Abstract
Tachykinins (TKs) are a group of conserved neuropeptides. In insects, tachykinin-related peptides (TRPs) are important modulators of several functions such as nociception and lipid metabolism. Recently, it has become clear that TRPs also play a role in regulating the insect immune system. Here, we report a transcriptomic analysis of changes in the expression levels of immune-related genes in the storage pest Tenebrio molitor after treatment with Tenmo-TRP-7. We tested two concentrations (10–8 and 10–6 M) at two time points, 6 and 24 h post-injection. We found significant changes in the transcript levels of a wide spectrum of immune-related genes. Some changes were observed 6 h after the injection of Tenmo-TRP-7, especially in relation to its putative anti-apoptotic action. Interestingly, 24 h after the injection of 10–8 M Tenmo-TRP-7, most changes were related to the regulation of the cellular response. Applying 10–6 M Tenmo-TRP-7 resulted in the downregulation of genes associated with humoral responses. Injecting Tenmo-TRP-7 did not affect beetle survival but led to a reduction in haemolymph lysozyme-like antibacterial activity, consistent with the transcriptomic data. The results confirmed the immunomodulatory role of TRP and shed new light on the functional homology between TRPs and TKs.
Similar content being viewed by others
Introduction
Tachykinins (TKs) are one of the largest neuropeptide families that is conserved across the animal kingdom, from Cnidaria to vertebrates1. In insects, neuropeptides with similar structural properties are classified as tachykinin-related peptides (TRPs). TRPs, like TKs, participate in the regulation of many processes. TRPs can, inter alia, modulate the contractile activity of visceral muscles, nociception, and lipid metabolism1,2. Recent results also indicate that TRPs are a very important part of the hormonal axis, which is crucial for fast reactions by insects to stress conditions2,3,4. This importance is indicated by the close interplay between TRPs, insulin-like peptides (ILPs) and adipokinetic hormones (AKHs), a functional homologue of vertebrate glucagon. The regulatory role of these hormones is mostly based on the adjustment of insect metabolism to the current physiological state and to the direct or indirect regulation of insect immune system activity3,4,5,6,7,8. Despite the well-known immunotropic properties of AKHs and ILPs, our knowledge about the role of TRPs in the activity of different immune mechanisms is very limited.
Our previous research provided the first evidence for the possible role of TRPs in regulating the insect immune system in the mealworm beetle Tenebrio molitor9, a storage pest species. The application of Tenmo-TRP-7 (one of the TRPs identified in T. molitor) elicited many physiological effects, resulting in an increase in the total number of circulating haemocytes, a decrease in the number of phagocytic immune cells, and altered haemocyte adhesion. Moreover, Tenmo-TRP-7 enhanced the activity of phenoloxidase (PO) in T. molitor haemolymph9, which is one of the main components of the insect immune system10. The injection of Tenmo-TRP-7 also reduced the DNA damage observed in haemocytes9. We also identified and predicted the sequence and structure of the TRP receptor (TRPR) and confirmed the presence of gene expression encoding TRPR in Tenebrio haemocytes. This result supports the notion that TRPs directly influence the activity of insect haemocytes9. In addition, research conducted by Kamareddine et al.11 showed that the innate immune deficiency (IMD) pathway can regulate TRP transcription in the Drosophila melanogaster gut. However, the regulatory mechanisms of TRPs are still unknown. Based on research conducted in other model organisms, especially vertebrates, one can hypothesize that the application of TRPs could induce changes in the expression level of a wide spectrum of immune-related genes. Current research clearly indicates that in vertebrates, the application of substance P (SP, one of the vertebrate TKs) affects the expression level of genes encoding various cytokines12. Here, we report the transcriptomic changes in immune-related tissues (fat body and haemocytes) of T. molitor after Tenmo-TRP-7 application using RNA-seq. In addition, we investigated insect survival after applying TRP, and we tracked the lysozyme-like antimicrobial activities of T. molitor haemolymph.
Materials and methods
Insects
To control for age- and sex-specific differences in immune system functioning, only 7-day-old adult males of T. molitor were used. The beetles were reared at the Institute of Zoology, Freie Universität Berlin and at the Department of Animal Physiology and Developmental Biology, Adam Mickiewicz University in Poznań according to a method described by El-Shazely et al.13 and Urbański et al.9. Adult males were kept in an incubator under stable conditions (dark, 28 °C). Beetles were kept in sterile, compartmentalized square plastic dishes with oatmeal and apple pieces.
Neuropeptide and tissue collections
Similar to previous research, the neuropeptide Tenmo-TRP-7 (MPRQSGFFGMRa) was used for all the experiments9. Tenmo-TRP-7 was synthesized by Creative Peptides (Shirley, NY, USA; purity > 95% HPLC). Tenmo-TRP-7 was used because of its structural similarity to SP, which possesses immunomodulatory activity in vertebrates6,9.
The neuropeptide solution in physiological saline (2 μL; 274 mM NaCl, 19 mM KCl, 9 mM CaCl2) was injected under the coxa of the third pair of legs 6 or 24 h before tissue collection. In the experiment, two concentrations of Tenmo-TRP-7 were used, 10–7 and 10–5 M (for final concentrations in the Tenebrio haemocoel of 10–8 and 10–6 M, respectively)9,14. In the “Results and discussion” section, the results are related to the final concentration of Tenmo-TRP-7 in the insect haemocoel. The neuropeptide concentrations are based on previous research on TRPs in the Tenebrio immune system activity and on other studies in insects9,15,16.
Before neuropeptide injection or haemolymph and fat body collection, the beetles were anaesthetized with CO2. Haemolymph samples (depending on the experiment, 2 or 5 µL) were collected by cutting the tibia of the first pair of legs. The fat body was collected under sterile conditions just after beetle decapitation using microsurgical tools and a dissecting microscope (Zeiss Stemi 508, Carl Zeiss, Jena, Germany). For the transcriptomic analyses, the fat body and haemolymph were pooled. The collected samples were placed directly in RNA Lysis buffer (Zymo, Irvine, USA). For each experimental condition, at least three biological replicates were collected. One biological replicate contained tissues pooled from 5 individuals. Haemolymph samples were also used for spectrophotometric analysis of their lysozyme-like activity.
Survival
The survival study was modified according to the method described previously by El-Shazely et al.13. Ten male T. molitor individuals that were injected with physiological saline or a Tenmo-TRP-7 solution at concentrations of 10–7 and 10–5 M were kept in a plastic box for 21 days. This box of 10 was considered one biological replicate. The number of individuals was checked every day at the time of the experiment. Each research variant (control, 10–8 and 10–6 M) was repeated at least 5 times (5 replications × 10 individuals = 50 individuals per treatment).
Sequencing, transcriptome assembly and analysis
We used RNA-seq to study the expression of immune-related genes in T. molitor after neuropeptide administration. The fat body and haemolymph were suspended in RNA Lysis buffer (Zymo Research, Irvine, USA) and homogenized using TissueLyser II (Qiagen, Hilden, Germany). RNA isolation was performed using the Zymo Quick RNA MiniPrep kit according to the manufacturer’s protocol, including sample incubation with DNase (Zymo Research, Irvine, USA). The quantity and quality of the RNA were determined with a NanoDrop (Thermo Fisher Scientific, Waltham, USA) and BIOANALYZER 2100 (Agilent, Santa Clara, USA). The mRNA library was prepared using a NEXTflexTM Rapid Directional mRNA-seq Kit (Bio Scientific, Austin, USA). To sequence the prepared library, the Illumina NextSeq500/550 platform was used (Illumina, San Diego, USA).
The raw data processing was based on methods described by Johnston et al.17 and He et al.18. First, Trimmomatic, part of Trinity (v. 2.2.0), was used for data trimming and filtering. During this step, barcodes, adapters, short reads (< 25 bp) and reads of low quality were removed. Trinity was used to assemble pair-end reads. The quality of the assembly was assessed by BUSCO v. 2 with the Arthropod BUSCO set from OrthoDB (version 9). The transcriptome was annotated in accordance with the Trinotate annotation suite guidelines. Trimmed reads were mapped to the reference assembly using RSEM and Bowtie. The difference in gene expression was analysed using the R Bioconductor package DESeq. Transcripts with a minimum of fourfold change in expression at p ≤ 0.05 were extracted and clustered using the R package DIRECT17,19. GO PANTHER (http://pantherdb.org) was used for Gene Ontology (GO) analyses. Based on the resulting transcriptomic data, GO term enrichment analyses on different sets of differentially expressed genes were performed using Goseq20. Further analysis was conducted based on the method described by Bonnot et al.21. The identification of the most representative GO terms from the list of enriched terms using REVIGO (http://revigo.irb.hr) was performed22. The lists of GO terms were prepared by applying a stringent dispensability cut-off (< 0.05). For the graphical presentation of the obtained data, ggplot2 (https://ggplot2.tidyverse.org) for RStudio was used (http://www.rstudio.com)21,23,24. The GO enrichment analyses for GO terms classified as “cellular components” are presented in the Supplementary Materials (Figs. S3–S6). The analysis was performed at the Institute of Biology, Freie Universität Berlin and Berlin Centre for Genomics in Biodiversity Research (BeGenDiv).
