1. Introduction

Aedes (Stegomya) albopictus (Diptera, Culicidae) (Skuse 1894), commonly known as the Asian tiger mosquito, and originally from Southeast Asia, experimented a quick expansion across the Pacific and Indian Ocean [1], reaching the Americas, Africa and Europe in the past few decades [2]. In Europe, A. albopictus was first reported in Albania in 1979 and, after its introduction in Italy, it rapidly colonized the rest of the Mediterranean countries [3,4,5]. It is thought that the expansion of this invasive species was mainly favored by the shipment of used tires infested with eggs, which were able to survive until they reached their destination. Additionally, the increase in the temperatures due to climate change may have facilitated its establishment in temperate European countries [6]. Although, A. albopictus is generally considered thermophilic; however, because of its ecological plasticity, tolerance to cold temperatures and the ability of its eggs to enter diapause have allowed it to be present in every inhabited continent [7]. For this reason, recent studies predict its establishment in every suitable environment beyond 2050, affecting up to 197 territories of the world [8,9].

Because of its opportunistic blood feeding behavior, A. albopictus can be exposed to different pathogens. Although A. albopictus can feed on a large number of animals, they prefer humans as a blood source, which results in the infection of more than one billion people with vector-borne diseases every year [10]. This makes it one of the most important vectors of arbovirus diseases, such as chikungunya (CHIKV) [11,12], dengue (DENV) [13] and Zika (ZIKV) [14,15], which are a major threat to public health, as they can cause symptoms like fever, hemorrhages and neurological diseases, among others [16]. In 2007, the first outbreak of chikungunya in Italy causing high fever, joint pain and an itchy skin rash caused public alarm and concern about the reemergence of previously eradicated mosquito-borne diseases in Europe [6].

Today, the control of dipteran vectors of disease is addressed through source reduction, chemical pesticides, biological control, genetic control or combinations of these [17,18]. A. albopictus larvae can grow in natural and artificial water containers, either outdoors or in peridomestic environments that can be eliminated when possible or treated with larvicidal insecticides [18]. Larvicide and source reduction are the most efficient methods because they give long-term results. The control of larvae can be achieved through chemical insect growth regulators, organophosphates or Bacillus thuringiensis (Bt)-based insecticides. Chemicals such as pyrethroids and organophosphates can be highly toxic if used in great amounts, and they are most likely to produce insecticide resistance in mosquitoes [19,20,21]. These have been consistently used as an efficient method to control the spread of mosquito-borne diseases; however, the development of resistances has led to outbreaks and an increased vector competence of mosquitoes [22]. The most common mechanisms of resistance in mosquitoes are genetic mutations on the target sites of the active ingredients or changes in metabolism [21].

Bt-based solutions represents a good alternative to chemicals since they have a relatively low environmental impact and a high target specificity that make them eligible for the treatment of drinkable water due to its non-toxicity to humans and animals [23,24]. Bt is a gram-positive and spore-forming bacterium capable of producing a parasporal crystal composed of insecticidal proteins [25]. Strains from the serovar israeliensis, Bti, are mainly used for the control of dipteran pests. Their parasporal crystals are mainly composed of four major δ-endotoxins (Cry4Aa, Cry4Ba, Cry11Aa and Cyt1Aa), which are highly toxic to insects of the Dipteran order, including mosquitoes. However, recent studies showed that species of the Aedes genus had started to develop resistances to the individual Bti proteins Cry4Aa, Cry4Ba and Cry11Aa [26,27,28,29,30]. Among the Bti-based products, Vectobac-12AS, a liquid formulation of strain AM 65–52^®, is probably the most popular [31,32,33]. Although this particular strain had already been evaluated against A. albopictus larvae, the effects of each of its individual proteins remained unknown [34]. In this study, we characterized the toxicity of the individual Cry4Aa, Cry4Ba, Cry11Aa and Cyt1Aa proteins against A. albopictus larvae. Additionally, we focused on identifying new Cry and Cyt proteins for the control of A. albopictus larvae that represent an alternative to the classic Bti toxins and, hence, serve as a preventive measure for upcoming resistances. Finally we found a new Cyt protein, Cyt1A-like, which behaved as a synergistic factor by enhancing the activity of Cry11Aa and as an enabler of activity of three new non-active mosquitocidal proteins.

2. Results

2.1. Activity of Cry and Cyt Proteins from Strain AM 65-52 against A. albopictus Larvae

In previous studies, the genome sequencing of strain AM 65-52 revealed its pesticidal gene content, which included the cry4Aa, cry4Ba, cry10Aa, cry11Aa, cry60Aa/cry60Ab, cyt1Aa, cyt2Ba and cyt1Ca genes [35,36,37,38,39]. Since there was no publicly available data on the activity of each of the top four components of its crystals, Cry4Aa, Cry4Ba, Cry11Aa and Cyt1Aa against A. albopictus larvae, we decided to evaluate them individually. For this purpose, the genes required for expressing each of the proteins were cloned in vectors optimized for the expression of δ-endotoxins in Bt [40,41], and the resulting plasmids transformed into the acrystalliferous Bt strain BMB171, as previously described [40]. The cry4Aa (3543 bp), cry4Ba (3426 bp), cry11Aa (1941 bp) and cyt1Aa (750 bp) genes were independently cloned, and the resulting recombinant strains expressing cry4Aa, cry4Ba, cry11Aa and cyt1Aa were grown in CCY medium for 48–72 h. The mixtures of spores and crystals were run in an SDS-PAGE. Figure 1 shows that the observed bands are coincidental with the predicted molecular weight of each of the four proteins: 134 kDa for Cry4Aa, 128 kDa for Cry4Ba, 27 kDa for Cyt1Aa and 73 kDa for Cry11Aa.

The mosquitocidal activity of the single δ-endotoxins was evaluated on second instar larvae of A. albopictus at two different concentrations of spores and crystals (1000 ng/mL and 1.00 ng/mL). Cry4Ba showed the highest activity at 1000 ng/mL, with a mortality of 100%. Conversely, Cry11Aa seemed to be the least active of the tested proteins, with a mortality of 73.33% ± 0.11 at 1000 ng/mL (Table S1). Once the activity scale for each toxin was defined, the LC₅₀ for each of them was calculated, which resulted in 178 ng/mL, 46 ng/mL, 228 ng/mL and 171 ng/mL for Cry4Aa, Cry4Ba, Cry11Aa and Cyt1Aa, respectively (Table 1). Strains AM 65-52 and BMB171 were used as positive and negative controls, respectively. As expected, AM 65-52 showed high mosquitocidal activity, with a LC₅₀ of 0.019 ng/mL.

2.2. Potential Mosquitocidal Cry, Cyt and Tpp Genes from the BST Collection

To expand the number of potential mosquitocidal proteins with activity against A. albopictus, we conducted an in silico screening of 36 Bt wild type strains from our private collection. These were previously isolated from soil samples from several regions and habitats from Spain. Considering that the literature on active Bt proteins against A. albopictus larvae is scarce, we used previously described toxins against Aedes aegypti (Diptera, Culicidae) and other Aedes species as a query to select potential new toxic proteins and synergistic factors [31,33,42,43,44]. Based on our sequencing data, we chose strains BST059.3 and BST-230 as a source of potentiators of toxicity and new mosquitocidal toxins, respectively. Although BST059.3 did not show any activity against A. albopictus larvae (LC₅₀ > 1 × 10⁵ ng/mL of spore-and-crystal mixture), the strain carried two cyt1-like genes: cyt1A-like and cyt1D-like. Cyt proteins have been extensively described as synergistic factors that are able to potentiate the activity of Bti toxins in different genera of mosquitoes, such as Aedes, Anopheles and Culex [45,46,47]. In particular, Cyt toxins were shown to increase the activity of Cry4Aa, Cry4Ba, Cry10Aa and Cry11Aa when combined together [40,42,45,48]. In agreement with this, we hypothesized that cyt1A-like and cyt1D-like might be able to produce proteins with a similar function to that of the previously described Cyt toxins. In the case of BST230, several new genes of interest were found, namely, cry4-like, cry53-like, cry56-like and tpp36-like. Table 2 contains a list of the new δ-endotoxins and their identity percentages with each of their closest matches, including Cyt1Aa5, Cyt1Da1, Cry4Aa4, Cry53Ab1, Cry56Aa2 and Tpp36Aa1.

