Key words
antimicrobials - attine ants - interspecies interactions - microbial symbiosis - social
insects - stingless bees
Introduction
Brazil is one of the worldʼs 17 megadiverse countries that host between 15 – 20% of
the entire worldʼs biological diversity, including the greatest number of endemic
species [1], offering innumerous research opportunities and sustainable technological development.
Natural products research in Brazil has been historically focused on plant-derived
compounds and evaluation of their biological activities [2], with only recent efforts directed to microbial-derived compounds and marine organisms
[3], [4], [5].
Recent estimates based on DNA sequence information have shown that microorganisms
consist in the highest number of living species, most of them yet to be described
[6], but there are no records on the number of microbial species in Brazil. This untapped
ecological niche represents a huge potential for natural products discovery, as suggested
by sequencing of environmental bacterial DNA collected in different biomes [7].
Microorganisms are the most ancient form of life on earth and have established symbiotic
interactions with several other organisms, from mammals to arthropods and plants [8]. Symbiosis involves any intimate species interaction, either positive or negative,
including mutualism, commensalism, and parasitism, as defined by Bary [9]. Indeed, symbioses with microorganisms have contributed with innovations in eukaryotic
evolution [10]. Much of the communication between microorganisms and between microorganisms and
their environment is based on chemical interactions [11], the subject of research in the interdisciplinary field of chemical ecology [12]. Deciphering the chemical language between species is key to understanding how they
interact and provides an opportunity for ecologically-guided natural products discovery
for biotechnological
purposes.
Insects dominate the known diversity of living organisms. Class Insecta comprises
about 1 million described species and makes up 83.5% of all species in the Phylum
Arthropoda [13]. Brazil harbors the highest diversity of insects in the world [14], but natural products research on insects is mainly focused on pheromones in the
country [15]. As with other organisms, insects have developed a plethora of interspecies interactions
with microorganisms, and social insects are fascinating examples of multipartite symbiosis.
Eusociality is an evolutionarily advanced level of social organization nearly confined
to insects, especially ants, bees, wasps, and termites. Eusocial adult insects in
a colony belong to different overlapping generations, care cooperatively for the offspring,
and are divided into reproductive and nonreproductive castes [16]. Some social insects have also evolved symbiotic mutualistic interactions with fungi
in which nutrient exchange between species is the key behind this association. Insects
provide food resources–usually plant-derived material difficult to digest–to the fungi
and protect them against opportunistic pathogens. In return, fungi can supply nutrients
and molecules important for insectʼs physiological functions [17], [18]. Social insects are particularly attractive for microbial disease agents, since
they live in high populational densities in relatively homeostatic nest
environments and store food resources [19]. To avoid pathogens, social insects have evolved several strategies, such as grooming,
nest hygiene, and chemical defenses [19], [20]. Another defensive strategy of insects is the symbiotic association with bacteria
that produce and secrete biologically active small molecules that are selective against
pathogens [20].
The biosynthetic potential of insect-associated microbes worldwide is covered elsewhere
[17], [20], [21], [22], and here we highlight some of the work done on the Brazilian biodiversity. The
biological activity of some microbial strains isolated from Brazilian social insects
has been investigated but not exhaustively studied. These microbial isolates comprise
yeasts, proteobacteria, and actinobacteria, which produce a variety of biologically
active small molecules.
Natural Products Mediating Microbial Symbiosis Fungus-Farming Ants
Natural Products Mediating Microbial Symbiosis Fungus-Farming Ants
E. O. Wilson, a recognized American biologist, naturalist, and writer, stated in 1975:
“There are more species of ants in a square kilometer of Brazilian forest than all
the species of primates in the world, more workers in a single colony of driver ants
than all the lions and elephants in Africa” [23].
