Plant-Associated Bacillus thuringiensis and Bacillus cereus: Inside Agents for Biocontrol and Genetic Recombination in Phytomicrobiome

Bacillus thuringiensis Berliner (Bt) and B. cereus sensu stricto Frankland and Frankland are closely related species of aerobic, spore-forming bacteria included in the B. cereus sensu lato group. This group is one of the most studied, but it remains also the most mysterious species of bacteria. Despite more than a century of research on the features of these ubiquitous bacteria, there are a lot of questionable issues related to their taxonomy, resistance to external influences, endophytic existence, their place in multidimensional relationships in the ecosystem, and many others. The review summarizes current data on the mutualistic relationships of Bt and B. cereus bacteria with plants, the structure of the phytomicrobiomes including Bt and B. cereus, and the abilities of plant-associated and endophytic strains to improve plant resistance to various environmental factors and its productivity. Key findings on the possibility of the use of Cry gene promoter for transcription of the target dsRNA and simultaneous release of pore-forming proteins and provocation of RNA-interference in pest organisms allow us to consider this group of microorganisms as unique tools of genetic engineering and biological control. This will open the prospects for the development and direct change of plant microbiomes, and possibly serve as the basis for the regulation of the entire agroecosystem.


Introduction
Currently, in B. cereus-group bacteria, Bacillus thuringiensis Berliner (Bt) is one of the most studied microorganisms-one of the Alpha and Omega of the modern biological control strategy.Bt-based pesticides account for up to 75% of the global bioinsecticide sales market and about 4% of all insecticides [1].It has been continuously used in agriculture and forestry for more than 50 years [1][2][3].Rod-shaped, poorly motile, spore-forming, facultatively anaerobic, synthesizing insectotoxic proteins bacteria Bt (Bacteria; Terrabacteria group; Bacillota; Bacilli; Bacillales; Bacillaceae; Bacillus; Bacillus cereus group) subspecies thuringiensis, kurstaki, aizawai, tenebrionis, and israelensis are most often used as the basis of bioinsecticides worldwide [1,4].In the past decade, research on the development and use of biological control agents based on Bt in vector control programs has been greatly stimulated for the prevention of dangerous human diseases spreading [1][2][3].Due to their high efficiency against various pests and environmental safety, many researchers consider Bt-based agents to be an effective and environmentally friendly alternative to chemicals [1][2][3][4][5].Unfortunately, the use of Bt raises a number of problems, which will be discussed below.
Bt insecticidal proteins possess susceptibility to a broad spectrum of environmental influences, among which ultraviolet (UV) rays are the most important [6,7].Ultraviolet radiation causes shorter persistence of Bt under the field conditions [8] due to extensive bacterial DNA cleavage, in particular, double-strand breaks [9].Unfortunately, it demands the repeated spraying of crops, and the cost of using Bt is rising.Therefore, creation of light-stable biocontrol agents based on Bt strains with higher insecticidal efficiency is of interest.
Bt is accepted by many authors as a single species of B. cereus group, but from different points of view, Bt can be seen as an independent species or a subspecies of B. cereus sensu lato, bearing plasmids encoding insectotoxic proteins [10,11].According to several experts, Bt are insectotoxin producers and belong to the supraspecific group of B. cereus sensu lato, which includes 21 [12].B. cereus sensu stricto (Bacteria; Terrabacteria group; Bacillota; Bacilli; Bacillales; Bacillaceae; Bacillus; Bacillus cereus group) toxins can cause gastrointestinal diseases, wound or systemic infections, and eye infections [11].Perhaps because of the controversies surrounding the approach, a lot of molecular investigations have shown that strains of these species are not distinguishable, since DNA-DNA hybridization similarities and the average nucleotide identity between these Bacillus types are slightly higher than the levels used to distinguish between closely related species, but B. cereus sensu stricto and Bt should continue to be recognized as validly published species [13,14].The extensive analysis of genomic data show that the distribution of insecticidal genes is irregular and numerous strains identified as Bt can be assigned to polyphyletic subclades within the B. cereus/Bt clade [14].Thus, the presence of certain plasmid encoding Cry and Vip cannot be used as a diagnostic marker of Bt.According to the composition vector tree (CVTree) method, there is the relationship between Bt and other B. cereus sensu lato species, but it was the best option to be used for typing Bt strains [15].On the basis of average nucleotide identity researchers set up Bt (so-called B. cereus sensu stricto serovar Berliner biovar Thuringiensis by authors) in B. cereus sensu stricto genomospecies containing 949 genomes [16].The proximity of Bt to pathogenic microorganisms, for example to B. cereus, put forward the problem of their identification and separation in food products [17,18].Now, Bt residues, which cannot be distinguished from natural populations of B. cereus in routine food safety diagnostics are enumerated as "presumptive B. cereus" [17], and approaches to its differentiation are often based on Cry-genes presence [18].Thus, the information on Bt and B. cereus features, set out in this review, is based on the definition of strains and isolates proposed by researchers, but it should be noted that some of them can be attributed to each other.Analysis of the above sources allows us to conclude that it is necessary to draw attention to the problem with the identification of B. cereus group using various taxonomic methods.
One of the important problems of the prolonged and large-scale pest control using Bt (Bt-crops) is the appearance of tolerant or resistant to Bt insect populations [19,20].A high level of pest resistance to Bt-toxins is based on the mutations/reduction in receptors to insectotoxins on the midgut epithelium [21], the development of the humoral responses, including the synthesis of antimicrobial peptides, the activation of the polyphenol oxidase system, the generation of reactive oxygen species, encapsulation of crystals and activation of phagocytosis systems [22].
Previously, Bt strains were considered a cosmopolitan soil bacteria with occasional insecticidal activity [23].Now, the niche of these bacteria is more often attributed to the phylloplane, considering them to be mutualists in relation to plants [24], and in our opinion, it is a kind of revolution in the concept of ecosystems.Plants intimately interact with diverse communities of microorganisms, such as bacteria, fungi, nematodes, protists, and viruses that colonize all plant tissues, rhizosphere, and soil [1,19,23,25].The microbiome establishes complex and dynamic interactions with the host plant and can improve plant resilience to environmental stresses due to the high level of flexibility of these important genetic resources of the whole plant/microbiome system [25,26].
According to modern data, among the bacterial species isolated from internal plant sites, the frequency of the detection of bacteria of B. cereus group, along with B. megaterium, is the highest [25][26][27][28].Endophytic Bt have been isolated from plants of the dicotyledonous and monocotyledonous families, from ferns and bryophytes, distributed in all hemispheres (Table 1).However, Bt strains, which were previously identified as endophytic, may have quantitative differences in population density in tissues of wheat plants [29] and in various organs (roots and shoots) of potato plants [30].Possibly, the endophytic lifestyle of Bt is one of the solutions of their UV susceptibility [6,7].At these time, it should be remembered that Bt strains can actively produce some exotoxins that are detrimental to eukaryotes: α-exotoxin (phospholipase C); β-exotoxin (thuringeinsin, toxic to mammalian); γ-exotoxin (toxic to sawfly insects); lice death factor; and exotoxin mouse death factor (toxic to mice and lepidoptera) [31].In particular, β-exotoxins occurrence limits the application of some Bt strains [32], and the endophyticity of Bt may also represent a hypothetical problem since Bt cells in this case are not removed from the plant surface and can be eaten.
Delanthabettu et al. [40] identified twelve Bt strains, producing crystal structures of Cry proteins, from cowpea root nodules.PCR analysis of those strains revealed the occurrence of Cry-genes of different families.However, endophytic Bt KMCL07 showed quorum quenching activity, and AiiA lactonase KMMI17 production by this strain inhibits biofilm formation and attenuates the pyocyanin of Gram-negative bacteria Pseudomonas aeruginosa PAO1 [41].It is possible that chitinase produced by Bt subsp.pakistani HD 395 can destroy the Nod factor of the soybean symbiont Bradyrhizobium japonicum Kirchner 1896, preventing root noduation [42].Since Bt strains exhibit activity against pathogenic fungi [43], it can be possible that arbuscular mycorrhiza may be interfered by Bt strains [33].
Thus, searching for biocontrol agents is based on the finding of bacteria that have a multidimensional effect on pest organisms and increase the development time of their resistance.Now it is clear that the paradigm of the use of Bt in the same way as chemical pesticides is ineffective, and that it is necessary to investigate Bt as a part of the microbiome of the whole biocenosis.