To study the mosquitocidal properties of the newly found crystal proteins, genes cry4-like, cry53-like, cry56A-like and Tpp36-like were amplified from strain BST-230, cloned into pTBT02, and the resulting vectors electroporated into strain BMB171. In the case of Cry53-like, we were not able to observe any crystals at first (Figure 2A). In order for it to crystallize, we had to include an additional open reading frame (ORF) of 1623 bp downstream of the cry53-like coding sequence (CDS) (3004 bp), mimicking its original architecture in the genome. The sequence of this ORF matched the typical Domain V from the crystallization region (C terminal) of Cry1Ac, according to the Conserved Domains Database (CDD) [49]. These C-terminal domain ORFs are often found in mosquitocidal protoxins [50] and, in this case, were required for crystal formation (Figure 2B). Likewise, Cry56A-like also required a fragment of 1692 bp, namely orf1, upstream of its CDS (1974 bp) for effective crystal formation (Figure 2B). Analogously, the cyt1A-like and cyt1D-like genes were amplified from strain BST059.3 and independently cloned into pTBT02. However, neither of them were able to form crystals (Figure 2A). To solve this, both genes were cloned including the p20 orf, and the resulting plasmids were used to transform strain BMB171. The reason for including p20 was to promote crystal formation in the Cyt proteins during sporulation (Figure 2B) [51,52].

2.3. Characterization of the Bt Recombinant Strains Expressing the New Potential Mosquitocidal Proteins

The BMB171 recombinant strains carrying cry4-like, cry53-like, cry56A-like, cyt1A-like, cyt1D-like and tpp36-like were able to produce spores and crystals when grown in CCY medium for 48–72 h. An SDS-PAGE analysis showed the expected molecular weights for most of the new recombinant proteins. The predicted sizes of Cyt1A-like (~31 kDa), Cyt1D-like (~59kDa) and Cry4-like (~130 kDa) correlated with their observed bands (Figure 3). Cry53-like:orf2 (lane 6) showed two bands: one of ~70 kDa (Cry53-like), which was a little lower than the expected size (76 kDa), and a band of ~62kDa (orf2). For Cry56A-like:orf1 (lane 7), we were able to detect both expected band sizes ~73 kDa (Cry56A-like) and 64 kDa (orf1). Tpp36-like produced a clear band of ~40 kDa (lane 8), although the expected size was about ~55kDa. All of the plasmids were sequenced and did not have any changes and/or mismatches in their sequences.

The mosquitocidal activity of the new δ-endotoxins was evaluated on second instar larvae of A. albopictus. For these experiments, 1 × 10⁵ ng/mL and 1 × 10³ ng/mL of spore-and-crystal mixtures were used as high and low concentrations, respectively. Surprisingly, when analyzing the results, none of the Cry-like and Tpp-like individual proteins showed activity, indicating that they might need to act in partnership with others to produce toxicity.

2.4. Synergies between Cyt and AM 65-52 Cry Proteins

To address the potential of Cyt1Aa, Cyt1A-like and Cyt1D-like to produce synergistic interactions with Cry4Aa, Cry4Ba and Cry11Aa against A. albopictus larvae, we decided to evaluate the effect of 1:1 mixtures on the aforementioned proteins. The preliminary results of the potential synergistic interactions are shown in Table S2. A potential synergy was considered when the activity of the 1:1 mix was higher than the sum of the individual activities of the two proteins. Finally, LC₅₀ values were calculated. As previously shown in other mosquito species, Cyt1Aa enhanced the activity of Cry4Aa, Cry4Ba and Cry11Aa. However, in the case of the two new Cyt proteins, only Cyt1A-like increased the activity of Cry11Aa, with a synergism factor of 23.14. Cyt1D-like did not potentiate the activity of any of the toxins. Table 3 shows the LC₅₀ for each of the binary combinations that produced synergistic interactions.

2.5. Cyt Proteins as Enablers of Activity of Cry and Tpp Toxins

Because none of the new potential mosquitocidal proteins found in strain BST-230 showed activity on their own, we wondered if Cyt1Aa, Cyt1A-like and Cyt1D-like might be able to make them active against A. albopictus larvae. Considering that Cry56A-like is non-active, we would have expected the LC₅₀ of the Cyt1Aa + Cry56A-like mix to equal the LC₅₀ of Cyt1Aa (171 ng/mL). However, the activity of the mix was higher by 7.3-fold, with an observed LC₅₀ of 23.3 ng/mL. For the Cyt1A-like combinations, the expected LC₅₀ was greater than 10⁵ ng/mL since no activity could be observed for them when tested individually. Nevertheless, when mixing Cyt1A-like with Cry53-like, Cry56A-like and Tpp36-like, the LC₅₀ values were 1331, 186 and 1053 ng/mL, respectively (Table 4). These results indicated that although Cyt1 proteins are considered synergistic factors of Cry proteins, in some cases, they may behave as enablers of activity of otherwise non-toxic proteins in a specific manner.

3. Discussion

Mosquito larvae are highly susceptible to Bti crystals, for which the typical composition is usually a combination of the Cry4Aa, Cry4Ba, Cry11Aa and Cyt1Aa proteins in variable proportions. Interestingly, when analyzing the relative amount of each of the proteins in the parasporal crystal, only a limited number of the anticipated pesticidal proteins are represented and with variable abundance: Cyt1Aa (38–61%), Cry60Ba (5–12%), Cry11Aa (10–27%), Cry4Ba (10–28%), Cry60Aa (2–4%) and Cry4Aa (2–4%) [53]. Although the activity of the major components of the AM 65-52 crystal were previously characterized against A. aegypti and species from the genera Culex and Anopheles, little information is available on their effect on A. albopictus larvae [54,55,56,57,58]. Additionally, the synergistic interactions between the components of the crystals received attention from different research groups due to the activity of the single Bti proteins being below the toxicity of the complex crystal. Despite this, A. albopictus has rarely been used as a model organism for these kind of studies. The reason for this may be the fact that it was traditionally associated with wild animals and territories, and hence, it was a less dangerous species for humans [59]. A. aegypti, on the contrary, has often been regarded as the primary vector of arborviruses in human health, becoming the most studied mosquito within its genus. However, in recent times, the A. albopictus gained notoriety due to its establishment in Western countries, specifically those in the Mediterranean coast. This led the European authorities to increase the resources allocated to monitoring its spread and to enforce measures to avoid the reemergence of previously eradicated diseases, such as Dengue, especially in countries like Italy and France, where outbreaks of this mosquito have been reported [10,60,61]. For this reason, our research group deemed it appropriate to expand the knowledge on the Bti toxin susceptibility of other Aedes species to A. albopictus. We began by characterizing the insecticidal activity of individual Bti toxins on tiger mosquito L2 larvae. The LC₅₀ values for Cry4Aa, Cry4Ba, Cry11Aa and Cyt1Aa of 178, 46, 228 and 171 ng/mL, respectively, were similar to the previously described ones for A. aegypti. These results suggested that both species may have a similar susceptibility to Bti toxins and crystals [42,44]. When analyzing the synergistic interactions of Cyt1Aa, we found that it was able to potentiate the activity of Cry4Aa, Cry4Ba and Cry11Aa by 28.14-, 32.46- and 11.44-fold, respectively. This synergistic effect on the activity of the individual toxins was considerably higher than previously reported in A. aegypti, for which the corresponding synergistic factors were 15.5, 10.91 and 3.15 for the Cyt1A+Cry4A, Cyt1A+Cry4B and Cyt1A+Cry11 combinations, respectively [42,45].

Crystal toxins differ in structure and sequence identity, those differences being that Cry proteins are characterized by a three-domain structure [62], Cyt proteins by a single domain constituted by a β-sheet in the middle and surrounded by two α-helical layers [63] and Tpp proteins by a single domain named Toxin_10 (Bin-like) [54]. The mode of action of Cry and Cyt δ-endotoxins is somehow similar at the beginning of the infection, when the crystals are ingested by a susceptible host. Once they reach the midgut, they are solubilized due to the alkaline conditions and processed by proteases into their active form [64]. However, whereas Cyt toxins directly interact with membrane lipids and insert themselves into the membrane of the epithelial host cells, Cry toxins interact with specific receptors of the surface of said cells and oligomerize before the insertion and pore formation occurs [64]. In the case of Tpp proteins, the mode of action is not completely clear, but it was observed that their toxin form binds to the mosquito midgut, specifically the posterior midgut and the gastric caecum [65].