Expression level of selected immune-related genes-quantitative PCR assay
The transcriptomic data were verified by analysing the expression levels of selected immune-related genes. Immune-related tissues (fat body and haemocytes) were transferred to 200 μL of RNA lysis buffer (Zymo Research, Irvine, USA) and homogenized for 2 min using a pellet homogenizer (Kimble Chase, USA). For each biological replicate, the tissues collected from 5 individuals were pooled. The homogenized tissues were immediately frozen in liquid nitrogen and stored at − 80 °C. For RNA isolation, a Quick-RNA® Mini-Prep kit (Zymo Research, Irvine, USA) was used. After RNA isolation, DNase treatment of samples with a Turbo DNase Kit (Thermo-Fisher Scientific, Waltham, USA) was performed. Quantification and verification of isolated RNA were performed using a Synergy H1 Hybrid Multi-Mode Microplate Reader (BioTek, Winooski, USA). Reverse transcription of the same amount of isolated RNA (200 ng) to cDNA was accomplished using the RevertAid® First Strand cDNA Synthesis Kit (Thermo-Fisher Scientific, Waltham, USA) according to the manufacturer’s protocol.
The primers for PCR were based on primer sequences previously published by Jacobs et al.25 (Supplementary Materials, Table S1) and were synthesized by Institute of Biochemistry and Biophysics of Polish Academy of Science in Warsaw. Based on the transcriptomic data, genes encoding attacin 2, tenecin 3 and the Toll receptor were selected for the analysis. Reverse transcription quantitative PCR (RT-qPCR) was performed on a Corbett Research RG-6000 Real-Time PCR Thermocycler (Qiagen, Hilden, Germany) with Fast SYBR Green Master Mix (Applied Biosystems, Thermo Fisher Scientific, Waltham, USA) according to the manufacturer’s protocol. The expression level of the gene encoding T. molitor ribosomal protein L13a (TmRpL13a) was used as an internal control to normalize differences in template concentrations between samples (Jacobs et al.25). To check for potential foreign contamination of samples, “no template control” (DNA/RNA free water) and “no RT control” reactions were also included in the analysis (Supplementary Materials, Figs. S1, S2). To confirm our results, the amplicons were sequenced by the Molecular Biology Techniques Laboratory (Faculty of Biology, Adam Mickiewicz University) and compared with data available in a public database (NCBI). For each treatment, 3 biological replicates were used, and 3 technical repetitions were performed. The relative expression was calculated using the 2−ΔΔCt method26.
Lysozyme-like antimicrobial activity of haemolymph from T. molitor
The lysozyme-like antimicrobial activity of haemolymph from T. molitor was tested on the basis of the method described by Arce et al.27. The tested individuals were injected with 2 µL of physiological saline or a solution of physiological saline and Tenmo-TRP-7 at concentrations of 10–7 or 10–5 M. To activate the T. molitor immune system, 2 h after injection, the beetles were injected with 2 µL of a 10% physiological saline solution and attenuated Staphylococcus aureus (Sigma S2014, Saint Louis, Missouri, USA). Twenty-four hours after the physiological saline or neuropeptide injection, haemolymph samples (2 µL) were collected and transferred to 90 µL of ice-cold physiological saline and Micrococcus luteus solution (3 mg/10 mL; OD600 = 0.4, Sigma M3770-5G). Then, the samples were mixed and incubated at 37 °C for 30 min using a Thermomixer comfort 5355 (Eppendorf, Hamburg, Germany). After incubation, the samples were immediately chilled on ice, and the absorbance was checked (λ = 600 nm) using a BioSpectrometer kinetic (Eppendorf, Hamburg, Germany). The sample absorbance was compared to the absorbance of a physiological saline and M. luteus solution (blank; 0). The level of the absorbance reduction, i.e., the reduction in M. luteus content was used to indicate the lysozyme-like activity of the haemolymph. As a positive control, the antimicrobial activity of a physiological saline and lysozyme solution (Sigma L-7651, Saint Louis, Missouri, USA) was tested (0.1 mg/mL). At least 13 individuals were used in each of the treatments, and three independent replications were conducted.
Statistical analysis
For the statistical analysis of physiological experiments, GraphPad Prism software was used (Adam Mickiewicz University licence, version 9.0.0 for Windows, GraphPad Software, San Diego, California USA, www.graphpad.com). Survival was analysed using the log-rank (Mantel–Cox) test. The outliers were defined using the ROUT method (Q = 1). The normality of the distribution was determined using the Shapiro–Wilk test. To check the homogeneity of variance, the Brown–Forsythe test and the Levene test were used. Normally distributed data were analysed with one-way ANOVA and a Student’s t test with Welch’s correction. Data with a non-normal distribution were analysed using the Mann–Whitney U test.
Results and discussion
Survival
Over 21 days, we did not find any statistically significant differences between the control individuals and beetles treated with Tenmo-TRP-7 at concentrations of 10–8 and 10–6 M, which suggests that a single injection does not influence the lifespan of T. molitor. This result suggests a low cytotoxicity from the tested neuropeptide, even at the high concentration of 10–6 M (Fig. 1).
General transcriptome information from T. molitor
We assembled the transcriptome from 20 libraries, each consisting of pooled samples from the fat body and haemocytes of T. molitor, after the injection of physiological saline or Tenmo-TRP-7 treatment at concentrations of 10–8 and 10–6 M. During the transcriptomic assay, 20.852.370–29.416.364 raw reads per library (average: 2.4814.596) were obtained. The average overall alignment rate was 80%. A total of 74–85% of reads uniquely mapped to the reference of the transcriptome assembly for T. molitor, as published by Johnston et al.17. The full transcriptome was submitted to the NCBI database (BioProject: PRJNA781435).
General functional annotation of the transcriptome from T. molitor
The results of a gene ontology analysis on molecular functions and biological processes are shown in Fig. 2. In the case of biological functions, the most abundant GO terms were related to cellular processes (GO:0009987; 35%), metabolic processes (GO:0008152; 23.9%) and biological regulation (GO:0065007; 14.5%). The GO analysis associated with the molecular processes showed that the dominant GO terms were catalytic activity (GO:0003824; 38.7%), ligand binding (GO:0005488; 35.4%) and molecular function regulator (GO:0098772, 11.3%) (Fig. 2).
Differences in the expression levels of genes 6 h after Tenmo-TRP-7 injection
GO enrichment analysis
The GO enrichment analysis showed that Tenmo-TRP-7 injection induced changes in the expression levels of various sets of genes after 6 h. Differences were observed for biological processes, molecular functions, and cellular components (Figs. 3, 4, Figs. S3, S4). GO term enrichment analysis indicated that Tenmo-TRP-7 participates in the regulation of metabolic processes. This regulation is associated with changes in the expression of genes classified to generally metabolic process (GO:0008152), digestion (GO:0007586) or carbohydrate transport (GO:1901505 and GO:0008643) (Figs. 3, 4). These results support previous research concerning the physiological role of TRPs in insects1,28. The results also suggest that Tenmo-TRP-7 may elicit effects directly and indirectly related to immune processes and cell death. These effects are observed after the application of both concentrations used here. In the case of the 10–8 M Tenmo-TRP-7 concentration, a differential expression of genes classified as serine-type peptidase activity terms (GO:0008236, molecular function) was noted, likely connected with the immune-regulatory role of Tenmo-TRP-729 (Fig. 3). Six hours after Tenmo-TRP-7 treatment at a concentration of 10–6 M, GO enrichment analysis confirmed the participation of TRPs in the regulation of immune response and cell death, which was especially visible in the case of GO terms associated with biological processes and molecular functions. At this concentration, the most representative GO terms were positive regulation of Ikappa-B phosphorylation (GO:1903721), programmed necrotic cell death (GO:0097300) or serpins family protein binding (GO:0097655) (Fig. 4).
Differences in the expression levels of immune-related genes
The GO enrichment analysis was enriched by a detailed analysis of differentially expressed genes in the fat body and haemocytes 6 h after Tenmo-TRP-7 injection (Table 1). The presence of the neuropeptide at a concentration of 10–8 M led to a reduction in the expression levels of genes regulating the haemocyte activity. One of these genes is the gene encoding saccharopine dehydrogenase-like oxidoreductase, the overexpression of which is characteristic of the times before and after haemocyte spreading and encapsulation30. Moreover, the gene for a putative serine proteinase, one of the mediators of insect immune responses29, was also downregulated (Table 1).
For the samples collected 6 h after injection, Tenmo-TRP-7 at a 10–6 M concentration also caused a significant downregulation of the putative serine proteinase gene. In addition, a reduction in the expression level of TNF receptor-associated factor 6, which is also involved in the regulation of the insect immune system as a signal transducer of the Toll/Toll-like receptor31, was found (Table 1). In beetles treated with 10–6 M Tenmo-TRP-7, the downregulation of the lysosomal alpha-mannosidase-like precursor gene was shown (Table 1). This precursor is involved in neutrophil degranulation in vertebrates32. In insects, lysosomal alpha-mannosidase, a component of Bracon nigricans venom, can be involved in the regulation of host immunity, especially for the recruitment of haemocytes for wound healing33. Additionally, the gene encoding methyltransferase 2, which inhibits NF-κB function, was strongly overexpressed34. Despite the changes that may indicate the inhibition of immune system functioning, the overexpression of a gene encoding a corepressor that interacts with the recombination signal binding protein for immunoglobulin kappa J 1 (RBPJ 1) was detected. This protein is a part of Notch signalling, which regulates insect development, but crosstalk with immune-related genes was also confirmed35,36,37.
