Abstract
Tuta absoluta (the tomato pinworm) is an invasive insect pest with a highly damaging effect on tomatoes causing between 80 and 100% yield losses if left uncontrolled. Resistance to chemical pesticides have been reported in some T. absoluta populations. Insect microbiome plays an important role in the behavior, physiology, and survivability of their host. In a bid to explore and develop an alternative control method, the associated microbiome of this insect was studied. In this study, we unraveled the bacterial biota of T. absoluta larvae and adults by sequencing and analyzing the 16S rRNA V3-V4 gene regions using Illumina NovaSeq PE250. Out of 2,092,015 amplicon sequence variants (ASVs) recovered from 30 samples (15 larvae and 15 adults), 1,268,810 and 823,205 ASVs were obtained from the larvae and adults, respectively. A total of 433 bacterial genera were shared between the adults and larval samples while 264 and 139 genera were unique to the larvae and adults, respectively. Amplicon metagenomic analyses of the sequences showed the dominance of the phylum Proteobacteria in the adult samples while Firmicutes and Proteobacteria dominated in the larval samples. Linear discriminant analysis effect size (LEfSe) comparison revealed the genera Pseudomonas, Delftia and Ralstonia to be differentially enriched in the adult samples while Enterococcus, Enterobacter, Lactococcus, Klebsiella and Wiessella were differentially abundant in the larvae. The diversity indices showed that the bacterial communities were not different between the insect samples collected from different geographical regions. However, the bacterial communities significantly differed based on the sample type between larvae and adults. A co-occurrence network of significantly correlated taxa revealed a strong interaction between the microbial communities. The functional analysis of the microbiome using FAPROTAX showed that denitrification, arsenite oxidation, methylotrophy and methanotrophy as the active functional groups of the adult and larvae microbiomes. Our results have revealed the core taxonomic, functional, and interacting microbiota of T. absoluta and these indicate that the larvae and adults harbor a similar but transitory set of bacteria. The results provide a novel insight and a basis for exploring microbiome-based biocontrol strategy for this invasive insect pest as well as the ecological significance of some of the identified microbiota is discussed.
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Introduction
On a global scale, insect pests and pathogens are one of the major constraints in crop production1 with up to $2.5 billion per year as cost for their control2. T. absoluta, also called the Tomato pinworm or leafminer, is a destructive invasive insect pest that originated from South America and has spread to other regions of the world including Europe, the Middle East and Africa where the damage is increasingly occurring3,4. It primarily infests tomato plants both in greenhouse and in the open field5, but can also invade other economic crops such as pepper and eggplant6. T. absoluta is a significant threat to tomato farmers worldwide, which if left uncontrolled can cause severe losses of up to 100%4.
Chemical control is usually the main method for control of T. absoluta in several countries and recently with biological control agents like nematodes4,7. However, the use of synthetic pesticide products often results in serious environmental degradation and economic issues, as a result, food and environment are contaminated, cost of production driven up and natural enemies of the insect pests are killed. In addition, some population of T. absoluta have the ability to develop rapid resistance to these chemicals8,9,10,11. Also, the effectiveness of synthetic pesticides is limited as the larvae are difficult to target with insecticide sprays due to their endophytic feeding behaviour12. T. absoluta belongs to the insect order Lepidoptera which undergo complete metamorphosis (holometabolous) with their larval stage being the period of active feeding and growth13,14.
Alternative control strategies should therefore be used within the context of integrated pest management (IPM) for this destructive pest. In the field of pest management, the microbiome of insects has emerged as a promising tool with immense potential for enhancing insect biocontrol strategies15,16,17,18. By understanding the complex interactions between insect hosts and their associated microbes, scientists are uncovering new ways to control pests and reduce the reliance on traditional chemical pesticides19. The understanding and manipulation of the microbial communities associated with insects as a means of biocontrol has proven to be effective in managing pest populations and maintaining ecological balance in agricultural systems20. Furthermore, targeting the microbiome directly or altering it to reduce the vector competence of pests can have significant implications in managing insect populations15.
The microbiomes associated with insect pests are highly diverse. The dynamics within and between members of this microbial communities which include fungi, bacteria and viruses affect the fitness and behaviour of insect pests in various ways21. Studies on insect pest microbiota have demonstrated that various factors shape the microbial community composition, ranging from life stages to the environment as well as host genetics22. In some cases, microbes also contribute towards the pest status of invasive insects23.