Synergistic interactions between Cry and Cyt toxins have been extensively described in mosquitoes, but the precise mechanism of action remains poorly understood. The most studied combination is the one between Cyt1Aa and Cry11Aa. One of the major assumptions is that Cyt1Aa may function as a receptor for Cry11Aa, facilitating its insertion in the peritrophic membrane of the insect midgut [66]. In agreement with this, Cyt1Aa was shown to delay the development of resistances in mosquitoes by, hypothetically, habilitating new binding sites to other toxins that do not necessarily need to be from the same crystals, such as the Lysinibacillus sphaericus Mtx1 and Mtx2 toxins [67]. Currently, there is no evidence of mosquito resistances to Bti crystals as a whole, probably due to the interactions that occur between the proteins within the crystal [68,69].

Although resistance to Bti crystals seems unlikely, results showing the existence of resistant biotypes to single Bti proteins open the possibility of specific populations of mosquitoes becoming resistant to Bti-based solutions over time if used irresponsibly. Therefore, we decided to look for new Bt toxins and synergistic factors that represent an alternative to the most common Bti proteins for the control of A. albopictus larvae. Acknowledging that resistances are less likely to develop when synergies take place, one of our focuses was to find new synergistic proteins and characterize them. For this purpose, we selected strain BST059.3, which, despite not showing any activity against A. albopictus larvae (LC₅₀ > 1 × 10⁵ ng/mL of spore-and-crystal mixture), carried two cyt1-like genes: cyt1A-like and cyt1D-like. In addition, BST230, came across as an interesting strain due to its novel insecticidal content: cry4-like, cry53-like, cry56-like and tpp36-like. Cyt1A-like and Cyt1D-like were selected as possible synergistic factors, and the rest of the proteins were selected as hypothetical mosquitocidal proteins. Cry4 toxins have been widely described as one of the major mosquitocidal toxins [54,70,71], whereas, in a previous study, Cry56 showed activity against A. aegypti larvae [72]. Despite Cry53 and Tpp36 not been previously reported as potential mosquitocidal toxins, we decided to include them in the study because strain BST-230 showed toxicity against A. albopictus larvae (LC₅₀ = 39.5 ng/mL) (Table S4). Interestingly, the Cyt1A-like toxin showed high specificity as a synergistic factor. As opposed to Cyt1Aa, which had activity against A. albopictus larvae and interacted synergistically with Cry4Aa, Cry4Ba and Cry11Aa, Cyt1A-like showed no activity (not active at a concentration of 1 × 10⁵ ng/mL) and was only able to potentiate Cry11Aa when tested in combination with the aforementioned proteins. Interestingly, such synergistic effect increased the activity of Cry11Aa 23.14 fold, which was at least two times greater than the one provided by Cyt1Aa (synergistic factor of 11.44).

Possibly the most remarkable feature of Cyt1A-like was the ability to activate the otherwise non-active and newly described Cry53-like, Cry56A-like and Tpp36-like, which showed no activity on their own at a concentration of 1 × 10⁵ ng/mL. This phenomenon was shared with Cyt1Aa for Cry56-like, for which the mixture produced a similar LC₅₀. The combination of Cyt1A-like+Cry56A-like was the most effective, with an LC₅₀ of 186 ng/mL of spore-and-crystal mixture, a concentration that is close to the ones found in some of the major Bti toxins alone such as Cry4Aa and Cyt1Aa. Cyt1A-like+Cry53-like and Cyt1A-like+Tpp36-like had considerably higher LC₅₀ values of 1331 ng/mL and 1053 ng/mL, respectively. Although the combination Cyt1A-like+Tpp36-like was among the least active ones, it confirmed that Cyt1A-like was also able to activate proteins that have a different structure compared to the classic three-domain Cry proteins (Tpp proteins have a typical structure that includes only one domain, named Toxin_10 [54]. In this study, Cyt1A and Cyt1Aa-like were able to activate toxins that were non-active on their own, came from different strains, and had different structures, opening the possibility for them to enable the activity of proteins that have been, until now, considered non-toxic. The biological explanation for this could be that communities of Bt strains in the wild act in a cooperative manner by activating and potentiating the crystal toxins of their fellow Bt neighbors in the pursuit of higher efficacies and more varied mechanisms of actions for when infecting their hosts. Although we were unable to decipher the mechanism of action of said interactions, it may be similar to the one described for Cyt1Aa and Cry11Aa [64]. Here we propose that the characterized Cyt1A and Cyt1A-like toxins could function as enablers of the activity of otherwise non-active Cry and Tpp proteins by habilitating binding sites for them on the lipidic membrane of the insect midgut epithelial cells.

Considering that Cyt1A toxins may delay the appearance of resistance and that the proteins that we described are new, we believe they could represent a great alternative for the control of A. albopictus larvae. Additionally, the capability of Cyt proteins to activate non-toxic proteins in a specific manner may be a common characteristic among Cyt1A proteins. To the best of our knowledge, this represents a new function for Cyt proteins, rendering them not only as capable of potentiating the activity of Cry proteins but also as activators of otherwise non-active proteins.

4. Materials and Methods

4.1. Total DNA Extraction and Genomic Sequencing of the Bacterial Strains

Bacillus thuringiensis var. israeliensis was isolated from the commercial Bt-based product Vectobac-12AS^®. TF059.3 and BST-230 were obtained from Spanish soils and belong to the BST collection. Total genomic DNA (chromosome and plasmid) was extracted from the strains using the Wizard^® Genomic DNA purification kit (Promega, Madison, WI, USA). A sequencing library was prepared for Illumina sequencing by using a NextSeq500 sequencer (Genomics Research Hub Laboratory, School of Biosciences, Cardiff University, Cardiff, UK).

4.2. Identification of the Potential Mosquitocidal Genes in the BST Collection

CLC Genomic Workbench 10.1.1 (QIAGEN, Aarhus, Denmark) was used to process and assemble the genomic raw data. Reads were trimmed and filtered to remove those of low quality, and reads shorter than 50 bp were removed. Processed reads were de novo assembled using a stringent criterion of overlap of at least 95 bp of the read and 95% identity, and reads were then mapped back to the contigs for assembly correction. Genes were predicted using GeneMark v2.5 (Georgia Institute of Technology, Atlanta, GA, USA) [73]. To assist the identification process of potential mosquitocidal toxin proteins, the Basic Local Alignment Search Tool [74,75] was deployed against a database built in our laboratory, including the amino acid sequences of known Bt toxins with pesticidal activity from the bacterial pesticidal protein database (https://www.bpprc.org, accessed on 18 July 2022) [76,77]. The pairwise sequence alignment comparison was calculated by using needle v6.6.0 [78]. The prediction of structurally conserved domains was carried out using CD-search [49].

4.3. Bacterial Strains and Plasmids Used in the Cloning Process

The recombinant plasmids pHT606:cry4Aa, pHT618:cry4Ba and pWF45:cyt1Aa:p20 were provided by Dr. Colin Berry (Cardiff University, Cardiff, UK) and electroporated into the acrystalliferous BMB171 strain. BMB171 was used as a host vector to express all of the proteins used in this study. Escherichia coli XL1 blue was used for transformation. Cry4Aa4-like, cry53Ab1-like, cry56Aa2-like, cyt1Aa5-like, cyt1Da1-like and tpp36Aa1-like were expressed in vector pTBT02. Cry11Aa (1941 bp) was cloned alongside p19 (540 bp) and p20 (549 bp) [40]. Both P19 and P20 helped crystalize Cry11Aa as well as increase its mosquitocidal activity [79].

4.4. Amplification, Cloning and Sequencing of Cyt1a-like, Cyt1d-like, Cry4-like, Cry53-like, Cry56a-like and Tpp36-like

SnapGene^® software (GSL Biotech, Chicago, IL, USA) was used to design plasmids and simulate the cloning process.

To clone each of the selected toxin genes, these were first amplified using a specific set of oligonucleotides listed in Table 5.