These results are consistent with the results on haemocyte activity obtained by Urbański et al.9, which showed that the injection of Tenmo-TRP-7 led to decreasing numbers of haemocytes participating in phagocytosis. Additionally, a similar effect was observed in an in vitro experiment when neuropeptide was added to the physiological saline during haemocyte incubation on microscopic slides. Previously, we showed that 6 h after Tenmo-TRP-7 injection, the adhesion ability of haemocytes significantly decreased, which aligns with the differences in the expression of saccharopine dehydrogenase-like oxidoreductase30,37. The downregulation of a putative serine proteinase gene that mediates the immune response was also reported. The members of this superfamily participate in many immune processes, such as haemolymph clotting, melanotic encapsulation, antimicrobial peptide (AMP) induction, and cytokine activation38.
The differences between the two Tenmo-TRP-7 concentrations in the modulation of the expression levels of the different sets of immune-related genes observed here can be explained in a number of ways. In immunological studies, our knowledge is based only on data collected in research conducted on vertebrates after the application of SP, TKs homological to Tenmo-TRP-7. Many examples of dose-dependent SP actions on immune mechanisms in vertebrates have been reported39. For example, this neuropeptide might affect different regulatory cytokines39. Additionally, a similar dose-dependent SP activity was observed in the modulation of macrophage and mast cell functions39,40,41. These results are likely related to the fact that the effects of SP can be mediated by the C-terminal and N-terminal ends39,40,41. Recent studies on SP also connect dose-dependent actions of TKs with the regulation of the de/re-sensitization process. As suggested by Roosterman et al.42 and Vigna43, the phosphorylation of neurokinin 1 receptor (NK1R, receptor for SP) is strongly dependent on the concentration of SP. Research conducted on Drosophila TRPs seems to confirm this phenomenon in insects44. Research by Birse et al.45 and Poels et al.46 showed that TRPs can increase the intracellular calcium and cyclic AMP levels differently depending on the concentration. In addition, research conducted on, for example, the fly Bactrocera dorsalis, showed that the EC50 value for TRP oscillated at approximately 10–8 M, but the maximal response was observed at approximately 10–5 M47. We did not exclude the possibility that the effects observed at the highest concentration used here may also be related to the release of other neuropeptides in response to high concentrations of Tenmo-TRP-7 in the insect body. For example, Locmi-TRP-1, identified in Locusta migratoria, may modulate the release of AKH from the locust corpora cardiaca. This effect is known to be dose-dependent48,49.
Differences in the expression levels of genes involved in DNA repair and apoptosis
The GO enrichment analysis showed that Tenmo-TRP-7 injection not only influenced the expression levels of immune-related genes after 6 h but also changed the transcript levels of genes directly/indirectly related to DNA repair and apoptosis. After neuropeptide treatment at a concentration of 10–8 M, the overexpression of the protein downstream neighbour of son homolog gene was visible (Table 1). In humans, this protein is crucial to maintaining genome stability by protecting stalled or damaged replication forks50. At a concentration of 10–6 M, more changes related to the genes participating in DNA repair were reported. Under these conditions, DNA ligase 3-like protein and poly [ADP-ribose] polymerase were overexpressed, and they are involved in the activation and modulation of DNA repair machinery51,52 (Table 1). The results related to DNA repair are consistent with the results presented by Urbański et al.9: administering Tenmo-TRP-7 led to a significant decrease in DNA damage in Tenebrio haemocytes after 6 h, but only at a concentration of 10–8 M. These results also indicate functional homology in TK signalling in vertebrates and insects because SP can delay neutrophil and macrophage apoptosis53,54. In contrast, we previously reported that 6 h post-injection, Tenmo-TRP-7 at a 10–6 M concentration decreased the level of DNA integrity in Tenebrio haemocytes compared to control individuals. This finding may be a result of the overexpression of the previously mentioned methyltransferase 2, which is also a promoter of apoptosis34 (Table 1).
RT-qPCR analysis
The expression levels of genes encoding attacin 2, tenecin 3 and the Toll receptor did not change significantly 6 h after the application of Tenmo-TRP-7 (Fig. 5). The results of the RT-qPCR assay are consistent with the transcriptomic data, which did not show changes in the expression levels of these selected immune-related genes.
Differences in the expression of genes 24 h after Tenmo-TRP-7 injection
GO enrichment analysis
Similar to the differences observed 6 h after the application of Tenmo-TRP-7, the GO enrichment analysis clearly showed that after 24 h, the tested neuropeptide elicited numerous changes in the expression levels of different sets of genes closely related to metabolic processes (Figs. 6, 7). Twenty-four hours after the application of Tenmo-TRP-7, other processes started to become more pronounced, such as biological processes and molecular functions related to energy metabolism (for example, at a concentration of 10–8 M: oxidative phosphorylation, GO:0006119; at a concentration of 10–6 M, ATP metabolic process, GO:0046034), and response to different stimuli, including stress responses (for example, differences in the expression of genes associated with catalytic activity (GO:0003824) at both tested concentrations or the tyrosine metabolic process (GO:0006570) at a concentration of 10–6 M)55,56.
Despite these changes, GO enrichment analysis clearly showed that 24 h after the application of Tenmo-TRP-7, the immunomodulatory impact increased (Figs. 6, 7). At a concentration of 10–8 M, one of the most representative GO terms was cytokine activity (GO:0005125, molecular function) (Fig. 6). In the 10–6 M Tenmo-TRP-7 treatment, the increasing number of GO terms related to immune system functioning was clear (Fig. 7). Under this treatment, the enhanced significance of immune processes was connected to the increasing number of differentially expressed genes classified, for example, as immune response (GO:0006955, biological process), immune system process (GO:0002376, biological process), coagulation (GO:0050817, biological process), pigmen biosynthesis process (GO:0046148), pigment metabolic process (GO:0042440, biological process), cell adhesion (0007155, biological process) or serine-type peptidase activity (GO:0008236, molecular function) (Fig. 7).
Differences in the expression levels of immune-related genes
The detailed bioinformatic analysis of transcriptomic data from immune-related tissues 24 h after Tenmo-TRP-7 injection showed statistically significant changes in the expression of a wide spectrum of immune-related genes (Table 2).
A detailed transcriptomic analysis showed that 10–8 M Tenmo-TRP-7 significantly changed the expression level of genes mostly involved in the regulation of the cellular response (Table 2). Under this treatment, compared to the control individuals, we observed an overexpression of genes encoding cathepsin L-like proteinase (the degradation of internalized material in phagocytic cells), E cadherin (limitation of pro-haemocyte differentiation) and glass bottom boat protein precursor (a cytokine of the TGFβ superfamily)57,58,59 (Table 2). A slight but significant increase in the expression levels of a gene that participates in the generation of damage-causing reactive oxygen species (ROS), xanthine dehydrogenase, was observed60. Additionally, the gene encoding glucose dehydrogenase [FAD, quinone] was downregulated, and it is a marker of the initial activation of the cellular immune response61 (Table 2). The regulation of the previously mentioned different set of immune-related genes confirms our previous findings concerning dose- and time-dependent effects elicited by TRPs but also by other neuropeptides, such as AKHs9,62,63,64 (Table 2).
Tenmo-TRP-7 treatment at a concentration of 10–6 M led to significant changes in the expression levels of many genes related to immune system functioning, including genes encoding AMPs and genes related to the activity of PO system (Table 2). Compared to the control individuals, Tenmo-TRP-7 at a 10–6 M concentration caused a downregulation of genes encoding the AMPs attacins (1a, 1b and 2), tenecins (precursors for tenecins 1 and 3, tenecin 4) and coleoptericins (C and D) (Table 2). Not only did the expression levels of AMP genes decrease, but other genes encoding proteins connected with AMP synthesis, such as beta-1,3-glucan-binding protein 2, Toll-like protein, and serine protease easter-like protein17,65, were also repressed. Interestingly, the gene for the serine protease Persephone (which participate in Toll activation) was overexpressed66. Also, research conducted by Issa et al.67 showed that Persephone belongs to a danger pathway activated by elevated proteolytic activities that can lead to the activation of Toll signalling. Additionally, other important components of the humoral, but also the cellular response were inhibited. For example, the expression levels of genes encoding lysozyme precursors and genes involved in the melanization process, including PO system activity (melanization-related protein, tyrosine hydroxylase, masquerade-like serine proteinase homologue, serpin 40)38,68,69,70,71, were reduced. The expression level of the apolipophorin-III precursor gene, which is involved in the regulation of cellular responses and PO system activity, was significantly decreased72,73. The transcriptomic analysis also showed a decrease in the expression of other genes involved in the regulation of immune system activity, such as genes for grainyhead-like protein (regulation of wound healing), WASH complex subunit 7 (regulation of cytoskeleton arrangement during cell migration), delta and Notch-like epidermal growth factor-related receptor and galactose-binding lectin (involved in immuno-recognition) or lysosomal alpha-mannosidase-like precursor (haemocyte recruitment)33,35,74,75,76 (Table 2). There are other genes that contribute to immune system regulation, but their immunomodulatory role has not been confirmed in insects, and they were also downregulated. For example, the mast cell tryptase-like gene, which is involved in vertebrates, is involved in regulating inflammation, peroxiredoxin 6, which modulates Toll signalling in red swamp crayfish, and cyclic GMP-AMP synthase, the endogenous second messenger in innate immune signalling by cytosolic DNA, were all downregulated32,77,78,79 (Table 2).