Spectrum of Bt and B. cereus Availabilities
Now, it is believed that systems of plants and their associated microbiota resulting from the evolutionary selection contributes to the overall stability of the whole holobiont [23,33,83].The biocontrol of pathogens and pests by benefit microorganisms, originating from the competition for niches/nutrients, is possibly one of the most important, at least now, features of microbiomes in agrocenosis [23,24].Mechanisms of biocontrol on direct (the production of antimicrobial/insecticide compounds) and indirect (the induction of systemic resistance in plants) means can be conditionally divided [33].These branches determine all spectra of biocontrol possibilities of plant-associated microbes, including, for example, pathogen quorum sensing interference and the altering of the soil microbiota [83].

Production of Insectotoxic Proteins
The insecticidal activity of Bt is based on their ability to synthesize toxic Cry (and any other) proteins that cause the death of more than 3000 insect species from 16 orders [4].More than 800 sequences of genes encoding insecticidal Cry proteins have now been identified in the plasmid genome of various Bt strains [5].The products of these genes usually accumulate in the form of crystalline inclusions in bacterial cell compartments, which can account for 20 to 30% of the dry weight of sporulating cells [1][2][3][4][5].Cry proteins possess the selective insectotoxicity in relation to insects from families Lepidoptera, Diptera, Coleoptera, Rhabditida, Hemiptera, Hymenoptera, Gastropoda.CryI proteins, for example, showed toxicity to Lepidopteran insects, CryII to Lepidoptera and Diptera, CryIII to Coleoptera, CryIV to Diptera exclusively, and CryV to Coleoptera and Lepidoptera [1,4,84,85].Recently, Cry1Ab and Cry1Ac proteins are found to be toxic to cervical cancer (HeLa) cells were also found [86].
Of particular interest is the fact that the production of Cry proteins in Bt cells is under the regulatory control of bacterial miRNAs, depending on its interaction with a potential host.For example, Bt strain YBt-1518 regulates the accumulation of the Cry5Ba protein only in the infected nematode organism with the help of microRNA [93].The suppression of Cry5Ba synthesis is due to the cyclic BtsR1 RNA binding to the gene Cry5Ba transcript through direct base pairing.It has been reported that strains B. cereus BCM2 and B. cereus SZ5, which were described as endophytes of strawberries (Fragaria ananassa (Duchesne ex Weston) Duchesne ex Rozier, (1785)) and eastern persimmon (Diospyros kaki Thunb.)exhibit high nematocidal activity against Meloidogyne incognita Kofoid & White, 1919 on tomato plants [67].The impact of Bt on nematodes M. hapla Chitwood, 1949, which worsens their reproductive properties and efficiency of tomato root colonization, is connected with the synthesis of the Cry6A insectotoxin [94] It is well-known that aphids (Aphidoidea), whiteflies (Aleyrodidae), thrips (Thysanoptera), nematodes of the genera Trichodorus, and Paratrichodorus intensively transfer many viruses from plant to plant [1,2,29,96].Now, the application of insecticides to control virus vectors is almost the only reliable way to limit viruses from spreading [2,97].Cry proteins of Bt possess limited field and laboratory efficacy against Hemiptera [2].For example, a Cry41related toxin had moderate toxic activity against M. persicae, and this effect was achieved, among other things, due to the influence of aphid endosymbiont Buchnera sp.[98].Pests of this group, in contrast to chewing pests (Lepidoptera and Coleoptera), have piercingsucking oral apparatus and feed on the phloem (whiteflies, aphids, and mealybugs), xylem (spittlebugs and sharpshooters), or juice of seeds and fruit (stinkbugs) and do not eat cells or Cry crystals on the surface of plants.The prevalence of Bacillus spp. in plant sap, in our opinion, can be improved using endophytic strains of Bt.Endophytic Bt B-5351 as they killed about 60% greenbug aphids and stopped their reproduction on isolated leaves of wheat, which were immersed in Bt B-5351 suspension, and increased transcriptional activity of potato PR-genes [29].Under the field conditions, this Bt strain reduced the severity of PVY, PVM, and PVS on potato plants [30].Bt strains produce other classes of compounds that can be toxic for hemipteran pests or have direct antiviral activity, in particular, lipopeptides iturin, surfactin, and fengycin [29,99].
Extracellular ribonucleases (RNases), which are produced by B. amyloliquefaciens; B. pumilus; B. licheniformis [100,101]; and Bt [102] can hypothetically be used for protecting plants and other organisms from viruses [99].It was reported that preparations based on Bt culture fluid with the maximum yield of secreted RNases were effective against A/Aichi/2/68 (H3N2) human influenza virus in experiments on infected mice, close to that of the reference drug Tamiflu [102].