• cyt1-like

Primers harboring the restriction enzymes PstI and SalI recognition sites at their extremes were used to amplify the full coding sequence of the cyt1-like genes. SalI and SacI were used for the amplification of p20.

• cry4-like

The coding sequence of cry4-like was amplified by using primers harboring SalI and SacI recognition sites.

• cry53-like

Primers harboring the restriction enzymes SalI and SacI recognition sites at their extremes were used to amplify the full coding sequence of the two contiguous genes cry53-like and orf2.

• cry56A-like

Primers harboring the restriction enzymes SalI and SacI recognition sites were used to amplify the gene cry56A-like, whereas PstI and SalI were used for the orf1 gene.

• tpp36-like

Primers used for the amplification of tpp36-like harbored SalI and SacI recognition sites.

The PCR reactions were performed using a Q5^® High-Fidelity 2X Master Mix (New England Biolabs, Ipswich, SD, USA). PCR products were gel-purified by using NucleoSpin^® Gel and a PCR Clean Up kit (Macherey-Nagel Inc., Bethlehem, PA, USA). After the first ligation into pJET-blunt plasmid using a CloneJET PCR Cloning Kit (Thermo Scientific, Waltham, MA, USA), the ligation products were electroporated into E. coli XL1 blue cells. Colonies were checked via PCR in order to isolate the ones carrying the plasmid. Plasmids from positive clones were purified using the NucleoSpin^® Plasmid Kit (Macherey-Nagel Inc., Bethlehem, PA, USA), following the manufacturer’s instructions. Finally, pJET plasmids sequences were confirmed via sequencing (StabVida, Caparica, Portugal). Once the sequences were verified, the plasmids were digested with the specific set restriction enzymes for each fragment of interest and run in agarose gels, and the corresponding bands were excised and purified. These were then ligated to pre-digested expression vectors using the Rapid DNA ligation kit (ThermoScientific, Vilnius, Lithuania). Cyt1A-like:p20, cyt1D-like:p20, cry4-like, cry53-like:orf2, orf1:cry56A-like and Tpp36-like were cloned in the pTBT02 vector. The final plasmids were then electroporated into E. coli XL1 blue cells. Positive clones were verified via colony-PCR, and plasmids were purified and verified via digestion. pTBT02-cyt1A-like:p20, pTBT02:cyt1D-like:p20, pTBT02:cry4-like, pTBT02:cry53-like:orf2, pTBT02:orf1:cry56A-like and pTBT02:Tpp36-like were finally introduced into the BMB171 Bt strain. The pTBT02 expression vector was created using the pSTAB backbone and by adding a more versatile multicloning site (MCS) as well as a terminator of transcription (TT), which was not present in the previously utilized plasmid. The new MCS and the TT were amplified from the pCN47 plasmid [80] using primers MCS-TT_MfeI and MCS-TT_AatII. The resulting amplicon was cloned in pJET and excised utilizing the MfeI and Aatll enzymes. Next, the digested fragment was inserted in the pSTAB plasmid. Additionally, the cyt1A promoter was relocated in pSTAB by amplifying it with new primers carrying the sequence for the Sphl and SalI restriction sites. The resulting fragment was subcloned in pJET, digested using the corresponding restriction enzymes and inserted into the pSTAB.

4.5. Nucleotide Sequence Accession Numbers

The nucleotide sequence data reported in this paper were deposited in the GeneBank database under the following accession numbers: OQ397557 for cyt1A-like, OQ397558 for cyt1D-like, OQ397551 for cry4-like, OQ397553 for Cry53-like, OQ397554 for orf2, OQ397555 for cry56A-like, OQ397556 for orf1 and OQ397552 for tpp36-like.

4.6. Spore-and-Crystal Mixture Production, Protein Quantification and SDS-PAGE Analysis

BMB171 recombinant strains carrying pHT606:cry4Aa, pHT618:cry4Ba, pWF45:cyt1Aa:p20, pTBT02-cyt1Aa-like:p20, pTBT02:cyt1Da1-like:p20, pTBT02:cry4Aa4-like, pTBT02:cry53Ab1-like:orf2, pTBT02:orf1:cry56Aa-like and pTBT02:Tpp36Aa1-like were grown in 50 mL of CCY medium (supplemented with 20 μg/mL erythromycin) after inoculating single colonies from LB plates [81]. The strains were grown constantly at 28 °C with shaking at 200 rpm. Crystal formation was observed daily at the microscope. Once the cells lysed, after 48–72 h, spore-and-crystal mixtures were washed first with 1M NaCl and 10 mM EDTA, resuspended in 1 mL of dH₂O water and kept at 4 °C until use. The mixtures were solubilized in carbonate buffer (50 mM Na₂CO₃ and 100 mM NaCl, pH 11.3) and quantified for their total amounts of protein by using the Bradford method [82] and by using bovine serum albumin as a standard. For protein profile analysis, the washed spore-and-crystal mixtures were mixed with 2× sample buffer (Bio-Rad, Hercules, CA, USA), boiled at 100 °C for 5 min and then subjected to electrophoresis with a previously described method [83] using Criterion TGX™ 4–20% Precast Gel (Bio-Rad, Laboratories Inc., Hercules, CA, USA). Gels were stained with Coomassie brilliant blue R-250 (Bio-Rad, Laboratories Inc., Hercules, CA, USA) and then destained in a solution of 30% ethanol and 10% acetic acid.

4.7. Bioassays on L2 Larvae of A. Albopictus

The toxicities of the single proteins and mixtures were determined on second instar larvae of A. albopictus. Eggs of A. albopictus were provided by BioGenius GmbH (Friedrich-Ebert-Straße 75, 51429 Bergisch Gladbach, Germany). The bioassays were performed by placing between 10–15 larvae (L2) in each well of a 6-well plate Corning^® Costar^® (Corning^TM, Corning, NY, USA). The bioassays were performed following a previously described method [84]. Each well contained a known concentration of spores and crystals in a total volume of 5 mL, with 0.5 mg of brewer’s yeast as food source for the larvae. In order to calculate the median lethal concentration LC₅₀, 6 concentrations (from high to low) of Bt suspension were chosen for each recombinant strain: 1000, 500, 250, 125, 62.5 and 31.5 ng/mL for Cry4Aa and Cyt1Aa, 500, 250, 125, 62.5, 31.5 and 15.75 ng/mL for Cry4Ba and 2500, 1250, 625, 312.5, 156.25 and 78.12 ng/mL for Cry11Aa. The highest concentrations (C1) were defined as a dose that produces between 90–100% of mortality, whereas the lower doses were simply 1:2 serial dilutions of the C1 dose.

4.8. Statistical Analysis

Concentration–mortality data were subjected to logit regression to estimate the LC₅₀ for individual toxins and mixtures of toxins [85].The observed and expected LC₅₀ values for the individual toxins and the toxin mixture in A. albopictus were used to evaluate the interaction of Cyt1Aa with Cry4Aa, Cry4Ba, Cry11Aa and Cry56Aa2 and the interaction between Cyt1Aa and Cyt1A-like with Cry11Aa, Cry53Ab-like, Cry56Aa-like and Tpp36Ab-like. To calculate the expected LC₅₀ values for the toxin mixture under the null hypothesis of no interaction, the “simple similar action” model was used [86]. This model assumes that the concentration–response regression lines for different components of a mixture are parallel and suitable for testing synergism in chemically compounds that are alike, such as Bt toxins. All synergies were evaluated by first calculating the expected LC₅₀, as follows, as there were no synergisms between them:

$L{C}_{50\left(m\right)}\left[\frac{ra}{L{C}_{50\left(A\right)}}+\frac{rb}{L{C}_{50\left(B\right)}}\right]\begin{array}{ccc}-1& & \\ & & \\ & & \end{array}$

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Enlarge this image.

Figure 1. SDS-PAGE showing the protein profile of the BMB171 recombinant strains expressing the AM 65-52 major crystal proteins. Lane M, molecular weight; lane 1, BMB171 carrying an empty plasmid; lane 2, BMB171-Cry4Aa (134 kDa); lane 3, BMB171-Cry4Ba (128 kDa); lane 4, BMB171-Cry11Aa (73 kDa); lane 5, BMB171-Cyt1Aa (27 kDa); lane 6, AM 65-52. Triangles point at major protein bands.

