The effects of social environment and the metapleural gland on disease resistance in acorn ants

Eusocial species differ in living conditions when compared to solitary species primarily due to the dense living conditions of genetically related individuals. Consequently, these crowded conditions can induce a high rate of pathogen transmission and pathogen susceptibility. To resist an epidemic, individuals rely on sets of behaviors, known as social immunity, to decrease pathogen transmission among nestmates. Alongside social immunity, ants have a pair of secretory metapleural glands (MG), thought to secrete antimicrobial compounds important for antisepsis, that are believed to be transferred among nestmates by social immune behaviors such as grooming. To investigate the effects of social immunity on pathogen resistance, we performed a series of experiments by inoculating acorn ants Temnothorax curvispinosus with a lethal spore concentration of the entomopathogenic fungus Metarhizium brunneum . After inoculation ant survival was monitored in two environments: solitary and in groups. Additionally, the MG role in pathogen resistance was evaluated for both solitary and grouped living ants, by sealing the MG prior to inoculations. Individuals within a group environment had a higher survival compared to those in a solitary environment, and individuals with sealed glands had significantly decreased survival than ants with non-sealed-MG in both solitary and social environments. We observed the lowest survival for solitary-sealed-MG individuals. Although sealing the MG reduced survival probability, sealing the MG did not remove the benefits of grouped living. We show here that social living plays a crucial role in pathogen resistance and that the MG has an important role in pathogen resistance of individual T. curvispinosus ants. Although important for an individual's pathogen resistance, our data show that the MG does not play a strong role in social immunity as previously believed. Overall, this study provides insights into mechanisms of social immunity and the role of MG in disease resistance.

Gut and Colony Microbiota of Honey Bees: Social Immunity and Opportunism Overwinter

Overwintering is a major contributor to honey bee colony loss and involves factors that influence disease susceptibility. Honey bees possess a secretory head gland that interfaces with the extended social environment on many levels. With the coming of winter, colonies produce a long-lived (diutinus) worker phenotype that survives until environmental conditions improve. We used a known-age worker cohort to investigate microbiome integrity and social gene expression of diutinus workers overwinter. We provide additional context by contrasting host-microbial interactions from warm outdoor and cold indoor overwintering environments. Our results provide the first evidence that social immune gene expression is associated with diutinus bees, and highlight the midgut as a target of opportunistic disease overwinter. Host microbial interactions suggest opportunistic disease progression and resistance in diutinus workers, but susceptibility to opportunistic disease in younger workers that emerged during the winter, including increases in Enterobacteriaceae, fungal load and bacterial diversity abundance. The results are consistent with increased social immunity overwinter, including host associations with the colony microbiota, and a social immune response by long-lived diutinus workers to combat microbial opportunism. The cost/benefit ratio associated with limited expression of the diutinus phenotype may be a strong determinant of colony survival overwinter.

Gut and Colony Microbiota of Honey Bees Apis mellifera: Social Immunity, Opportunistic Disease and Survival Overwinter.

BackgroundOverwintering is a major contributor to honey bee colony loss and involves changes in environmental conditions, host physiology and group behavior that influence disease susceptibility. Honey bees possess a secretory head gland that interfaces with the extended colony environment on many levels, producing pro-oxidants, antioxidants and antimicrobial peptides. With the coming of winter, colonies produce a long-lived (diutinus) worker phenotype that survives until environmental conditions improve. We used a known-age worker cohort to investigate microbiome integrity and social gene expression of diutinus workers overwinter. We provide additional context by contrasting host-microbial interactions from warm outdoor and cold indoor overwintering environments. ResultsWe produce the first evidence that social immune gene expression is associated with the core hindgut and colony microbiota in honey bees, and highlight the midgut as a target of opportunistic disease overwinter. We discovered a distinct physiological and microbiological trajectory for diutinus workers that differs drastically from younger, short-lived workers in the colony. Diutinus bees were associated with decreased fungal load and decreased bacterial diversity, and increased core microbiota and longevity. Colonies overwintered indoors maintained a stable or improved microbiota structure and complimentary gene expression overwinter. In contrast, workers from colonies overwintered outdoors in warm southern conditions possessed changes co-occurring throughout the alimentary tract microbiota that suggest opportunistic disease progression and resistance in diutinus workers, but susceptibility to opportunistic disease in younger workers that emerged during the winter, including increases in Enterobacteriaceae, fungal load and bacterial diversity abundance. ConclusionsOur results highlight social selection pressures that shaped the colony and hindgut microbiome with evolution to a perennial life history. The results are consistent with a “group level” explanation of social immunity, including host associations with the colony microbiota, and a social immune response by long-lived diutinus workers to accompany microbial opportunism. The cost/benefit ratio associated with limited expression of the diutinus phenotype may be a strong determinant of colony survival overwinter. The relationship of colony and gut microbiota with social immune function highlights the range of host-microbial interaction associated with the honey bee superorganism, and its potential influence on colony health, disease resistance and gut integrity.