Fungus-farming “attine” ants (Formicidae: Myrmicinae: Attini: Attina) originated in
a single ancestral attine in Amazon around 45 million y ago [24]. Approximately 250 species of fungus-farming ants are found in the “New World”,
ranging from North America to South America [25]. Attine ants collect plant and other material they forage from the environment to
nurture basidiomycete fungi they cultivate for food. During the evolution of these
interactions, the foraged material has been diversified, giving rise to the so-called
“basal” and “highly evolved” agricultural systems, based on the substrate that the
fungal crop is fed [26]. Other microbes found in this multipartite symbiosis are a specialized pathogenic
fungus from the genus Escovopsis, which can suppress the crop fungal cultivar and destroy the ant colony [27], and a symbiotic actinobacterium
usually belonging to the genus Pseudonocardia, which produces small molecules that selectively inhibit the pathogenic fungus over
the crop fungus [28], [29]. Dentigerumycin, produced by Pseudonocardia associated with Apterostigma ants collected in Central America, was the first selective antifungal characterized
as mediator of the defensive symbiosis in attine ants ([Fig. 1]) [30]. Even though there is a reasonable number of publications examining the chemistry
involved in this symbiosis from attine colonies sampled in Central America [30], [31], [32], [33], [34], the potential of the microbial symbionts from Brazilian attine ants still remains
to be explored.
Fig. 1 Ecological relationships between microorganisms and attine ants. Mutualistic interactions
are represented by green arrows and red T-bars represent harmful interactions. Investigations
into this system led to the isolation of the antifungal dentigerumycin [30]. Source: Monica Tallarico Pupo
Some attine ants have their exoskeletons covered by the actinobacteria, whereas others
do not show the same obvious association. Ants of Atta genus, for instance, do not show specialized crypts–morphological structures that
harbor actinobacteria–in their bodies. The bacterial symbionts are supposed to be
internalized inside antsʼ bodies [35] or even in other places of the colony. The hypothesis that opportunistic pathogens
were inhibited by microorganisms living in the colony was therefore tested. Different
parts of Atta sexdens colonies (fungal garden, waste deposit, and surface of leaves collected by ants)
were sampled and resulted in the isolation of 99 yeast strains. These strains had
their inhibitory activities tested against 6 reporter yeast strains and also against
each other. The results showed that 77 strains (78%) inhibited the growth of the competing
strain. This high number of active strains pointed toward a role in
maintaining the nest microbial community [36]. Investigations were also conducted into the role of bacterial strains associated
with the fungal gardens of Atta sexdens ants collected in eucalyptus plantations in Rio de Janeiro state, Brazil. A high
number of colonies was found to be associated with Burkholderia sp. strains, which inhibited different entomopathogenic fungi, such as Metarhizium anisopliae, Beauveria bassiana, the saprophytic fungus Verticillium lecaniii, and the specific ant pathogen Escovopsis weberi. Although these strains had antifungal activity against different fungi, they did
not show any activity against the fungal cultivar. Burkholderia sp. strains were isolated from 32 out of 57 ant nests (56%), also suggesting an important
ecological role [37].
As well as producing small molecules with defensive roles, Proteobacteria can also
fulfill other ecological functions. Serratia marcescens isolated from Atta sexdens rubropilosa colonies produce volatile pyrazines, including 2,5-dimethylpyrazine (1) and 3-ethyl-2,5-dimethylpyrazine (2) ([Fig. 2]), that are components of antsʼ trail pheromone [38]. However, the dependence of ants on the microbial biosynthesis of trail pheromones
remains to be elucidated. The microbial involvement in the production of pheromones
has been recognized for some insects, but more efforts are needed to experimentally
validate connections between the presence of specific symbionts, changes in the hostʼs
chemistry, and behavioral effects [39].
Fig. 2 Compounds isolated from microbial symbionts of attine ants collected in Brazil.