All these changes in the expression level of genes associated with the T. molitor immune response indicate a strong inhibition of immune system activity by TRPs during extended stress conditions, consistent with the overexcitation hypothesis62,80,81. This hypothesis assumes that the high concentration of hormones, characteristic of prolonged stress conditions, should result in a reduction in the activity of the immune system. This mechanism has been suggested to be crucial for the protection of host tissues against autoimmunological injuries62,80,81,82. It should also be noted that some of the genes involved in the regulation of insect immune system activity were upregulated. Compared to the control group, the slight overexpression of the peptidoglycan-recognition protein LE gene was observed (Table 2). Genes involved in the integration of signals from pattern recognition receptors (genes encoding modular serine protease zymogen and CLIP-associating protein)83 were overexpressed. Interestingly, the upregulation of some genes related to the melanization process and PO system activity was also found (Table 2). Twenty-four hours after the application of 10–6 M Tenmo-TRP-7, the expression levels of yellow-y precursor and hexamerin precursors (4 and 5) significantly increased84,85. Additionally, overexpression of the Notch pathway (E3 ubiquitin-protein ligase, merlin) and serpin B12 (which plays an important role as an inflammatory regulator in humans) was observed86,87,88. The potential simultaneous inhibition and stimulation of some of the immune system components support previous research concerning the possible role of TRPs in the modulation of the Tenebrio immune system as well as other research on the influence of hormones on insect physiology9. According to the hypothesis proposed by Adamo62, this situation may be explained by the adaptive reconfiguration of the immune system. It is manifested by switching the function of some elements participating in immune process regulation, which causes the inhibition of specific immune mechanisms to be compensated by the stimulation of other parts of this system62.
The differences in transcription 24 h after applying Tenmo-TRP-7 at different concentrations may be explained in a similar way as the presence of the dose-dependent changes observed 6 h after neuropeptide application. The dose-dependent modulation of the expression level of immune-related genes is almost certainly associated with the different activation of the TRP receptor and/or the influence of other neuropeptides, which can be released in response to the presence of TRPs. Moreover, the time-dependent action of Tenmo-TRP-7 can be explained by a general mode of action of neuropeptides. Based on the research by Diniz et al.89 conducted on the TRPs identified in Triatoma infestans, the time to the full degradation of TRPs oscillated at approximately 120 min. The results in vertebrate TKs, especially SP, are comparable to those obtained in research on insects90. However, neuropeptides usually bind to GPCRs (G protein-coupled receptors) and elicit second messenger cascades to modulate cell activity on longer timescales91,92. Research conducted on vertebrate SP found time-dependent activity39. For example, research by Scicchitano et al.93 showed that the time of incubation is crucial in determining the effects of SP on human lymphocytic responses. The inhibitory response was observed after 24 h of incubation with SP, but no effect was found after 48 h of treatment93.
Differences in the expression levels of genes involved in DNA repair and apoptosis
We also found significant changes in the expression of genes involved in DNA repair and apoptosis 24 h post-treatment (Table 2). In the 10–8 M Tenmo-TRP-7 treatment, primarily differences related to apoptosis were observed (Table 2). This observation is linked to the overexpression of caspase-like protein in addition to inositol hexakisphosphate and diphosphoinositol-pentakisphosphate kinase, which are the physiological mediators of cell death94,95. The downregulation of the gene encoding equilibrative nucleoside transporter 3, which is crucial for DNA and RNA synthesis, was also noted96. However, slight overexpression of the DNA mismatch repair protein Msh2 was found97 (Table 2). In the 10–6 M Tenmo-TRP-7 treatment, we observed the overexpression of 26S protease regulatory subunit 4 and an apoptotic chromatin condensation inducer in the nucleus, which are likely involved in regulating apoptosis98,99. The genes for CCR4-NOT transcription complex subunit 6-like protein and E3 UFM1-protein ligase 1 homolog, which is related to the DNA damage response100,101, were downregulated. The gene for histone-arginine methyltransferase CARMER was also downregulated. This methyltransferase is important for the modulation of the ecdysone-induced expression of cell death genes102. In addition, peroxiredoxin 6, which protects DNA against damage associated with oxidative stress77, was downregulated (Table 2). In accordance with our previously published results9, 24 h after Tenmo-TRP-7 injection, changes were observed in the expression levels of genes involved in regulating apoptosis. Our previous research clearly demonstrated that 24 h after testing neuropeptide application, compared to the control, a higher level of DNA damage in Tenebrio haemocytes was observed9. This finding was especially visible in the case of Tenmo-TRP-7 treatment at a concentration of 10–8 M, in which, as current research showed, the overexpression of the gene encoding caspase-like protein was reported9.
RT-qPCR analysis
The RT-qPCR analysis supports the transcriptomic data. Applying Tenmo-TRP-7 led to significant changes in the expression levels of the genes encoding attacin 2, tenecin 3 and Toll receptor (Fig. 8). Similar to the transcriptomic data, the neuropeptide caused a decrease in the expression levels of selected immune genes 24 h after its application at a concentration of 10–6 M (Mann Whitney U test; attacin 2, U = 4.00; p ≤ 0.05; t test with Welch’s correction; tenecin 3, t = 3.70; p ≤ 0.01; and Toll, t = 2.24; p ≤ 0.05). However, significant downregulation of the tenecin 3 and Toll receptor genes was also observed after Tenmo-TRP-7 treatment at a concentration of 10–8 M (t test with Welch’s correction; tenecin 3, t = 4.19; p ≤ 0.01; and Toll, t = 3.28; p ≤ 0.01) (Fig. 8B,C). The observed variances between the RT-qPCR assay and transcriptomic data may be related to the different accuracies of these two methods103.
Differences in the expression levels of genes that may indirectly influence T. molitor immune system activity
The comparative transcriptomic analysis of Tenebrio immune-related tissue revealed genes that are directly involved in regulating immune system functioning. We now report the differential expression of genes that are likely to indirectly influence the immune system. The candidates are genes involved in regulating stress responses (including detoxification and nociception), metabolism, circadian clock, and hormone biosynthesis. All this information is summarized in Table 3.
The changes in the expression level of metabolism-related genes were visible in genes involved in regulating lipid and sugar metabolism (Figs. 3, 4, 6, 7). Some changes were also visible in the expression of genes participating in energy metabolism, protein synthesis and degradation (Figs. 3, 4, 6, 7). The current literature shows that some of these genes can be indirectly involved in modulating immune system functioning104,105,106. A gene encoding glucose-6-phosphate isomerase was downregulated 24 h after applying Tenmo-TRP-7 at a concentration of 10–6 M (Table 3). This protein participates in glycolysis and glyconeogenesis but also immunoglobulin secretion from T-lymphocytes in humans107. Under this concentration, genes for 3-ketodihydrosphingosine reductase (sphingolipid metabolism may be important for immune functioning), transferrin and Malvolio protein (crucial for the regulation of iron homeostasis and immune system activity)104,105,106 were also significantly upregulated (Table 3).
Hormone biosynthesis was also affected by our treatments. Across all treatments, we observed differences in the expression levels of genes associated with juvenile hormones (JHs) biosynthesis and/or JH signalling. In addition to their regulatory role in development and reproduction, JHs may also act as immune suppressors108,109,110. However, some of the published data may also suggest an immunostimulatory role for JH111. Tenmo-TRP-7 at a concentration of 10–8 M led to the upregulation of genes participating in JH biosynthesis (farnesol dehydrogenase and the previously mentioned glass bottom boat protein precursor)58,112,113 (Tables 2, 3). Twenty-four hours after Tenmo-TRP-7 treatment at a concentration of 10–6 M, a decreasing level of expression of the Tenebrin gene (a protein likely involved in JHs and ecdysone signalling) and ornithine decarboxylase (its activity is stimulated by JH) were observed114,115 (Table 3).
Angiotensin converting enzyme (ACE), which is closely associated with the regulation of reproduction, development and hormone biosynthesis116, was overexpressed. Interestingly, research conducted by Macours et al.117 showed that ACE can be important for haemocyte activity because bacterial infection led to the increased expression of a gene for ACE in the haemocytes of desert locust. Wang et al.116 supported these results experimentally and showed elevated transcript levels of the ACE gene in the fat body during viral infection. Additionally, the application of 10–6 M Tenmo-TRP-7 after 24 h caused an increase in the expression levels of genes encoding ACE and ACE2 (Table 3). However, this finding may be related to the fact that ACE is required for TRP degradation in insects118.
An interesting finding is that in tissues collected 24 h after neuropeptide application at a concentration of 10–6 M, the gene encoding insulin-related peptides (LIPR-lGF_insulin_bombyxin_like domain-containing protein) was significantly downregulated (Table 3). This result supports the hypothesis about a close connection between TRPs and ILP signalling4,119. The inhibition of ILP signalling can cause multiple changes in insect physiology ranging from sugar and lipid metabolism to the direct and indirect modulation of immune system functioning2,3,5. We also found the downregulation of the gene encoding the insulin-like growth factor-binding protein complex acid labile subunit (Table 3). Insulin-like growth factor-binding proteins are a group of secreted proteins that serve as transport proteins for insulin-like growth factors (IGFs) that also influence the immune system120,121. Notably, the gene for tyrosine decarboxylase (TDC) was also downregulated (Table 3). Tyrosine decarboxylase, an enzyme catalysing the first decarboxylation step in the biosynthesis of tyramine and octopamine, is extremely important in the modulation of insect homeostasis during the stress response, including the modulation of insect metabolism and immune system functioning56,122. The decreased expression level of the TDC gene may lead to the inhibition of the immune response after Tenmo-TRP-7 administration because octopamine can enhance phagocytosis and AMP synthesis123,124. The importance of this observation is highlighted by the fact that one of the most representative GO terms was tyrosine metabolism process (Fig. 7). Interestingly, 24 h post-injection, 10–8 M Tenmo-TRP-7 modulated other hormonal signalling related to stress because the overexpression of the neuromedin U/CAPA-PVK receptor gene was observed (Table 3). CAPA-PVK signalling is primarily involved in the regulation of ion homeostasis, but our current research suggests that this group of neuropeptides could be involved in regulating the cellular response and haemocyte adhesion ability125.