Production of Nematocidal Compounds
Plant-damaging nematodes have a high-level resistance to Cry toxins.Thus, the resistance to Cry1Ac in Trichoplusia ni Hübner is due to multi-gene mutations in ABCC2 gene and the altered expression of APN1 and APN6 genes [103].Therefore, it is even suggested to study the effect of other Bt metabolites on nematodes.The treatment of tomato plants with endophytic strain Bt AK08 resulted in 95.46% mortality of nematodes Meloidogyne sp., which, as the authors believe, is associated with the production of nematocidal cholest-5-en-3-ol(3.beta.)-carbonochloridate[48].High nematocidal activity against juvenile M. incognita parasitizing on tomato roots was demonstrated by the endophytic strain B. cereus BCM2 The authors of the work believe that this effect of the strain is associated with the production of 2,4-di-tert-butylphenol and 3,3-dimethyloctane [67].Bt GBAC46 and Bt NMTD81 strains isolated from plants of the Qinghai-Tibetan Plateau possess high nematocidal activity due to properties of the bacteria themselves and their ability to induce defense reactions of Oryza sativa plants against the nematode Aphelenchoides besseyi [104].
The treatment of grape plants with a multicomponent mixture of Bt FS213P; Bt FB833T; B. amyloliquefaciens FR203A; B. megaterium FB133M; B. weihenstephanensis FB25M; B. frigoritolerans FB37BR; and P. fluorescens FP805PU strains showed effectiveness against Xiphinema sp. and Meloidogyne sp.nematodes comparable with the action of a chemical nematicide [105].In our opinion, the last mentioned data are very important since it demonstrates the possibility of the artificial construction of plant microbiomes, thereby changing plant phenotype.

