@phdthesis{Mildner2018, author = {Mildner, Stephanie}, title = {Temporal organization in \(Camponotus\) \(ants\): endogenous clocks and zeitgebers responsible for synchronization of task-related circadian rhythms in foragers and nurses}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-149382}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {The rotation of the earth around its axis causes recurring and predictable changes in the environment. To anticipate those changes and adapt their physiology and behavior accordingly, most organisms possess an endogenous clock. The presence of such a clock has been demonstrated for several ant species including Camponotus ants, but its involvement in the scheduling of daily activities within and outside the ant nest is fairly unknown. Timing of individual behaviors and synchronization among individuals is needed to generate a coordinated collective response and to maintain colony function. The aim of this thesis was to investigate the presence of a circadian clock in different worker castes, and to determine the daily timing of their behavioral tasks within the colonies of two nectar-collecting Camponotus species. In chapter I, I describe the general temporal organization of work throughout the worker life in the species Camponotus rufipes. Continuous tracking of behavioral activity of individually- marked workers for up to 11 weeks in subcolonies revealed an age-dependent division of labor between interior and exterior workers. After eclosion, the fairly immobile young ants were frequently nurtured by older nurses, yet they started nursing the brood themselves within the first 48 hours of their life. Only 60\% of workers switched to foraging at an age range of one to two weeks, likely because of the reduced needs within the small scale of the subcolonies. Not only the transition rates varied between subcolonies, but also the time courses of the task sequences between workers did, emphasizing the timed allocation of workers to different tasks in response to colony needs. Most of the observed foragers were present outside the nest only during the night, indicating a distinct timing of this behavioral activity on a daily level as well. As food availability, humidity and temperature levels were kept constant throughout the day, the preference for nocturnal activity seems to be endogenous and characteristic for C. rufipes. The subsequent monitoring of locomotor activity of workers taken from the subcolonies revealed the presence of a functional endogenous clock already in one-day old ants. As some nurses displayed activity rhythms in phase with the foraging rhythm, a synchronization of these in-nest workers by social interactions with exterior workers can be hypothesized. Do both castes use their endogenous clock to schedule their daily activities within the colony? In chapter II, I analyzed behavioral activity of C. rufipes foragers and nurses within the social context continuously for 24 hours. As time-restricted access to food sources may be one factor affecting daily activities of ants under natural conditions, I confronted subcolonies with either daily pulses of food availability or ad libitum feeding. Under nighttime and ad libitum feeding, behavioral activity of foragers outside the nest was predominantly nocturnal, confirming the results from the simple counting of exterior workers done in chapter I. Foragers switched to diurnality during daytime feeding, demonstrating the flexible and adaptive timing of a daily behavior. Because they synchronized their activity with the short times of food availability, these workers showed high levels of inactivity. Nurses, in contrast, were active all around the clock independent of the feeding regime, spending their active time largely with feeding and licking the brood. After the feeding pulses, however, a short bout of activity was observed in nurses. During this time period, both castes increasingly interacted via trophallaxis within the nest. With this form of social zeitgeber, exterior workers were able to entrain in-nest workers, a phenomenon observed already in chapter I. Under the subsequent monitoring of locomotor activity under LD conditions the rhythmic workers of both castes were uniformly nocturnal independent of the feeding regime. This endogenous activity pattern displayed by both worker castes in isolation was modified in the social context in adaption to task demands. Chapter III focuses on the potential factors causing the observed plasticity of daily rhythms in the social context in the ant C. rufipes. As presence of brood and conspecifics are likely indicators of the social context, I tested the effect of these factors on the endogenous rhythms of otherwise isolated individuals. Even in foragers, the contact to brood triggered an arrhythmic activity pattern resembling the arrhythmic behavioral activity pattern seen in nurses within the social context. As indicated in chapter I and II, social interaction could be one crucial factor for the synchronization of in nest activities. When separate groups were entrained to phase-shifted light-dark-cycles and monitored afterwards under constant conditions in pairwise contact through a mesh partitioning, both individuals shifted parts of their activity towards the activity period of the conspecific. Both social cues modulated the endogenous rhythms of workers and contribute to the context dependent plasticity in ant colonies. Although most nursing activities are executed arrhythmically throughout the day (chapter II), previous studies reported rhythmic translocation events of the brood in Camponotus nurses. As this behavior favors brood development, the timing of the translocations within the dark nest seems to be crucial. In chapter IV, I tracked translocation activity of all nurses within subcolonies of C. mus. Under the confirmed synchronized conditions of a LD-cycle, the daily pattern of brood relocation was based on the rhythmic, alternating activity of subpopulations with preferred translocation direction either to the warm or to the cold part of the temperature gradient at certain times of the day. Although the social interaction after pulse feeding had noticeable effects on the in-nest activity in C. rufipes (chapter I and II), it was not sufficient to synchronize the brood translocation rhythm of C. mus under constant darkness (e.g. when other zeitgebers were absent). The