Under all Tenmo-TRP-7 treatments, differences in the expression of other genes involved in the stress response were reported (Table 3). In particular, differences in the expression levels of genes participating in the detoxification and/or metabolism of endogenous substances were observed. This participation included genes for cytochrome P450 or the multidrug resistance-associated protein lethal and genes related to oxidative stress responses (for example, genes for G-protein coupled receptor Mth-like 1, alpha-tocopherol transfer protein or apolipoprotein D)55,126,127,128,129,130,131,132 (Table 3). Moreover, 10–6 M Tenmo-TRP-7 caused the overexpression of heat shock 70 kDa protein (Hsp70) 24 h after its administration. Research conducted by Tang et al.133, for example, confirmed that Hsp70 also plays an essential role in regulating insect immune system activity.
Nociception is closely associated with the functioning of transient receptor potential channels (TRP channels). Tachykinins are a key component of nociception via the modulation of TRP channel activity134. Current research clearly shows that the activity of these channels is also required to modulate pathogen recognition and inflammation135,136. TRP channels are evolutionarily conserved structures that are involved in nociception and the modulation of different physiological processes in insects137. We found a decrease in the expression level of the gene encoding the TRP channel protein painless138 24 h after Tenmo-TRP-7 treatment at a concentration of 10–6 M (Table 3). TRP channels are also strongly involved in regulating the circadian cycle, consistent with the finding that other genes involved in the modulation of this process were downregulated 24 h after the application of Tenmo-TRP-7 (see also Wolfgang et al.137). Our comparative transcriptomic analysis showed that the tested neuropeptide injection at the highest concentration led to a decrease in the expression level of genes encoding regucalcin, takeout-like protein, and circadian clock-controlled protein-like protein139,140,141. Recent studies have shown that genes related to the control of circadian clock genes are required to modulate immune system activity, including cellular and humoral responses142,143. In addition, research conducted on the Pacific oyster Crassostrea gigas showed that regucalcin can suppress the apoptosis of haemocytes by regulating caspase-3 activity and nitric oxide (NO) production144.
Lysozyme-like antimicrobial activity of T. molitor haemolymph
To confirm that the reported changes in the expression level of immune-related genes have a significant impact on the activity of T. molitor immune mechanisms, the lysozyme-like antimicrobial activity of the haemolymph was analysed. The results showed statistically significant differences in the antimicrobial activity of T. molitor haemolymph after Tenmo-TRP-7 injection (one-way ANOVA, df = 3, 49; F = 16.03; p ≤ 0.0001) (Fig. 9): neuropeptide application led to a decrease in the lytic activity of T. molitor haemolymph against M. luteus. Despite the differences between the positive control (lysozyme 0.1 mg/mL), the inhibition of lysozyme-like antimicrobial activity in haemolymph was observed only in the comparison of the control group to the individuals treated with Tenmo-TRP-7 at a concentration of 10–6 M (t test with Welch’s correction, t = 2.30; p ≤ 0.05). These results are consistent with the previously mentioned overexcitation hypothesis and our previously published data9. Moreover, the antimicrobial assay also supports the presented transcriptomic analysis, which suggests that the observed changes in immune system functioning might be a result of the downregulation of immune-related genes, especially genes for lysozyme precursor and antimicrobial peptides as well as changes associated with genes participating in the regulation of metabolism and stress response (Tables 1, 2, 3). The lack of a significant inhibition of lysozyme-like activity after injecting 10–8 M Tenmo-TRP-7 does not indicate a lack of immunomodulatory properties for TRP at lower concentrations. Our previous research clearly showed that 10–8 M Tenmo-TRP-7 can modulate the haemocyte adhesion ability, which can also affect the activity of the T. molitor immune system9. Moreover, the transcriptomic data also confirmed that 10–8 M Tenmo-TRP-7 mostly modulated the cellular response.
Conclusions
Our results shed new light on the regulation of the insect immune system by neuropeptides such as Tenmo-TRP-7 and the functional homology of TK signalling across different animal phyla. The comparative transcriptomic analysis confirmed previously published results and hypotheses on the time- and dose-dependent action of TRPs on insect immune system activity. The immunomodulatory effect was also observed in the analysis of lysozyme-like antimicrobial properties of Tenebrio haemolymph after the injection of Tenmo-TRP-7.
Knowledge about the hormonal regulation of basic physiological processes and factors that lead to immune deficiency in T. molitor, one of the storage pests, may be useful for developing new, specific and biosafe methods of pest control. In addition, due to confirmed structural and functional homology between TKs and TRPs, the presented results may be helpful for searching new alternative models in biomedical research for the study of hormonal regulation in innate immune function.
Data availability
The transcriptomic data were submitted to the NCBI database (BioProject: PRJNA781435; https://www.ncbi.nlm.nih.gov/bioproject/PRJNA781435). The rest of the datasets used during the current study are available from the corresponding author on reasonable request.
References
Nässel, D. R., Zandawala, M., Kawada, T. & Satake, H. Tachykinins: Neuropeptides that are ancient, diverse, widespread and functionally pleiotropic. Front. Neurosci. 13, 1262 (2019).
Toprak, U. The role of peptide hormones in insect lipid metabolism. Front. Physiol. 11, 434 (2020).
Dolezal, T., Krejcova, G., Bajgar, A., Nedbalova, P. & Strasser, P. Molecular regulations of metabolism during immune response in insects. Insect Biochem. Mol. 109, 31–42 (2019).
Urbański, A. & Rosiński, G. Role of neuropeptides in the regulation of the insect immune system—Current knowledge and perspectives. Curr. Protein Pept. Sci. 19, 1201–1213 (2018).
Chowański, S. et al. Insulin-like peptides and cross-talk with other factors in the regulation of insect metabolism. Front. Physiol. 12, 973 (2021).
Ahlers, L. R. et al. Insulin potentiates JAK/STAT signaling to broadly inhibit flavivirus replication in insect vectors. Cell Rep. 29, 1946–1960 (2019).
Suzawa, M., Muhammad, N. M., Joseph, B. S. & Bland, M. L. The toll signaling pathway targets the insulin-like peptide Dilp6 to inhibit growth in Drosophila. Cell Rep. 28, 1439–1446 (2019).
Zhang, J. et al. Regulation of antimicrobial peptide genes via insulin-like signaling pathway in the silkworm Bombyx mori. Insect Biochem. Mol. 103, 12–21 (2018).
Urbański, A. et al. A possible role of tachykinin-related peptide on an immune system activity of mealworm beetle, Tenebrio molitor L.. Dev. Comp. Immunol 120, 104065 (2021).
Cerenius, L. & Söderhäll, K. Immune properties of invertebrate phenoloxidases. Dev. Comp. Immunol. 122, 104098 (2021).
Kamareddine, L., Robins, W. P., Berkey, C. D., Mekalanos, J. J. & Watnick, P. I. The Drosophila immune deficiency pathway modulates enteroendocrine function and host metabolism. Cell Metab. 28, 449–462 (2018).
Zhang, Y., Berger, A., Milne, C. D. & Paige, C. J. Tachykinins in the immune system. Curr. Drug Targets 7, 1011–1020 (2006).
El-Shazely, B., Urbanski, A., Johnston, P. & Rolff, J. In vivo exposure of insect AMP resistant Staphylococcus aureus to an insect immune system. Insect Biochem. Mol. 110, 60–68 (2019).
Marciniak, P., Urbański, A., Kudlewska, M., Szymczak, M. & Rosiński, G. Peptide hormones regulate the physiological functions of reproductive organs in Tenebrio molitor males. Peptides 98, 35–42 (2017).
Marciniak, P. et al. Short neuropeptide F signaling regulates functioning of male reproductive system in Tenebrio molitor beetle. J. Comp. Physiol. B 190, 521–534 (2020).
Mashaghi, A. et al. Neuropeptide substance P and the immune response. Cell. Mol. Life Sci. 73, 4249–4264 (2016).
Johnston, P. R., Makarova, O. & Rolff, J. Inducible defenses stay up late: Temporal patterns of immune gene expression in Tenebrio molitor. G3 4, 947–955 (2014).
He, S. et al. Termite soldiers contribute to social immunity by synthesizing potent oral secretions. Insect Mol. Biol. 27, 564 (2018).
Team, R. C. A Language and Environment for Statistical Computing (2018).
Young, M. D., Wakefield, M. J., Smyth, G. K. & Oshlack, A. Gene ontology analysis for RNA-seq: Accounting for selection bias. Genome Biol. 11, 1–12 (2010).
Bonnot, T., Gillard, M. B. & Nagel, D. H. A simple protocol for informative visualization of enriched gene ontology terms. Bio-protocol 9, e3429 (2019).
