Abstract
Insects (Insecta,
Arthropoda), undeniably represent the most triumphant group of living
organisms, in terms of evolutionary achievement, existing on earth. With over
one million described species, they account for more than 75 percent of all
known species, and it is estimated that at least 4-5 million insect species
still remain undiscovered and undescribed (Stork, 2018). They represent one
of the largest components of biodiversity in the world, closely associated
with human's wellbeing in different forms like pests, natural enemies,
producers of economic products and facilitators of pollination. In
contemporary times, despite notable progress in agricultural output and
economic prosperity in many regions, the problem of food insecurity persists
as a significant concern affecting substantial segments of the global
population (Palli, 2022). To cater the food demand of the fast expanding
global population, intensive agricultural practices like extensive use of
chemical fertilizers and insecticides, greater tillage and irrigation, as
well as heavy mechanization are followed. The result is frequent outbreak of
phytophagous insect pests along with a rapid decline in the biodiversity of
beneficial insects including natural enemies and pollinators. It is estimated
that crop losses caused by insects are a major problem in both developed and
developing countries, destroying 18 to 20 per cent of the annual crop
production globally, having worth over US$ 470 billion (Srivastava and
Chakravarty, 2021).
Initially,
when pesticides were used to control or prevent insect pest outbreaks, the
chemicals were often applied as soon as a problem was perceived, without
accurate identification of the insect's identity or discovery of why the
problem had developed in the first place. This lack of understanding of the
cause of outbreak meant that the same problem could reoccur. Sustainable pest
management requires a more scientific approach. The first step in this
direction is the correct identification of the insect species. Accurate
species identification, whether of the pest or its associated natural enemy
along with their biological systematic studies provide backbone information
for the success of any integrated pest management programme (Chakravarty et
al., 2022). Traditional systematics or taxonomy was primarily reliant on
morphology-based taxon identification systems. However, the process of
morphological identification poses significant challenges in numerous insect
taxa, mostly attributable to the absence of dependable diagnostic traits or
the presence of cryptic species complexes (Shashank et al., 2022).
Moreover, due to a decrease in the number of proficient morpho-taxonomists,
specifically those specializing in lesser-known insect groups, there is a
need for alternate approaches to species identification. Presently,
entomologists are leveraging a wide array of molecular techniques that were
previously untapped, while also embracing novel technologies under the
paradigm of a "technology-driven revolution" in the field of
systematics (Srivastava et al., 2019).
Molecular
techniques present a highly advantageous strategy for the identification and
classification of insects, offering distinct benefits when compared to
traditional morphological methods. Over the past twenty years, DNA barcoding
has emerged as a swift and dependable technique for the identification of species,
thereby revitalizing the field of taxonomic study. It refers to the
technique, where short fragment of the conserved mitochondrial cytochrome c
oxidase subunit I (COI) gene, the “DNA barcode,” is sequenced from a
taxonomically undesignated specimen and comparisons are made with the DNA
sequence of species of known origin for establishing a species level
identification (Hebert et al., 2003). This approach has been frequently
employed in various studies focusing on insects (and other arthropods in general),
leading to the identification of previously unknown or cryptic species.
Additionally, it has helped identify species complexes and evolutionary
significant units, thereby establishing a basis for further comprehensive
integrative taxonomic research (Firake and Behere, 2021). DNA barcoding
considerably facilitates the monitoring of invasive species, vectors, and
economically important endangered and/or endemic arthropod species.
Furthermore, the utilization of DNA metabarcoding in ecological and surveillance
initiatives has become increasingly prevalent. This approach enables the
rapid evaluation of biodiversity in certain geographical regions, as well as
the study of arthropod biosystems and communities that would otherwise be
inaccessible.
In
recent times, entomologists in India have efficiently identified various
invasive insect pest species, such as the elephant beetle, tomato pinworm,
rugose spiralling whitefly, coconut case caterpillar, fall armyworm, and
cassava mealy bug, by incorporating molecular systematics either as the sole
method or in conjunction with traditional taxonomical tools (Srivastava and
Chakravarty, 2021). In addition, there have been endeavours to offer
extensive data through molecular characterization and/or DNA barcoding of
indigenous organisms that serve as natural enemies and pollinators within
diverse agricultural systems of India (Srivastava et al., 2019). A
good number of insect genomes, particularly the mitochondrial genome have
also been wholly sequenced in the country, including both crop pests and
beneficial insects (Firake and Behere, 2021). However, our nation renowned
for its exceptional biodiversity, exhibits a mere 3.73% coverage of DNA
barcodes for its documented insect species. Notably, the orders Lepidoptera
and Hemiptera are the most extensively represented in this limited dataset
(Shashank et al., 2022). Such a delay in developing DNA barcode reference
libraries for insects will set us back in our efforts to effectively document
and preserve our rich biodiversity.