Knowledge about the insect microbiome can be harnessed to control invasive insect pests24. Most studies of the lepidopteran microbiota and specifically few studies on T. absoluta have focused only on the adult stage which only reveal a snapshot of the microbial community at that stage. Little is known about the changes in the microbiome at the most important stages of larvae. Previous research on the amplicon metagenomic analyses of the microbiome of invasive insect pest have revealed core microbiota associated with their host. Earlier studies25,26 on larvae of Fall armyworm (Spodoptera frugiperda), causing destruction in maize have revealed the dominance of the phyla Actinobacteria, Proteobacteria and Firmicutes. Similar trend was also recorded on adult T. absoluta in China27 with the phyla Proteobacteria and Firmicutes dominating the microbiome and with samples from different regions having similar microbiome structures.
However, little is known about the complex microbial community associated with both adult and larvae of T. absoluta particularly in sub-saharan Africa. In the present study, we used the NovaSeq Illumina NGS platform to reveal the bacterial microbiome of the larvae and adults of T. absoluta, the network interaction and potential ecological functions.
Materials and methods
Sample collection
Larval and adult samples of T. absoluta were randomly collected from farmers’ tomato fields based on availability. The sampling was done from August to October during the 2022 farming season from six different locations within two agroecological zones in Nigeria: North Central and North West (Table 1).
The North Central (Ilorin and Minna collection points) is a Southern Guinea Savannah with a mean annual rainfall of 1150 mm30, while the North West (Jigawa and Kano), a Sudan Savannah, has a mean annual rainfall of 1000 mm31. Larval samples were collected from the leaves and upper stem by hand picking while adults were collected by swipe net. The adult and larval samples were stored in 90% ethanol in 15 mL falcon and 2 mL Eppendorf tubes, respectively. DNA extraction for all samples was done at the Forest Pathology Research Lab at the University of Helsinki, Finland.
DNA extraction, polymerase chain reaction (PCR), amplification of 16S region and Illumina next generation sequencing
Total genomic DNA was extracted from the larvae and adults of T. absoluta using a modified cetyltrimethylammonium bromide (CTAB) protocol32. Briefly, the protocol is as follows, the larval and adult samples were grinded with a micropestle in a 2 ml tube in presence of liquid nitrogen. CTAB extraction buffer (pre-heated at 65 °C) and DTT (1 mol/L) was added to the tube, vortexed and incubated for 30 min at 65 °C on an Eppendorf Thermomixer Comfort (900 rpm). One volume of chloroform:isoamylalcohol (24:1) was added to the tube, mixed together and then centrifuged at 10,000g for 10 min, after which the upper phase (about 700 μL) was transferred to a new tube. Subsequently, another one volume of chloroform:isoamyl alcohol (24:1) was added to the tube, mixed and centrifuged at 10,000g for 10 min. The supernatant was then transferred into a new 1.5 ml Eppendorf tube, 40 μL NaAc (3 M) and one volume of cold isopropanol were added and incubated at − 20 °C for 20 min. The tube was then centrifuged at 10,000g for 20 min at 4 °C. The supernatant was discarded, and the pellet was washed with 70% ethanol at 12,000g for 5 min at 4 °C. Thereafter, the pellet was dried by discarding the supernatant and inverting the tube in a sterile hood. The DNA was then resuspended in Milli-Q water. The DNA extracted was quantified using NanoDrop Spectrophotometer (2000C, Thermo Scientific) following the manufacturer's protocol.
PCR amplification of the V3–V4 regions of the 16S rRNA regions were performed using the primers 341F (CCTAYGGGRBGCASCAG) and 806R (GGACTACNNGGGTATCTAAT)33 connecting with barcodes. The PCR products with proper size were selected by 2% agarose gel electrophoresis. Libraries were made by pooling equal amounts of PCR products from each sample, end-repaired, A-tailed, and then ligated with Illumina adapters. Libraries were sequenced on a paired-end Illumina platform at Novogene (UK) to generate 250 bp paired-end raw reads (Raw PE). The raw reads were demultiplexed, adapters trimmed and raw data with the sequencing quality information were recorded in a FASTQ file34.
Processing of sequencing data
The paired-end reads were demultiplexed and assigned to samples based on their unique barcodes. Barcodes and primer sequences were cut off from the reads. Quality filtering of the raw reads was performed under specific filtering conditions to obtain the high-quality clean reads. Paired-end reads for each sample were merged using FLASH Version 1.2.11 (http://ccb.jhu.edu/software/FLASH/)35 and then spliced when reads overlapped. The paired-end sequence data were further processed through the Quantitative Insights Into Microbial Ecology (QIIME2) pipeline36. Reads were denoised (i.e. filtered and dereplicated) based on quality scores (below Q30), chimera were detected and removed using the DADA2 algorithm37 to generate amplicon sequence variants (ASVs).
