Archaeologists, anthropologists, and museum practitioners around the world commonly enquire as to identification of fibre type represented in artefacts. Polarised light microscopy (PLM) is one of the older and most accessible techniques... more
Archaeologists, anthropologists, and museum practitioners around the world commonly enquire as to identification of fibre type represented in artefacts. Polarised light microscopy (PLM) is one of the older and most accessible techniques available for fibre identification, particularly for discriminating among plant, animal and synthetic fibre types. However, fibres from some plant species can appear very similar under the microscope, and have a reputation for being difficult to identify to species level. Despite this, there is renewed interest in developing PLM techniques for plant fibre identification. A recently published method has claimed success with discriminating among plant species represented in the fibres in ancient European textiles. This paper reports on the further development of this method and its application to New Zealand plant species commonly used in Māori textile artefacts.
Exotic fish species frequently acquire native parasites despite the absence of closely related native hosts. They thus have the potential to affect native counterparts by altering native host-parasite dynamics. In New Zealand, exotic... more
Exotic fish species frequently acquire native parasites despite the absence of closely related native hosts. They thus have the potential to affect native counterparts by altering native host-parasite dynamics. In New Zealand, exotic brown trout Salmo trutta and rainbow trout Oncorhynchus mykiss have acquired two native trematodes (Telogaster opisthorchis and Stegodexamene anguillae) from their native definitive host (the longfin eel Anguilla dieffenbachii). We used a combination of field surveys and experimental infections to determine the relative competence of native and exotic fish hosts for these native parasites. Field observations indicated that the longfin eel was the superior host for both parasites, although differences between native and exotic hosts were less apparent for S. anguillae. Experimental infections indicated that both parasites had poorer establishment and survival in salmonids, although some worms matured and attained similar sizes to those in eels before dyi...
Publication Date: 2013
Publication Name: International journal for parasitology. Parasites and wildlife
ABSTRACT Disease-mediated threats posed by exotic species to native counterparts are not limited to introduced parasites alone, since exotic hosts frequently acquire native parasites with possible consequences for infection patterns in... more
ABSTRACT Disease-mediated threats posed by exotic species to native counterparts are not limited to introduced parasites alone, since exotic hosts frequently acquire native parasites with possible consequences for infection patterns in native hosts. Several biological and geographical factors are thought to explain both the richness of parasites in native hosts, and the invasion success of free-living exotic species. However, the determinants of native parasite acquisition by exotic hosts remain unknown. Here, we investigated native parasite communities of exotic freshwater fish to determine which traits influence acquisition of native parasites by exotic hosts. Model selection suggested that five factors (total body length, time since introduction, phylogenetic relatedness to the native fish fauna, trophic level and native fish species richness) may be linked to native parasite acquisition by exotic fish, but 95% confidence intervals of coefficient estimates indicated these explained little of the variance in parasite richness. Based on R2-values, weak positive relationships may exist only between the number of parasites acquired and either host size or time since introduction. Whilst our results suggest that factors influencing parasite richness in native host communities may be less important for exotic species, it seems that analyses of general ecological factors currently fail to adequately incorporate the physiological and immunological complexity of whether a given animal species will become a host for a new parasite.
... RICKJ. STOFFELS1 STEFANIE KARBE2 RACHEL A. PATERSON1 Department of Zoology University of Otago PO Box 56 Dunedin, New Zealand email: rick.stoffels@toroa.otago.ac.nz 2Fachhochschule Eberswalde Friedrich-Ebert-Str. 28 16225 Eberswalde... more
... RICKJ. STOFFELS1 STEFANIE KARBE2 RACHEL A. PATERSON1 Department of Zoology University of Otago PO Box 56 Dunedin, New Zealand email: rick.stoffels@toroa.otago.ac.nz 2Fachhochschule Eberswalde Friedrich-Ebert-Str. 28 16225 Eberswalde Berlin, Germany ...
Publication Date: 2003
Publication Name: New Zealand Journal of Marine and Freshwater Research
While there is good evidence linking animal introductions to impacts on native communities via disease emergence, our understanding of how such impacts occur is incomplete. Invasion ecologists have focused on the disease risks to native... more
While there is good evidence linking animal introductions to impacts on native communities via disease emergence, our understanding of how such impacts occur is incomplete. Invasion ecologists have focused on the disease risks to native communities through "spillover" of infectious agents introduced with nonindigenous hosts, while overlooking a potentially more common mechanism of impact, that of "parasite spillback." We hypothesize that parasite spillback could occur when a nonindigenous species is a competent host for a native parasite, with the presence of the additional host increasing disease impacts in native species. Despite its lack of formalization in all recent reviews of the role of parasites in species introductions, aspects of the invasion process actually favor parasite spillback over spillover. We specifically review the animal-parasite literature and show that native species (arthropods, parasitoids, protozoa, and helminths) account for 67% of the parasite fauna of nonindigenous animals from a range of taxonomic groups. We show that nonindigenous species can be highly competent hosts for such parasites and provide evidence that infection by native parasites does spillback from nonindigenous species to native host species, with effects at both the host individual and population scale. We conclude by calling for greater recognition of parasite spillback as a potential threat to native species, discuss possible reasons for its neglect by invasion ecologists, and identify future research directions.