The
introduction of molecular systematics has also precipitated a revolution in
our understanding of intraspecific genetic diversity and population genetic
structure of several key insect pest species of agricultural importance in
the country, helpful to detect the changes they adapt to overcome hurdles of
various selection pressures including insecticides (Chakravarty et al., 2020).
A necessity for the development of effective and safe management techniques
for a target pest is the acquisition of comprehensive knowledge pertaining to
its population structure and dynamics. Despite the emergence of
inconsistencies between morphological and molecular phylogenies, as well as
conflicting results from different molecular research, the utilization of
phylogenomic analysis has proved helpful in resolving numerous controversial
connections within insects. Over the past decade, our working group has
devoted its research efforts entirely to this particular issue. Based on the
molecular characterization with RAPD markers (Deepa and Srivastava, 2011) and
COI gene (Chakravarty et al., 2021), phenotyping of immature and adult
stages (Chakravarty and Srivastava, 2020; Chakravarty et al., 2023b),
and other biological traits (Chakravarty et al., 2019 and 2023a), existence
of sub-specific level variations among Helicoverpa armigera
populations from diverse agro-ecologies of India has been deciphered. Similar
studies for Leucinodes orbonalis (Padwal et al., 2022), Spodoptera
litura (Ganguly et al., 2023) and Maruca vitrata (Mahalle et
al., 2022) revealed genetic homogeneity for these pest species in the
country. Further, Mahalle et al. (2023) have also screened publically
accessible expressed sequence tag resources to identify microsatellites and
evaluate their suitability as DNA markers for investigating gene flow
patterns among populations of M. vitrata from pigeonpea fields
throughout India.
Molecular
systematics has also proven to be a valuable tool in the identification of
convergent evolution phenomena, such as the emergence of eusocial behaviours
and caste systems among Hymenoptera (Berens et al., 2015);
comprehending predator-prey dynamics within trophic food web investigations
(Novotny and Miller, 2014), as well as resolving challenges associated with
limited specimen availability or local species populations (Deng et al.,
2019). Nevertheless, it is important to note that relying solely on molecular
analyses to determine the identity of a species or assess population
diversity can be precarious. This is due to potential biases introduced by
the improper utilization of neighbor-joining trees, fixed distance
thresholds, bootstrap resampling, interpretation of the barcoding gap, as
well as limitations associated with DNA barcode repositories such as the
Barcode of Life Data Systems (BOLD) and the National Centre for Biotechnology
Information (NCBI). For instance, in a study conducted by Kvist (2013), it
was found that 42% of invasive insects were not included in the BOLD
database. Furthermore, the outcomes of phylogenetic analyses can be affected
by various factors, such as the occurrence of recent speciation events, the
presence of paraphyly, inadequate taxonomy, interspecific hybridization, and
the high prevalence of endosymbiotic bacteria like Wolbachia, that hinders
the replication or detection of the target sequence from insect specimens
during the polymerase chain reaction, as highlighted by Shashank et al.
(2022). Therefore, it is recommended that molecular methodologies should be
utilized in conjunction with, rather than in lieu of, morphological
identification in order to achieve optimal outcomes (Chakravarty et al.,
2023b).
Last
but not the least, a note of appreciation for the “Journal of
Environmental Biology” is also appropriate at this juncture. We are
pleased to share our research experience and expertise through this editorial
in the aforementioned journal, with which we have been affiliated for several
years in various roles such as author, reviewer, and editor. This open access
journal is notable for its comparatively modest processing charges, which
enable researchers to publish their original work at an affordable cost. The
enduring anticipation for highly critical reviews has contributed to the
continued prominence of this journal within the realm of environmental
science and related disciplines. We appreciate the visions of late Professor
R.C. Dalela and his dedicated team, who have worked tirelessly over the years
to make this journal a valuable resource for the global environmental
outlook, with the ultimate aim of promoting societal well-being. Currently,
the responsibility of overseeing this journal rests with Dr. Divakar Dalela,
the Executive Editor, and Dr. Sumati Gaumat, the Editor, together with their
dedicated publication team. They are diligently working towards upholding the
international standards of this esteemed journal. We extend our best wishes
for the continued success of the journal in the years to come.
|
|