Review of import conditions for fresh taro corms

Probability of establishment

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1.12.2Probability of establishment

The likelihood that Patchiella reaumuri will establish within Australia, based on a comparison of factors in the source and destination areas considered pertinent to their survival and reproduction, is: MODERATE.

Patchiella reaumuri can reproduce without fertilization by males (Sato and Hara 1997), which would increase the likelihood of establishing a population.
In Hawaii, short distance transport of these wingless aphids is mediated by ants (Macfarlane 1999; Carmichael et al. 2008). There is no information on how specific this relationship is, but Australian ants are known to farm aphids for honeydew.
Arum spp. act as alternative hosts for Patchiella reaumuri in Europe (Macfarlane 1999; Carmichael et al. 2008), so other species of Araceae (native, naturalised or cultivated) might act as alternative hosts for this aphid.

1.12.3Probability of spread

The likelihood that Patchiella reaumuri will spread within Australia, based on a comparison of those factors in the source and destination areas considered pertinent to the expansion of the geographic distribution of the pest, is: MODERATE.

It is likely that ant vectors would be available to transport taro root aphids locally if they established in areas with taro.
Most wild and naturalised taro in Australia is found in wet areas (along creeks etc.), which are known to be unsuitable habitats for this aphid (Sato and Hara 1997).
Most Australian commercial taro is grown under dryland conditions, which are favourable for taro root aphid.
Other possible host genera, Arum and Tilia, are not native or naturalised in Australia, and occur only as sparsely distributed horticultural plants. It is not known if the Arum lily (Zantedeschia aethiopica), a weed introduced from South Africa that is common in parts of coastal southern Australia, would be an effective host for the taro root aphid.
If the taro root aphid established in an Australian taro growing region, it could spread via movement of locally produced corms.

1.12.4Probability of entry, establishment and spread

The overall likelihood that Patchiella reaumuri will enter Australia as a result of trade in fresh taro corms from any country where this pest is present, be distributed in a viable state to a susceptible host, establish and spread within Australia, is: VERY LOW.

1.12.5Consequences

Assessment of the potential consequences (direct and indirect) of Patchiella reaumuri for Australia is: MODERATE.

Criterion	Estimate and rationale
Direct
Plant life or health	Impact score: E – significant at the regional level If this pest became established in dryland taro crops it could potentially be very serious, depending on the varieties of taro involved. In Hawaii, losses of 75–100 percent have been recorded from some varieties (Sato and Hara 1997). Australia has 44 species of native and naturalised aroids, all potentially susceptible to taro root aphid attack, although it is not known how many might be affected. If this pest was to establish in naturalised taro populations, this would be beneficial in a biocontrol sense for weedy taro but it would form a source for infestation back into taro crops.
Other aspects of the environment	Impact score: A – indiscernible at the local level There are no known direct consequences of this aphid on the natural or built environment.
Indirect
Eradication, control etc.	Impact score: C – minor significance at the district level Tillage and crop rotation are used to eradicate small scale infestations. No chemical controls are suitable, although controlling ants should reduce local spread. A hot water dip treatment for planting material has been found to be effective in Hawaii (Sato and Hara 1997).
Domestic trade	Impact score: B – minor significance at the local level The pest is very host specific. The main consequences would arise from quarantine restrictions to prevent further spread to other taro growing areas.
International trade	Impact score: B – minor significance at the local level Australia's taro export trade is small. Taro root aphid would be considered a quarantine pest for most countries.
Environmental and non-commercial	Impact score: A – indiscernible at the local level No information was found indicating possible indirect effects on the environment.

1.12.6Unrestricted risk estimate

The unrestricted risk for Patchiella reaumuri is: VERY LOW.

Unrestricted risk is the result of combining the probability of entry, establishment and spread with the outcome of overall consequences. Probabilities and consequences are combined using the risk estimation matrix shown in Table 2.5.

The unrestricted risk estimate for Patchiella reaumuri of ‘very low’ achieves Australia’s ALOP. Therefore, specific risk management measures are not required for this pest.

1.13Spiral nematodes

Helicotylenchus microcephalus; Helicotylenchus mucronatus

Helicotylenchus species are polyphagous plant parasitic root feeders that are found throughout tropical and subtropical regions of the world. Helicotylenchus is the most common plant nematode genus in Fiji (Orton Williams 1980). A number of spiral nematode species are present in Australia, including Helicotylenchus multicinctus, which is a serious pest of banana and sugarcane (McLeod et al. 1994).

