The Chinese citrus fly, Bactrocera minax (Enderlein) (Diptera: Tephritidae), is the most destructive citrus pest in many citrus production areas in China. The pest is oligophagous, feeding exclusively on the fruits of citrus plants. The pest is univoltine, with adults emerging during April to May and overwintering as pupae. Evidence suggests that the region of origin of the species might be in the elevated temperate southern Yunnan-Guizhou Plateau, spreading out through China’s major waterway systems. Currently, B. minax occurs in nine citrus producing provinces in China, but mostly prominently in the five south central provinces or municipalities of Guizhou, Hubei, Hunan, Sichuan, and Chongqing. Fruit infestations in these provinces are generally moderate to severe. The species is not reported in the four southern citrus production provinces of Guangdong, Fujian, Zhejiang, and Hainan (island). Orchard sanitation such as collection and treatment of the fallen and hanging infested fruits, mass trapping by using various food-based traps with insecticides, and foliar and ground insecticide sprays are the primary pest management options. Sterile insect technology was studied in the field in the 1980s to 1990s, with promising outcomes. The two highly attractive kairomone lures used for many Bactrocera species, cuelure or methyl eugenol, are not attractive to this species. Hydrolyzed protein, sugar and vinegar mixture, and waste brewer's yeast are the most common lures being used in China. Published data indicated that the quality and efficacy of these lures are inconsistent and disputable. Visual cue lures such as colored sticky spheres are also being used in the field. Preliminary field studies suggested that female rectum extracts demonstrated high attraction to males as well as females of the species. Phytosanitary treatment studies in China focus on irradiation and cold treatment. The outcomes of irradiation appeared promising. When B. minax larvae were treated with an irradiation dose of 50 Gy, no adults emerged from the surviving pupae and larvae failed to pupate when the dose reached 70 Gy. No fruit quality was impacted by the treatment. Results from several small-scale cold treatment studies were less promising and inconsistent. One study indicated that under 0°C constant treatment, no mortality of 3rd instar larvae occurred until day 12, and only 55% mortality occurred by day 22. The scientific and technological gaps in safeguarding US citrus industry from the invasion of this destructive pest include: 1) lack of effective lures for early detection and emergency responses; 2) insufficient work on phytosanitary treatment techniques; and 3) weak definition of and lack of data for B. minax pest free areas in China.
The Chinese citrus fly, Bactrocera minax (Enderlein), is the most destructive citrus pest in many groves in south-central China. The pest can cause up to 100% fruit damage in severe situations [
Interest in this pest outside of China has risen in recent years. This is primarily due to the concern that B. minax might spread to the world’s other major citrus production regions through fresh fruit trade and travelers. China has already exported a large volume of fresh citrus fruits to a number of countries in Asia, Russia, Europe, and the Americas [
Laboratory and field studies of the pest have been carried out in China since the early part of the last century. However, results of these works were almost exclusively published in Chinese journals, with few exceptions [
B. minax has several biological characteristics that separate this species from the vast majority of species in the genus Bactrocera. First, B. minax is univoltine; second, the species is oligophagous, exclusively feeding on citrus plants; third, the pest is large in size, larvae can be as long as 16 mm, adults can reach as long as 24 mm [
The life cycle of B. minax is well studied in China. Adults start to emerge in April across most occurrence regions (
| Province | Stage | Month | References | |||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| J | F | M | A | M | J | J | A | S | O | N | D | |||
| Hunan | Adult | [ | ||||||||||||
| Egg | [ | |||||||||||||
| Larva | [ | |||||||||||||
| Pupa | [ | |||||||||||||
| Shaanxi | Adult | [ | ||||||||||||
| Egg | [ | |||||||||||||
| Larva | [ | |||||||||||||
| Pupa | [ | |||||||||||||
| Hubei | Adult | [ | ||||||||||||
| Egg | [ | |||||||||||||
| Larva | [ | |||||||||||||
| Pupa | [ | |||||||||||||
| Sichuan Chongqing | Adult | [ | ||||||||||||
| Egg | [ | |||||||||||||
| Larva | [ | |||||||||||||
| Pupa | [ | |||||||||||||
larvae fall from hanging fruits or exit from fallen fruits into soil for overwintering. The larval stage lasts roughly two months. The pupal stage is the longest stage of the species, lasting from 150 to almost 200 days [
B. minax occurs in nine citrus production provinces in China (
Areas in China where B. minax is widely occurring and causes significant economic damage to citrus include the following provinces and/or municipalities:
Guizhou. B. minax has been reported in all citrus production areas in the province [
Sichuan. Sichuan is one of China’s major citrus growing provinces. Similar to Guizhou, B. minax has a long occurrence history in Sichuan province [