Production of Fungicidal and Bactericidal Compounds and Triggering Systemic Resistance in Plants
During the last decade, the ability of Bt and B. cereus to control pathogenic components in agrocenoses has been widely taken into account [106,107].It is evident that endophytic bacteria are natural competitors to invaders, and that their action combines antimicrobial and immunostimulating activities [refs below].Wang M. et al. [108] showed that Bt 4F5 induced ISR through the jasmonic acid/ethylene (JA/ET) and salicylic acid pathways in Brassica campestris L. against the pathogen Sclerotinia sclerotiorum (Lib.) de Bary and the pest P. xylostella, engaging exopolysaccharides as elicitors.The protective role of the endophytic Bt FVA 2-3 associated with the roots of Capsicum annuum L. fruits against the fungus B. cinerea, which causes gray rot, is associated with the side with direct antagonism of the strain and with the induction of defense systems in plant cells [53].While Bt serovar aizawai AbtS-1857, which is a part of the commercial bioinsecticide XenTari ® , which was used against the same pathogen on tomatoes did not show direct antagonism against the fungus, it induced PR-1 and PR-5 genes transcription in plants, which determines the salicylate-dependent defense reactions [109].In the same way, the protective effect of B cereus EC9 treatment against Fusarium wilt (F.oxysporum Schltdl., 1824) on tomato [110] and Kalanchoe sp.[111] was not associated with the direct antagonistic effect of bacteria on the fungus, but functioned indirectly, through the expression of plant genes associated with the JA signaling system.B. cereus AR156 treatment significantly suppressed the growth of gray mold on strawberry caused by B. cinerea and prevented senescence during storage.Treatment with B. cereus AR156 enhanced the reactive oxygen-scavenging and defenserelated expression of salicylate-dependent PR-genes (PR1, PR2 (β-1,3-glucanases), and PR5 (thaumatin-like proteins)) [112].Treatment with the same strain indirectly induced the systemic resistance of A. thaliana plants to B. cinerea through signaling defense pathways regulated by salicylic acid and mitogen-activating protein kinases [112], which are associated with the suppression of the accumulation of microRNA miR825/825*, as well as plant ubiquitin protein ligases (miR825) and TIR-NBS-LRR receptor proteins (miR825*) targeted against mRNA [113].Transgenic Arabidopsis plants with the attenuated expression of miR825 and miR825* were more resistant to B. cinerea B1301, while plants overexpressing miR825 and miR825* were more susceptible to the pathogen as compared to wild-type plants.Accordingly, the transcription of defense-related genes and oxidative burst were faster and stronger in miR825 and miR825* knockdown plant lines [114].In addition, it was shown that under the influence of the B. cereus AR156 strain, the accumulation of microRNA miR472, which negatively regulates the transcription of the NBS-LRR gene, was suppressed in Arabidopsis plants infected with P. syringae pv.tomato DC3000 [115].Two transcription factors in Arabidopsis plants, WRKY11 (regulated by JA) and WRKY70 (regulated by salicylic acid), were identified as important regulators involved in induced systemic resistance which was observed under the influence of B. cereus AR156.Gene products modulated the B. cereus AR156-initiated defense cascade in an NPR1-dependent manner [115].
Plant-associated Bt and B. cereus strains are capable of producing a lot of volatile organic compounds (VOCs) [115], for example, some Bt strains from the rhizosphere of Vigna subterranea (L.) Verdc., 1980 [116].Thus, B. cereus C1L produces dimethyl disulfide which induces systemic resistance in tobacco against B. cinerea [117].The violation of glucose transport in the ptsG mutant line of the B. cereus C1L (the deficient synthesis of acetoin and 2,3-butanediol) led to the sygnificant decrease in its ability to exist endophytically in maize roots, as well as to the triggering of systemic resistance [75].After whole genome sequencing, eight clusters of genes were identified in the genome of B. cereus D1 (BcD1), including those responsible for the synthesis of VOCs; serine proteases; plant-growthstimulating metabolites, for example, indoleacetic (IAA); abscisic acid (ABA); and JA, were expressed under stress conditions [118].The production of 3,5,5-trimethylhexanol, which disrupts the permeability of bacterial membranes by the B. cereus D13 strain, led to the growth inhibition of R. solanacearum and P. syringae pv.tomato DC3000 and Xanthomonas oryzae pv.oryzicola [119].A strong inhibition of the growth of S. sclerotiorum mycelium (65.4%) under the influence of a VOC produced by B. cereus, CF4-51 (2-pentadecanone, bis (2-methylpropyl) ester of 6,10,14-trimethyl-1,2-benzenedicarboxylic acid, dibutyl phthalate), which is associated with changes in the expression of four genes of the pathogenic fungus, was associated with sclerotia formation (Ss-sl2, SOP1, SsAMS2, and SsSac1) [120].
The antifungal activity of Bt and B. cereus strains may be associated with their production of chitinases, glucanases, and proteases.Fuente-Sacido et al. [121] showed that the fungicidal activity of Bt subsp.tenebrionis DSM-2803 against the fungus Colletotrichum gloeosporioides (Penz.)Penz.& Sacc., 1884 responds to bacterial endochitinases.It was shown that oligosaccharides of chitin and chitosan produced with the participation of extracellular chitinases and chitosanases of Bt subsp.dendrolimus B-387 possess high bactericidal and fungicidal activity [122].Similarly, endophytic B. cereus XB177R, which show high chitinase activity effectively protected eggplant plants from bacterial wilt caused by R. solanacearum [69].
Bt strains are known to produce antibiotic compounds that inhibit the growth of other bacteria, in particular, other Bt strains.Thus, it is known that Bt strains synthesize up to 18 different types of bacteriocins, for example, the turincin family, tochicin, turicin 7, entomocin 9, bacturicin F4, etc. [123].Bt and B. cereus produce cyclic or linear heptapeptides kurstakins, which are able to damage the biological membranes of bacteria and fungi [124].Bt NEB17 isolated from soybean nodules produced bacteriocin subclass IId (3.162 kDa) and turicin-17 with high antibacterial activity against rhizospheric pathogens [125].The treatment of plants with turicine-17 resulted in the accumulation of proteins of the carbon and energy metabolism pathway, which, together with changes in the phytohormonal balance, compensate for the losses that occur during osmotic stress, besides its antimicrobial activity [126].
The information above suggests that the use of Bt-based biopreparations can alter the composition of the plant-associated microbial population, as well as in its environment, directly or indirectly through the influence on plants metabolism [33,68,81].Considering these data, it can be concluded that there are endophytic polyfunctional Bt and B. cereus strains that possess not only insecticidal but also fungicidal, bactericidal, and viricidal properties against a broad spectrum of important pathogens, or have the ability to stimulate plant defense system, incidentally affecting the functioning of pathogen virulence factors.

