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- Theodor-Boveri-Institut für Biowissenschaften (18) (entfernen)
Plants initially accepted by foraging leaf-cutting ants are later avoided if they prove unsuitable for their symbiotic fungus. Plant avoidance is mediated by the waste produced in the fungus garden soon after the incorporation of the unsuitable leaves, as foragers can learn plant odors and cues from the damaged fungus that are both present in the recently produced waste particles. We asked whether avoidance learning of plants unsuitable for the symbiotic fungus can take place entirely at the colony dump. In order to investigate whether cues available in the waste chamber induce plant avoidance in naïve subcolonies, we exchanged the waste produced by subcolonies fed either fungicide-treated privet leaves or untreated leaves and measured the acceptance of untreated privet leaves before and after the exchange of waste. Second, we evaluated whether foragers could perceive the avoidance cues directly at the dump by quantifying the visits of labeled foragers to the waste chamber. Finally, we asked whether foragers learn to specifically avoid untreated leaves of a plant after a confinement over 3 hours in the dump of subcolonies that were previously fed fungicide-treated leaves of that species. After the exchange of the waste chambers, workers from subcolonies that had access to waste from fungicide-treated privet leaves learned to avoid that plant. One-third of the labeled foragers visited the dump. Furthermore, naïve foragers learned to avoid a specific, previously unsuitable plant if exposed solely to cues of the dump during confinement. We suggest that cues at the dump enable foragers to predict the unsuitable effects of plants even if they had never been experienced in the fungus garden.
Defense against biotic or abiotic stresses is one of the benefits of living in symbiosis. Leaf-cutting ants, which live in an obligate mutualism with a fungus, attenuate thermal and desiccation stress of their partner through behavioral responses, by choosing suitable places for fungus-rearing across the soil profile. The underground environment also presents hypoxic (low oxygen) and hypercapnic (high carbon dioxide) conditions, which can negatively influence the symbiont. Here, we investigated whether workers of the leaf-cutting ant Acromyrmex lundii use the CO\(_{2}\) concentration as an orientation cue when selecting a place to locate their fungus garden, and whether they show preferences for specific CO\(_{2}\) concentrations. We also evaluated whether levels preferred by workers for fungus-rearing differ from those selected for themselves. In the laboratory, CO\(_{2}\) preferences were assessed in binary choices between chambers with different CO\(_{2}\) concentrations, by quantifying number of workers in each chamber and amount of relocated fungus. Leaf-cutting ants used the CO\(_{2}\) concentration as a spatial cue when selecting places for fungus-rearing. A. lundii preferred intermediate CO\(_{2}\) levels, between 1 and 3%, as they would encounter at soil depths where their nest chambers are located. In addition, workers avoided both atmospheric and high CO\(_{2}\) levels as they would occur outside the nest and at deeper soil layers, respectively. In order to prevent fungus desiccation, however, workers relocated fungus to high CO\(_{2}\) levels, which were otherwise avoided. Workers’ CO\(_{2}\) preferences for themselves showed no clear-cut pattern. We suggest that workers avoid both atmospheric and high CO\(_{2}\) concentrations not because they are detrimental for themselves, but because of their consequences for the symbiotic partner. Whether the preferred CO\(_{2}\) concentrations are beneficial for symbiont growth remains to be investigated, as well as whether the observed preferences for fungus-rearing influences the ants’ decisions where to excavate new chambers across the soil profile.
