Experimental Design
Two series of experiments were conducted to determine the optimum developmental conditions for I. anatis. In the first, engorged larvae, nymph and adult were incubated under laboratory conditions (laboratory experiments) and in the second, engorged ticks were maintained in artificial kiwi burrows (field experiments) in a forested area close to the laboratory (40.3709° S, 175.6303° E; Figure 1). In all experiments, the pre-moult period was defined as the time from when a fully engorged tick was placed in the incubator or burrow to the time it started moulting. Moulting duration was the time from when the tick started moulting until the time the new stage first appeared. Moulting success was the proportion of ticks that were able to successfully ecdyse. For females, preoviposition was the time from the moment the female was placed in the incubator to the time it started laying eggs, and oviposition was the time taken for the female from the start to stop of egg laying .
Tick collection
Ticks were collected from NIBK inhabiting a high-density population of one bird per hectare on Ponui Island (Inner Hauraki Gulf, New Zealand; 36.8622° S, 175.1842° E; Figure 1) (23). These birds had been observed to have high densities of ticks, with up to 250 individuals recorded on one host (18, 24). Between April and June 2016 (for the laboratory experiments) and March 2018 (for the field experiment), detached, free -walking engorged ticks were collected. No ticks were forced off the hosts but were found walking on their feathers, on the surface of their bodies, on bird handlers and inside the bags used to cover the birds during handling. We assumed these ticks would have been naturally leaving the hosts after being satiated. All ticks used also looked fully engorged to the eye. Ticks were separated into the three stadial groups (larva, nymph, adult female), placed in plastic containers with fresh vegetation to provide moisture and stored at 4oC, for a mean duration of five days (± 5 days), until they arrived in the laboratory at Massey University, Palmerston North (546 km distant from the study site; Figure 1).
Tick identification
NZ has only one species of Haemaphysalis present and that genus is readily separated from the genus Ixodes based on palpal morphology. This and other features separating the species of Ixodes in NZ (shape of scutum, presence or absence of coxal spurs, etc.) were understood by the authors and taken into consideration when ticks were collected and identified, using keys in Dumbleton (17).
Pilot experiment
To test the combined effect of temperature and humidity on the stages of the tick we needed to provide ticks with different RHs and place these at different temperatures. Winston and Bates (25) developed protocols to create various RHs for exactly this purpose by dissolving enough solid salt to super saturate distilled water at boiling point. The basic principal of this mechanism is that any saturated salt solution, when placed at a constant temperature produces a fixed vapour pressure (vp) which is in equilibrium with the vp of water and thus expresses a fixed relative humidity (25, 26). We conducted a pilot test using salt solutions from their protocols (25, 26) with the idea to be able to produce a range of RHs for further experiments with our ticks. The salt solutions we used to achieve the required RH are given in Table 1. These solutions were placed at the bottom of sealed plastic containers with mesh lids and an iButton HygrochronTM Temperature/Humidity Loggers (Model DS1923; Maxim Integrated, San Jose, California) was hung from the lid, so it was at the same level as the ticks. The entire setup was placed in fixed temperature incubators, and the temperatures selected were 5˚C, 10˚C, 15˚C, 20˚C, 25˚C and 30˚C. The hygrometers were set to record temperature and humidity every 10 minutes for a week. Despite numerous attempts, not all the salt solutions produced the desired RHs reported in Winston and Bates (25) and therefore we used the actual RHs achieved (Table 1) as our final RHs for the main laboratory experiment.
Laboratory Experiment – Effects of a range of temperatures and humidity
Engorged larvae and nymphs were individually placed into small fabric mesh pockets which were suspended above the saturated salt solutions (Table 1). These were then incubated at a range of temperatures (5ºC, 10ºC, 15ºC, 20ºC, 25ºC and 30ºC). There were 20 engorged larvae and 10 engorged nymphs for each humidity and temperature combination. In addition, 12 engorged adult females were available and divided into four groups of three. To measure preoviposition and oviposition time, two of the groups were incubated at 15ºC and 93% and 96% RH respectively; one at 10ºC and 94% RH and one at 20ºC and 85.5% RH. Eggs obtained from these female ticks were subsequently divided into batches and placed in mesh bags (50 eggs/bag) at all temperature and RH combinations (Table 1, 2). Temperatures and RH were measured every hour using iButton HygrochronTM Temperature/Humidity Loggers . The ticks were observed every two days for evidence of development, for a total of six months. In this experiment the hypothesis was that larvae, nymphs and females of I. anatis, would have more successful and faster developmental times at temperatures between 15ºC - 20ºC and RH above 90% than in conditions outside this range.
Field Experiment
Engorged larvae and nymphs were placed in artificial burrows (n=12) from June to August (Southern Hemisphere winter) 2018. At Massey University, horizontal burrows were dug in a forest environment consisting of clay/silt loam-type soil, and imitated natural burrows. These simulated burrows were approximately 120-150mm diameter and 600mm deep (Figure 2). A larger chamber was constructed at the end to mimic a typical kiwi-constructed burrow (D. Galvez, 2019). Ten nymphs and 20 larvae were placed in each burrow in mesh pockets (one for each stage). These ticks were checked every two to three days to record moulting. Temperature and RH were recorded every hour using iButton HygrochronTM Temperature/Humidity Loggers. For this experiment, we expected both the stages to follow the same pattern as found in the laboratory experiment.
Statistical analysis
One-way ANOVA were carried out in R Core Team (2013) to test for significance between the number of days taken to start and complete moult for the different stages, where applicable. We also carried out linear regressions to test the significance of temperature and RH on preoviposition and oviposition times in females.
The saturation deficit (SD), which is the amount of water vapour required to saturate air, (in mm of Hg) was calculated using the formula: SD = (1- RH/100) * 4.9463e0.0621T (where RH is relative humidity in %, e is the mathematical constant ‘Euler’s number’ and T is temperature in ºC) (27). For both the laboratory experiment and the field experiment results were reported using both RH and the corresponding SD at the given temperatures.