Improving of Plant Tolerance to Abiotic Stressors
Last decade it has been shown that some strains of Bt or B. cereus can protect plants from abiotic factors.Thus, the plant-associated strain B. cereus AKAD A1-1, which synthesizes ACC deaminase, increased the resistance of soybean to osmotic stress [72].The treatment of rice plants growing in soils contaminated with arsenic with Bt contributed to a decrease in the accumulation rate of arsenic ions in grains and the tolerance of plants to toxic influence [127].The formation of tolerance of black mustard plants to Cr 3+ ions was found under the influence of B. cereus treatment due to ability of the strain under investigation to solubilize phosphate and synthesize siderophore, osmolyte (proline and sugar), and phytohormones in soils contaminated with chromium [128].The cadmiuminduced phytotoxic influence on pepper after the treatment of plants with Bt IAGS 199 and putrescine was decreased [129].The exopolysaccharide of the B. cereus SZ-1 strain isolated from annual mugwort (Artemisia annua L., 1753) plants showed antioxidant activity against toxic 1,1-diphenyl-2-picrylhydracyl radicals [130].The promotion of antioxidant activity has been shown in ryegrass plants inoculated with Bt EhS7 and B. cereus RA2 strains, which allowed plants to grow more efficiently in soils with a high content of heavy metals [131].It was found that the influence of the halotolerant strain Bt PM25 on corn promotes plant growth in saline soils through the high antioxidant activity of bacterial metabolites [132].ACC deaminase-producing plant-associated bacteria are of particular interest.This enzyme is therefore often designated as a "stress modulator", limiting ethylene levels in plants [133,134].Thus, endophytic B. cereus AV-12, isolated from Vigna mungo Hepper, 1956, synthesizes ACC deaminase [79].B. cereus brm, which synthesizes ACC deaminase, significantly stimulated the growth of mung bean V. radiata plants and improved the viability of plants under salt stress [135].There are some opinions that bacteria with high ACC-deaminase activity also have effective mechanisms of phosphate solubilization [136].Interestingly, ACC deaminase-producing strain Bt GDB1 improved the efficiency of the phytoremediation of areas contaminated with heavy metals by Alnus firma Siebold & Zucc., 1846, a metal ion hyperaccumulator [70].The insertion of the acdS gene encoding ACC deaminase from B. cereus HK012, an endophytic strain isolated from the root tuber of halophytic plant Kosteletzkya virginica L. in tobacco genome, contributed to an increase in biomass, chlorophyll content and, significantly, an up to 50% increase in proline content in plants exposed to salt stress (150 mmol/L −1 NaCl).Accordingly, tobacco plants expressing the B. cereus HK012 acdS gene showed higher salt tolerance than wild-type plants [74].The increase in arabidopsis tolerance to salinity under the influence of B. cereus KP120 bacterium isolated from K. virginica was accompanied by the accumulation of proline in tissues [73].
In wheat plants, the endophytic strain B. cereus LN714048, isolated from buffel grass Cenchrus ciliaris L., caused an increase in salt tolerance under salinity stress, accompanied by an increase in the level of proline, phytohormones, antioxidant enzyme activity and, subsequently, an improvement of yield parameters such as the weight of seeds and ear length [80].It was shown that the stimulation of Cucumis sativus L. seedling growth under the influence of B. cereus [137] and Glycyrrhiza uralensis Fisch.ex DC., 1825 under the influence of B. cereus G2 [138] under salt stress is associated with the accumulation of antioxidants.In the last case, bacterial treatment increases the content of proline and glycinbetaine, and the transcriptional activity of genes encoding betaine aldehyde dehydrogenase, α-glucosidase, and SS-genes, which regulate osmotic potential of plant cells.
Bt MH161336 treatment increased growth parameters in salinity stressed lettuce and caused the up-regulation of proline, superoxide dismutase, catalase, polyphenol oxidase, and peroxidase activity in plants [138].Climate changes demand the investigation of the possibility of using endophytic and rhizospheric bacteria to promote plant tolerance to arid conditions of growth [139,140].Thus, BtAZP2 isolated from the roots of Pinus ponderosa trees, which grew under violent conditions (drought, nutrient limitation heat, and UV-irradiation stress) exhibited the high potential to enhance drought stress tolerance in wheat [61].
The treatment of soybean plants with B. cereus UFGRB2 and combined treatment with B. cereus CP003187.1 and P. fluorescens GU198110.1 influenced the efficiency of photosynthesis, maintaining the potential quantum yield of PSII and the rate of photosynthesis under the drought conditions, while these indicators decreased in non-inoculated plants [141].B. cereus MKA4 treatment led to the activation of enzymes of the pro-/antioxidant system of drought-sensitive wheat variety HD2733 under stressful drought conditions [142].The increase in tolerance to high temperature in soybean plants after their treatment with an endophytic strain of B. cereus SA1 was found.Thus, in Bt SA1-inoculated plants GmLAX3 and GmAKT2 genes were overexpressed, reactive oxygen species generation was decreased, which can be critical in plants under heat stress [81].So, to summarize, through all these different abiotic influences, we think that the most important impact of Bt and B. cereus on stressed plants include its ability to decrease oxidative damage in plant cells.
Data on the ability of endophytic B. cereus strains to scavenge the air from ozone [143], formaldehyde [144], and ethylbenzene [145] in the plant-microorganism biome are of interest.A characteristic feature of the strain Bt ZS-19 isolated from the sludge of the wastewater containing pyrethroids is the ability to degrade 3-phenoxybenzoic acid and also a number of pyrethroid compounds [146].In a recent study, Bt MB497, isolated from wheat rhizosphere in Pakistan, showed the ability to degrade up to 90.57% of 3,5,6-trichloro-2pyridinol (pesticide chlorpyrifos) within 72 h in vitro [147].It has been reported that the Bt strain from the commercial bioinsecticide Bac-Control WP from the company VectorControl (Brazil) is able to degrade the insecticide cypermethrin [148].On the one hand, the last mentioned property opens new prospects for the disposal of dangerous pesticides, and on the other hand, this possibility shall be taken into consideration as a determining factor in plant protection systems, including biocontrol agents and chemical means.
The ability of strains of endophytic bacteria, including Bt and B. cereus, to detoxify pollutants opens up new opportunities for improving the ecological component of urbanized areas by forming "green" plant-microbial communities that can reduce the negative background of atmospheric and soil pollutants.