Amplicon sequence variant (ASV) assignment and taxonomic annotation
Amplicon sequence variants (ASVs) taxonomic assignments were done against a pre-trained Naive Bayes classifier and QIIME2-compatible SSUrRNA SILVA database (clustering at 97% similarity threshold, release 138 (http://www.arb-silva.de/)38,39 at each taxonomic rank. Abundance normalization of the ASVs were done based on the smallest sample size (31,101) and was used in further analysis. Rarefaction and diversity analyses including ACE40, Chao141, Shannon and Simpson indices42 were done both in Qiime243 and in Rstudio (version 4.2.0). Principal coordinate analysis (PCoA) was used to assess the Beta diversity with the weighted UniFrac (Bray–Curtis) distance matrix of the relative abundance of ASVs calculated by the QIIME2 using the vegan and ggplot244 package in RStudio (version 4.2.0)45,46. Further analyses and visualizations were carried out using R packages which include qiime2R (v0.99.6) (https://github.com/jbisanz/qiime2R?search=1), phyloseq (v1.38.0)47, and tidyverse (v2.0.0)48.
Statistical analyses of data
Differences in the alpha diversity between samples and relative genera abundances were tested using Wilcoxon rank-sum and Kruskal–Wallis tests (with post hoc Dunn test). Permutational analysis of variance (PERMANOVA) and Kruskal–Wallis test (at p ≤ 0.05) were used to compare the differences in the beta diversity. Microbial ecological network analyses49 was done to assess the interaction between each taxa based on the ASV abundance correlations using the psych package in R and visualized in Gephi (Version 0.9.2). Functional annotation of prokaryotic taxa (FAPROTAX) was used to predict the ecological functional groups of the taxa using the annotated prokaryotic 16S sequence database50,51.
Deposition of nucleotide sequences
The sequences obtained in this study were deposited in the GenBank short-read archive (SRA) with accession number PRJNA1032433 (https://dataview.ncbi.nlm.nih.gov/object/PRJNA1032433).
Results
Sequencing data
A total of 2,561,953 paired-read sequences were obtained from 30 samples which after quality filtering, denoising and chimera removal yielded 2,092,015 sequences (Supplementary Table S1). The sequences from each sample ranged from 31,101 to 102,707 sequences with an average ± standard deviation of 71,276 ± 20,000 reads per sample.
All samples had good coverage based on the rarefaction curves (Fig. 1).
From all the 2,092,015 ASVs recovered from the 30 samples (15 larvae & 15 adults), 1,268,810 ASVs were obtained from the larvae and 823,205 ASVs from the adults. All the ASVs in all samples were identified to belong to bacteria (99.8%) with only 1 sample (AO1) containing an unassigned proportion of 6.86% (Supplementary Fig. S1).
Composition and structure of T. absoluta bacterial biota
The bacterial biota was classified into 36 phyla with Proteobacteria (77.56%) being the most abundant followed by Firmicutes (18.86%), Bacteroidota (1.71%), Actinobacteria (0.96%), Bdellovibrionota (0.27%) and Cyanobacteria (0.22%). The phyla Proteobacteria were more abundant in the adult sample than in the larvae and both Proteobacteria and Firmicutes were more abundant in the larvae (Fig. 2).
Also at the Order taxonomic rank, Pseudomonadales were more abundant in the adult samples which gradually decreased in the larvae while Enterobacterales and Lactobacillales were more abundant in the larvae compared to the adults (Supplementary Fig. S2). A similar changing pattern of relative abundance in the adults and larvae were also obtained at the genus and species level (Fig. 3) where Pseudomonas was more abundant in the adults which reduced drastically in the larvae while Klebsiella, Enterococcus and Enterobacter had the opposite.
A total of 792 bacteria genera (Supplementary Table S2) were present in both the adult and larvae samples with the top 10 members of the group including Pseudomonas, Enterococcus, Klebsiella, Enterobacter, Ralstonia, Erysipelatoclostridium, Lactococcus, Weissella, Aeromonas, and Stenotrophomonas in decreasing other of relative abundance. A similar number of genera 264 and 139 were unique to the adults and larvae respectively while 389 genera were shared (Fig. 3). All the top 10 most abundant genera were not unique to either the adults or larvae but were found overlapping (shared) between the two sample types.