Leaf-cutter ants start new colonies with queen ants fecundated during the nuptial
flight; however, mortality is extremely high during the nuptial flight and immediately
afterward [24]. A. sexdens rubropilosa queen ants were found to be infected by the entomopathogenic fungus Aspergillus nomius after nuptial flight. The fungus produced aflatoxin B1 (3) and aflatoxin G1 (4) ([Fig. 2]) both in situ and in vitro. These compounds may play a pivotal role in the fungal pathogenicity observed for
the Atta queens [40].
Different from Atta ants, leaf-cutter ants of genus Acromyrmex usually carry the symbiotic actinobacteria in crypts in their exoskeletons. Acromyrmex subterraneus brunneus worker ants at USP-campus, Piracicaba-SP, Brazil were sampled for the presence of
actinobacteria, leading to the isolation of 20 actinobacteria strains. Among these
bacteria, 17 strains belong to the genus Streptomyces, and the remaining are Pseudonocardia, Kitasatospora, and Propionicimonas. The majority of Streptomyces isolates inhibited the growth of the nest pathogen Escovopsis weberi
[41]. These studies suggested that the ant-associated microbes isolated from samples
collected in Brazil–other than Pseudonocardia–produce secondary metabolites with biological activity; however, chemical compounds
responsible for antimicrobial activities are still elusive.
Actinobacteria can produce compounds showing great chemical diversity and a large
variety of biological activities, and have evolved protective symbiotic interactions
with different organisms [42]. Indeed, Streptomyces has been proven to be a good source of antimicrobial defenses in insects [22]. The first compounds from Streptomyces strains associated with fungus-farming ants in Brazil were the antimycins urauchimycin
A (5) and urauchimycin B (6) ([Fig. 2]) [43], with broad and potent antifungal activity against medically important Candida strains.
Recently, interdisciplinary research groups in Brazil have been mainly focused on
the characterization of biologically active natural products from microbial symbionts
of social insects [44]. Using an ecological-driven approach, the actinobacterial symbionts of attine ants
have been systematically screened against the specialized pathogenic fungus Escovopsis and then selected for further screening against other bacterial, fungal, and protozoan
human pathogens.
The search for symbionts of Acromyrmex subterraneus brunneus ants, collected at USP-campus, Ribeirão Preto-SP, led to the isolation of Streptomyces chartreusis ICBG377, recovered from the fungal garden. The actinobacterium produces the antibiotic
streptazolin (7), its E-isomer (8), strepchazolin A (9), strepchazolin B (10), and the inorganic compound cyclooctasulfur (11), the active compound against Escovopsis ([Fig. 2]) [45]. Compound 11 was also produced by S. chartreusis ICBG323, isolated from the exoskeleton of winged males of Mycocepurus goeldii
[45].
The actinobacterium S. puniceus ICBG378, isolated from Acromyrmex rugosus rugosus ants, produces griseorhodin A (12) and griseorhodin C (13), natural products known by their cytotoxic activity against cancer cell lines [46], and dinactin (14), active against Escovopsis ([Fig. 2]) [47]. Dinactin (14) was also active against Leishmania donovani, one of the etiological agents of leishmaniasis, a neglected tropical disease that
causes thousands of deaths yearly in developing countries.
Similarly, Cyphomyrmex-associated Streptomyces sp. ICBG292 produced Mer-A2026B (15), piericidin-A1 (16), and nigericin (17) ([Fig. 2]), all active against Escovopsis and against intracellular amastigotes of L. donovani. Compounds 15 and 16 were also isolated from Atta-associated Streptomyces, while 14 and 17 showed the most potent leishmanicidal activities, with good selectivity indexes [47]. The biological activity of these compounds highlights the importance of exploring
different sources for prospecting compounds that can help treating human diseases
[47].
The hypothesis that the ant microbiome is a good source for exploring new medically
useful antimicrobial agents was further reiterated. The isolation of cyphomycin (18) ([Fig. 2]), a new antifungal polyketide, proved that the Brazilian biodiversity should be
explored in order to find new candidates for the treatment of fungal infections. Cyphomycin
(18) was produced by a Cyphomyrmex-associated Streptomyces strain and showed potent activity against human fungal pathogens both in vitro and in vivo
[22].