Plant-Growth Promoting Effect
An endophytic lifestyle and the ability to protect plants from biotic and abiotic influences suggest that strains of Bt and B. cereus can improve viability and adaptive potential of the whole plant/microbes system, which leads to the increase in plant growth and yield [1][2][3][4]149,150]. It was assumed that the plant growth-stimulating effect of Bt and B. cereus strains is associated with the production of metabolites by bacteria, among which phytohormone-like compounds are the most discussed [151].At the same time, surfactins, bacteriocins, and siderophores can also play a significant role in the process of inducing plant growth characteristics.
Plant-growth stimulation by B. cereus was documented, for example, for wheat, potato, pea, soybean, Chinese cabbage (B.rapa L. Chinensis group), maize, and rice plants [152][153][154][155].For example, after the pre-sowing inoculation of rice with the B. cereus GGBSU-1 strain, the rate of their germination was increased up to 100% compared to 65% in controls, which was accompanied by corresponding changes in phenotypic (morphological parameters and the biomass of seedlings) and biochemical (the content of chlorophylls a and c, total soluble sugar, and α-amylase activity) parameters in seedlings [155].The inoculation of plants with B. cereus T4S, isolated from the endosphere of H. annuus L. roots, promoted crop growth, including taproot length, root length, number and weight, and seed, weight compared to the controls [83].The treatment of chickpea seeds with B. cereus MEN8 stimulated seed germination and plant growth [156].The solubilization of phosphates and the formation of auxins, HCN, and ammonia by B. cereus LPR2 (isolated from the spinach rhizosphere) [152] and Bt KVS25 [157] are referred to as the backbone of the ability of these strains to stimulate the germination and growth of maize plants and the growth of Brassica juncea L., respectively.
The endophytic bacterium Bt W65, isolated from potato shoots, increased the duration of the flowering of plants of the corresponding culture by 8-13 days compared to control.The yield of tubers also increased by 7.9-14.6%,and with the joint inoculation of tubers with B. amyloliquefaciens and Bt W65 cells, an increase in the yield of large tubers and a decrease in the presence of infectious agents in plantings was observed [64].Similarly, the potassium-solubilizing B. cereus strain WR34 efficiently promoted plant growth and the accumulation of dry biomass of the aerial part of the potato, which increased the yield of this crop by 20% compared to the control plots [153].Tsvetkova P. et al. [158] showed that treatment of potato plantings with Bt ssp.darmstadiensis BtH10 (RCAM 01490) stimulated the accumulation in the crop by up to 1.6 times and led to a more than three-fold decrease in the population of L. decemlineata and an up to twelve-fold decrease in the development of leaf and stolon rot caused by the fungus Rhizoctonia sp.
The seed treatment of spring rapeseed and wheat with Bt ssp.fukuokaensis; ssp.toumanoffi; ssp.morrisoni; ssp.amagiensis; and ssp.dakota led to a positive effect on the length of roots by up to 3.4 times and seedlings by up to 1.9 times, and a decrease in the number of seedlings affected by root rot caused by pathogenic fungi F. oxysporum and A. alternata [159].The studied strains made it possible to obtain a higher quality and higher yield compared to the control variant.When using strains of Bt spp.morrisoni and Bt spp.dacota potato yield increased by 1.4 and 1.5 times, respectively [160].
The growth potential of Lavandula dentata L. was found to be preserved, even under drought conditions, after inoculation with a composition of five strains of arbuscular mycorrhizal fungi with an endophytic Bt isolate, which the authors attribute to the ability of bacteria and fungi to produce auxins and ACC deaminase and effectively immobilize phosphates [161].A consortium containing strains of B. cereus LN714048 and Pseudomonas moraviensis LN714047 stimulated plant biometric parameters, including height, weight, and seed weight [162].The complex use of B. cereus TSH77 and B. endophyticus TSH42 contributed to an increase in the biomass of turmeric (Curcuma longa L.) rhizomes and, accordingly, the content of curcumin [163].The double inoculation of Stevia rebaudiana Bertoni, 1905 seedlings with cells of B. cereus SrAM1 and A. brasilense contributed to an increase in chlorophyll content, as well as the activity of antioxidant enzymes and the positive regulation of genes responsible for the biosynthesis of steviol glycoside [49,164].

Genetic Engineering Approach to Develop Next-Generation of Bt-Based Agents
Now, genetic modifications of Bt serve the purpose of dissolving two main problems of Bt-preparations, such as increase in bacteria tolerance to the impact of environmental factors and improving its insecticidal effects against different pests.The strategies of genetic engineering approaches to constructing strains with the required properties are as follows: (1) the up-regulation of the key enzyme gene involved in the target compound biosynthesis; (2) relieving the inhibition and/or repression of the key enzyme; and (3) the interruption of the pathways for synthesizing by-products [165].The development of next-generation artificially improved Bt strains or strains heterologically producing Bt-toxins involves a broad spectrum of DNA reorganization, such as site-directed mutagenesis (SDM), the suppression and overexpression of genes, including RNA interference (RNAi) [166,167] Initially, RNAi was proposed as a suggestive strategy for the inhibition of viral infection.It is a post-transcriptional gene regulation mechanism characteristic of (possibly) all eukaryotes, including insect pests [106][107][108].The mechanism is triggered by double-stranded RNA (dsRNA) precursors that are processed into short-interfering RNA (siRNA) duplexes, which then realize the recognition and repression of complementary dsRNAs, such as mRNAs or viral genomic RNAs [168].