The genera Aurantisolimonas, Luteolibacter, Filimonas, Edaphobaculum, Siphonobacter, Kerstersia and Peredibacter were exclusively found in the larvae, Eubacteriaceae, Muribaculaceae, Kerstersia and Romboutsia were exclusively found in the adults.
Significant differences in the bacterial taxa were also identified by linear discriminant analysis effect size (LEfSe) comparison. The LEfSe chart (Fig. 4) showed that Lactococcus, Enterococcus, Enterobacter and Klebsiella were differentially abundant in the larvae while Pseudomonas, Ralstonia, Delftia were differentially abundant in the adults. This shows that the larvae samples had more taxa signatures than the adults. This is also supported by the Venn diagram above (Fig. 5).
Bacteria community richness and diversity of T. absoluta microbiome
There were differences between the larval (15 samples) and adults (15 samples) alpha diversities (Wilcoxon P ≤ 0.01) (Fig. 6). However, there were no significant differences in the alpha diversities (observed, Shannon and Simpson) between the larval samples from the 3 different (Kruskal–Wallis P > 0.05). Sample F1 from Southwest had the highest diversity species richness (chao1) with Shannon index of 4.04 (Supplementary Fig. S4) while sample K1 had the lowest diversity.
Within the adults, sample AH1 collected from Kazaure, Jigawa had the highest chao1 species richness index of 449 followed by sample AO1 from Rogo, Kano with 388 while sample AL1 from Rogo, Kano had the least richness (127.11) (Supplementary Fig. S5).
The principal coordinates analysis (PCoA) of the ASVs from the larval and adults samples showed distinct clustering which was confirmed significant by PERMANOVA at P < 0.01 (Fig. 7). Larval samples showed higher similarities with each other than with the adult samples and same pattern was observed with the adult-adult samples. Also, the samples did not differ based on location with the microbial communities having more similarities based on sample type.
Microbial network interaction analysis of T. absoluta bacteria communities
The inter-taxa correlations of the bacterial communities were revealed by the network analysis in Rstudio. The networks were explored and visualized with Gephi 0.10.1 (Bastian et al., 2009). The network topology indices such as modularity, clustering coefficient, average node connectivity, average path length and network diameter were calculated (Newman, 2003, 2006). The network analyses involved 150 and 337 core taxa in the adults (Fig. 8A) and larvae (Fig. 8B) respectively with Spearman correlation values ρ > 0.7, and P < 0.001. These core taxa had stronger and more significant connections between them in the larvae than in the adults. The phylum Proteobacteria had more interactions in both the larvae and adult bacterial communities. The average network distance between all pairs of taxa (average path length) and network diameter was lower in the adult bacterial communities (1.28 edges/diameter of 5) compared to (2.7 edges/diameter of 10) in the larvae respectively. The pattern of the network showed that the taxa tend to cluster together more in the adult than in the larvae with a clustering coefficient/modularity index of 0.29/0.79 for the adults and 0.27/0.72 for the larvae respectively.
Based on the weighted in-degree index from the different properties of the network analyses (Supplementary Tables S3 and S4), ASV5511 (Bordetella genomosp), ASV5247 (Enterobacter kobei), ASV5087 (Rhizobium naphthalenivorans), ASV5054 (Kaistia sp.) & ASV5039 (Devosia sp.) with ≥ 15 index were identified as the top keystone taxa in the adult bacterial communities while ASV5511 (Bordetella genomosp), ASV5503 (Bordetella genomosp), ASV4965 (Sphingomonas sp.), ASV4943 (Sphingobium herbicidovorans) and ASV 5099 (Rhizobium sp.) with ≥ 30 index were identified in the larvae.
Potential functional analysis of T. absoluta bacteria microbiome
Functional Annotation of Prokaryotic Taxa (FAPROTAX) was used to predict the functions of the bacterial communities of T. absoluta larvae and adults. A total of 20 putative functional groups (Fig. 9) were prominently identified such as sulphur respiration, arsenite reduction and oxidation as well as nitrification. Nitrous oxide denitrification and nitrite denitrification were the most dominant putative functions both in the adult and larvae bacterial biota followed by nitrate denitrification, dissimilatory arsenite oxidation, arsenite oxidation detoxification, methanol oxidation and methylotrophy.
There were no differences among the larvae and adults and bacterial functional groups (Fig. 9). However, the adults had an increased functional groups in sulfate respiration and methanogenesis activities.