Helicotylenchus microcephalus and Helicotylenchus mucronatus are pest species that feed on taro. Neither species has been reported in Australia. These two species have been grouped together for this PRA due to their similar biology.

The lifecycles and biology of these species are not well documented. Helicotylenchus spp. nematodes are usually ectoparasitic feeders on roots, but they can sometimes feed inside the roots (Kazi 1996; Luc et al. 1990). All life stages can be found in the soil and root cortex. Migration through the root tissues has not been reported. Small lesions are formed that become necrotic as secondary infections take place. The two species considered here are parthenogenetic (Luc et al. 1990). There are other Helicotylenchus species known to occasionally feed on taro that have not been reported as causing economic damage. The similar biological characteristics of these species means they would pose similar risks in terms of entry, distribution, establishment and spread.

1.13.1Probability of entry

Probability of importation

The likelihood that Helicotylenchus microcephalus and Helicotylenchus mucronatus will arrive in Australia with the importation of fresh taro corms from any country where these pests are present is: LOW.

Helicotylenchus microcephalus and Helicotylenchus mucronatus are polyphagous (Luc et al. 1990), and are associated with the roots of many different hosts, including taro.
Helicotylenchus microcephalus and Helicotylenchus mucronatus have been identified as minor pests of taro (Bridge 1988; Orton Williams 1980).
While the lifecycle and biology of both species is not well documented, they are likely to predominantly feed on the outside of the roots like other Helicotylenchus species (Kazi 1996). However, Helicotylenchus microcephalus is reported to be endoparasitic in sweet potato roots by Njuguna and Bridge (1998).
All life stages can be found in the root cortex of host plants, but migration through (i.e. inside) the root tissues has not been reported (Luc et al. 1990). Their association is with the roots, rather than the corm.
The most likely pathway for entry would be via infested soil attached to poorly cleaned corms.
Removal of feeder roots as part of the cleaning process, and drying of any remaining roots and the surface of the corm in storage will further reduce the numbers of nematodes.

Probability of distribution

The likelihood that Helicotylenchus microcephalus and Helicotylenchus mucronatus will be distributed within Australia in a viable state to a susceptible part of a host, as a result of the processing, sale or disposal of fresh taro corms from any country where these pests are present, is: MODERATE.

These nematodes are not known to penetrate deeply into root tissue, and they remain on or near the surface (Luc et al. 1990). As the outer surfaces of the corm and the fine feeder roots dry during storage and distribution, conditions will become less favourable for survival of the nematodes.

Corms will be distributed to many localities by wholesale and retail trade and by individual consumers.
Individual consumers could carry small quantities of taro corms to urban, rural and natural localities. Small amounts of corm waste could be discarded in these localities.
Some corms will be distributed to areas where host plants are grown.
Small amounts of corm waste will be discarded into domestic compost.
Living nematodes in discarded taro waste may be able to find a compatible host in the area where they are discarded. Spiral nematodes are polyphagous, feeding on a wide range of plant hosts (Luc et al. 1990).
Their ability to move from the corm to locate a new host is very limited.
Active movement of nematodes in the soil is probably limited to several centimetres per year. Movement is dependent on moisture, and will be affected by rainfall, soil texture, compaction and structure, and slope position (Norton and Niblack 1991). Longer distance movement may occur via surface water or wind currents (Norton and Niblack 1991).

Probability of entry (importation × distribution)

The likelihood that Helicotylenchus microcephalus and Helicotylenchus mucronatus will enter Australia and be distributed in a viable state to a susceptible host, as a result of trade in fresh taro corms from any country where this pest is present, is: LOW.

1.13.2Probability of establishment

The likelihood that Helicotylenchus microcephalus and Helicotylenchus mucronatus will establish within Australia, based on a comparison of factors in the source and destination areas considered pertinent to their survival and reproduction, is: HIGH.

Climatic conditions in parts of Australia will match those in source areas.
These nematodes feed on the roots of a broad range of plants. Helicotylenchus microcephalus has been recorded on more than 60 different plant hosts, most commonly on breadfruit, cassava, maize, peanut and sugarcane (Orton Williams 1980). Kazi (1996) reported 23 plant hosts of Helicotylenchus mucronatus, many of which are present and common in Australia, such as capsicum, citrus, corn, cucumber, mango, potato, rice and sugarcane.
Nematodes in the vicinity of roots of host plants will be able to feed and reproduce.

