Description
The body of ''N. nepalensis'' is shiny black and has unique elytral patterns with four separated scalloped, orange markings and black dots in both anterior and posterior fascia. The basal segment of the antennae is black and the tips are club shaped with three orange segments.Distribution
''N. nepalensis'' can be found primarily in the mountainous regions in eastern Asia and the Malay Archipelago, with a distribution ranging from 73°E (Pakistan) to 149°E (Papua New Guinea) longitudinally and from 51°N (Ussuri, Russia) to 9°48′S (Papua New Guinea) latitudinally. Countries within this range includes Pakistan, India, China, Laos, Burma, Thailand, Vietnam, Taiwan, Japan, Philippines, and Malaysia.Habitat
''N. nepalensis'' can migrate along elevational gradients depending on their thermal optimum and the surrounding temperature. In most tropical areas, they are found at high elevations in cool temperatures. Yet, they can also be found in lower elevations likely due to their tolerance to warmer weather. Under certain circumstances such as limited resources and competition from other insects or vertebrates, ''N. nepalensis'' would cooperate with individuals of the same species to optimize their chances of reproduction and survival. Group size differs with elevation and air temperature. Cooperative groups, which are thermal generalists can perform high breeding success at all temperatures and elevations, whereas non-cooperative groups can only breed well at intermediate temperatures and elevations, making them thermal specialists.Environmental variability
N. nepalensis demonstrates an exceptional capacity to move over elevational gradients in response to fluctuations in environmental variables. While traditionally associated with mountainous regions in eastern Asia, including areas with elevations exceeding 4000 meters above sea level, recent findings suggest a broader habitat range. The species has shown a capacity to adapt to varying thermal optima, allowing it to thrive in diverse ecosystems ranging from montane forests to lowland grasslands. Additionally, the research underscores the significance of microhabitat features such as soil moisture and vegetation structure in shaping the distribution of N. nepalensis populations. This ecological flexibility is crucial for the species' survival in dynamic environments and underscores its role as a key player inResources and environmental conditions
''N. nepalensis'' can live up to four months, with its lifespan heavily dependent upon the availability of food resources and surrounding environmental conditions. Changing seasons and day lengths that directly influenceParental care
''N. nepalensis'' tend to exhibit lessSocial behavior
Intraspecies dynamics within populations of ''N. nepalensis'' has been forgone in most research settings and instead interspecific competition such as the competitive exclusion by small Indian mongoose populations has been more heavily investigated. Interspecies competition can be used as an influencing force on the transformation of intraspecies conflict to intraspecies competition in N. nepalensis. Only one chemical cue, the emittance ofBehavior and reproduction
''N. nepalensis'' is carnivorous and feeds on carcasses of small vertebrates such as rodents and birds. Carcasses are crucial resources for reproduction, as beetles would deposit eggs around a buried carcass where their larval broods can feed on. Fresh carcasses are rare in the wild due to intense competition from the same or different species of burying beetle, blow flies, invertebrates and other mammals. ''N. nepalensis'' is one of the few species of beetle that exhibits extensive biparental care, which includes defending the larvae against competitors and regurgitating predigested carcass to their young. The larvae of ''N. nepalensis'' go through threeMigration
Based on the premonition that beetle species tend to migrate to regions at a higher latitude with very similar climates to their native climate when global warming occurs, researchers looked at migration patterns of ''N. nepalensis'' between different microhabitats. This is known as the regional climate model. Researchers investigated forest and meadow ecosystems and found that ''N. nepalensis'' exhibits great temperature sensitivity. As a result, they are known to exhibit both hibernation behaviors and estivation behaviors. While their life history didn't significantly change, ''N. nepalensis'' showed different habitat preferences for different temperatures. Their existence and activity decreased when the ambient temperature exceeded 26˚C. Their peak activity was shown to be in autumn, but it shifted year over year. This showed that the migration of stenothermal species like ''N. nepalensis'' alters their diversity within ecosystems. In addition toClimate
There are certainly several intrinsic species factors such as small mammal decomposition in carcasses being influenced by the ambient temperatures. According to researchers, it is expected that warmer climates accelerate carcass decomposition, but carcass size, water and sunlight availability, and microbial activity all determine carcass condition. As a result, thermally sensitive ''N. nepalensis'' populations vary in meadow and forest habitats due to migration patterns. They shift based on climate warming to preserve nutrient cycling, but long-term trends cannot be established without further longitudinal experimentation.Enemies