In der vorliegenden Dissertation wurden verschiedene Themenbereiche bearbeitet, die zur Charakterisierung der intrazellulären, bakteriellen Endosymbionten im Mitteldarm von Ameisen der Gattung Camponotus beitrugen. Es wurden phylogenetische Untersuchungen mit Hilfe der 16S rDNA-Sequenzen der Symbionten und der Sequenzen der Cytochrom-Oxidase-Untereinheit I (COI-Sequenzen) ihrer Wirte durchgeführt, die zur näheren Klärung der Fragen zu Übertragungsweg und Stellung der Camponotus-Endosymbionten verhalfen. Untersuchungen an dreizehn verschiedenen Camponotus-Arten brachten folgende Ergebnisse. Die intrazellulären Bakterien der Ameisen gehören zur g-Subklasse der Proteobakterien. Innerhalb des 16S-Stammbaumes der Symbionten kann man drei Untergruppen unterscheiden, in denen die einzelnen Arten enger miteinander verwandt sind. Bei den nächstverwandten Bakteriennachbarn der Camponotus-Endosymbionten handelt es sich um die ebenfalls symbiontisch lebenden Bakterien der Gattungen Wigglesworthia und Buchnera. Die Ameisen-Symbionten besitzen in ihren rrs-Genen intervenierende DNA-Sequenzen (IVS), die stabile Sekundärstrukturen ausbilden können. Ihre 16S-Gene sind nicht strangaufwärts von den 23S-Genen lokalisiert. Durch diese genetische Besonderheit ähneln die Camponotus-Symbionten den Buchnera-Symbionten, deren rRNA-Gene auf zwei Transkriptionseinheiten verteilt sind. Innerhalb des Stammbaumes der untersuchten Wirtsameisen existieren ebenfalls drei Untergruppen, deren einzelne Arten enger miteinander verwandt sind. Die direkte Gegenüberstellung des Symbionten-Stammbaumes mit dem der Ameisen zeigt ein weitgehend gleiches Verzweigungsmuster. Beide Dendrogramme zeigen signifikante Übereinstimmungen bezüglich ihrer taxonomischen Beziehungen und legen eine kongruente Entwicklung von Symbionten und Wirten, die nur durch einen vertikalen Übertragungsweg erzeugt werden kann, nahe. Einzige Ausnahme bildete hierbei der C. castaneus-Symbiont, bei dem ein horizontaler Transfer von Symbionten nicht gänzlich ausgeschlossen werden kann. Die im Rahmen dieser Dissertation durchgeführten phylogenetischen Untersuchungen ermöglichten die Benennung einer neuen Symbiontengattung innerhalb der gamma-Subgruppe der Proteobakterien: "Candidatus Blochmannia spp." Histologische Studien der Endosymbiose mit Hilfe von licht- und elektronenmikroskopischen Methoden sollten Fragen zur Symbiontenlokalisation innerhalb adulter Individuen beantworten und die Ergebnisse zum Übertragungsweg der intrazellulären Bakterien festigen. Die Endosymbionten sind in den Mitteldarmepithelien von Arbeiterinnen, Königinnen und Männchen in Myzetozytenzellen lokalisiert, die in das Mitteldarmepithel interkalieren. Diese spezialisierten Zellen besitzen kaum Vesikel und tragen keinen Mikrovillisaum. In den Oozyten der Ovarien von Königinnen und Arbeiterinnen wurden ebenfalls große Symbiontenmengen gefunden. Die Spermatheka der Königinnen und die Geschlechtsorgane der Männchen waren symbiontenfrei. Die Abwesenheit von Symbionten innerhalb dieser beiden Organe zeigt, dass eine Bakterieninfektion der weiblichen Tiere nicht durch die Männchen stattfindet, sondern wie schon in den phylogenetischen Untersuchungen postuliert, ein rein maternaler Übertragungsweg der Symbionten vorliegt. Die Detektion der Bakterien in Eiern und Larven der Ameisen mittels In situ-Hybridisierungen trugen zur Aufklärung des Weges der Endosymbionten während der Embryogenese bei. Während sich im abgelegten Ei ein Ring aus Symbionten bildete, kam es in den Larvenstadien 1 bis 3 zur Auswanderung der Bakterien in Meso- bzw. Ektoderm. Im größten untersuchten Larvenstadium 4, das kurz vor der Verpuppung stand, konnten die Symbionten ausschließlich in den Myzetozyten des Mitteldarmes detektiert werden. Die Behandlung der Ameisen mit Antibiotika ermöglichte es, symbiontenfreie Ameisen zu erzeugen, die über einen längeren Zeitraum weiterlebten, ohne ihre Symbionten zu regenerieren. Im Rahmen dieser Arbeit gelang es erstmals, die intrazellulären Bakterien intakt aus dem sie umgebenden Mitteldarmgewebe zu isolieren. Somit konnten gereinigte Symbionten für Kultivierungs- und Infektionsversuche verwendet werden. Diese Versuche die mit Hilfe von Bakteriennährmedien und Insektenzelllinien durchgeführt wurden, zeigten jedoch sehr deutlich, dass es nicht möglich ist, die Camponotus-Symbionten außerhalb ihrer Wirte zu kultivieren.