1.13.3Probability of spread

The likelihood that Helicotylenchus microcephalus and Helicotylenchus mucronatus will spread within Australia, based on a comparison of those factors in the source and destination areas considered pertinent to the expansion of the geographic distribution of the pests, is: HIGH.

Spread of these nematodes is thought to occur mainly by the planting of infested material and movement of soil.
If the nematodes established in growing areas, it is possible that they could remain undetected for some time, causing little damage, and may then be inadvertently spread via planting stock.
Spread is also possible by transfer to alternative hosts and subsequent propagation via that pathway.
Natural spread would be slow, as nematodes only actively move several centimetres per year in the soil (Norton and Niblack 1991). However, nematodes on the soil surface could be carried greater distances by wind or surface water.

1.13.4Probability of entry, establishment and spread

The overall likelihood that Helicotylenchus microcephalus and Helicotylenchus mucronatus will be imported as a result of trade in fresh taro corms from any country where these pests are present, be distributed in a viable state to a susceptible host, establish and spread within Australia, is: LOW.

1.13.5Consequences

Assessment of the consequences (direct and indirect) of Helicotylenchus microcephalus and Helicotylenchus mucronatus for Australia is: LOW.

Criterion	Estimate and rationale
Direct
Plant life or health	Impact score: D – significant at the district level There is no evidence that spiral nematodes seriously affect taro, although Helicotylenchus mucronatus has been identified as a potential problem (Bridge 1988). Their main impact would probably be on other crops such as sugarcane and bananas, which are already subject to infestation by more aggressive Helicotylenchus spp.. They may also infest aroid foliage plants that are part of the horticultural trade. Existing control measures for those other species would mitigate the effect of these spiral nematodes.
Other aspects of the environment	Impact score: A – indiscernible at the local level There are no known direct consequences of these nematodes on the natural or built environment.
Indirect
Eradication, control etc.	Impact score: C – minor significance at the district level Once established, eradication of these species would not be possible. Control measures would be aimed at ensuring nematode-free planting stock. Treatment of planting material by immersion in hot water at 50 °C for 15–40 minutes has been shown to be effective in eliminating other nematode species from taro planting material without damaging the planting stock (Luc et al. 1990), although there is no published evidence that it would be equally effective for Helicotylenchus microcephalus and Helicotylenchus mucronatus. Impacts on other crops are possible because spiral nematodes are not host-specific. However, the crops most at risk (bananas, sugarcane) are already subject to attack by Helicotylenchus multicinctus, a more serious pest, and efforts to control that nematode would simultaneously control these species.
Domestic trade	Impact score: B – minor significance at the local level Establishment of spiral nematodes in taro growing areas would possibly elicit controls on movement of produce to prevent further spread.
International trade	Impact score: B – minor significance at the local level The export trade in taro from Australia is small. As infestations are confined to feeder roots, effects on trade in non-root crops are likely to be negligible. Both species are already widespread in countries likely to be recipients of exported taro.
Environmental and non-commercial	Impact score: A – indiscernible at the local level Most recorded hosts are crop plants. Little information is available on the susceptibility of native plants to spiral nematodes. Pandanus sp. and Macadamia sp. are reported as hosts of Helicotylenchus microcephalus (Orton Williams 1980). No indirect environmental consequences of these nematodes are known.

1.13.6Unrestricted risk estimate

The unrestricted risk for Helicotylenchus microcephalus and Helicotylenchus mucronatus is: VERY LOW.

The unrestricted risk estimate for Helicotylenchus microcephalus and Helicotylenchus mucronatus of ‘very low’ achieves Australia’s ALOP. Therefore, specific risk management measures are not required for these pests.

1.14Taro root nematode

Hirschmanniella miticausa

Hirschmanniella miticausa is a migratory endoparasitic nematode and the causal organism of the corm rot disease known as ‘miti miti’ in the Solomon Islands (Bridge 1988). The disease was first noted on the island of Choiseul, Solomon Islands, in the 1920s, but spread with the movement of planting material (Mortimer et al. 1981). The highest populations of the nematode live inside the taro corms, and some may be found in the roots. Only a few nematodes may be found in the surrounding soil (Bridge et al. 1983; Jatala and Bridge 1990).