Supek, F., Bošnjak, M., Škunca, N. & Šmuc, T. REVIGO summarizes and visualizes long lists of gene ontology terms. PLoS ONE 6, e21800 (2011).
Wickham, H. ggplot2: Elegant Graphics for Data Analysis (Springer, 2016).
R Team. RStudio: Integrated Development for R (RStudio, 2021).
Jacobs, C. G. et al. Endogenous egg immune defenses in the yellow mealworm beetle (Tenebrio molitor). Dev. Comp. Immunol. 70, 1–8 (2017).
Livak, K. J. & Schmittgen, T. D. Analysis of relative gene expression data using real-time quantitative PCR and the 2−ΔΔCT method. Methods 25, 402–408 (2001).
Arce, A. N., Smiseth, P. T. & Rozen, D. E. Antimicrobial secretions and social immunity in larval burying beetles, Nicrophorus vespilloides. Anim. Behav. 86, 741–745 (2013).
Song, W., Veenstra, J. A. & Perrimon, N. Control of lipid metabolism by tachykinin in Drosophila. Cell Rep. 9, 40–47 (2014).
Cao, X. et al. Sequence conservation, phylogenetic relationships, and expression profiles of nondigestive serine proteases and serine protease homologs in Manduca sexta. Insect Biochem. 62, 51–63 (2015).
Hu, J., Du, Y., Meng, M., Dong, Y. & Peng, J. Development of two continuous hemocyte cell sublines in the Asian corn borer Ostrinia furnacalis and the identification of molecular markers for hemocytes. Insect Sci. 28(5), 1382–1398 (2021).
Wajant, H., Henkler, F. & Scheurich, P. The TNF-receptor-associated factor family: Scaffold molecules for cytokine receptors, kinases and their regulators. Cell. Signal. 13, 389–400 (2001).
Nebes, V. L. & Schmidt, M. C. Human lysosomal alpha-mannosidase: Isolation and nucleotide sequence of the full-length cDNA. Biochem. Biophys. Res. Commun 200, 239–245 (1994).
Becchimanzi, A. et al. Venomics of the ectoparasitoid wasp Bracon nigricans. BMC Genom. 21, 1–15 (2020).
Ganesh, L. et al. Protein methyltransferase 2 inhibits NF-κB function and promotes apoptosis. Mol. Cell. Biol. 26, 3864–3874 (2006).
Duvic, B., Hoffmann, J. A., Meister, M. & Royet, J. Notch signaling controls lineage specification during Drosophila larval hematopoiesis. Curr. Biol. 12, 1923–1927 (2002).
Flaherty, M. S., Zavadil, J., Ekas, L. A. & Bach, E. A. Genome-wide expression profiling in the Drosophila eye reveals unexpected repression of notch signaling by the JAK/STAT pathway. Dev. Dyn. 238, 2235–2253 (2009).
Mishra, A. K., Sharma, V., Mutsuddi, M. & Mukherjee, A. Signaling cross-talk during development: Context-specific networking of Notch, NF-κB and JNK signaling pathways in Drosophila. Cell Signal. 82, 109937 (2021).
Jiang, R. et al. 93-kDa twin-domain serine protease inhibitor (Serpin) has a regulatory function on the beetle Toll proteolytic signaling cascade. J. Biol. Chem. 286, 35087–35095 (2011).
Eglezos, A., Andrews, P. V., Boyd, R. L. & Helme, R. D. Modulation of the immune response by tachykinins. Immunol. Cell Biol. 69, 285–294 (1991).
Hartung, H. P. & Toyka, K. V. Activation of macrophages by substance P: Induction of oxidative burst and thromboxane release. Eur. J. Pharmacol. 89, 301–305 (1983).
Mazurek, N., Pecht, I., Teichberg, V. & Btumberg, S. The role of the N-terminal tetrapeptide in the histamine releasing action of substance P. Neuropharmacology 20, 1025–1027 (1981).
Roosterman, D., Cottrell, G. S., Schmidlin, F., Steinhoff, M. & Bunnett, N. W. Recycling and resensitization of the neurokinin 1 receptor: influence of agonist concentration and Rab GTPases. J. Biol. Chem. 279, 30670–30679 (2004).
Vigna, S. Phosphorylation and desensitization of neurokinin-1 receptor expressed in epithelial cells. J. Neurochem. 73, 1925–1932 (1999).
Van Loy, T. et al. Tachykinin-related peptides and their receptors in invertebrates: A current view. Peptides 31, 520–524 (2010).
Birse, R. T., Johnson, E. C., Taghert, P. H. & Nässel, D. R. Widely distributed Drosophila G-protein-coupled receptor (CG7887) is activated by endogenous tachykinin-related peptides. J. Neurobiol. 66, 33–46 (2006).
Poels, J. et al. Functional comparison of two evolutionary conserved insect neurokinin-like receptors. Peptides 28, 103–108 (2007).
Gui, S.-H. et al. Role of a tachykinin-related peptide and its receptor in modulating the olfactory sensitivity in the oriental fruit fly, Bactrocera dorsalis (Hendel). Insect Biochem. Mol. 80, 71–78 (2017).
Nässel, D. R. et al. Evidence that locustatachykinin I is involved in release of adipokinetic hormone from locust corpora cardiaca. Regul. Peptides 57, 297–310 (1995).
Vanden Broeck, J. et al. Tachykinin-like peptides and their receptors: A review. Ann. N. Y. Acad. Sci. 897, 374–387 (1999).
Roseaulin, L. C. et al. Coordinated degradation of replisome components ensures genome stability upon replication stress in the absence of the replication fork protection complex. PLoS Genet. 9, e1003213 (2013).
Amé, J.-C. et al. PARP-2, A novel mammalian DNA damage-dependent poly (ADP-ribose) polymerase. J. Biol. Chem. 274, 17860–17868 (1999).
Wei, Y.-F. et al. Molecular cloning and expression of human cDNAs encoding a novel DNA ligase IV and DNA ligase III, an enzyme active in DNA repair and recombination. Mol. Cell. Biol. 15, 3206–3216 (1995).
Böckmann, S., Seep, J. & Jonas, L. Delay of neutrophil apoptosis by the neuropeptide substance P: Involvement of caspase cascade. Peptides 22, 661–670 (2001).
Kang, B.-N. et al. Regulation of apoptosis by somatostatin and substance P in peritoneal macrophages. Regul. Peptides 101, 43–49 (2001).
Radominska-Pandya, A., Czernik, P. J., Little, J. M., Battaglia, E. & Mackenzie, P. I. Structural and functional studies of UDP-glucuronosyltransferases. Drug Metab. Rev. 31, 817–899 (1999).
Kuo, H.-W. & Cheng, W. Cloning and characterization of tyrosine decarboxylase (TDC) from Litopenaeus vannamei, and its roles in biogenic amines synthesis, immune regulation, and resistance to Vibrio alginolyticus by RNA interference. Dev. Comp. Immunol. 123, 104167 (2021).
Gao, H., Wu, X., Simon, L. & Fossett, N. Antioxidants maintain E-cadherin levels to limit Drosophila prohemocyte differentiation. PLoS ONE 9, e107768 (2014).
Lieber, M. J. & Luckhart, S. Transforming growth factor-βs and related gene products in mosquito vectors of human malaria parasites: Signaling architecture for immunological crosstalk. Mol. Immunol. 41, 965–977 (2004).
Tryselius, Y. & Hultmark, D. Cysteine proteinase 1 (CP1), a cathepsin like enzyme expressed in the Drosophila melanogaster haemocyte cell line mbn-2. Insect Mol. Biol. 6, 173–181 (1997).
Kim, Y. S. et al. Role of xanthine dehydrogenase and aging on the innate immune response of Drosophila. J. Am. Aging Assoc. 24, 187–193 (2001).
Lovallo, N. & Cox-Foster, D. L. Alteration in FAD–glucose dehydrogenase activity and hemocyte behavior contribute to initial disruption of Manduca sexta immune response to Cotesia congregata parasitoids. J. Insect Physiol. 45, 1037–1048 (1999).
Adamo, S. A. The effects of stress hormones on immune function may be vital for the adaptive reconfiguration of the immune system during fight-or-flight behavior. Integr. Comp. Biol. 54, 419–426 (2014).
Goldsworthy, G., Chandrakant, S. & Opoku-Ware, K. Adipokinetic hormone enhances nodule formation and phenoloxidase activation in adult locusts injected with bacterial lipopolysaccharide. J. Insect Physiol. 49, 795–803 (2003).
Goldsworthy, G., Opoku-Ware, K. & Mullen, L. Adipokinetic hormone and the immune responses of locusts to infection. Ann. N. Y. Acad. Sci. 1040, 106–113 (2005).
Paskewitz, S., Reese-Stardy, S. & Gorman, M. An easter-like serine protease from Anopheles gambiae exhibits changes in transcript abundance following immune challenge. Insect Mol. Biol. 8, 329–337 (1999).
Ligoxygakis, P., Pelte, N., Hoffmann, J. A. & Reichhart, J.-M. Activation of Drosophila Toll during fungal infection by a blood serine protease. Science 297, 114–116 (2002).
Issa, N. et al. The circulating protease Persephone is an immune sensor for microbial proteolytic activities upstream of the Drosophila Toll pathway. Mol. Cell 69, 539–550 (2018).
Cerenius, L., Lee, B. L. & Söderhäll, K. The proPO-system: Pros and cons for its role in invertebrate immunity. Trends Immunol. 29, 263–271 (2008).
