7% to 35.4%. All ORs were tissue-specifically expressed in olfactory organs, without sex-biased characteristics. However, LmigOR1, LmigOR3 and LmigOR4 were only expressed in the antenna, while LmigOR2 could also be detected in mouthparts. In situ hybridization demonstrated that the LmigOR1antisense probe labelled olfactory receptor neurons (ORNs) in almost all segments of the antenna, but only a few segments housed ORNs expressing LmigOR2. The number of neurons labelled by LmigOR1 antisense probes in each antennal segment was much greater (>10 neurons/segment) than that labelled by LmigOR2 probes (generally 1–3 neurons/segment). Furthermore, some of the labelled neurons could be attributed to the basiconic sensilla, but LmigOR1 and LmigOR2 were expressed in different subtypes.
Our results strongly suggested that these newly discovered genes encode locust ORs and the differential expression patterns of LmigOR1 and LmigOR2 implied distinct functions. These results may offer insights into locust olfaction and contribute to the understanding of the evolution of insect chemoreception.
Mammals and insects have adapted evolutionarily to the heterogeneous chemical environments in which they live. Odorant receptors (ORs) in ORNs systems are involved in scent detection and discrimination and are therefore key to understanding the molecular evolution of olfactory mechanisms in animals [1–4].
Insect ORs are evolutionarily unrelated to their vertebrate counterparts. Although insect ORs possess seven transmembrane domains like the G-protein-coupled ORs in vertebrates, the transmembrane topology is completely inverted [5–7]. Since the discovery of the first OR in Drosophila through bioinformatics analysis of the partially sequenced genome [2, 8, 9], numerous OR-coding genes have been identified in various holometabolous insects. In the genomes characterized to date, 60 OR genes have been found in Drosophila [10, 11], 79 in mosquito , 162 in honey bee , and 341 in red floor beetle . Insect ORs evolve rapidly, and there is considerable sequence diversity among OR proteins—many show only ~20% similarity . The olfactory systems of a variety of insect species have been extensively studied. However, it is still very difficult to draw satisfying conclusions about the evolution of insect olfaction because of the absence of studies on some important taxa, such as orthopteran insects .
Most insect ORs are only expressed in olfactory organs such as antennae or maxillary palps [16–19]. Aside from the highly conserved odorant receptor co-receptor (ORco) subfamily, the expression of each individual OR is confined to a unique subset of ORNs, resulting in molecular diversity among ORNs. The “One-Receptor-One-Neuron” model proposed for mammalian olfactory systems also applies to most insect ORNs [2, 20]. ORNs expressing the same ORs were housed in electrophysiologically identical sensilla subtypes and converged to the same glomerulus in the antennal lobe. Extracellular single-unit recordings from individual olfactory sensilla have revealed that different odorants elicit responses from different subsets of ORNs, and that ORNs exhibit a remarkable diversity of response properties [3, 4, 21]. ORNs housed in different sensilla types expressed distinct ORs, allowing the sensilla to be characterized by their molecular and cellular properties [2, 4, 19, 21–23].
Locust (Locusta migratoria) is regarded as a model animal of hemimetabolous insects, and is a notorious worldwide pest that has historically caused tremendous damage to agricultural production . Its behaviours, such as feeding, migration, mating, defence, aggregation, and reproduction, are probably mediated by chemoreception. The development of alternative control methods to replace chemical pesticides will depend on understanding the molecular mechanisms that regulate locust behaviour.
Thus far, we have identified and characterized several locust odorant-binding proteins (OBPs) and chemosensory proteins (CSPs) that are thought to be involved in chemoreception in insects [25–29]. Recently, the evolutionally conserved ORco was identified in locust and found to be ubiquitously expressed in ORNs, just as in other insects . However, extensive efforts to identify functionally specific ORs have failed because of the low sequence homology between ORs and the large evolutionary distances among insect clades. The absence of knowledge about ORs that transduce the binding of odorants into neural activity has hindered further understanding of locust olfaction.
Here, we have identified four novel OR-coding genes in locust and found that LmigOR1 and LmigOR2 showed differential expression patterns in olfactory organs. LmigOR1 was specifically expressed in antennae, whereas LmigOR2 transcripts could also be detected in mouthparts. Some of the ORNs expressing LmigOR1 or LmigOR2 could be found in the basiconic sensilla, but the receptors were present in different sensilla subtypes. These results may offer insights into locust olfaction and contribute to the understanding of the evolution of insect chemoreception.