Researchers have recently found a form of competitive exclusion against ''N. nepalensis'' by way of the small Indian mongoose. The competitive exclusion has led to local extinction,''N. nepalensis'' in Okinawa. Competitive exclusion is a biological process through which one species can rapidly drive another species towards extinction by outcompeting them for food and habitat space. Unlike other biological forms of competition likeGenetics
Larval morphology was analyzed to determine the genetic relatedness between three different instars of ''Nicrophorus''. Using reared larvae, researchers found that the Palearctic and Oriental ''nepalensis'' share many characteristics with the western Paleaarchtic nepalensis. As Sikes previously found, there is a probable phylogenetic affinity of the ''N. nepalensis'' group with the ''N. humator'' group. Researchers have also analyzed the complete mitochondrial genome of ''N. nepalensis''. It consists of 17,299 base pairs, includes 13 genes that encode for proteins (exon sequences that were not spliced out during post-transcriptional modifications), with a mitogenomen distribution of 39.5% A, 37.2% T, 13.5% C, and 9.7% G. The extensive genome also consists of 22 tRNA genes (transfer RNA), 2 rRNA genes (ribosomal RNA), and a 2693 base pair adenine-thymine control region. Researchers performed the genome sequencing on an Illumina HiSeq2500 platform and built a full ML phylogenetic tree. They divided the tree into eight separate partitions and used bootstrap values to assign accuracy (accounting for variance and prediction error). To offer a broad overview, researchers only look at adult ''N. nepalensis'', which on average, were about 20 mm in length. They were typically black, had a brow with a red-orange spot, and had a clypeal membrane.Phylogeny
To better understand the assembled mitogenome of ''N. nepalensis'', researchers hope to shed light on the evolutionary history of its phylogenetic relationships with other species within the genus (like the humator species and oriental species). Furthermore, in better understanding its genomic underpinnings, researchers will be able to investigate certain unique reproductive behaviors in the realm of parental care that share close similarities with human physiology (i.e. providing carrion for larvae and cooperation between males and females in caring for newborns).Mating
Mating systems among ''N. nepalensis'' center quite extensively around competition for reproductive resources. Their body sizes determine who wins these competitions for breeding resources. There is a relationship between secondary sexual characteristics degeneration and body size in males. They then compared the strategies used by different forms of male beetles based on their vocal structure and associated behavior. They used simulated data of wild-caught males and laboratory-bred males under a series of parental crosses. Ultimately, they found no influence of the genetic makeup of congenital parents on female body size (no significant difference was found in the sexual characteristic ratio among female groups). Researchers also looked at the impact of food intake on body size, the effects of gender and sexual characteristics on vocal organs, and the effect of gender and sexual characteristics on vocal behaviors. Ultimately, they found that males engage in intimidating behaviors as the size of competing males gets smaller. They found the converse to be true as well, that males possess less intimidating behavior when competitors have larger bodies. Researchers also found a certain form of development plasticity in ''N. nepalensis'' in response to being at a competitive disadvantage during mating processes. These are usually the result of food shortages orPhysiology
An important aspect of the physiology of ''N. nepalensis'' includes their tarsal morphology and the extent to which they can maintain traction force. In a comparative analysis, researchers looked into the friction and traction forces generated by ''N. nepalensis'' and ''Sexual dimorphisms
In terms of sex differences, it was found that ''N. nepalensis'' have differences on their front-side tarsi between males and females. While males have a spatula-shaped hair pattern, females have a lanceolate-type hair pattern. Despite different types of adhesive setae between the sexes, however, there were no intraspecies sex differences in traction force. Furthermore, researchers found that adhesive setae were generally longer towards the distal end of the tarsal structure which holds across several species of burying beetles. In addition to adhesive setae and tarsal length, researchers analyzed claws as an important metric for generating traction force for burying capabilities. They found that claw removal reduced traction force and that ''N. nepalensis'' showed a reduction in attachment force on smooth surfaces (as well as partially rough surfaces) after claw removal. This intrinsically shows that claws are fundamentally important for generating great force, providing ''N. nepalensis'' with locomotion in soil, and for general ground digging. The study focuses on intact vs. clipped claws, so the extent to which claw length can affect digging behavior has yet to be proven by experimentation.Social rank and hierarchy