Enlarge this image.

Figure 2. Graphical representation of the impact of helper proteins on the crystallization of Cry53-like, Cry56A-like, Cyt1A-like and Cyt1D-like and of their phenotypes under the microscope after their expression in strain BMB171. (A) Images of BMB171 expressing cry53-like, cry56A-like, cyt1A-like and cyt1D-like (produce only spores). (B) cry53-like + orf2, orf1:cry56A-like, cyt1A-like:p20 and cyt1D-like:p20 are able to form both spores and crystals.

Enlarge this image.

Figure 3. SDS-PAGE showing the protein profile of the BMB171 recombinant strains carrying the new recombinant proteins. Lane M, molecular weight; lane 1, strain TF059.3; lane 2, BMB171-Cyt1A-like (31 kDa); lane 3, BMB171-Cyt1D-like (59 kDa); lane 4, strain BST-230; lane 5, BMB171-Cry4-like (130 kDa); lane 6, BMB171-Cry53-like:orf2 (76 kDa:62 kDa); lane 7, BMB171-orf1:Cry56A-like (64 kDa:73 kDa); lane 8, BMB171-Tpp36-like (55 kDa). Triangles point at major protein bands that correspond with the expressed proteins.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/toxins15030211/s1, Table S1: Mean lethal concentration (LC50) value of BST-230; Table S2: Raw data of the synergies between Cry and Cyt toxins; Table S3: Raw data of the activated Cry and Tpp toxins; Table S4: Mean lethal concentration (LC50) value of BST-230.

References

1. Kambhampati, S.; Black Iv, W.C.; Rai, K.S. Geographic Origin of the US and Brazilian Aedes Albopictus Inferred from Allozyme Analysis. Heredity; 1991; 67, pp. 85-94. [DOI: https://dx.doi.org/10.1038/hdy.1991.67]

2. Bonizzoni, M.; Gasperi, G.; Chen, X.; James, A.A. The Invasive Mosquito Species Aedes Albopictus: Current Knowledge and Future Perspectives. Trends Parasitol.; 2013; 29, pp. 460-468. [DOI: https://dx.doi.org/10.1016/j.pt.2013.07.003]

3. Adhami, J.; Reiter, P. Introduction and Establishment of Aedes (Stegomyia) Albopictus Skuse (Diptera: Culicidae) in Albania. J. Am. Mosq. Control. Assoc.; 1998; 14, pp. 340-343. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/9813831]

4. Tippelt, L.; Werner, D.; Kampen, H. Tolerance of Three Aedes Albopictus Strains (Diptera: Culicidae) from Different Geographical Origins towards Winter Temperatures under Field Conditions in Northern Germany. PLoS ONE; 2019; 14, e0219553. [DOI: https://dx.doi.org/10.1371/journal.pone.0219553] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31310645]

5. Sabatini, A.; Raineri, V.; Trovato, G.; Coluzzi, M. Aedes Albopictus in Italy and Possible Diffusion of the Species into the Mediterranean Area. Parassitologia; 1990; 32, pp. 301-304.

6. Rezza, G. Chikungunya Is Back in Italy: 2007–2017. J. Travel Med.; 2018; 25, tay004. [DOI: https://dx.doi.org/10.1093/jtm/tay004]

7. Lwande, O.W.; Obanda, V.; Lindström, A.; Ahlm, C.; Evander, M.; Näslund, J.; Bucht, G. Globe-Trotting Aedes Aegypti and Aedes Albopictus: Risk Factors for Arbovirus Pandemics. Vector-Borne Zoonotic Dis.; 2020; 20, pp. 71-81. [DOI: https://dx.doi.org/10.1089/vbz.2019.2486]

8. Battaglia, V.; Agostini, V.; Moroni, E.; Colombo, G.; Lombardo, G.; Rambaldi Migliore, N.; Gabrieli, P.; Garofalo, M.; Gagliardi, S.; Gomulski, L.M. et al. The Worldwide Spread of Aedes Albopictus: New Insights from Mitogenomes. Front. Genet.; 2022; 13, [DOI: https://dx.doi.org/10.3389/fgene.2022.931163] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36092930]

9. Kraemer, M.U.G.; Reiner, R.C.; Brady, O.J.; Messina, J.P.; Gilbert, M.; Pigott, D.M.; Yi, D.; Johnson, K.; Earl, L.; Marczak, L.B. et al. Past and Future Spread of the Arbovirus Vectors Aedes Aegypti and Aedes Albopictus. Nat. Microbiol.; 2019; 4, pp. 854-863. [DOI: https://dx.doi.org/10.1038/s41564-019-0376-y] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/30833735]

10. Leta, S.; Beyene, T.J.; de Clercq, E.M.; Amenu, K.; Kraemer, M.U.G.; Revie, C.W. Global Risk Mapping for Major Diseases Transmitted by Aedes Aegypti and Aedes Albopictus. Int. J. Infect. Diseases; 2018; 67, pp. 25-35. [DOI: https://dx.doi.org/10.1016/j.ijid.2017.11.026]

11. Sasayama, M.; Benjathummarak, S.; Kawashita, N.; Rukmanee, P.; Sangmukdanun, S.; Masrinoul, P.; Pitaksajjakul, P.; Puiprom, O.; Wuthisen, P.; Kurosu, T. et al. Chikungunya Virus Was Isolated in Thailand, 2010. Virus Genes; 2014; 49, pp. 485-489. [DOI: https://dx.doi.org/10.1007/s11262-014-1105-5]

12. da Cunha, R.V.; Trinta, K.S. Chikungunya Virus: Clinical Aspects and Treatment. Mem. Inst. Oswaldo Cruz; 2017; 112, pp. 523-531. [DOI: https://dx.doi.org/10.1590/0074-02760170044] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28767976]

13. Rezza, G. Aedes Albopictus and the Reemergence of Dengue. BMC Public Health; 2012; 12, 72. [DOI: https://dx.doi.org/10.1186/1471-2458-12-72]

14. Gardner, L.M.; Chen, N.; Sarkar, S. Global Risk of Zika Virus Depends Critically on Vector Status of Aedes Albopictus. Lancet Infect. Dis; 2016; 16, pp. 522-523. [DOI: https://dx.doi.org/10.1016/S1473-3099(16)00176-6] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/26997578]

15. Ciota, A.T.; Bialosuknia, S.M.; Zink, S.D.; Brecher, M.; Ehrbar, D.J.; Morrissette, M.N.; Kramer, L.D. Effects of Zika Virus Strain and Aedes Mosquito Species on Vector Competence. Emerg. Infect. Dis; 2017; 23, pp. 1110-1117. [DOI: https://dx.doi.org/10.3201/eid2307.161633]

16. Gómez, M.; Martinez, D.; Muñoz, M.; Ramírez, J.D. Aedes Aegypti and Ae. Albopictus Microbiome/Virome: New Strategies for Controlling Arboviral Transmission?. Parasit Vectors; 2022; 15, 287. [DOI: https://dx.doi.org/10.1186/s13071-022-05401-9]

17. Rivero, A.; Vézilier, J.; Weill, M.; Read, A.F.; Gandon, S. Insecticide Control of Vector-Borne Diseases: When Is Insecticide Resistance a Problem?. PLoS Pathog; 2010; 6, pp. 5-6. [DOI: https://dx.doi.org/10.1371/journal.ppat.1001000]

18. Medlock, J.M.; Hansford, K.M.; Schaffner, F.; Versteirt, V.; Hendrickx, G.; Zeller, H.; van Bortel, W. A Review of the Invasive Mosquitoes in Europe: Ecology, Public Health Risks, and Control Options. Vector-Borne Zoonotic Dis.; 2012; 12, pp. 435-447. [DOI: https://dx.doi.org/10.1089/vbz.2011.0814] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/22448724]

19. Rodríguez, M.M.; Bisset, J.A.; Fernández, D. Levels of Insecticide Resistance and Resistance Mechanisms in Aedes Aegypti from Some Latin American Countries. J. Am. Mosq. Control Assoc.; 2007; 23, pp. 420-429. [DOI: https://dx.doi.org/10.2987/5588.1]

20. Hemingway, J.; Hawkes, N.J.; McCarroll, L.; Ranson, H. The Molecular Basis of Insecticide Resistance in Mosquitoes. Insect Biochem. Mol. Biol. Insect Biochem. Mol. Biol.; 2004; 34, pp. 653-665. [DOI: https://dx.doi.org/10.1016/j.ibmb.2004.03.018] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/15242706]

21. Marcombe, S.; Farajollahi, A.; Healy, S.P.; Clark, G.G.; Fonseca, D.M. Insecticide Resistance Status of United States Populations of Aedes Albopictus and Mechanisms Involved. PLoS ONE; 2014; 9, e101992. [DOI: https://dx.doi.org/10.1371/journal.pone.0101992]

22. Liu, N. Insecticide Resistance in Mosquitoes: Impact, Mechanisms, and Research Directions. Annu. Rev. Entomol.; 2015; 60, pp. 537-559. [DOI: https://dx.doi.org/10.1146/annurev-ento-010814-020828] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/25564745]

23. Department of Control of Neglected Tropical Diseases WHO Pesticide Evaluation Scheme (WHOPES). Pesticides and Their Application for the Control of Vectors and Pests of Public Health Importance; WHO: Geneva, Switzerland, 2006.