Lee, K. S., Kim, B. Y. & Jin, B. R. Differential regulation of tyrosine hydroxylase in cuticular melanization and innate immunity in the silkworm Bombyx mori. J. Asia Pac. Entomol. 18, 765–770 (2015).
Tsakas, S. & Marmaras, V. Insect immunity and its signalling: An overview. Invertebr. Surviv. J. 7, 228–238 (2010).
Shu, M. et al. Mechanisms of nodule-specific melanization in the hemocoel of the silkworm, Bombyx mori. Insect Biochem. Mol. 70, 10–23 (2016).
Contreras, E., Rausell, C. & Real, M. D. Tribolium castaneum apolipophorin-III acts as an immune response protein against Bacillus thuringiensis Cry3Ba toxic activity. J. Invertebr. Pathol. 113, 209–213 (2013).
Zakarian, R. J., Dunphy, G. B., Albert, P. J. & Rau, M. E. Apolipophorin-III affects the activity of the haemocytes of Galleria mellonella larvae. J. Insect Physiol. 48, 715–723 (2002).
Lackie, A. & Vasta, G. The role of galactosyl-binding lectin in the cellular immune response of the cockroach Periplaneta americana (Dictyoptera). Immunology 64, 353 (1988).
Pearson, J. C., Juarez, M. T., Kim, M., Drivenes, Ø. & McGinnis, W. Multiple transcription factor codes activate epidermal wound-response genes in Drosophila. PNAS 106, 2224–2229 (2009).
Verboon, J. M., Rahe, T. K., Rodriguez-Mesa, E. & Parkhurst, S. M. Wash functions downstream of Rho1 GTPase in a subset of Drosophila immune cell developmental migrations. Mol. Biol. Cell. 26, 1665–1674 (2015).
Chu, S.-H. et al. Peroxiredoxin 6 modulates Toll signaling pathway and protects DNA damage against oxidative stress in red swamp crayfish (Procambarus clarkii). Fish Shellfish Immunol. 89, 170–178 (2019).
Vitte, J. Human mast cell tryptase in biology and medicine. Mol. Immunol. 63, 18–24 (2015).
Wu, J. et al. Cyclic GMP-AMP is an endogenous second messenger in innate immune signaling by cytosolic DNA. Science 339, 826–830 (2013).
Adamo, S. Why should an immune response activate the stress response? Insights from the insects (the cricket Gryllus texensis). Brain Behav. Immun. 24, 194–200 (2010).
Elenkov, I. J. & Chrousos, G. P. Stress system—Organization, physiology and immunoregulation. NeuroImmunoModulation 13, 257–267 (2006).
Schmid-Hempel, P. Evolutionary ecology of insect immune defenses. Annu. Rev. Entomol. 50, 529–551 (2005).
Kanost, M. R. & Jiang, H. Clip-domain serine proteases as immune factors in insect hemolymph. Curr. Opin. Insect Sci. 11, 47–55 (2015).
Eliautout, R. et al. Immune response and survival of Circulifer haematoceps to Spiroplasma citri infection requires expression of the gene hexamerin. Dev. Comp. Immunol. 54, 7–19 (2016).
Massimino, C. et al. Annotation and analysis of yellow genes in Asian citrus psyllid, Diaphorina citri, vector for the Huanglongbing disease. BioRxiv. https://doi.org/10.1101/2020.12.22.422960 (2020).
Lanz-Mendoza, H. & Garduño, J. C. Advances in Comparative Immunology 193–211 (Springer, 2018).
Moretti, J. & Brou, C. Ubiquitinations in the notch signaling pathway. Int. J. Mol. Sci. 14, 6359–6381 (2013).
Vidalino, L. et al. SERPINB3, apoptosis and autoimmunity. Autoimmun. Rev. 9, 108–112 (2009).
Diniz, L. C. L., Alves, F. L., Miranda, A. & da Silva Junior, P. I. Two tachykinin-related peptides with antimicrobial activity isolated from Triatoma infestans hemolymph. Microbiol. Insights 13, 1178636120933635 (2020).
Bury, R. W. & Mashford, M. L. The stability of synthetic substance P in blood. Eur. J. Pharmacol. 45, 257–260 (1977).
Caers, J. et al. More than two decades of research on insect neuropeptide GPCRs: An overview. Front. Endocrinol. 3, 151 (2012).
Hökfelt, T., Bartfai, T. & Bloom, F. Neuropeptides: Opportunities for drug discovery. Lancet Neurol. 2, 463–472 (2003).
Scicchitano, R., Bienenstock, J. & Stanisz, A. M. The differential effect with time of neuropeptides on the proliferative responses of murine Peyer’s patch and splenic lymphocytes. Brain Behav. Immun. 1, 231–237 (1987).
Courtiade, J., Pauchet, Y., Vogel, H. & Heckel, D. G. A comprehensive characterization of the caspase gene family in insects from the order Lepidoptera. BMC Genomics 12, 1–12 (2011).
Nagata, E. et al. Inositol hexakisphosphate kinase-2, a physiologic mediator of cell death. J. Biol. Chem. 280, 1634–1640 (2005).
Boswell-Casteel, R. C. & Hays, F. A. Equilibrative nucleoside transporters—A review. Nucleos. Nucleot. Nucl. 36, 7–30 (2017).
Sekelsky, J. J., Brodsky, M. H. & Burtis, K. C. DNA repair in Drosophila: Insights from the Drosophila genome sequence. J. Cell Biol. 150, 31–36 (2000).
Murachelli, A. G., Ebert, J., Basquin, C., Le Hir, H. & Conti, E. The structure of the ASAP core complex reveals the existence of a Pinin-containing PSAP complex. Nat. Struct. Mol. Biol. 19, 378–386 (2012).
Naujokat, C. & Hoffmann, S. Role and function of the 26S proteasome in proliferation and apoptosis. Lab. Investig. 82, 965–980 (2002).
Klebanovych, A. et al. C53 interacting with UFM1-protein ligase 1 regulates microtubule nucleation in response to ER stress. BioRxiv 1863, 1282 (2020).
Zhang, X.-P., Liu, F. & Wang, W. Two-phase dynamics of p53 in the DNA damage response. PNAS 108, 8990–8995 (2011).
Cakouros, D., Daish, T. J., Mills, K. & Kumar, S. An arginine-histone methyltransferase, CARMER, coordinates ecdysone-mediated apoptosis in Drosophila cells. J. Biol. Chem. 279, 18467–18471 (2004).
Rachinger, N. et al. Loss of gene information: Discrepancies between RNA sequencing, cDNA microarray, and qRT-PCR. Int. J. Mol. Sci. 22, 9349 (2021).
Abhyankar, V., Kaduskar, B., Kamat, S. S., Deobagkar, D. & Ratnaparkhi, G. S. Drosophila DNA/RNA methyltransferase contributes to robust host defense in aging animals by regulating sphingolipid metabolism. J. Exp. Biol. 221, 187989 (2018).
Iatsenko, I., Marra, A., Boquete, J.-P., Peña, J. & Lemaitre, B. Iron sequestration by transferrin 1 mediates nutritional immunity in Drosophila melanogaster. PNAS 117, 7317–7325 (2020).
Tang, X. & Zhou, B. Iron homeostasis in insects: Insights from Drosophila studies. IUBMB Life 65, 863–872 (2013).
Faik, P., Walker, J. I., Redmill, A. A. & Morgan, M. J. Mouse glucose-6-phosphate isomerase and neuroleukin have identical 3′ sequences. Nature 332, 455–456 (1988).
Rolff, J. & Siva-Jothy, M. T. Copulation corrupts immunity: A mechanism for a cost of mating in insects. PNAS 99, 9916–9918 (2002).
Chang, M.-M. et al. Regulation of antimicrobial peptides by juvenile hormone and its receptor, Methoprene-tolerant, in the mosquito Aedes aegypti. Insect Biochem. Mol. 128, 103509 (2021).
Flatt, T. et al. Hormonal regulation of the humoral innate immune response in Drosophila melanogaster. J. Exp. Biol. 211, 2712–2724 (2008).
Tian, L. et al. Genome-wide regulation of innate immunity by juvenile hormone and 20-hydroxyecdysone in the Bombyx fat body. BMC Genomics 11, 1–12 (2010).
Mayoral, J. G., Nouzova, M., Navare, A. & Noriega, F. G. NADP+-dependent farnesol dehydrogenase, a corpora allata enzyme involved in juvenile hormone synthesis. PNAS 106, 21091–21096 (2009).
Van der Zee, M., Da Fonseca, R. N. & Roth, S. TGFβ signaling in Tribolium: Vertebrate-like components in a beetle. Dev. Genes Evol. 218, 203–213 (2008).
Birnbaum, M. J. & Gilbert, L. I. Juvenile hormone stimulation of ornithine decarboxylase activity during vitellogenesis in Drosophila melanogaster. J. Comp. Physiol. B 160, 145–151 (1990).
Royer, V., Hourdry, A., Fraichard, S. & Bouhin, H. Characterization of a putative extracellular matrix protein from the beetle Tenebrio molitor: Hormonal regulation during metamorphosis. Dev. Genes Evol. 214, 115–121 (2004).
Wang, X. et al. Immune function of an angiotensin-converting enzyme against Rice stripe virus infection in a vector insect. Virology 533, 137–144 (2019).