Die komplexen Aktivitätsmuster während der Futtersuche bei Ameisen sind kein Resultat einer einfachen Selbstorganisation mit starren Regeln sind, sondern diese Regeln werden vielmehr permanent durch den Informationsaustausch zwischen den Arbeiterinnen modifiziert. Die Furagierökologie hat vor allem einen Einfluss auf die Rekrutierungsstrategie der Tiere. Blattschneiderameisen furagieren an großen und stabilen Nahrungsressourcen auf diese sie nach dem Auffinden sofort stark rekrutieren. Camponotus rufipes besucht hingegen Futterquellen, die in ihrer Ergiebigkeit schlecht vorhersagbar sind. Daher steigern die Tiere ihre Rekrutierungsintensität erst nachdem sie sich durch mehrmaliges Aufsuchen der Futterquelle von deren Beständigkeit überzeugt haben.
Ameisen der Gattung Camponotus beherbergen bakterielle Symbionten der Gattung Blochmannia in spezialisierten Zellen des Mitteldarms (Blochmann, 1882; Buchner, 1965; Sauer, 2000; Schröder et al., 1996). Die Genomsequenzierung dieser Symbionten zeigte, dass Blochmannia, ähnlich den Symbionten von Blattläusen, hauptsächlich Gene der Aminosäurebiosynthese beibehalten hat (Degnan et al., 2005; Gil et al., 2003). Die Relevanz dieser nahrungsaufwertenden Funktion konnte experimentell bestätigt werden (Feldhaar et al., 2007). Ein Schwerpunkt der vorliegenden Arbeit war die Aufklärung der dynamischen Interaktion der beiden Partner während des komplexen Lebenszyklus des holometabolen Wirtes. Frühere Studien deuteten darauf hin, dass die Symbiose vor allem während der Larven- und Puppenphasen von Bedeutung sein könnte (Feldhaar et al., 2007; Wolschin et al., 2004; Zientz et al., 2006). Mit fluoreszenter in situ Hybridisierung (FISH) und konfokaler Laserscanning Mikroskopie konnte in der vorliegenden Arbeit die Lokalisierung von B. floridanus während der wichtigsten Entwicklungsstadien aufgeklärt werden. Hierbei konnte gezeigt werden, dass die Symbionten schon im ersten Larvenstadium in spezialisierten Zellen um den Darm angeordnet sind, aber in späteren Stadien nicht, wie bisher angenommen, auf diese Bakteriozyten beschränkt sind, sondern bis zum Schlupf der jungen Arbeiterinnen massiv andere Darmzellen infizieren. Übereinstimmend mit Bestimmungen der Zellzahl in den verschiedenen Wirtsstadien ist die Anzahl der Symbionten gegen Ende der Metamorphose am höchsten. Die Symbiose degeneriert in sehr alten Arbeiterinnen, gut gefüllte Bakteriozyten werden jedoch noch monatelang beibehalten. Mit Macroarray- und qRT- PCR- basierten Transkriptomanalysen wurde die Expression der bakteriellen Gene in charakteristischen Entwicklungsstadien des Wirtes untersucht. Allgemein zeigen vor allem Gene für molekulare Chaperons und bestimmte bakterielle Grundfunktionen eine hohe Expression. Aber auch viele Gene, die möglicherweise wichtige Funktionen in der Symbiose besitzen, wie die Biosynthese essentieller Aminosäuren und das Recycling von Stickstoffverbindungen, zeigen ein hohes absolutes Transkriptlevel. Zudem besteht eine positive Korrelation zwischen dem Expressionsniveau und dem GC- Gehalt der Gene, die in dem höheren Selektionsdruck und damit einer geringeren Mutationsrate der essentiellen Gene begründet liegt (Schaber et al., 2005). Durch Proteinanalysen konnte bestätigt werden, dass die Faktoren mit der höchsten absoluten Transkription die dominanten Proteine der Symbionten darstellen. In den unterschiedlichen Entwicklungsstadien zeigen viele Gene eine deutliche Dynamik, deren Ausmaß aber, verglichen mit freilebenden Bakterien, gering ist. Aus den Expressionsprofilen aufeinanderfolgender Gene lassen sich mögliche Transkriptionseinheiten ableiten, die teilweise auch experimentell bestätigt wurden. Oftmals zeigen auch Gene, die nicht in Transkriptionseinheiten angeordnet sind, aber verwandten Stoffwechselwegen angehören, ähnliche Muster. Dies deutet auf das Vorhandensein grundlegender Genregulations-mechanismen hin, obwohl im Genom von B. floridanus nur noch sehr wenige Transkriptionsfaktoren codiert sind (Gil et al., 2003). Auf übergeordneter Ebene zeigt sich, dass bei Symbionten aus späten Puppenstadien viele symbioserelevante Gene im Vergleich zu Genen des Grundmetabolismus eine erhöhte Expression zeigen. Dies betrifft besonders die Biosynthese aromatischer und verzweigter Aminosäuren, die in diesen Stadien vom Wirt in hoher Menge benötigt werden, während die internen Reserven gleichzeitig zur Neige gehen. Dies äußert sich auch im deutlichen Abfallen der Speicherproteinmenge des Wirts gegen Ende der Puppenphase. Die festgestellte Veränderung der Symbiontenzahl