Natural Products Mediating Microbial Symbiosis in Stingless Bees
Natural Products Mediating Microbial Symbiosis in Stingless Bees
Although a wide diversity of microorganisms, such as bacteria, fungi, and yeasts are
found to be associated with bees, little is known about their role as beneficial symbionts
[48]. Indeed, honey bees across the world harbor a rich bacterial community [49], [50], [51], [52]. Lactic acid bacteria (LAB) are frequently isolated from the guts of honey bees
and bumble bees, and it is believed that this specific microbiota coevolved with their
hosts. playing roles in nutrition and defense against pathogens [53], [54], [55], [56].
More information is available regarding microbial pathogens of honey bees, which span
several kingdoms, including the most damaging threats such as viruses, bacteria, and
fungi [57]. Paenibacillus larvae and Melissococcus plutonius, the infective agents of American and European foulbrood diseases, respectively,
are major bacterial threats to honey bees (Apis species) [57]. The American foulbrood disease (AFB) is widespread in honey bee larvae [58], [59] and drastically impacts the apiculture and the pollination of crops and wild plants
[60]. The long-lived spores produced by the bacterium are infectious only for larvae,
especially in early larval stages [61]. Burning the infected colonies is one usual treatment for AFB [62]. Antibiotics such as
oxytetracycline are used in some countries for prevention and treatment of contaminated
colonies still, but this approach is not effective against spores [63], [64], [65], [66], [67]. Other problems can be caused using antibiotics as their chemical residues accumulate
in honey, reducing the longevity of the bees and selecting resistant P. larvae strains [61], [68]. The European foulbrood disease is caused by the globally distributed Gram-positive,
non-spore-forming bacterium M. plutonius
[69]. Ingestion of larval food contaminated with M. plutonius causes infection in larvae. Bumble bees (Bombus terrestris), important pollinators of the northern hemisphere, are colonized by the virulent
parasite trypanosomatid
Crithidia bombi (Trypanosomatidae, Zoomastigophorea) [70]. These infections have a variety of consequences, such as the mortality of the colonies.
While microbial diseases are better understood for honey bees, little is known about
microbial diseases affecting stingless bees. Stingless bees (Apidae: Meliponini) are
a large group of bees with more than 500 species described, around 300 of them occur
in Brazil [71]. Although A. mellifera is originally from Africa, this species is an important pollinator widespread around
the world [72]. The global distribution of honey bees favors their microbial pathogens to spillover
stingless bees native to tropical and subtropical regions [73]. Indeed, some honey bee pathogens already detected in stingless bees include the
disease-causing bacterium Lysinibacillus sphaericus in Australia [74], the acute bee paralysis virus (ABPV) in Brazil [75], the bacterium M. plutonius in Brazil [76], and
the fungus Nosema ceranae in laboratory colonies [73]. Therefore, an ecological approach to study bacterial symbionts of stingless bees
involved in defensive responses can be based on microbial pathogens of honey bees
and bumble bees.
Research has been directed toward the role of the associated microbiota in protecting
bees against pathogens. LAB have a potential role in controlling the bacterial pathogens
causing American and European foulbrood diseases [77]. Stingless bees from different geographical regions also carry LAB [78] that might possess similar functions. Bacteriocin-like compounds, active against
P. larvae were also identified from LAB isolated from honey bees in Argentina [79]. Actinobacteria have also been isolated from stingless bees from other tropical
and subtropical regions. Antibiotic-producing Streptomyces spp. were isolated from the stingless bee Tetragonisca angustula in Costa Rica, showing antimicrobial activities against a variety of human pathogens
[80]. Actinobacteria strains active against P. larvae and M. plutonius were
isolated from colonies of honey bees (A. mellifera, A. cerana, A. florae) and stingless bees (Trigona laeviceps and T. fuscobalteata) in Thailand [81]. However, the small molecules mediating these defensive symbioses have not been
comprehensively studied.