24. Kache, P.A.; Eastwood, G.; Collins-Palmer, K.; Katz, M.; Falco, R.C.; Bajwa, W.I.; Armstrong, P.M.; Andreadis, T.G.; Diuk-Wasser, M.A. Environmental Determinants of Aedes Albopictus Abundance at a Northern Limit of Its Range in the United States. Am. J. Trop. Med. Hyg.; 2020; 102, pp. 436-447. [DOI: https://dx.doi.org/10.4269/ajtmh.19-0244] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31833467]

25. Raymond, B.; Federici, B.A. In Defense of Bacillus Thuringiensis, the Safest and Most Successful Microbial Insecticide Available to Humanity—A Response to EFSA. FEMS Microbiol. Ecol.; 2017; 93, fix084. [DOI: https://dx.doi.org/10.1093/femsec/fix084] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28645183]

26. Wirth, M.C.; Park, H.W.; Walton, W.E.; Federici, B.A. Cyt1A of Bacillus thuringiensis Delays Evolution of Resistance to Cry11A in the Mosquito Culex Quinquefasciatus. Appl. Environ. Microbiol.; 2005; 71, pp. 185-189. [DOI: https://dx.doi.org/10.1128/AEM.71.1.185-189.2005] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/15640186]

27. Stalinski, R.; Tetreau, G.; Gaude, T.; Després, L. Pre-Selecting Resistance against Individual Bti Cry Toxins Facilitates the Development of Resistance to the Bti Toxins Cocktail. J. Invertebr. Pathol.; 2014; 119, pp. 50-53. [DOI: https://dx.doi.org/10.1016/j.jip.2014.04.002]

28. Stalinski, R.; Laporte, F.; Tetreau, G.; Després, L. Receptors Are Affected by Selection with Each Bacillus thuringiensis Israelensis Cry Toxin but Not with the Full Bti Mixture in Aedes Aegypti. Infect. Genet. Evol.; 2016; 44, pp. 218-227. [DOI: https://dx.doi.org/10.1016/j.meegid.2016.07.009]

29. Lee, S.B.; Aimanova, K.G.; Gill, S.S. Alkaline Phosphatases and Aminopeptidases Are Altered in a Cry11Aa Resistant Strain of Aedes Aegypti. Insect. Biochem. Mol. Biol.; 2014; 54, pp. 112-121. [DOI: https://dx.doi.org/10.1016/j.ibmb.2014.09.004]

30. Cadavid-Restrepo, G.; Sahaza, J.; Orduz, S. Treatment of an Aedes Aegypti Colony with the Cry11Aa Toxin for 54 Generations Results in the Development of Resistance. Mem. Inst. Oswaldo Cruz; 2012; 107, pp. 74-79. [DOI: https://dx.doi.org/10.1590/S0074-02762012000100010]

31. Boyce, R.; Lenhart, A.; Kroeger, A.; Velayudhan, R.; Roberts, B.; Horstick, O. Bacillus thuringiensis Israelensis (Bti) for the Control of Dengue Vectors: Systematic Literature Review. Trop. Med. Int. Health; 2013; 18, pp. 564-577. [DOI: https://dx.doi.org/10.1111/tmi.12087]

32. Russell, T.L.; Brown, M.D.; Purdie, D.M.; Ryan, P.A.; Kay, B.H. Efficacy of VectoBac (Bacillus thuringiensis Variety Israelensis) Formulations for Mosquito Control in Australia. J. Econ. Entomol.; 2003; 96, pp. 1786-1791. [DOI: https://dx.doi.org/10.1603/0022-0493-96.6.1786]

33. Federici, B.A.; Park, H.W.; Bideshi, D.K.; Wirth, M.C.; Johnson, J.J. Recombinant Bacteria for Mosquito Control. J. Exp. Biol.; 2003; 206, pp. 3877-3885. [DOI: https://dx.doi.org/10.1242/jeb.00643] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/14506223]

34. Kamgang, B.; Marcombe, S.; Chandre, F.; Nchoutpouen, E.; Nwane, P.; Etang, J.; Corbel, V.; Paupy, C. Insecticide Susceptibility of Aedes Aegypti and Aedes Albopictus in Central Africa. Parasit Vectors; 2011; 4, 79. [DOI: https://dx.doi.org/10.1186/1756-3305-4-79]

35. Guerchicoff, A.; Ugalde, R.A.; Rubinstein, C.P. Identification and Characterization of a Previously Undescribed Cyt Gene in Bacillus thuringiensis subsp. Israelensis. Appl. Environ. Microbiol.; 1997; 63, pp. 2716-2721. [DOI: https://dx.doi.org/10.1128/aem.63.7.2716-2721.1997] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/9212418]

36. Waalwijk, C.; Dullemans, A.M.; van Workum, E.S.; Visser, B. Molecular Cloning and the Nucleotide Sequence of the Mr 28000 Crystal Protein Gene of Bacilus Thuringiensis Subsp. Israelensis. Nucleic Acids Res.; 1985; 13, pp. 8207-8217. [DOI: https://dx.doi.org/10.1093/nar/13.22.8207] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/4070003]

37. Anderson, I.; Sorokin, A.; Kapatral, V.; Reznik, G.; Bhattacharya, A.; Mikhailova, N.; Burd, H.; Joukov, V.; Kaznadzey, D.; Walunas, T. et al. Comparative Genome Analysis of Bacillus Cereus Group Genomes with Bacillus Subtilis. FEMS Microbio.l Lett.; 2005; 250, pp. 175-184. [DOI: https://dx.doi.org/10.1016/j.femsle.2005.07.008] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/16099605]

38. Donovan, W.P.; Dankocsik, C.; Pearce Gilbert, M. Molecular Characterization of a Gene Encoding a 72-Kilodalton Mosquito-Toxic Crystal Protein from Bacillus thuringiensis subsp. Israelensis. J. Bacteriol.; 1988; 170, pp. 4732-4738. [DOI: https://dx.doi.org/10.1128/jb.170.10.4732-4738.1988] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/2902069]

39. Berry, C.; O’Neil, S.; Ben-Dov, E.; Jones, A.F.; Murphy, L.; Quail, M.A.; Holden, M.T.G.; Harris, D.; Zaritsky, A.; Parkhill, J. Complete Sequence and Organization of PBtoxis, the Toxin-Coding Plasmid of Bacillus thuringiensis Subsp. Israelensis. Appl. Environ. Microbiol.; 2002; 68, pp. 5082-5095. [DOI: https://dx.doi.org/10.1128/AEM.68.10.5082-5095.2002] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/12324359]

40. Valtierra-De-Luis, D.; Villanueva, M.; Lai, L.; Williams, T.; Caballero, P. Potential of Cry10Aa and Cyt2Ba, Two Minority δ-Endotoxins Produced by Bacillus thuringiensis Ser. Israelensis, for the Control of Aedes Aegypti Larvae. Toxins; 2020; 6, 355. [DOI: https://dx.doi.org/10.3390/toxins12060355]

41. Park, H.-W.; Bideshi, D.K.; Federici, B.A. Overview of the Basic Biology of Bacillus thuringiensis with Emphasis on Genetic Engineering of Bacterial Larvicides for Mosquito Control. Open Toxinol. J.; 2010; 3, pp. 83-100.