Improvement of Insecticidal Properties of Bacterial Strains
Currently, genetic engineering approaches make it possible to transfer/supplement/ modify genes encoding insectotoxin to other Bt strains or strains of another bacterial species using homologous recombination [169].Current information on Cry-and non-Cry genes, which were used for the recombination of a broad spectrum of bacterial strains is assumed in [106,170].An important tool for the recombination of Bt strains is site-specific recombination (SSR), which is useful for engineering strains with original combinations of Cry toxins genes with improved insecticidal activity [166,167,171].It seems interesting to create endophytic Bt or other bacterial species whose populations in the internal tissues of plants would be safe from the environment and have greater activity against pests.These investigations originated in the last decade of the 20th century when the Bt gene encoding Cry1Aa was expressed in root-associated P. fluorescens [172].Thus, the introduction of the cry1Ia gene into the endophytic strain B. subtilis 26D does not lead to the loss of the endophytic status of B. subtilis 26DCryChS line and gives impetus to its insecticidal and aphicidal activity in vitro and in planta [29,30].Endophytic Burkholderia pyrrocinia JKSH007 heterologically expressing the Btcry218 gene showed an effectiveness against Bombyx mori L. [173].The ability of Pantoea agglomerans 33.1:pJTT expressing cry1Ac7 to inhabit Saccharum officinarum L. tissues was confirmed by re-isolation from the plant's rhizosphere, roots and shoots.Thus, the introduction of an exogenous gene did not affect the plant-host interaction but increased the mortality of Diatraea saccharalis Fabricius, 1794 fed on inoculated stems [174].The transfer of "useful" insectotoxin genes from other economically important Bt strains to endophytic bacteria, as well as the maintenance of their consortiums, should contribute to the creation of new-generation biological agents based on them.At the same time, modern technologies for editing microbial genomes based on the CRISPRCas9 platform [168,175] can be proposed to disable the α-exotoxin and β-exotoxin synthesis of Bt.

Approaches to the Development of UV-Tolerant Bt
The problem of the UV-irradiation susceptibility of Bt seriously restricts its effective use.The exogenous addition of UV protective agents, such as rhodamine B or methyl green, can protect spores from the light [176].Subsequently, for the same purpose, latex particles, ethanol, and olive oil have been used to encapsulate Bt in colloidosomes [177,178].
Homologous recombination technology was used for the insertion of the yhfS gene encoding acetyl-CoA acyltransferase in Bt LLP29 R-yhfS.The loss of the yhfS gene in the knockout strain Bt LLP29 ∆-yhfS led to the reduction in antioxidant ability and reduced UV resistance of the mutant [179].The cell-surface exposure of chitinase Chi9602∆SP was developed on the basis of Bt BMB171 using two repeat N-terminal regions of autolysin (Mbgn)2 as the anchoring motif.After continuous culturing for 120 h, the line of Bt expressing chitinase Chi9602∆SP showed narrow pH tolerance and obviously enhanced UV radiation resistance capacity in addition to a high inhibitory effect towards phytopathogenic fungi, F. oxysporum FB012 and Botryosphaeria berengeriana FB016 [180].CRISPR/Cas9 systems have been used to knock out the homogentisate-1,2-dioxygenase (hmgA) gene and obtain a melanin-producing mutant Bt HD-1-1 hmgA.The anti-UV test shows that melanin arranges protection to both Bt cells and Cry toxin crystals.After UV-irradiation the strain Bt HD-1-1 hmgA still had an 80% insecticidal activity against H. armigera, while the wild line only had about 20% [8].
Cry genes have been expressed in P. fluorescens and Anabaena sp. to increase the damage to crystals from UV light [181,182], as well as in E. coli; B. megaterium [183] [170]; Beauveria bassiana (Bals.-Criv.)Vuill., 1912 [184]; etc.The recombinant strain P. fluorescens is the base of biopesticide "CellCapTM" (Mycogen Corp.; Indianapolis, IN, USA), contains encapsulated Cry toxins [185].The increase in the amount of Bt-plants can be partially attributed to the means of the protection of insectotoxins from UV rays [72].

Bt Crops Prospects
Since 1996, genetically engineered Bt crops have been planted in the fields, which led to a "gene revolution" in agricultural production [186,187].By the early 21th century, Bt-potato, Bt-cotton, Bt-maize, Bt-eggplant, etc. were actively distributed worldwide, which allowed for a significant reduction in the amount of chemical insecticides used in a number of countries [96,188].However, this approach lead to a fairly rapid spread of resistant pest populations [80,189,190].To overcome insect resistance, it is possible to introduce Bt crops containing more than two genes encoding insecticidal proteins [189,190].The Bollgard cotton variety bearing Cry1Ac gene decreased the viability of pink bollworm Pectinophora gossypiella (Saunders, 1844) and corn earworm Helicoverpa zea Boddie, 1850.Plants of the Bollgard II variety, expressing two Bt endotoxins, expand the spectrum of protective features against lepidopteran pests [191].Bt-cotton with cassettes of protective genes (1Ac/Cry2Ab/Vip3A), (Cry1Ab/Cry2Ac/Vip3Aa19) or (Cry1Ac/Cry1F/Vip3A) was cultivated in the 2016-2017 season on more than 90% of the arable lands of Australia [192].
Currently, the creation of plants containing not only Cry or Vip genes but also containing other gene sequences is of interest in order to increase the effectiveness of biological plant protection against pests.Recently, the US EPA approved a transgenic corn, Smart-StaxPRO, expressing the Cry3Bb1 protein, and a dsRNA complementing the RNA of the vacuolar protein DvSnf7 of Diabrotica virgifera LeConte, 1858 [193,194].A vector containing information about dsRNA targeting the acid methyltransferase gene of the juvenile hormone biosynthesis of H. armigera was inserted into the genome of Bt-cotton and impaired the resistance of pest compared to plants expressing only insectotoxic proteins [195].The RNAi-mediated knockdown of H. armigera acetylcholinesterase, the ecdysone receptor, and v-ATPase-A genes by producing dsRNAs homologous to genetic targets in potato plants led to mortality and abnormal development in the larva of this insect (recorded ten days post feeding) [167].
Apparently, the application of single Bt genes to modify plant genomes will be gradually replaced by multiple Bt toxin genes or Bt with other nucleotide sequences.