The first unprecedented example of nutritional symbiosis in stingless bees is the
Brazilian bee Scaptotrigona depilis, which is surrounded by a complex microbial community. S. depilis cultivates a fungus of the genus Zygosaccharomyces in the brood cell, which provides ergosterol (19) ([Fig. 3]) as a precursor for ecdysteroid biosynthesis and, consequently, for proper larval
development and metamorphosis [82], [83]. Two additional fungi are also active in the cerumen of brood cells, Candida sp. and Monascus ruber, which modulate Zygosaccharomyces sp. growth. Candida sp. produces volatile alcohols such as ethanol and isoamyl alcohol that stimulate
the growth of Zygosaccharomyces sp., while Monascus ruber inhibits Zygosaccharomyces sp. and Candida sp. by the production of lovastatin (20) and monascin
(21), respectively ([Fig. 3]) [84]. Fungi of the genus Monascus were also found in association with other species of stingless bees in Brazil, but
their chemical-ecological functions remain unknown [85]. The larvae of S. depilis also engage in associations with microbes. Genome analyses of the Bacillus sp. SDLI1 isolated from S. depilis larvae indicated the presence of biosynthetic gene clusters that encode the production
of a variety of antibiotics, suggesting a bacterial defensive symbiosis [86]. Bacillus spp. have been commonly associated with honey beesʼ larvae and inhibit P. larvae
[87], [88]. The isolation of Bacillus DNA in fossils showed close phylogenetic relationships with strains typically isolated
from stingless bees, which could
provide information about the evolution of microbe-insect symbiosis [89].
Fig. 3 Compounds isolated from microbial symbionts of Brazilian stingless bees.
The stingless bee Melipona scutellaris inhabits in Northeast Brazil and engages in a relationship with various bacteria.
The ecological-driven approach of bioassays against entomopathogens led to the identification
of some bacterial strains as possible defensive symbionts and their chemical signals.
The bacterium Paenibacillus polymyxa was isolated from the larval food of M. scutellaris and produces (L)-(−)-phenyllactic acid (22) and a family of 9 lipodepsipeptides known as fusaricidins, including the major compounds
fusaricidin A (23) and fusaricidin B (24) ([Fig. 3]), active against the entomopathogenic fungus B. bassiana and bacterium P. larvae. Interestingly, fusaricidins 23 and 24 were also detected directly in the larval food of different sampled colonies, suggesting
a beneficial defensive role against pathogens [90]. Adult
M. scutellaris bees also carry several actinobacteria in their bodies. Streptomyces sp. ICBG1323 and Micromonospora sp. ICBG1321 were isolated from nurse and forager bees, respectively. Two families
of structurally complex bioactive polyketides were isolated from the associated strains:
lobophorins (25 – 28) from Streptomyces sp. ICBG1323 and anthracyclines from Micromonospora sp. ICBG132 (29 – 39), including the rare quinocyclines 29 – 34 and the novel compound 39 ([Fig. 3]). The compounds presented variable levels of activities against P. larvae. Compounds 28 and 30 showed the higher antibacterial activity, better than the control antibiotics [91]. Finally, two new compounds were isolated from Streptomyces sp. ICBG1318 strain in association with M. scutellaris nurse bees. The novel
cyclodepsipeptides named meliponamycin A (40) and meliponamycin B (41) ([Fig. 3]) were strongly active against P. larvae and human pathogens, such as Staphylococcus aureus and L. infantum
[92].
The examples highlight that more research on the stingless bees-associated microbiota
is essential to enhance the current knowledge of the molecular signals involved in
these symbiotic interactions. This knowledge might contribute to design policies for
the preservation of these important pollinators of native flora and agricultural crops.