übertrifft das geringe Ausmaß der Genregulation um ein Vielfaches. Die Bakterien liegen in jedem Stadium polyploid mit bis zu 100 Genomkopien vor, dieser Polyploidiegrad bleibt jedoch während der gesamten Wirtsentwicklung weitestgehend konstant. Somit scheint die Kontrolle des Wirts über die bakterielle Vermehrung der entscheidende Faktor dieser Symbiose zu sein. Die verbleibenden regulatorischen Fähigkeiten der Bakterien stellen möglicherweise eine Feinjustierung von optimierten Produktionseinheiten dar, deren Anzahl nach den Bedürfnissen des Wirtes verändert wird. Insgesamt konnten in der vorliegenden Arbeit neue Einblicke in das komplexe Zusammenleben von Blochmannia und Camponotus gewonnen werden, die zu einem besseren Verständnis der biologischen Funktion und der grundlegenden Mechanismen dieser Symbiose führen. Eine der wichtigsten Fragestellungen nach dem Sinn einer nahrungsaufwertenden Symbiose für einen Nahrungsgeneralisten konnte mit starken Hinweisen auf eine stadienabhängige Relevanz der Symbiose beantwortet werden, die den enormen evolutionären Erfolg dieser Ameisengattung erklären könnte. 
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; Schröder 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.
Tropical mountain forests contribute disproportionately to terrestrial biodiversity but little is known about insect diversity in the canopy and how it is distributed between tree species. We sampled tree-specific arthropod communities from 28 trees by canopy fogging and analysed beetle communities which were first morphotyped and then identified by their DNA barcodes. Our results show that communities from forests at 1100 and 1700 m a.s.l. are almost completely distinct. Diversity was much lower in the upper forest while community structure changed from many rare, less abundant species to communities with a pronounced dominance structure. We also found significantly higher beta-diversity between trees at the lower than higher elevation forest where community similarity was high. Comparisons on tree species found at both elevations reinforced these results. There was little species overlap between sites indicating limited elevational ranges. Furthermore, we exploited the advantage of DNA barcodes to patterns of haplotype diversity in some of the commoner species. Our results support the advantage of fogging and DNA barcodes for community studies and underline the need for comprehensive research aimed at the preservation of these last remaining pristine forests.
During colony growth, leaf-cutting ants enlarge their nests by excavating tunnels and chambers housing their fungus gardens and brood. Workers are expected to excavate new nest chambers at locations across the soil profile that offer suitable environmental conditions for brood and fungus rearing. It is an open question whether new chambers are excavated in advance, or will emerge around brood or fungus initially relocated to a suitable site in a previously-excavated tunnel. In the laboratory, we investigated the mechanisms underlying the excavation of new nest chambers in the leaf-cutting ant Acromyrmex lundi. Specifically, we asked whether workers relocate brood and fungus to suitable nest locations, and to what extent the relocated items trigger the excavation of a nest chamber and influence its shape. When brood and fungus were exposed to unfavorable environmental conditions, either low temperatures or low humidity, both were relocated, but ants clearly preferred to relocate the brood first. Workers relocated fungus to places containing brood, demonstrating that subsequent fungus relocation spatially follows the brood deposition. In addition, more ants aggregated at sites containing brood. When presented with a choice between two otherwise identical digging sites, but one containing brood, ants' excavation activity was higher at this site, and the shape of the excavated cavity was more rounded and chamber-like. The presence of fungus also led to the excavation of rounder shapes, with higher excavation activity at the site that also contained brood. We argue that during colony growth, workers preferentially relocate brood to suitable locations along a tunnel, and that relocated brood spatially guides fungus relocation and leads to increased digging activity around them. We suggest that nest chambers are not excavated in advance, but emerge through a self-organized process resulting from the aggregation of workers and their density-dependent digging behavior around the relocated brood and fungus.