''N. nepalensis'' populations establish intraspecies social ranks and hierarchies. These power structures based on intraspecies dominance hold value concerning investment into cooperative behaviors (such as foraging and parental care) as well as competitive behaviors seen during mating and reproductive processes. Despite the established hierarchy, social conflict among these beetles decrease in turbulent environments because the interests of the group become more aligned. Inferior ''N. nepalensis'' demonstrate high levels of cooperativity due to interspecies competition and/or extremely insufficient abiotic factors.Interspecies cooperation
Researchers interested in climate-mediated social interactions between species have tested their prediction that interspecies competition creates a narrow range for temperature preference on ''N. nepalensis''. They used the more natural competitor to ''N. nepalensis'', blowflies, to analyze how recovering a certain breeding temperature (optimal to secure mating patterns, enhance child rearing, and optimize postnatal parental care) explains ''N. nepalensis'' outcompeting the blowflies. Researchers noted how ''N. nepalensis'' lay eggs around the carcasses of small animals (like mice) to provide their offspring with food. ''Nicrophorus nepalensis'' cooperate to defend offspring from blowflies, who also tend to lay their eggs on the carcasses of small animals. It was found that the presence of blowflies created a larger temperature range in which ''N. nepalensis'' could optimally survive and reproduce. A form of indirect intraspecies competition, however, was also observed as antagonistic effects of cooperation were found. According to researchers, ''N. nepalensis'' relies on vertebrate carcasses for reproductive success, which leads to intense interspecies competition over limited resources. While interspecific cooperation can reduce the realized niche regarding temperature preference, intraspecies cooperation can also affect the optimal temperature performance of ''N. nepalensis''. Researchers formed thermal preference curves (TPCs) in which they looked at how biotic factors like intraspecies cooperation could allow a thermal preference species like ''N. nepalensis'' to naturally adapt to lower temperatures. Thus, research has shown that intraspecies competition can have antagonistic effects on temperature. This is different from innate physiological preferences, as this temperature change reflects a behavioral adaptation to collective group efforts. Research on the antagonistic effects of interspecies competition has remained prevalent in recent years, but these new findings on intraspecies competition having antagonistic effects on thermal preference present troubling news in light of the imposing effects of climate change.Conservation
Using ''N. nepalensis'' as a model system, researchers have been able to better monitor the long-term biodiversity of different ecosystems. Most markedly, researchers have analyzed the biodiversity of the Hapen Nature Preserve in northern Taiwan, where they have been investigating fluctuations in species compositions of various beetle populations for six years. They analyzed species richness, looked at individual numbers within populations, and utilized diversity indices in ''N. nepalensis'' in both forest and meadow habitats. In looking at survey periods from both 2001 and 2006, they were able to create a six-year observational screening. They found that communities of ''N. nepalensis'' were strongly influenced by various biotic and abiotic factors in both environments. However, they found greater species richness and individual numbers, as well as higher scores on the diversity indices for the forest habitat than the meadow habitat. This had important implications for conservation efforts in forest habitats by evaluating the long-term impact of climate change on species composition and population structure of ''N. nepalensis''.Preservation
In monitoring their existence and migration patterns within forest ecosystems, researchers have found that important decomposers like ''N. nepalensis'' are effectively changing how they both cycle nutrients but also interact with the biomass of vegetation available in their area. They are important for the conservation of ecosystems (both forest and meadow) due to their carcass recycling. By burying small carcasses and then consuming them, they speed up the decomposition process and help enrich the local soil. This, in turn, benefits the overall well-being of the ecosystem's health. Researchers monitoring their population is also invaluable since they are very sensitive to changes in the local environment. Thus, they act as effective indicator species to signal ecological imbalances.Ecology of wealth inequality
While inequality has been studied as a general feature in many human societies, it has been less thoroughly discussed in non-human animal societies. In non-human animal societies, there has been exhibited disparities in access to resources, social relationships, mating, etc. These differences can be thought of as a form of wealth inequality as it pertains to health, reproductive success, and survival odds. ''Nicrophorus nepalensis'' beetles exemplify this in the way they invest more in cooperation when faced with interspecific competitors than when no prevailing competition is present. It is through this mechanism that long-term dynamics of inequality develop and social systems become increasingly clarified within ''Nicrophorus nepalensis'' populations.References
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