Microbial Symbiosis in Wasps
Microbial Symbiosis in Wasps
Previous research efforts on digger wasps of the genus Philanthus (beewolves; Hymenoptera, Crabronidae), which consists of more than 100 species widespread
in Europe, Africa, Asia, and North America, showed association with the symbiotic
actinobacteria Candidatus Streptomyces philanthi
[93], [94]. The symbionts are cultivated in specialized antennal gland reservoirs and transferred
to the brood cells where they produce antibiotics such as streptochlorin and piericidin
derivatives responsible for protecting the waspsʼ larvae against pathogens [95], [96]. The Brazilian digger wasps Trachypus boharti also present bacteria in the antennal gland reservoirs. Gene sequences revealed that
among all antennal symbionts described, the Brazilian wasps cultivate the most distantly
related actinobacteria [97]. However, the
chemistry behind this protective symbiosis remains to be uncovered.
Another example of wasp-microbe symbiosis is established between the parasitic wasp
Asobara tabida with the bacterium Wolbachia. The bacterium is vertically transmitted via the eggs by wasps and plays a fundamental
role in oogenesis completion [98]. The treatment with antibiotics to eliminate Wolbachia found that aposymbiotic females of A. tabida are reproductively sterile, being unable to produce viable offspring [99]. An intense apoptosis process is responsible for the absence of egg production,
and there is evidence that Wolbachia inhibits the programmed cell death by the disruption of cellular physiology of the
host [100]. The symbiosis with the bacterium Wolbachia was found for wasps of the genus Encarsia; meanwhile, another bacterium described as “Encarsia bacterium” was found to be associated with a population of
Encarsia wasps, including E. pergandiella collected in Brazil. The bacterium is related to parthenogenesis [101]. The symbiont “Candidatus Cardinium hertigii” associated with Encarsia wasps from Brazil and USA is also linked to reproductive alterations in the host
[102].
Parasitoid wasps lay their eggs into other arthropods who are hosts for wasp larval
development [103]. Braconid wasps engaged in an ancient relationship with polydnavirus that suppress
host defense mechanisms and permit the larval development [104], [105], [106]. This symbiosis is so old (about 70 million y) that the genes involved in viral
replication have been incorporated into the wasp genome [107].
Invasive wood wasps Sirex noctilio collected in USA are associated with Streptomyces strains with specific enzymatic activities responsible for degrading cellulose, which
is used by the insect as source of energy [108]. Wood wasps still hold a close relationship with a fungal symbiont Amylostereum chailletii that feeds wasp larvae, providing them with digestive enzymes [109].
Very few efforts have been pursued on revealing the chemical signaling in interactions
between microbes and wasps in Brazil. The country harbors the richest fauna of social
wasps (Polistinae) in the world, with more than 300 species, 104 of them endemic from
Brazil [110], offering several opportunities for chemical ecology based natural products discovery.
Microbial Symbiosis in Termites
Microbial Symbiosis in Termites
Although fungus-farming ants and fungus-growing termites share behavioral similarities,
and both seem to rely on the presence of symbiotic actinobacteria to chemically defend
their nests against fungal pathogens [54], [111], they do not share a common ancestor with the same characteristics [112]. Moreover, these insects differ from each other in the geographical distribution.
While attine ants originated and are found in the “New World”, fungus growing Macrotermitinae
termites (Termitidae: Macrotermitinae) originated in Africa and comprise about 330
species distributed in the “Old World”, including Africa and Asia [113]. Macrotermitinae termites are subdivided into 11 genera [114].
Brazil houses around 300 species of termites belonging to the families Kalotermitidae,
Rhinotermitidae, Serritermitidae, and Termitidae [115]. Termites contribute to structure and composition of soils by efficiently degrading
biomass with the aid of resident gut microbiota, so most of the research in Brazil
has focused on the enzymatic potential of termite-associated microbiota [116]. Termite microbiota might also have a contribution in defensive symbiosis by the
production of secondary metabolites. Indeed, two Streptomyces strains from termite mounds collected in Bahia State showed percentages of inhibition
above 98% against bovine viral diarrhea virus (BVDV), but the active compound has
not been identified [117].