Macours, N., Hens, K., Francis, C., De Loof, A. & Huybrechts, R. Molecular evidence for the expression of angiotensin converting enzyme in hemocytes of Locusta migratoria: Stimulation by bacterial lipopolysaccharide challenge. J. Insect Physiol. 49, 739–746 (2003).
Nachman, R. J. et al. An aminoisobutyric acid-containing analogue of the cockroach tachykinin-related peptide, LemTRP-1, with potent bioactivity and resistance to an insect angiotensin-converting enzyme. Regul. Peptides 74, 61–66 (1998).
Birse, R. T., Söderberg, J. A., Luo, J., Winther, Å. M. & Nässel, D. R. Regulation of insulin-producing cells in the adult Drosophila brain via the tachykinin peptide receptor DTKR. J. Exp. Biol. 214, 4201–4208 (2011).
Chen, Y. et al. Insulin-like growth factor binding protein 3 gene of golden pompano (TroIGFBP3) promotes antimicrobial immune defense. Fish Shellfish Immunol. 103, 47–57 (2020).
Varma Shrivastav, S., Bhardwaj, A., Pathak, K. A. & Shrivastav, A. Insulin-like growth factor binding protein-3 (IGFBP-3): Unraveling the role in mediating IGF-independent effects within the cell. Front. Cell Dev. Biol. 8, 286 (2020).
Huang, J., Wu, S.-F., Li, X.-H., Adamo, S. A. & Ye, G.-Y. The characterization of a concentration-sensitive α-adrenergic-like octopamine receptor found on insect immune cells and its possible role in mediating stress hormone effects on immune function. Brain Behav. Immun. 26, 942–950 (2012).
Adamo, S., Roberts, J., Easy, R. & Ross, N. Competition between immune function and lipid transport for the protein apolipophorin III leads to stress-induced immunosuppression in crickets. J. Exp. Biol. 211, 531–538 (2008).
Yakovlev, A. Y. & Gordya, N. Hormonal influence on antimicrobial peptide synthesis by fat body cells of a blowfly, Calliphora vicina R.-D. (Diptera, Calliphoridae). Entomol. Rev. 93, 150–154 (2013).
Urbański, A., Walkowiak-Nowicka, K., Nowicki, G., Chowański, S. & Rosinski, G. Effect of short-term desiccation, recovery time and CAPA-PVK neuropeptides on the immune system of the burying beetle Nicrophorus vespilloides. Front. Physiol. 12, 845 (2021).
Cui, F. et al. Carboxylesterase-mediated insecticide resistance: Quantitative increase induces broader metabolic resistance than qualitative change. Pestic. Biochem. Physiol. 121, 88–96 (2015).
Ganfornina, M. D. et al. Apolipoprotein D is involved in the mechanisms regulating protection from oxidative stress. Aging Cell 7, 506–515 (2008).
Lu, K., Song, Y. & Zeng, R. The role of cytochrome P450-mediated detoxification in insect adaptation to xenobiotics. Curr. Opin. Insect Sci. 43, 103–107 (2021).
Parker, R. S. & McCormick, C. C. Selective accumulation of α-tocopherol in Drosophila is associated with cytochrome P450 tocopherol-ω-hydroxylase activity but not α-tocopherol transfer protein. Biochem. Biophys. Res. Commun. 338, 1537–1541 (2005).
West, A. P., Llamas, L. L., Snow, P. M., Benzer, S. & Bjorkman, P. J. Crystal structure of the ectodomain of Methuselah, a Drosophila G protein-coupled receptor associated with extended lifespan. PNAS 98, 3744–3749 (2001).
Kang, X. L., Zhang, M., Wang, K., Qiao, X. F. & Chen, M. H. Molecular cloning, expression pattern of multidrug resistance associated protein 1 (mrp1, abcc1) gene, and the synergistic effects of verapamil on toxicity of two insecticides in the bird cherry-oat aphid. Arch. Insect Biochem. Physiol. 92, 65–84 (2016).
Jagdale, S., Tellis, M., Barvkar, V. T. & Joshi, R. S. Glucosinolate induces transcriptomic and metabolic reprogramming in Helicoverpa armigera. 3 Biotech 11, 1–14 (2021).
Tang, T. et al. Stress-induced HSP70 from Musca domestica plays a functionally significant role in the immune system. J. Insect Physiol. 58, 1226–1234 (2012).
Naono-Nakayama, R., Sunakawa, N., Ikeda, T. & Nishimori, T. Differential effects of substance P or hemokinin-1 on transient receptor potential channels, TRPV1, TRPA1 and TRPM8, in the rat. Neuropeptides 44, 57–61 (2010).
Delvalle, N. M. et al. Communication between enteric neurons, glia, and nociceptors underlies the effects of tachykinins on neuroinflammation. Cell. Mol. Gastroenterol. 6, 321–344 (2018).
Khalil, M. et al. Functional role of transient receptor potential channels in immune cells and epithelia. Front. Immunol. 9, 174 (2018).
Wolfgang, W., Simoni, A., Gentile, C. & Stanewsky, R. The Pyrexia transient receptor potential channel mediates circadian clock synchronization to low temperature cycles in Drosophila melanogaster. Proc. R. Soc. B Biol. Sci. 280, 20130959 (2013).
Tracey, W. D. Jr., Wilson, R. I., Laurent, G. & Benzer, S. Painless, a Drosophila gene essential for nociception. Cell 113, 261–273 (2003).
Dong, C.-L., Lu, M.-X. & Du, Y.-Z. Transcriptomic analysis of pre-diapause larvae of Chilo suppressalis (Walker) (Lepidoptera: Pyralidae) in natural populations. Comp. Biochem. Physiol. D 40, 100903 (2021).
Sarov-Blat, L., So, W. V., Liu, L. & Rosbash, M. The Drosophila takeout gene is a novel molecular link between circadian rhythms and feeding behavior. Cell 101, 647–656 (2000).
Vesala, L., Salminen, T., Kankare, M. & Hoikkala, A. Photoperiodic regulation of cold tolerance and expression levels of regucalcin gene in Drosophila montana. J. Insect Physiol. 58, 704–709 (2012).
Damulewicz, M. et al. Daily regulation of phototransduction, circadian clock, DNA repair, and immune gene expression by heme oxygenase in the retina of Drosophila. Genes 10, 6 (2019).
Kuo, T.-H., Pike, D. H., Beizaeipour, Z. & Williams, J. A. Sleep triggered by an immune response in Drosophila is regulated by the circadian clock and requires the NFκB Relish. BMC Neurosci. 11, 1–12 (2010).
Lian, X. et al. The involvement of a regucalcin in suppressing hemocyte apoptosis in Pacific oyster Crassostrea gigas. Fish Shellfish Immunol. 103, 229–238 (2020).
Qin, W. & Walker, V. K. Tenebrio molitor antifreeze protein gene identification and regulation. Gene 367, 142–149 (2006).
Eidhof, I. et al. GDAP2 mutations implicate susceptibility to cellular stress in a new form of cerebellar ataxia. Brain 141, 2592–2604 (2018).
Meng, X. et al. Effects of Ag nanoparticles on growth and fat body proteins in silkworms (Bombyx mori). Biol. Trace Elem. Res. 180, 327–337 (2017).
Bergé, J., Feyereisen, R. & Amichot, M. Cytochrome P450 monooxygenases and insecticide resistance in insects. Philos. Trans. R. Soc. Lond. B Biol. Sci. 353, 1701–1705 (1998).
Birnbaum, M. J. & Gilbert, L. I. Juvenile hormone stimulation of ornithine decarboxylase activity during vitellogenesis in Drosophila melanogaster. J. Comp. Physiol. B Biochem. Syst. Environ. Physiol. 160, 145–151 (1990).
Hara, N. et al. Elevation of cellular NAD levels by nicotinic acid and involvement of nicotinic acid phosphoribosyltransferase in human cells. J. Biol. Chem. 282, 24574–24582 (2007).
Taniuchi, S., Miyake, M., Tsugawa, K., Oyadomari, M. & Oyadomari, S. Integrated stress response of vertebrates is regulated by four eIF2α kinases. Sci. Rep. 6, 1–11 (2016).
Acknowledgements
The research was partially supported by Grant No. 2021/41/B/NZ9/01054 from the National Science Centre (Poland). AU was supported by a scholarship from the Polish National Agency for Academic Exchange (NAWA) within the Bekker Programme, 2019 (personal stipend, PPN/BEK/2019/1/00167), a scholarship from the Deutscher Akademischer Austauschdienst (DAAD) within the program for Research Stays for University Academics and Scientists, 2018 (personal stipend, 91696887), and a scholarship from the Initiative of Excellence, Research University (ID-UB Project), within the International Junior and Senior Exchange, 2021 (personal stipend, 018/07/POB2/0001). The publication fee was supported by the ID-UB Project (040/08/POB2/0010). JR was funded by DFG FOR 5026.
Author information
Authors and Affiliations
Contributions
A.U. and J.R. conceived the original screening and research plan; A.U., E.B., V.P., M.K., K.W.N. and N.K. performed the experiments; A.U. and P.J. analysed the data; A.U. created the figures and tables; and A.U., K.W.N. and P.M. wrote the manuscript. All the authors reviewed the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Urbański, A., Johnston, P., Bittermann, E. et al. Tachykinin-related peptides modulate immune-gene expression in the mealworm beetle Tenebrio molitor L.. Sci Rep 12, 17277 (2022). https://doi.org/10.1038/s41598-022-21605-6
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-022-21605-6