Social Health, Social Pressure, and Social Immunity

The article addresses the problem of social health as a basic factor of positive sociocultural environment in the context of globalization. The research objective was to define the content of social health as a balance of such categories as social immunity and social pressure. The study relied on the methodology of philosophical analysis, dialectical method, and system approach. The phenomenon of social health was described as part of the system of dynamic and multidimensional social relations. The article featured the role of sociocultural environment of one's life and attitudes of spiritual and moral nature that make up one's social health formation. Social pressure is an attributive characteristic of social life, which is getting increasingly complex in all areas of human life. The article also introduces the term of social immunity as a set of spiritual foundations of one's activity that provides one with productive social relationships. Social immunity depends on one's age, lifestyle, and sociocultural environment. The author also analyzed various prosocial deviant forms of behavior. The decisive factor of social health formation is that social immunity should correspond with the current social pressure.

Does Communal Breeding Promote an Increase in Social Immunity in Burying Beetles? A Test Case with Nicrophorus Defodiens

Communal breeding is a reproductive system in which more than a single pair of individuals share parental care duties. Burying beetles (genus Nicrophorus) breed on small vertebrate carcasses, which is used as a food source for their young. On larger carcasses, burying beetles will breed communally, forming multiple male-female associations. A significant and costly component of parental investment by burying beetles is the preservation of the carcass with secretions containing immune molecules. Because this immune investment is for the benefit of the offspring, the behavior is a form of social immunity. We test the hypothesis that communal breeding in burying beetles evolved as a mechanism to increase the social immune investment on larger carcasses, which are more difficult to preserve. We used N. defodiens, a communal breeding burying beetle species to test the hypothesis. There were two experimental treatments wherein, the females either bred communally or non-communally. Our results show that the combined immune activity in the secretions were higher in communally breeding pairs than in the immune contribution of single male-female pairs. However, subordinate females were rarely observed on the carcass, and the level of social immune activity of dominant females was lower than females breeding singly. These data suggest that communal breeding in N. defodiens decreases the level of investment in social immunity. Our results demonstrate that the presence of multiple females, which is common under natural conditions, can greatly complicate patterns of social immunity investment in burying beetles.

Social Immunity in Honey Bees: Royal Jelly as a Vehicle in Transferring Bacterial Pathogen Fragments Between Nestmates

Social immunity is a suite of behavioral and physiological traits that allow colony members to protect one another from pathogens and includes the oral transfer of immunological compounds between nestmates. In honey bees, royal jelly is a glandular secretion produced by a subset of workers that is fed to the queen and young larvae, and which contains many antimicrobial compounds. A related form of social immunity, transgenerational immune priming (TGIP), allows queens to transfer pathogen fragments into their developing eggs where they are recognized by the embryo's immune system and induce higher pathogen-resistance in the new offspring. These pathogen fragments are transported by vitellogenin (Vg), an egg-yolk precursor protein that is also used by nurses to synthesize royal jelly. Therefore, royal jelly may serve as a vehicle to transport pathogen fragments from workers to other nestmates. To investigate this, we recently showed that ingested bacteria are transported to nurses’ jelly-producing glands, and here, we show that pathogen fragments are incorporated into the royal jelly. Moreover, we show that consuming pathogen cells induces higher levels an antimicrobial peptide found in royal jelly, defensin-1.

A model of infection in honeybee colonies with social immunity

Honeybees (Apis mellifera) play a significant role in the pollination of various food crops and plants. In the past decades, honeybee management has been challenged with increased pathogen and environmental pressure associating with increased beekeeping costs, having a marked economic impact on the beekeeping industry. Pathogens have been identified as a contributing cause of colony losses. Evidence suggested a possible route of pathogen transmission among bees via oral-oral contacts through trophallaxis. Here we propose a model that describes the transmission of an infection within a colony when bee members engage in the trophallactic activity to distribute nectar. In addition, we examine two important features of social immunity, defined as collective disease defenses organized by honeybee society. First, our model considers the social segregation of worker bees. The segregation limits foragers, which are highly exposed to pathogens during foraging outside the nest, from interacting with bees residing in the inner parts of the nest. Second, our model includes a hygienic response, by which healthy nurse bees exterminate infected bees to mitigate horizontal transmission of the infection to other bee members. We propose that the social segregation forms the first line of defense in reducing the uptake of pathogens into the colony. If the first line of defense fails, the hygienic behavior provides a second mechanism in preventing disease spread. Our study identifies the rate of egg-laying as a critical factor in maintaining the colony’s health against an infection. We propose that winter conditions which cease or reduce the egg-laying activity combined with an infection in early spring can compromise the social immunity defenses and potentially cause colony losses.

Man and his enlightenment: ideas, projects, practice

After the collapse of the USSR, Russia is in a state of crisis. The population of the country remembers its past, but does not know what its future will be. The old scale of values is no longer working, and the new one has not yet developed. The crisis affected all the main sectors of the country's life, including education. The continuity of generations was under threat. The situation is aggravated by the external expansion of the initiators of the next redistribution of the world. As a" Trojan horse", they impose values that are alien to us, aimed at destroying the cultural code of Russia, at breaking the connection between generations. Youth, deprived of social immunity, quite easily enters the path of corruption and perversion, destroying itself and the world around it. The authors of the stated monograph, in search of a worthy answer to the historical challenge of Russia, turn to those who are concerned about the fate of the Fatherland and on whom the future of our Motherland depends.