Bt as a Means of dsRNAs Deliverance
The important problem of interference methods is dsRNA degradation by nucleases in the gut lumen and tissues of insects.Retaining dsRNA molecules in the gut or hemocoel of pest insects is the key aspect of an effective dsRNA delivery [166].Thus, dsRNase catalyzing the specific cleavage of dsRNA has been found in the saliva of Lygus lineolaris Palisot de Beauvois, 1818 [196]; pea aphid Acyrthosiphon pisum Harris, 1776 [197]; Schistocerca gregaria Forskal, 1775 [198]; H. armigera [167]; etc.A dsRNA cassette targeting the multiple genes of H. armigera revealed more rapid cleavage in midgut juice compared to the hemolymph [167], and for this reason, the Bt-mediated appearance of pores in digestion membranes, in our opinion, can improve the efficacy of dsRNAs along with dsRNAs targeting dsRNases [199].The stability of mRNA provided by, for example, the Shine-Dalgarno sequence (GAAAG-GAGG), is a promising factor of the high-level expression of Cry genes in Bt [167,200,201].The binding of the 30S ribosomal subunit to this sequence might prevent mRNA cleavage by RNAses of pest.The use of a sporulation-dependent promoter of Cry genes of Bt for the transcription of the target dsRNA sequence, leads to the fact that the dsRNA will be spontaneously produced during the sporulation phase [201,202].It has been demonstrated that the incorporation of plasmid pBtdsSBV-VP1, which carries out dsRNA complemental to the VP1 sequence of the sacbrood virus (SBV) in Bt 4Q7 and the subsequent appliance of exogenous total RNA, leads to a decrease in SVB severance in Apis cerana (Fabricius, 1793) families [202].Then, the plasmid pBtdsSBV-VP1 was inserted into the Bt NT0423, which expresses Cry1 protein, resulting in SBV replication being repressed in A. cerana bees as well as the viability of the A. cerana parasite Galleria mellonella L. [200].These results demonstrated that dsRNA-expressing Bt products could be efficiently exploited for the control of both viral diseases and insect pests simultaneously.And furthermore, it is possible to enhance the toxicity of Cry toxins using dsRNA cassettes.Thus, Bt strains 8010AKi and BMB171AKi expressing the dsRNA of the arginine kinase gene (PxAK) of P. xylostella, flanking two ends with the promoter Pro3α, effectively decreased PxAK expression in ones treated with the composition with wild Cry-producing Bt 8010 and caused a higher lewel of mortality of the pest [203].Separately, E. coli HT115 dsINT expressing the dsRNA of integrin β1 subunit gene (SeINT) cause a less than 50% mortality rate against Spodoptera exigua Hubner, 1808 larvae, and E. coli expressing Cry1Ca led to a maximal 58% mortality rate of the pest.When S. exigua larvae were treated with the Cry1Ca-expressing bacteria (E. coli or Bt subsp.aizawai from commercial Xentari insecticide) after treatment with E. coli HT115 dsINT, the insecticidal activity of the Cry1Ca was significantly enhanced up to about 80% [201].The nuclease gene HaREase characteristic for Lepidoptera is up-regulated by dsRNA and affects RNAi in H. armigera.When this gene was knocked out using the CRISPR/Cas9 system, the midgut epithelium structure was not affected in the ∆HaREase mutant, but when larvae were fed an artificial diet with sublethal doses (2.5 or 4 µg/g) of Cry1Ac, the growth rate of the ∆HaREase line was repressed significantly [204].The insecticidal activity of the Bt-based biopesticide Xentari™ (Valent BioSciences) against larvae of S. littoralis was significantly enhanced by pre-treatment with dsRNA-Bac targeted against the Sl 102 gene, which is responsible for insect cell aggregation and encapsulation to protect against Bt infection [205].Likewise, the efficacy of biological preparations based on live Bt cells was enhanced when used together with dsRNA-Bac specific to sequences of the P. xylostella Pxf gene [206], which caused insect resistance to Cry1Ac toxin.The RNAi-mediated suppression of the Cat L-like gene encoding the lysosomal cathepsin L-like cysteine protease of Bombyx mori led to an increase in larvae mortality under the influence of Bt subsp.kurstaki strain ABTS-351 (Dipel ® , Valent BioSciences, Libertyville, IL, USA) [207].It is probably that the increase in insect resistance to biocontrol agents based on Bt strains producing toxins and the use of this bacterium as a platform for the expression of dsRNA can help in pest control using the Cry + RNAi strategy [205][206][207].

Conclusions
Currently, a broad spectrum of data has been accumulated on the influence of Bt and B. cereus on different species of plants.New studies in the field of interactions between plants and bacteria reveal the ability of Bt and B. cereus to invade and exist in plant microbiomes, where bacteria possess protection against environmental factors, in particular, UV radiation.New algorithms, which can be called "microbiome engineering" can detect, modulate, and enhance benefits and ways to improve the efficacy of strains.Unfortunately, our knowledge on the intricate interactions of plants with beneficial microbes is quite limited.
It is clear that the colonization of plant niches by microorganisms, including Bt and B. cereus, is a multifaceted process consisting of different steps that are mediated by plant and/or bacterial molecular patterns [208].These interactions can be strictly specific for different plant and microbe species and can be dependent on environmental conditions.Now, there are no data on universe genes or molecular patterns, which determine the plantassociated status of microbial strains [83,208].Therefore, the plant should be considered as an integral phytoholobiont, wherein the artificial introduction of endophytes which makes it possible to effectively protect the macroorganism not only from attacks by phytophagous insects, phytopathogenic viruses, bacteria, and fungi but also from unfavorable abiotic environmental factors, as well as pollutants.This approach makes it possible to obtain products that are safe for humans and animals in cenoses, which cannot avoid urban influences.The identification of additional abilities of endophytes to metabolize hazardous chemical compounds and increase the resistance of plants to heavy metals makes it possible to effectively use the above and other similar bacteria also for the phytoremediation of territories contaminated with various pollutants, including the air environment, which is becoming increasingly important for humankind around the world.

Table 1 .
B. thuringiensis and B. cereus endophytic strains and their properties.