This study investigated patterns of arthropod community organisation and the processes structuring these communities on a range of different tree species in a natural West African savannah (Comoé National Park, Côte d'Ivoire). It described and analysed patterns of arthropod distribution on the level of whole communities, on the level of multiple-species interactions, and on the level of individual insect species. Community samples were obtained by applying (i) canopy fogging for mature individuals of three tree species (Anogeissus leiocarpa, Burkea africana, Crossopteryx febrifuga) and (ii) a modified beating technique allowing to sample the complete arthropod communities of the respective study plants for medium-sized (up to 3 m) individuals of two other species (Combretum fragrans, Pseudocedrela kotschyi). General information on ant-plant interactions was retrieved from ant community comparisons of the mature savannah trees. In addition, ant-ant, ant-plant and ant-herbivore interactions were studied in more detail considering the ant assemblages on the myrmecophilic tree Pseudocedrela kotschyi. Herbivore-plant interactions were investigated on a multiple-species level (interrelationships between herbivores and Pseudocedrela trees) and on a species level (detailed studies of interrelationships between herbivorous beetles and caterpillars and the host tree Combretum fragrans). The studies on individual herbivore species were complemented by a study on an abundant ant species, clarifying not only the relationship between host plant and associated animal but allowing also to look at interactive (competitive) aspects of community organisation. The study demonstrated for the first time that (i) the structure of beetle communities on tropical trees can be strongly dependent on the host tree species, (ii) individual trees can host specific arthropod communities whose characteristic structure is stable over years and is strongly determined by the individual tree's attributes, (iii) ants can express a pronounced fidelity to single leaves as foraging area and can thereby determine distribution patterns of other ants, (iv) intraspecifically variable palatability of plants for insect herbivores can be stable over years and can influence the distribution of herbivores that can distinguish between individual hosts according to palatability and (v) intraspecific host plant change can positively affect fitness of herbivores if host plant quality is variable. In general, the present study contributes to our knowledge of anthropogenically unaltered processes affecting community assembly in a natural environment. The fundamental understanding of these processes is crucial for the identification of anthropogenic alterations and the establishment of sustainable management measures. The study points out the important role local factors can play for the distribution of organisms and thereby for community organisation. It emphasises the relevance of small scale heterogeneity of the abiotic and biotic environment to biodiversity and the need to consider these factors for development of effective conservation and restoration strategies.
Daily activities within an ant colony need precise temporal organization, and an endogenous clock appears to be essential for such timing processes. A clock drives locomotor rhythms in isolated workers in a number of ant species, but its involvement in activities displayed in the social context is unknown. We compared locomotor rhythms in isolated individuals and behavioral rhythms in the social context of workers of the ant Camponotus rufipes. Both forager and nurse workers exhibited circadian rhythms in locomotor activity under constant conditions, indicating the involvement of an endogenous clock. Activity was mostly nocturnal and synchronized with the 12:12h light-dark-cycle. To evaluate whether rhythmicity was maintained in the social context and could be synchronized with non-photic zeitgebers such as feeding times, daily behavioral activities of single workers inside and outside the nest were quantified continuously over 24 hours in 1656 hours of video recordings. Food availability was limited to a short time window either at day or at night, thus mimicking natural conditions of temporally restricted food access. Most foragers showed circadian foraging behavior synchronized with food availability, either at day or nighttime. When isolated thereafter in single locomotor activity monitors, foragers mainly displayed arrhythmicity. Here, high mortality suggested potential stressful effects of the former restriction of food availability. In contrast, nurse workers showed high overall activity levels in the social context and performed their tasks all around the clock with no circadian pattern, likely to meet the needs of the brood. In isolation, the same individuals exhibited in turn strong rhythmic activity and nocturnality. Thus, endogenous activity rhythms were inhibited in the social context, and timing of daily behaviors was flexibly adapted to cope with task demands. As a similar socially-mediated plasticity in circadian rhythms was already shown in honey bees, the temporal organization in C. rufipes and honey bees appear to share similar basic features.