Hirschmanniella miticausa is a serious pest of wetland cultivated taro, and is also considered to be a problem in dryland taro (Zettler et al. 1989). No other hosts are known. Although symptoms are usually only apparent when corms are harvested (Zettler et al. 1989), wilting, stunting and the eventual chlorosis of older leaves due to corm damage are the first above-ground symptoms of Hirschmanniella miticausa infestation (Carmichael et al. 2008). Infested corms exhibit irregular, small (1–10 mm wide) red or brown necrotic zones originating from the base of the corm (Bridge 1988; Carmichael et al. 2008). Infested corms have the appearance of uncooked fatty meat (hence the pidgin name ‘miti miti’ in the Solomon Islands) and often the basal parts of the corms succumb to secondary brown rots, resulting in their complete decay (Zettler et al. 1989; Carmichael et al. 2008).

Hirschmanniella miticausa has been reported from the Solomon Islands, and also has a limited distribution in the highlands of Papua New Guinea (Jatala and Bridge 1990; Bridge et al. 1983). Only taro imports from these countries pose a risk to Australia. An unspecified Hirschmanniella sp. has also been recorded as associated with taro in Taiwan (Jatala and Bridge 1990).

1.14.1Probability of entry

Probability of importation

The likelihood that Hirschmanniella miticausa will arrive in Australia with the importation of fresh taro corms from any country where this pest is present is: MODERATE.

Plants infested with this nematode show signs such as wilting of leaves, yellowing and distortion of the central leaf, and have reduced numbers of daughter corms. Affected plants usually die prematurely. The basal portions of the corms are often affected with a brown soft rot, as well as the dry brown rot of miti miti (Jatala and Bridge 1990). Such corms are unlikely to enter the export stream, and if they do, are likely to be detected during sorting, grading and packing.
However, corms with only dry internal rot may escape detection, as symptoms may only be apparent when the corms are cut open (Carmichael et al. 2008).

Probability of distribution

The likelihood that Hirschmanniella miticausa will be distributed within Australia in a viable state to a susceptible part of a host, as a result of the processing, sale or disposal of fresh taro corms from any country where this pest is present, is: LOW.

Corms with miti miti infestation are prone to secondary rots (Jatala and Bridge 1990), and it is likely that rotting would progress further during storage and transport within Australia, making the diseased corms more conspicuous and subject to culling.
However, because some infested corms do not initially show obvious external symptoms, it is possible that a small number of these corms could be distributed in the wholesale and retail supply chain.

Corms will be distributed to many localities by wholesale and retail trade and by individual consumers.
Individual consumers will carry small quantities of taro corms to urban, rural and natural localities. Small amounts of corm waste could be discarded in these localities.
Some corms will be distributed to areas where taro is grown.
Small amounts of corm waste could be discarded into domestic compost.
The most likely scenario for distribution would involve an infested corm entering the retail supply chain undetected, being cut open and found to be rotten by a consumer, and then being discarded as waste (e.g. composted) near cultivated taro plants, for example, in a domestic garden.
The nematode’s ability to move from the corm to locate a taro plant is very limited and dependant on factors such as soil moisture.

Probability of entry (importation × distribution)

The likelihood that Hirschmanniella miticausa will enter Australia and be distributed in a viable state to a susceptible host, as a result of trade in fresh taro corms from any country where this pest is present, is: LOW.

1.14.2Probability of establishment

The likelihood that Hirschmanniella miticausa will establish within Australia, based on a comparison of factors in the source and destination areas considered pertinent to its survival and reproduction, is: HIGH.

Climatic conditions in northern Australia are similar to the native environment where taro root nematode is found.
The nematode can probably survive for some time in field soil without hosts (Jatala and Bridge 1990).
Nematodes in the vicinity of taro roots will be able to feed and reproduce.
Taro is the only known host of Hirschmanniella miticausa (Zettler et al. 1989). If the local taro population was infested, it would provide a reservoir of infestation that would be difficult to eliminate.
Despite other aroids growing in the area where the taro root nematode occurs, the nematode is not known to attack them, so it is unlikely that it will affect other native and naturalised aroids.

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