There are some examples of natural products produced by actinobacteria in association
with African fungus-growing termites [118], [119], [120], [121], [122]. Amycolatopsis sp. produced macrotermycins A – D (42 – 45) ([Fig. 4]). Besides the antifungal ecological role, these 4 macrolactams presented antibacterial
activity against S. aureus
[123]. The polyketide fridamycin A (46) ([Fig. 4]) was isolated from the termite-associated Actinomadura sp.; it demonstrated glucose uptake stimulation and could be an option for type 2
diabetes therapeutics [124]. Microtermolides A (47) and B (48) ([Fig. 4]) were isolated from a
fungus-growing termite-associated Streptomyces sp. [125], [126]. Both compounds are depsipeptides; moreover, microtermolide B is a rare linear depsipeptide
and seems to be the first one of this class produced by a Streptomyces strain. The lack of extensive work on termite-associated actinobacteria in Brazil,
however, can be due to the absence of fungus-growing termites in this region of the
world [127]. Brazilian termites, as wasps, are eusocial insects. Even though there is not much
work on Brazilian termites, this system seems promising since their colonies are susceptible
to parasitic pressure, and previous works have demonstrated the beneficial association
between social insects and antibiotic-producing microbes.
Fig. 4 Compounds isolated from microbial symbionts of termites.
Conclusion
Brazil harbors an impressive reservoir of genetic resources in different biomes, including
the highest number of known insects in the world and an undescribed microbial diversity.
The chemistry of microbial natural products and chemical ecology of microbial symbiosis
are complementary research fields in their early days in the country. Two decades
have passed since the publication of the first natural product from a microbial source
[128], and 7 y since the first report on natural products mediating microbial interactions
[129] in Brazil.
The chemistry involved in interspecies interactions between insects and microbes remains
largely to be unveiled. The examples showed here are just a glimpse of the chemodiversity
involved in nutritional and defensive microbial symbiosis in some species of attine
ants and stingless bees in Brazil. Several other species of these insects should be
investigated, as well as other Brazilian social insects such as termites and wasps.
The understanding of how species interact in nature is instrumental to design sustainable
approaches for their uses. Besides improving the knowledge about interspecies interactions,
the chemical ecology approach to studying insect-microbe symbiosis might lead to the
identification of biologically active compounds with privileged scaffolds for biotechnological
development, mainly as agrochemicals and pharmaceuticals. The huge biodiversity remaining
in Brazil potentially encodes useful products to be developed based on sustainable
practices. Efforts of multidisciplinary research groups in chemistry, microbiology,
molecular biology, entomology, and pharmacology are instrumental to achieve such results.
Not less important is the regular and prioritized governmental financial support for
research in the field. The biodiversity of insects has declined worldwide; therefore,
researchers and government in Brazil might act synergistically. According to Sánchez-Bayoa
& Wyckhuys [130], the main drivers of insect decline are: i) habitat loss and conversion to intensive
agriculture and urbanization; ii) pollution, mainly that by synthetic pesticides and
fertilizers; iii) biological factors, including pathogens and introduced species;
and iv) climate change. It is out of scope to discuss each one of those factors in
this article but needless to explain that all of them occur in Brazil.
Strong public policies are urgently needed to protect Brazilian biodiversity. Specifically,
it is important to consider the preservation of native insects and, consequently,
the benefits they provide–in association with resident microbes–in the structure and
functioning of the ecosystems.
Contributorsʼ Statement
Conception and design of the work: M. T. Pupo; Data collection: C. Menegatti, T. T. H.
Fukuda, M. T. Pupo; Analysis and interpretation of the data: C. Menegatti, T. T. H.
Fukuda, M. T. Pupo; Drafting the manuscript: C. Menegatti, T. T. H. Fukuda, M. T.
Pupo; Critical revision of the manuscript: M. T. Pupo.