Discussion
In this study, the bacterial biota of T. absoluta were dominated by the phylum Proteobacteria with few Firmicutes which is similar to the only previous microbiome report on T. absoluta from China and Spain27. Proteobacteria has also been reported as dominant in other Lepidopteran insects such as in Spodoptera littoralis52, Brithys crini53 and Cnaphalocrocis medinalis54.
In contrast to the adults, the phylum Firmicutes followed by Proteobacteria were dominant in the larval samples of T. absoluta which is also in line with the larvae microbiome report of Spodoptera littoralis52, Spodoptera frugiperda55,56,57 and Helicoverpa armigera58.
Thakur et al.52 reported the dominance of the phylum Proteobacteria in adults of Spodoptera littoralis which was maintained in the eggs, reduced in the early-instar larvae, and then was gradually switched in the late-instar larvae where the Firmicutes were dominant with less Proteobacteria. This pattern possibly indicates that these bacterial biota are transmitted from adults to newborns via the eggs52. Proteobacteria which are mainly Gram negative are currently the largest phylum within the bacteria domain59 and Fimicutes which are mainly Gram positive and capable of breaking down carbohydrate in the human gut60. Our results are in agreement with previous reports that have shown that microbiomes of Lepidopteran insects are dominated by the phyla Proteobacteria and Firmicutes61.
The abundance of the genus Pseudomonas in the adult samples of T. absoluta has also been reported as dominant in Lepidopteran insects61 and it represents the core bacterial community in the adult samples together with Ralstonia and Delftia. The genus Enterococcus from the phylum Firmicutes which dominated the microbiome of the larval samples in this study has also been reported to be dominant in Lepidopteran insects62,63. Klebsiella and Enterobacter both from the phylum Proteobacteria were also reported present with relatively high abundance next to Enterococcus from the phylum Firmicutes from larvae of Spodoptera frugiperda57. Enterococcus were also found to be dominant in the microbiome study of larvae of Spodoptera littoralis52, S. frugiperda56,57 and from culture-dependent study of S. frugiperda larvae57. Enterobacter was also dominant in fresh larvae of mealworm larvae (Tenebrio molitor)64. Both Enterobacter and Enterococcus have been reported65 as dominant in adult Drosophilia melanogaster.
Bacterial genera such as Weissella, Pseudomonas, Lactococcus, Ralstonia, Enterococcus, Delftia, Enterobacter, Rhizobium, Klebsiella and Achromobacter which were observed in this study to be shared between the larvae and adult samples can persist as symbionts during the larval and adult stages66,67,68 with a considerable change in the composition from larvae to adults. This phenomenon is common in Lepidopteran insects, probably due to dramatic physiological and diet changes during metamorphosis61. It has been suggested that the crucial role of the microbiome in the development of insects is related to aspects such as immunity, reproduction, digestion, nutrition, and production of metabolites such as pheromones and antimicrobial molecules69. Enterococcus sp. isolated from the guts of Plutella xylostella enhance insecticide resistance to chlorpyrifos (organophosphate pesticide) by regulating the expression of an antimicrobial peptide named gloverin63. Insects may need specific bacteria such as Enterococcus sp. to degrade the toxic compounds like alkaloids and latex in their host plant as observed with the insects Hyles euphorbiae and Brithys crini70. Enterococcus spp. are also reported to be involved in plant defense suppression71.
The genus Pseudomonas is one of the most versatile bacterial genera with symbiotic relationship with their insect host72 and commonly found dominant in insects. It is believed to increase the genetic capacity of their hosts to degrade terpenes73 including plant defense suppression71,74 as well as providing pesticide resistance to their insect hosts75. Interestingly, Pseudomonas which was higher in the adults and disappeared in the larvae has been reported to have high larvicidal activity in Spodoptera littura larvae18. Several species of Pseudomonas such as P. paralactis, Pseudomonas entomophila and Pseudomonas chlororaphis have been reported to exhibit insecticidal activities against Spodoptera littura17, Heliothis virescens and Plutella xylostella76. In terms of diversity and richness, there were no significant difference both within the adult and larvae samples based on the different sample location which corroborates the reports of Wang et al.27 on T. absoluta from Spain, Xinjiang and Yunnan as well as that of Ugwu et al.25 on Spodoptera frugiperda. However, some reports revealed that environmental variability, developmental stage52,77 and diet61,78 can influence the insect microbiome. Furthermore, the community structures based on sample types (adults or larvae) were similar from the different agroecological locations.
