Biological and ecological effects of Ligula intestinalis (Linnaeus, 1758) in a fish host Engraulicypris sardella (Gütter, 1868) from Tanzanian side of Lake Nyasa

The current thesis investigates the epidemiological, behavioral and evolutionary effects of the tapeworm Ligula intestinalis in the ‘Nyasa sardine’ (Engraulicypris sardella), an intermediate fish host, endemic to Lake Nyasa, Tanzania. Most of the available knowledge on this parasite, and its host interactions, comes from small lakes and water reservoirs in Northern Europe, where the parasite tends to show epidemic cycles, where prevalence increases very rapidly, and causing population crashes in its host. This is followed by a rapid decline in infection levels as transmission rates are reduced, and ultimately leads to the local extinction of the parasite. My research investigated the dynamics between the parasite and its intermediate host in Lake Nyasa, a vast tropical lake which differs markedly in its ecological conditions compared to the small and relatively homogenous lakes that have been studied previously. Given the size of Lake Nyasa, we predicted that transmission rates and levels of infection of this parasite would vary markedly, both in time and space within Lake Nyasa. In accordance with this, we found that the population dynamics of the parasite appeared to change into an endemic state with small variations in prevalence from year to year. Therefore, we suggested that it is unlikely that L. intestinalis infestation would have a devastating effect on the E. sardella population within Lake Nyasa, as has been reported for smaller water bodies in the European freshwater systems (Paper I). In this thesis, we also investigated the influence of the cestode L. intestinalis on the behavior of its intermediate host E. sardella and explored if this parasite could cause adaptive modifications of its intermediate host (depending on the parasite infectivity stage) that could lead to increased rates of parasite transmission. We found that fish hosts infected with infective stage parasite larvae significantly altered antipredator defense behavior compared to uninfected individuals, and that hosts infected with pre-infective stage larvae behaved more or less the same as uninfected hosts (Paper II). Finally, based on our findings that we did not observe any indications of local extinctions of the cestode L. intestinalis in Lake Nyasa (Paper I), this suggests the parasite may act as a continuous selective force on the fish host E. sardella and may drive shifts in life history traits of E. sardella towards a higher reproductive investment. Consistent with our predictions, we found that the cestode L. intestinalis had a strong negative effect on the fecundity of E. sardella which may have driven the fish host to increase investment in reproduction at the expense of growth. Our findings therefore suggest that the cestode L. intestinalis might have selected for increased investment in current reproduction in its fish host E. sardella in Lake Nyasa. These results are discussed with respect to other selective factors that could have also influenced the life history traits of E. sardella in Lake Nyasa (Paper III)

Need for harmonized long-term multi-lake monitoring of African Great Lakes

To ensure the long-term sustainable use of African Great Lakes (AGL), and to better understand the functioning of these ecosystems, authorities, managers and scientists need regularly collected scientific data and information of key environmental indicators over multi-years to make informed decisions. Monitoring is regularly conducted at some sites across AGL; while at others sites, it is rare or conducted irregularly in response to sporadic funding or short-term projects/studies. Managers and scientists working on the AGL thus often lack critical long-term data to evaluate and gauge ongoing changes. Hence, we propose a multi-lake approach to harmonize data collection modalities for better understanding of regional and global environmental impacts on AGL. Climate variability has had strong impacts on all AGL in the recent past. Although these lakes have specific characteristics, their limnological cycles show many similarities. Because different anthropogenic pressures take place at the different AGL, harmonized multi-lake monitoring will provide comparable data to address the main drivers of concern (climate versus regional anthropogenic impact). To realize harmonized long-term multi-lake monitoring, the approach will need: (1) support of a wide community of researchers and managers; (2) political goodwill towards a common goal for such monitoring; and (3) sufficient capacity (e.g., institutional, financial, human and logistic resources) for its implementation. This paper presents an assessment of the state of monitoring the AGL and possible approaches to realize a long-term, multi-lake harmonized monitoring strategy. Key parameters are proposed. The support of national and regional authorities is necessary as each AGL crosses international boundaries

Need for harmonized long-term multi-lake monitoring of African Great Lakes

To ensure the long-term sustainable use of African Great Lakes (AGL), and to better understand the functioning of these ecosystems, authorities, managers and scientists need regularly collected scientific data and information of key environmental indicators over multi-years to make informed decisions. Monitoring is regularly conducted at some sites across AGL; while at others sites, it is rare or conducted irregularly in response to sporadic funding or short-term projects/studies. Managers and scientists working on the AGL thus often lack critical long-term data to evaluate and gauge ongoing changes. Hence, we propose a multi-lake approach to harmonize data collection modalities for better understanding of regional and global environmental impacts on AGL. Climate variability has had strong impacts on all AGL in the recent past. Although these lakes have specific characteristics, their limnological cycles show many similarities. Because different anthropogenic pressures take place at the different AGL, harmonized multi-lake monitoring will provide comparable data to address the main drivers of concern (climate versus regional anthropogenic impact). To realize harmonized long-term multi-lake monitoring, the approach will need: (1) support of a wide community of researchers and managers; (2) political goodwill towards a common goal for such monitoring; and (3) sufficient capacity (e.g., institutional, financial, human and logistic resources) for its implementation. This paper presents an assessment of the state of monitoring the AGL and possible approaches to realize a long-term, multi-lake harmonized monitoring strategy. Key parameters are proposed. The support of national and regional authorities is necessary as each AGL crosses international boundaries