ABSTRACT Disease-mediated impacts of exotic species on their native counterparts are often ignored when parasite-free individuals are translocated. However, native parasites are frequently acquired by exotic species, thus providing a... more
ABSTRACT Disease-mediated impacts of exotic species on their native counterparts are often ignored when parasite-free individuals are translocated. However, native parasites are frequently acquired by exotic species, thus providing a mechanism through which native host-parasite dynamics may be altered. In Argentina, multiple exotic salmonids are host to the native fish acanthocephalan parasite Acanthocephalus tumescens. Field evidence suggests that rainbow trout, Oncorhynchus mykiss, may be a major contributor to the native parasite’s population. We used a combination of experimental infections (cystacanth—juvenile worm transmission from amphipod to fish; post-cyclic—adult worm transmission between definitive fish hosts) and dynamic population modelling to determine the extent to which exotic salmonid hosts may alter A. tumescens infections in native freshwater fish. Experimental cystacanth infections demonstrated that although A. tumescens establishes equally well in native and exotic hosts, parasite growth and maturity is superior in exotic O. mykiss. Experimental post-cyclic infections also showed greater establishment success of A. tumescens in O. mykiss, though post-cyclic transmission did not result in greater parasite size or maturity. Dynamic population modelling, however, suggested that exotic salmonids may have a very limited influence on the A. tumescens population overall, due to the majority of A. tumescens individuals being maintained by more abundant native hosts. This research highlights the importance of considering both a host’s relative density and its competency for parasites when evaluating whether exotic species can modify native host-parasite dynamics.
ABSTRACT Whataroa virus, first detected in 1962 in bird populations around Whataroa township, is the only mosquito-borne virus circulating in New Zealand that has been isolated. Even though at least one other mosquito-borne pathogen... more
ABSTRACT Whataroa virus, first detected in 1962 in bird populations around Whataroa township, is the only mosquito-borne virus circulating in New Zealand that has been isolated. Even though at least one other mosquito-borne pathogen (avian malaria) has greatly increased in prevalence in New Zealand in recent decades, no surveillance for Whataroa virus in its vertebrate hosts has been carried out for four decades. This is of concern since Whataroa virus may infect humans, possibly causing influenza-like symptoms. Here we reassess the status of Whataroa virus in the same bird species in the same area where it was detected previously. Molecular diagnostics identified Whataroa virus in three out of 95 non-native birds screened: two out of eight song thrushes Turdus philomelos, and one out of nine blackbirds Turdus merula. The detection of virus in birds, in contrast with recent screening of mosquitoes, highlights how wildlife surveillance for pathogens can be far more effective than vector surveillance. Results of this survey indicate the virus has not increased substantially in prevalence since last monitored, possibly because of little change in the local mosquito vector community. Finally, virus detection in the two Turdus species alone supports earlier claims that these non-native hosts act as reservoirs that maintain the virus, sourcing spillover infections in other native and non-native species. A similar role for the blackbird in avian malaria epidemiology in New Zealand has also recently been hypothesized.
Understanding the composition of an artefact has ramifications for advancing human history and behaviour knowledge, providing cultural information about trade, agricultural practices and adaptation to new environments. However, accurate... more
Understanding the composition of an artefact has ramifications for advancing human history and behaviour knowledge, providing cultural information about trade, agricultural practices and adaptation to new environments. However, accurate plant identification from artefacts is problematic, since textile production, age, dirt and/or conservation treatments obscure morphological features, and specimen size and/or ethical considerations hamper modern analytical methods. This study tested the efficacy of polarized light microscopy (PLM) in the identification of New Zealand plant species commonly used in Māori textiles, and demonstrates that morphological and birefringent features observed using PLM have the potential to distinguish between- and within-plant genera.
Black-dyed artefacts are found in museums worldwide, many produced using an iron-tannate compound. Deterioration of iron-tannate dyed artefacts is an international preservation issue: in New Zealand the deterioration of paru... more
Black-dyed artefacts are found in museums worldwide, many produced using an iron-tannate compound. Deterioration of iron-tannate dyed artefacts is an international preservation issue: in New Zealand the deterioration of paru (iron-tannate) dyed Māori textiles is widespread. This article reports experimental work testing the efficacy of sodium alginate, a consolidant developed for deteriorated paru-dyed muka (fibre from harakeke; Phormium tenax). The colour stability, strength retention, and acidity of paru-dyed muka consolidated with sodium alginate (0.25, 0.5, and 1% w/v in water) was tested pre- and post-artificial light ageing. This study found that sodium alginate had no negative effect on paru-dyed muka and in some cases provided benefit. Interestingly, the colour of paru-dyed muka is substantially more stable in UV-filtered light than previously recognised. Also microfading results were in agreement with visual assessments of colour change at 1 Mlux hour exposure, providing confidence in this relatively new technique to assess colour change.
A number of new methods and technologies for investigating Māori textiles have emerged from ten years of research in the Department of Applied Sciences - Clothing and Textile Sciences, University of Otago, Dunedin, New Zealand. Research... more
A number of new methods and technologies for investigating Māori textiles have emerged from ten years of research in the Department of Applied Sciences - Clothing and Textile Sciences, University of Otago, Dunedin, New Zealand. Research projects undertaken include development of numerous identification methods for textile plants endemic to New Zealand (bright field microscopy, Scanning Electron Microscopy (SEM), Micro-Computed tomography (micro-CT), Polarised Light Microscopy (PLM)); exploration and improvement of safe display parameters for naturally-dyed Māori textiles (artificial light-ageing, microfading); and testing the efficacy of consolidants recommended for remedial conservation treatment of black-dyed muka (fibre) from harakeke (New Zealand flax, Phormium tenax). Of note is the collaborative and interdisciplinary nature of the work undertaken (research partnerships with iwi (Māori tribal grouping), customary weaving practitioners, New Zealand museums, conservation laboratories and other University departments), in addition to the adaptation of international standard textile testing methods to better reflect the artefact types of interest (for instance testing of fibre aggregates rather than woven European fabrics). Research outcomes are of relevance to practitioners and artists as well as those caring for Māori taonga, and have added to knowledge about both Māori textiles, and plants and dyes used in Māori textiles production.