Identification of odorant receptors in locust
Amino acids identities among the four putative locust ORs
The temporal and spatial expression profile of LmigORs
Expression of LmigOR1 and LmigOR2 in ORNs in olfactory organs
LmigOR1 and LmigOR2 map to distinct subtypes of the basiconic sensilla
We have identified four putative ORs in Locusta migratoria, named as LmigOR1, LmigOR2, LmigOR3 and LmigOR4 and found that they harboured all the characteristic features of insect ORs: seven trans-membrane domains and conserved Ser-Tyr-Ser motif, expression in olfactory organs, and more conserved amino acids at the C terminus than in the N terminal region [2, 8, 17, 31]. However, the new ORs were highly divergent from known insect ORs. This is consistent with the requirement for recognition of a large number of molecularly diverse odorants, and with species-specific expansion of insect OR gene subfamily lineages. Locust has the special microglomerular systems innervated by branched ORNs and projection neurons and may not follow the law of one receptor to one glomerulus in insect . The complex organization of the olfactory system in locust might increase coding capacity and this was correlated with the complicated behavioural plasticity of the locust. Our analysis of the phylogenetic relationships of locust ORs with ORs from other insects further agreed with the view that orthopteran insects, including the locust, play a special role in the study of olfactory evolution, particularly in invertebrates .
ORco is generally expressed in insect ORNs and may serve as a marker for ORNs [3, 30, 33]. Our observation that a few antennal cells expressing LmigOR1 were located within clusters of LmigORco-expressing cells unambiguously defined them as ORNs. The specific expression of LmigOR1 and LmigOR2 in olfactory organs indicated that they are involved in olfaction. Although both OR transcripts could be detected in antennae, their labelling patterns were different. ORNs expressing individual genes were restricted to distinct subsets of antennal ORNs. The assignment of the two OR genes to different functional types of basiconic sensilla indicate that they have contrasting response profiles. The failure of our attempts to localize the expression of LmigOR3 and LmigOR4 in antenna using RNA in situ hybridization experiments may be partially caused by the high GC content of these ORs, which was 71.6% and 67% respectively.
Insects are also equipped with a second nose: the palps. These organs in hawk moth and mosquito serve as detectors for CO2[34, 35], while in Drosophila, they may play a role in taste enhancement . Locust palps have been shown to play critical roles for locating and evaluating food resources . It was therefore not surprising that the expression of LmigOR2 was detected in mouthparts. However, the most fascinating finding was that LmigOR2 was expressed in both antenna and palps. ORs in Drosophila are selectively expressed in only one of these organs [16, 38, 39]. In Drosophila, ORNs housed by basiconic sensilla on antennae and maxillary palpi expressed discrete subsets of OR genes and projected to distinct regions of the antennal lobe, indicating different functions [39, 40]. In locust, the external morphology of the basiconic sensilla on maxillary palpi resembles that on antennae, except for a prominent socket in connection with a membranous cuticle . Whether the basiconic sensilla on maxillary palpi and antennae have different physiological functions must be experimentally verified. Nevertheless, the overlapping expression of LmigOR2 on antennae and palpi, which resembles the differential expression of some mosquito ORs across all three olfactory appendages, reflected a topographic ordering of sensitivity [34, 41].
Some odorant binding proteins, such as LUSH, may serve as triggers that activate ORs through conformational change upon odorant binding . In locust, the odorant-binding protein LmigOBP1 was expressed in all basiconic sensilla on antennae and palps [28, 43]. Its coexpression with LmigORs in the same sensilla made it reasonable to guess that these two proteins may interact; this awaits further investigation.
We can only tentatively deduce the functions of LmigORs because of their high sequence divergence from known ORs. Nevertheless, the differential expression of LmigOR1 and LmigOR2 indicates distinct functions. Furthermore, their ubiquitous expression during development and sex-independent expression pattern suggests that these two receptors may be involved in the detection of general odours rather than pheromones. The LmigOR2 is more likely to be involved in feeding because of its abundant expression in mouthparts [43, 44].
We have for the first time identified four novel OR-coding genes in locust, named as LmigOR1, LmigOR2, LmigOR3 and LmigOR4. Their encoded proteins consist of amino acids of 478, 436, 413 and 403; and their theoretical molecular weights were 50.762, 47.867, 44.321 and 44.805 KD respectively. Sequence identities among them ranged from 19.7% to 35.4%. Our analysis of the phylogenetic relationships of locust ORs with ORs from other insects further agreed with the view that orthopteran insects, including the locust, play a special role in the study of olfactory evolution, particularly in invertebrates. They all specifically express in olfaction related organs, antenna or mouthparts in locust. LmigOR1 and LmigOR2 showed differential expression patterns in olfactory organs. LmigOR1 was specifically expressed in antennae, whereas LmigOR2 transcripts could also be detected in mouthparts. Some of the ORNs expressing LmigOR1 or LmigOR2 could be found in the basiconic sensilla, but the receptors were present in different sensilla subtypes. These results may offer insights into locust olfaction and contribute to the understanding of the evolution of insect chemoreception.