42. Valtierra-de-Luis, D.; Villanueva, M.; Berry, C.; Caballero, P. Potential for Bacillus thuringiensis and Other Bacterial Toxins as Biological Control Agents to Combat Dipteran Pests of Medical and Agronomic Importance. Toxins; 2020; 12, 773. [DOI: https://dx.doi.org/10.3390/toxins12120773]

43. Silva-Filha, M.; Romão, T.; Rezende, T.; Carvalho, K.; de Menezes, H.G.; Nascimento, N.A.D.; Soberón, M.; Bravo, A. Bacterial Toxins Active against Mosquitoes: Mode of Action and Resistance. Toxins; 2021; 13, 523. [DOI: https://dx.doi.org/10.3390/toxins13080523]

44. Ben-Dov, E. Bacillus thuringiensis subsp. Israelensis and Its Dipteran-Specific Toxins. Toxins; 2014; 6, pp. 1222-1243. [DOI: https://dx.doi.org/10.3390/toxins6041222] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/24686769]

45. Crickmore, N.; Bone, E.J.; Williams, J.A.; Ellar, D.J. Contribution of the Individual Components of the δ-Endotoxin Crystal to the Mosquitocidal Activity of Bacillus thuringiensis Subsp. Israelensis. FEMS Microbiol. Lett.; 1995; 131, pp. 249-254. [DOI: https://dx.doi.org/10.1016/0378-1097(95)00264-6]

46. Fernández-Luna, M.T.; Tabashnik, B.E.; Lanz-Mendoza, H.; Bravo, A.; Soberón, M.; Miranda-Ríos, J. Single Concentration Tests Show Synergism among Bacillus thuringiensis Subsp. Israelensis Toxins against the Malaria Vector Mosquito Anopheles Albimanus. J. Invertebr. Pathol.; 2010; 104, pp. 231-233. [DOI: https://dx.doi.org/10.1016/j.jip.2010.03.007]

47. Georghiou, G.P.; Wirth, M.C. Influence of Exposure to Single versus Multiple Toxins of Bacillus thuringiensis Subsp. Israelensis on Development of Resistance in the Mosquito Culex Quinquefasciatus (Diptera: Culicidae). Appl. Environ. Microbiol.; 1997; 63, pp. 1095-1101. [DOI: https://dx.doi.org/10.1128/aem.63.3.1095-1101.1997]

48. Wirth, M.C.; Georghiou, G.P.; Federici, B.A. CytA Enables CryIV Endotoxins of Bacillus thuringiensis to Overcome High Levels of CryIV Resistance in the Mosquito, Culex Quinquefasciatus. Proc. Natl. Acad. Sci. USA; 1997; 94, pp. 10536-10540. [DOI: https://dx.doi.org/10.1073/pnas.94.20.10536] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/9380670]

49. Marchler-Bauer, A.; Bo, Y.; Han, L.; He, J.; Lanczycki, C.J.; Lu, S.; Chitsaz, F.; Derbyshire, M.K.; Geer, R.C.; Gonzales, N.R. et al. CDD/SPARCLE: Functional Classification of Proteins via Subfamily Domain Architectures. Nucleic Acids Res.; 2017; 45, pp. D200-D203. [DOI: https://dx.doi.org/10.1093/nar/gkw1129] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/27899674]

50. Adalat, R.; Saleem, F.; Crickmore, N.; Naz, S.; Shakoori, A.R. In Vivo Crystallization of Three-Domain Cry Toxins. Toxins; 2017; 9, 80. [DOI: https://dx.doi.org/10.3390/toxins9030080]

51. Sazhenskiy, V.; Zaritsky, A.; Itsko, M. Expression in Escherichia Coli of the Native Cyt1Aa from Bacillus thuringiensis subsp. Israelensis. Appl. Environ. Microbiol.; 2010; 76, pp. 3409-3411. [DOI: https://dx.doi.org/10.1128/AEM.03068-09]

52. Wu1, D.; Federici’, B.A. A 20-Kilodalton Protein Preserves Cell Viability and Promotes CytA Crystal Formation during Sporulation in Bacillus thuringiensis. J. Bacteriol.; 1993; 175, pp. 5276-5280.

53. Caballero, J.; Jiménez-Moreno, N.; Orera, I.; Williams, T.; Fernández, A.B.; Villanueva, M.; Ferré, J.; Caballero, P.; Ancín-Azpilicueta, C.; Johnson, K.N. Unraveling the Composition of Insecticidal Crystal Proteins in Bacillus thuringiensis: A Proteomics Approach. Appl. Environ. Microbiol.; 2020; 86, e00476-20. [DOI: https://dx.doi.org/10.1128/AEM.00476-20]

54. Crickmore, N.; Berry, C.; Panneerselvam, S.; Mishra, R.; Connor, T.R. Bacterial Pesticidal Protein Resource Center, Viewed (02/12/2022). Available online: https://www.Bpprc.Org (accessed on 12 November 2022).

55. de Barros Moreira Beltrão, H.; Silva-Filha, M.H.N.L. Interaction of Bacillus thuringiensis Svar. Israelensis Cry Toxins with Binding Sites from Aedes Aegypti (Diptera: Culicidae) Larvae Midgut. FEMS Microbiol. Lett.; 2007; 266, pp. 163-169. [DOI: https://dx.doi.org/10.1111/j.1574-6968.2006.00527.x]

56. Delécluse, A.; Bourgouin, C.; Klier, A.; Rapoport, G. Specificity of Action on Mosquito Larvae of Bacillus thuringiensis Israelensis Toxins Encoded by Two Different Genes. Mol. Genet. Genom.; 1988; 214, pp. 42-47. [DOI: https://dx.doi.org/10.1007/BF00340177]

57. Chilcott, C.N.; Ellar, D.J. Comparative Toxicity of Bacillus thuringiensis Var. Israelensis Crystal Proteins in Aiuo and in Tritvo. Microbiology; 1988; 134, pp. 2551-2558. [DOI: https://dx.doi.org/10.1099/00221287-134-9-2551] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/3254944]

58. Otieno-Ayayo, Z.N.; Zaritsky, A.; Wirth, M.C.; Manasherob, R.; Khasdan, V.; Cahan, R.; Ben-Dov, E. Variations in the Mosquito Larvicidal Activities of Toxins from Bacillus thuringiensis ssp. Israelensis. Environ. Microbiol.; 2008; 10, pp. 2191-2199. [DOI: https://dx.doi.org/10.1111/j.1462-2920.2008.01696.x] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/18637949]

59. Hawley, W. The Biology of Aedes Albopictus. J. Am. Mosq. Control Assoc. Suppl.; 1988; 1, pp. 1-39. [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/3068349]

60. Albieri, A.; Carrieri, M.; Angelini, P.; Baldacchini, F.; Venturelli, C.; Zeo, S.M.; Bellini, R. Quantitative Monitoring of Aedes Albopictus in Emilia-Romagna, Northern Italy: Cluster Investigation and Geostatistical Analysis. Bull. Insectology; 2010; 63, pp. 209-216.