free-running translocation activity in some nurses demonstrated nevertheless the involvement of an endogenous clock in this behavior, which could be entrained under natural conditions by other potential non-photic zeitgebers like temperature and humidity cycles. Daily cycling of temperature and humidity could not only be relevant for in-nest activities, but also for the foraging activity outside the nest. Chapter V focuses on the monitoring of field foraging rhythms in the sympatric species C. mus and C. rufipes in relation to abiotic factors. Although both species had comparable critical thermal limits in the laboratory, foragers in C. mus were strictly diurnal and therefore foraged under higher temperatures than the predominant nocturnal foragers in C. rufipes. Marking experiments in C. rufipes colonies with higher levels of diurnal activity revealed the presence of temporally specialized forager subpopulations. These results suggest the presence of temporal niches not only between the two Camponotus species, but as well between workers within colonies of the same species. In conclusion, the temporal organization in colonies of Camponotus ants involves not only the scheduling of tasks performed throughout the worker life, but also the precise timing of daily activities. The necessary endogenous clock is already functioning in all workers after eclosion. Whereas the light-dark cycle and food availability seem to be the prominent zeitgebers for foragers, nurses may rely more on non-photic zeitgeber like social interaction, temperature and humidity cycles.}, subject = {circadian clocks}, language = {en} } @phdthesis{Ratzka2012, author = {Ratzka, Carolin}, title = {Immune responses of the ant Camponotus floridanus towards pathogens and its obligate mutualistic endosymbiont Blochmannia floridanus}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-69350}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Ants of the species Camponotus floridanus live in huge colonies composed of genetically identical or closely related animals, which should predispose them to an increased vulnerability towards infection by pathogens (Cremer et al. 2007). Therefore the question is how ants (or social insects in general) can nevertheless efficiently combat infections. In order to investigate the immune response of the ant C. floridanus, the present study initially focused on the identification of possible immune factors, encoded by the ant´s genome. By using the method "suppression subtractive hybridization" as well as by Illumnia sequencing technology, several immune-related genes could be identified. Among these were genes encoding proteins involved in pathogen recognition, signal transduction, antimicrobial activity, or general stress response. In accordance with the ant´s genome sequence (Bonasio et al. 2010), only three antimicrobial peptide (AMP) genes could be identified in C. floridanus. The gene and cDNA sequences of these AMPs were established and their expression was shown to be induced by microbial challenge. Two different defensin genes (type 1 and 2) were characterized. A detailed characterization of the mRNA and gene sequence of the other AMP, a hymenoptaecin, revealed a special repeat structure. The C. floridanus hymenoptaecin has a signal and a pro-sequence followed by a hymenoptaecin-like domain and six directly repeated hymenoptaecin domains (HDs). Since each HD is flanked by two known processing sites, proteolytic processing of the precursor protein may generate several mature AMPs. Bioinformatical analyses revealed the presence of hymenoptaecin genes with similar multipeptide precursor structure in genomes of other ant species suggesting an evolutionary conserved important role of this gene in ant immunity. C. floridanus ants harbor the obligate intracellular bacterium, Blochmannia floridanus, in specialized cells (so-called bacteriocytes), which are intercalated between midgut cells as well as in ovaries of females (Blochmann 1882; Sauer et al. 2002; Schr{\"o}der et al. 1996). Ant hosts face the problem that on the one hand they have to maintain the beneficial symbiotic bacteria and on the other hand they need to raise an immune response against harmful pathogenic bacteria during an infection. It was investigated, if endosymbionts are actually detected by the host immune system. Injection of B. floridanus induced an immune response of its host C. floridanus, which was comparable to the one towards pathogens. This means that, despite the evolutionary established cooperation of the endosymbionts and their hosts, these bacteria are still recognized as „non-self" by the host immune system. This finding led to the question, if the ant immune system might be involved in regulation of the endosymbiont number in the midgut tissue in order to avoid their uncontrolled replication. During the holometabolous life cycle of the ant hosts the distribution of bacteriocytes and of Blochmannia endosymbionts is remarkably dynamic and peaks in late pupal stages, in which the entire midgut is transformed into a symbiotic organ (Stoll et al. 2010). It was hypothesized that hosts could regulate the number of endosymbionts present in their tissues via the innate immune system. A quantitative gene expression analysis of assumed symbiosis-relevant candidate genes revealed distinct expression patterns of some genes according to developmental stage and tissue. Moreover, the immune gene expression in response to bacterial challenge was investigated in the pupal stage. By an artificial immune-challenge of pupae it was confirmed that in fact the immune response of the endosymbiont-bearing midgut tissue differs from that of other body parts. The data support a key role for amidase peptidoglycan recognition proteins (PGRPs), especially PGRP-LB, in endosymbiont tolerance and suggest an involvement of the lysosomal system in control of Blochmannia endosymbionts. In sum, this thesis provides a first description of the immune response of the ant C. floridanus. A comprehensive set of immune-relevant genes was determined. Especially, the identification and molecular characterization of the hymenoptaecin gene delivered new insights into the immune competence of ants in general. Moreover, first indications could be gathered for the involvement of the immune system in controlling the endosymbiont B. floridanus.}, subject = {Humorale Immunit{\"a}t}, language = {en} }