Locusts (L. migratoria) were obtained from the Department of Entomology, China Agricultural University, Beijing, and raised in crowded conditions at 28–30°C, with 60% relative humidity, and a light:dark photoperiod of 18:6 h. They were fed daily with fresh wheat shoots. Intact antennae, mouthparts, tarsi, wings, and midguts were dissected using forceps and stored at −80°C until further processing.
cDNA Library construction
An antennal cDNA library of fourth-instar nymphal locusts was constructed using the SuperScript® Full Length cDNA Library Construction Kit II (Invitrogen, Grand Island, NY, USA) following the manufacturer’s protocol. Highly abundant transcripts were subtracted using the genome-saturation hybridization procedure . Sequencing of ~104 randomly selected positive clones was performed using an ABI 3730XL capillary sequencer (Invitrogen).
Identification of putative LmigORs-coding genes and sequence analysis
Vector sequences were detected and masked using Cross_Match. Assembly of clean ESTs into contigs was performed using the Phrap software package (http://www.phrap.org/phredphrapconsed.html). Previously identified insect OR-coding genes were downloaded from NCBI and used as queries to identify putative locust ORs in the formatted EST database by tBlastn searches with the blast-2.2.25+ package (http://ftp.ncbi.nlm.nih.gov/blast/executables/blast+/2.2.25/). Newly identified ORs were used as query sequences across the database to identify others iteratively. For transmembrane domain predictions, the TMHMM program (v. 2.0) (http://www.cbs.dtu.dk/services/TMHMM-2.0/) was used. Protein sequence alignment was performed in DNAMAN version 7. An unrooted consensus neighbour-joining tree was calculated using default settings with pairwise gap deletions in MEGA-5 . Branch support was assessed using 1,000 bootstrap replicates.
Rapid amplification of cDNA ends (RACE)
The gene fragments were extended in both 5′ and 3′ directions for LmigOR1 and 3′ directions for LmigOR2 by RACE-PCR with gene-specific primers in conjunction with a SMART-amplified antennal cDNA and SMART adapter-specific primers using the Smarter RACE Kit (Clontech, Palo Alto, CA, USA) according to the manufacturer’s manual. Based on the partial LmigORs sequences obtained by blast search of the cDNA library, specific primers for RACE-PCR were designed for touchdown PCRs. PCR products were gel-purified and subcloned using the pGEM-T Easy Kit for sequencing (Promega, Madison, WI, USA).
Expression of LmigORs in different tissues and developmental stages
Total RNA was isolated from frozen tissues using Trizol reagent (Invitrogen) following the manufacturer’s protocols. Reverse transcription was performed using the Quant cDNA Synthesis Kit (Tiangen, Beijing, China) with 1 μg unpurified total RNA as template. Non-quantitative RT-PCRs were performed with gene-specific primers. To test the integrity of the cDNA preparation, primers for the L. migratoria actin gene [Genebank: AY344445] were used. PCR products were run on 1.2% agarose gels and visualized by ethidium bromide staining.
Probe preparation and in situhybridization
Templates of both ORs were generated by standard PCR using gene-specific primer pairs. Digoxigenin (DIG)- or Biotin- labelled antisense and sense probes were generated from linearized recombinant pGem-T Easy plasmids using the T7/SP6 RNA transcription system (Roche, Basel, Switzerland) following recommended protocols. RNA probes were subsequently fragmented to an average length of about 300 bp by incubation in carbonate buffer. RNA in situ hybridization was performed according to previously reported procedures . Briefly, antennae were dissected, embedded in the freezing medium (Tissue-Tek O.C.T. Compound; Sakura Finetek Europe, Zoeterwoude, Netherlands). Sections (12 μm) were prepared at −24°C using a Jung CM300 cryostat (Leica, Nussloch, Germany) and thaw-mounted on SuperFrost Plus slides (Boster, Wuhan, China). After series of fixing and washing procedures, 100 μl hybridization solution (Boster) containing RNA probe was placed onto the tissue section. After adding a coverslip, slides were incubated in a humid box at 55°C overnight. After hybridization, slides were washed twice for 30 min in 0.1 × saline-sodium citrate (SSC) at 60°C, treated with 1% blocking reagent (Roche) in TBST for 30 min at room temperature, then incubated for 30 min with an anti-digoxigenin alkaline phosphatase conjugated antibody (Roche,). Hybridization signals were visualized using NBT/BCIP substrate. Tissue sections were analysed on Olympus IX71microscope (Olympus, Tokyo, Japan).
Fluorescent RNA in situ hybridization was carried out in the same way using DIG- and/or biotin-labelled probes. DIG-labelled probes were visualized by the anti-DIG alkaline phosphatase-conjugated antibody in combination with HNPP/Fast Red (Roche). For biotin-labelled probes, TSA kit (Perkin Elmer, MA, USA), including a strepavidin horse radish peroxidase-conjugate and fluorescin-tyramides as substrate, were used. Images were captured on Olympus BX45 confocal microscope and analyzed using FV1000 software. Images were not altered except for adjusting the brightness or contrast uniformly within a single figure (Additional file 1: Table S2).
We thank Dr. X. Jin’s and two reviewers’ comments on the manuscript. This work was supported by grants from the Natural Science Foundation of China (30730012) and the Special Fund for Agro-scientific Research in the Public Interest (200903021).
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