The PCoA showed a significant difference in the beta diversity between the larval and adult samples which might be as a result of significant shifts in the microbiome as the larvae mature and metamorphosed into the adult stage79. It has been noted that insect developmental stages also have influence on the host microbiome as the composition, pattern, and relative abundance of each taxa changes52,77,80. The larvae had a core microbial taxa which were significantly different from those of the adults which was also supported by the LEfSe analyses. The biomarker discovery by LEfSe identifies the most biologically informative taxa distinguishing two or more genomic dataset81. In this study, the LEfSe result showed that the larvae samples have more taxa signatures than the adults. Gupta et al.82 found that differential abundant increase of Pseudomonas sp. improved pesticide resistance and survivability in adult brown planthopper (Nilaparvata lugens) causing damage in Rice fields. In the same way, Gong et al.83 showed that Delftia which was differentially abundant in T. absoluta adults has been linked with detoxification of insecticides and increased fitness in Nilaparvata lugens. These suggests that one of the ways which insects adapt to insecticides is by shifting its microbiome to interact with beneficial symbiont.
Enterococcus have also been reported to increase larval defense of Bombyx mori to biological control and removal of the Enterococcus symbiont from the larvae would increase the success of biocontrol of this insect larvae84. Enterococcus and Lactococcus can protect insect larvae against pathogens, plant toxins and increase host fitness54,85. Enterococcus is significantly abundant in Hyles euphorbiae and Brithys crini70 and other Lepidopteran larvae86,87.
The microbial network analyses explores the microbiome beyond the compositional and diversity inferences to reveal near real-world interactions between taxa. The co-occurrence pattern observed in this study indicate the presence of highly connected taxa of 4 nodes each on average. The clustering coefficient of the networks also indicate taxa from the same phylum clustered much more closely (77%) as expected in real-world microbial communities88. One of the most useful features of network analysis is that hubs (also termed keystone ASVs), which are taxa that are highly associated in a microbiome can be identified89. The network analyses clearly showed that ASV5511 (Bordetella genomosp.) identified as a keystone taxa in both adult and larvae bacterial microbiomes in T. absoluta had the most interactions with other taxa within the network. However, several other taxa also contributed to interactions within their hubs.
The predicted ecological functions of T. absoluta bacterial biota which showed a dominance of nitrous oxide and nitrite denitrification corroborates the results of the dominance of Pseudomonas, Klebsiella, Enterobacter and Rhizobium both in the network and taxonomic analyses. Denitrifying bacteria enhance the detoxification of organic insecticides in their host63,90,91. Furthermore, members of the Alicagenaceae, Pseudomonaceae and Rhizobiaceae to which most dominant and keystone taxa in this study belong to have been reported to have the As(III) oxidase gene92,93 which is responsible for oxidizing the arsenic found in some arsenic contaminated farms93. This result corroborates the recent study of Wang et al.94 on the abundance of nitrate reduction functions in bacterial communities of the brown planthopper (Nilaparvata lugens) destroying rice fields in Asia.
Conclusion
With the continuous expansion in the geographic distribution of T. absoluta, characterizing the microbial diversity of T. absoluta is a significant step to developing alternative non-chemical methods to combat this pest. This study reveals the bacterial microbiomes of T. absoluta, their abundance, distribution, and interaction. Although no obvious impact on sampling sites was observed, a more detailed study involving samples from the six agroecological zones merit further investigation to ascertain any potential impact of geographical location on the microbiome. The results, however, could further contribute to the development and exploitation of the microbial symbionts and natural enemies of T. absoluta as an alternative to chemical control management strategy of this destructive invasive pest.
Data availability
The sequencing dataset can be found in online SRA repository of the National Center for Biotechnology Information (NCBI) under the BioProject ID PRJNA1032433.
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Acknowledgements
The University of Helsinki is acknowledged for early career mobility postdoc fellowship to AAL and also Ministry of Agriculture and Forestry project funding to FOA (Grant number 4400T-2002), and the University of Ilorin for the permission to carry out the research.
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FOA conceived the study. AAL, HSH, AOO collected the insect samples. FOA, AAL, AA and WR contributed to experiment and data analyses. All authors contributed to the manuscript.
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Lateef, A.A., Azeez, A.A., Ren, W. et al. Bacterial biota associated with the invasive insect pest Tuta absoluta (Meyrick). Sci Rep 14, 8268 (2024). https://doi.org/10.1038/s41598-024-58753-w
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DOI: https://doi.org/10.1038/s41598-024-58753-w
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