61. Caputo, B.; Ienco, A.; Cianci, D.; Pombi, M.; Petrarca, V.; Baseggio, A.; Devine, G.J.; della Torre, A. The “Auto-Dissemination” Approach: A Novel Concept to Fight Aedes Albopictus in Urban Areas. PLoS Negl. Trop. Dis.; 2012; 6, e1793. [DOI: https://dx.doi.org/10.1371/journal.pntd.0001793]

62. Li, J.; Carroll, J.; Ellar, D.J. Crystal Structure of Insecticidal 6-Endotoxin 0 from Bacillus thuringiensis at 2.5 A Resolution. Nature; 1991; 353, pp. 815-821. [DOI: https://dx.doi.org/10.1038/353815a0] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/1658659]

63. Xu, C.; Wang, B.C.; Yu, Z.; Sun, M. Structural Insights into Bacillus thuringiensis Cry, Cyt and Parasporin Toxins. Toxins; 2014; 6, pp. 2732-2770. [DOI: https://dx.doi.org/10.3390/toxins6092732]

64. Bravo, A.; Gill, S.S.; Soberón, M. Mode of Action of Bacillus thuringiensis Cry and Cyt Toxins and Their Potential for Insect Control. Toxicon; 2007; 49, pp. 423-435. [DOI: https://dx.doi.org/10.1016/j.toxicon.2006.11.022] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/17198720]

65. Best, H.L.; Williamson, L.J.; Lipka-Lloyd, M.; Waller-Evans, H.; Lloyd-Evans, E.; Rizkallah, P.J.; Berry, C. The Crystal Structure of Bacillus thuringiensis Tpp80Aa1 and Its Interaction with Galactose-Containing Glycolipids. Toxins; 2022; 14, 863. [DOI: https://dx.doi.org/10.3390/toxins14120863] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36548760]

66. Pérez, C.; Fernandez, L.E.; Sun, J.; Folch, J.L.; Gill, S.S.; Soberó, M.; Bravo, A. Bacillus thuringiensis subsp. Israelensis Cyt1Aa Synergizes Cry11Aa Toxin by Functioning as a Membrane-Bound Receptor. Proc. Natl. Acad. Sci. USA; 2005; 102, pp. 18303-18308. [DOI: https://dx.doi.org/10.1073/pnas.0505494102]

67. Wirth, M.C.; Delécluse, A.; Walton, W.E. Cyt1Ab1 and Cyt2Ba1 from Bacillus thuringiensis Subsp. Medellin and B. thuringiensis Subsp. Israelensis Synergize Bacillus sphaericus against Aedes Aegypti and Resistant Culex Quinquefasciatus (Diptera: Culicidae). Appl. Environ. Microbiol.; 2001; 67, pp. 3280-3284. [DOI: https://dx.doi.org/10.1128/AEM.67.7.3280-3284.2001]

68. Tetreau, G.; Stalinski, R.; David, J.P.; Després, L. Monitoring Resistance to Bacillus thuringiensis subsp. Israelensis in the Field by Performing Bioassays with Each Cry Toxin Separately. Mem. Inst. Oswaldo Cruz.; 2013; 108, pp. 894-900. [DOI: https://dx.doi.org/10.1590/0074-0276130155]

69. Paris, M.; Tetreau, G.; Laurent, F.; Lelu, M.; Despres, L.; David, J.P. Persistence of Bacillus thuringiensis Israelensis (Bti) in the Environment Induces Resistance to Multiple Bti Toxins in Mosquitoes. Pest Manag. Sci.; 2011; 67, pp. 122-128. [DOI: https://dx.doi.org/10.1002/ps.2046] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/21162152]

70. Delecluse, A.; Poncet, S.; Klier, A.; Rapoport, G. Expression of CryIVA and CryIVB Genes, Independently or in Combination, in a Crystal-Negative Strain of Bacillus thuringiensis Subsp. Israelensis. Appl. Environ. Microbiol.; 1993; 59, pp. 3922-3927. [DOI: https://dx.doi.org/10.1128/aem.59.11.3922-3927.1993] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/16349095]

71. Abdullah, M.A.F.; Alzate, O.; Mohammad, M.; McNall, R.J.; Adang, M.J.; Dean, D.H. Introduction of Culex Toxicity into Bacillus thuringiensis Cry4Ba by Protein Engineering. Appl. Environ. Microbiol.; 2003; 69, pp. 5343-5353. [DOI: https://dx.doi.org/10.1128/AEM.69.9.5343-5353.2003]

72. Zhu, J.; Zheng, A.P.; Tan, F.R.; Wang, S.Q.; Deng, Q.M.; Li, S.C.; Wang, L.X.; Li, P. Characterisation and Expression of a Novel Holotype Crystal Protein Gene, Cry56Aa1, from Bacillus thuringiensis Strain Ywc2-8. Biotechnol. Lett.; 2010; 32, pp. 283-288. [DOI: https://dx.doi.org/10.1007/s10529-009-0147-6]

73. Borodovsky Mark; McIninch James GENMARK: Parallel Gene Recognition for Both DNA Strands. Comput. Chem.; 1993; 17, pp. 123-133. [DOI: https://dx.doi.org/10.1016/0097-8485(93)85004-V]

74. Altschul, S.F.; Gish, W.; Miller, W.; Myers, E.W.; Lipman, D.J. Basic Local Alignment Search Tool. J. Mol. Biol.; 1990; 215, pp. 403-410. [DOI: https://dx.doi.org/10.1016/S0022-2836(05)80360-2] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/2231712]

75. Available online: Https://Blast.Ncbi.Nlm.Nih.Gov/Blast.Cgi (accessed on 12 November 2022).

76. Crickmore, N.; Berry, C.; Panneerselvam, S.; Mishra, R.; Connor, T.R.; Bonning, B.C. A Structure-Based Nomenclature for Bacillus thuringiensis and Other Bacteria-Derived Pesticidal Proteins. J. Invertebr. Pathol.; 2020; 186, 107438. [DOI: https://dx.doi.org/10.1016/j.jip.2020.107438] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32652083]

77. Crickmore, N.; Zeigler, D.R.; Feitelson, J.; Schnepf, E.; van Rie, J.; Lereclus, D.; Baum, J.; Dean, D.H. Revision of the Nomenclature for the Bacillus thuringiensis Pesticidal Crystal Proteins. Microbiol. Mol. Biol. Rev.; 1998; 62, pp. 807-813. [DOI: https://dx.doi.org/10.1128/MMBR.62.3.807-813.1998]

78. Madeira, F.; Pearce, M.; Tivey, A.R.N.; Basutkar, P.; Lee, J.; Edbali, O.; Madhusoodanan, N.; Kolesnikov, A.; Lopez, R. Search and Sequence Analysis Tools Services from EMBL-EBI in 2022. Nucleic Acids Res.; 2022; 50, pp. W276-W279. [DOI: https://dx.doi.org/10.1093/nar/gkac240]

79. Xu, Y.; Nagai, M.; Bagdasarian, M.; Smith, T.W.; Walker, E.D. Expression of the P20 Gene from Bacillus thuringiensis H-14 Increases Cry11A Toxin Production and Enhances Mosquito-Larvicidal Activity in Recombinant Gram-Negative Bacteria. Appl. Environ. Microbiol.; 2001; 67, pp. 3010-3015. [DOI: https://dx.doi.org/10.1128/AEM.67.7.3010-3015.2001]

80. Charpentier, E.; Anton, A.I.; Barry, P.; Alfonso, B.; Fang, Y.; Novick, R.P. Novel Cassette-Based Shuttle Vector System for Gram-Positive Bacteria. Appl. Environ. Microbiol.; 2004; 70, pp. 6076-6085. [DOI: https://dx.doi.org/10.1128/AEM.70.10.6076-6085.2004]

81. Stewart, G.S.; Johnstone, K.; Hagelberg, E.; Ellar, D.J. Commitment of Bacterial Spores to Germinate A Measure of the Trigger Reaction. Biochem. J.; 1981; 198, pp. 101-106. [DOI: https://dx.doi.org/10.1042/bj1980101]

82. Bradford, M.M. A Rapid and Sensitive Method for the Quantitation of Microgram Quantities of Protein Utilizing the Principle of Protein-Dye Binding. Anal. Biochem.; 1976; 72, pp. 248-254. [DOI: https://dx.doi.org/10.1016/0003-2697(76)90527-3]

83. Laemmli, U.K. Cleavage of Structural Proteins during the Assembly of the Head of Bacteriophage T4. Nature; 1970; 227, pp. 680-685. [DOI: https://dx.doi.org/10.1038/227680a0] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/5432063]

84. Mclaughlin, R.E.; Dulmage, H.T.; Alls, R.; Couch, T.L.; Dame, D.A.; Hall, I.M.; Rose, R.I.; Versoi, P.L. Standard Bioassay for the Potency Assessment of Bacillus thuringiensis Serotype H-14 against Mosquito Larvae [Aedes Aegypti, Biological Control]. Bull. Entomol. Soc. Am.; 1984; 30, pp. 26-29.

85. Finney, D.J. Probit Analysis. J. Pharm. Sci.; 1971; 60, 1432.

86. Tabashnikt, B.E. Evaluation of Synergism among Bacillus thuringiensis Toxins. Appl. Environ. Microbiol.; 1992; 58, pp. 3343-3346. [DOI: https://dx.doi.org/10.1128/aem.58.10.3343-3346.1992] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/1444368]