Chongqing. Administratively, this central government direct-controlled municipality city was a part of Sichuan province until 1997. As discussed above, B. minax has widely occurred in Sichuan since the 1950s and accordingly, the pest is common in the municipality of Chongqing as well. The pest is particularly prevalent in the citrus production area near the Three Gorges Dam [
Hubei. Hubei is another major citrus growing province in China. B. minax occurs commonly throughout the province [
Hunan. Hunan is China’s number one citrus growing province based on annual fruit production [
Areas of China where B. minax is present but occurs in limited areas with moderate to low population levels and where economic damage to the citrus industry is correspondingly moderate to low, include the following provinces:
Yunnan. Although Yunnan-Guizhou Plateau is believed to be the original home of this species, B. minax is mainly found in the northeast regions bordering with Guizhou province [
Guangxi. Although B. minax has been reported from Guangxi province since the 1950s, the economic damage and distribution area appear moderate [
Shaanxi. Shaanxi is the northern most citrus producing province in China. The province is at similar latitudes as Oklahoma in US B. minax can be commonly found in areas around Hanzhong, the province’s major citrus production region [
Jiangxi. Jiangxi is China’s major sweet orange production province. However, citrus production has been severely impacted by the outbreak of huanglongbing (citrus greening) in recent years. B. minax occurs in the northern region of Jiujiang [
Henan and Jiangsu Provinces have reported occurrences of B. minax, however, the pest was either eradicated or disappeared itself [
According to existing data, B. minax is not reported in four southern coastal citrus production provinces: Guangdong, Fujian, Zhejiang, and Hainan Island. No study has been conducted to explore why B. minax does not occur in these provinces [
It is our opinion that Yunnan-Guizhou Plateau is likely the region of origin for B. minax for the following three reasons. First, B. minax appeared widely distributed in the mountainous Guizhou province long before other places in China [
Further discussion of the possible region of origin of B. minax is beyond the purpose of this writing. However, knowledge of the pest’s origin can be critical in the development of a pest risk assessment and other safeguarding efforts. For example, Yunnan-Guizhou Plateau is a typical moderate climate region in spite of its low latitude location. Average high temperatures during July in Yunnan are about 25˚C, vs. 34˚C in Orlando, Florida (
Although B. minax has a long history of occurrence in China, the pest didn’t have widespread economic impact until recent decades. Three factors contributed to the change in pest status. First, citrus growing acreage in China has experienced dramatic expansion in recent decades. For the period of 1949 to 2008, China’s citrus production area and fresh fruit yield rose 62.2 and 103.8 fold, respectively, vs. world averages of 7.3 and 6.7 fold for the same period [
majority of the production expansion occurred in the south-central region such as in Hubei and Hunan, where B. minax commonly occurs. Second, changes in China’s agricultural production system occurred in the late 1970s to the early 1980s that disrupted area-wide pest management programs. The previously large collective-owned orchards were replaced with small-scale (usually less than 0.3 ha), family-owned orchards. This change made it much more challenging to coordinate and enforce pest management activities. Third, weak domestic pest quarantine and inspection efforts failed to stop the spread of this pest. There was essentially no domestic quarantine and inspection in China before 1950 and even today the system is unreliable. B. minax, has not been on China’s quarantine pest list since 2009 [
Theoretically, both trapping and fruit infestation data are good indicators of pest severity. However, due to the fact that there is no effective trap for the pest, as we will discuss later, negative trapping data for this pest can be misleading. Fruit infestation might be the only reliable indicator of pest severity in the case of B. minax.
Guizhou. Fruit infestation by B. minax in the province varied widely, from less than 1 to 100%. The Plant Protection Station of Guizhou Province conducted a province-wide survey from 1994 to 1996. Among 6080 ha surveyed, B. minax occurred in 4180 ha, accounting for 68.8% of the surveyed area. A total of 55 counties in the province had B. minax occurrence. Zunyi region had an average of 20% - 40% fruits infested [
Hubei. B. minax occurrence in Hubei is more severe than Guizhou, based on the data of infested fruits. Most surveys indicated 20% or higher of fruits infested.
Hunan. Hunan is another severe B. minax occurring province. A recent survey by [
Sichuan. As discussed above, Sichuan has a long history of B. minax occurrence. The most notorious outbreak of B. minax in recent China’s history occurred in Guangyuan region of the province. The severity of the outbreak was unprecedented; few fruits in the entire region were saved from B. minax infestation [
Henan and Shaanxi. These two provinces have very limited citrus production areas. B. minax was reported to cause various degrees of fruit damages.
Strong scientific evidence suggests that B. minax prefers navel oranges and/or other sweet orange cultivars [
| Province/Survey Year(s) | Host-Common Name/ scientific name | % infested | References |
|---|---|---|---|
| Guizhou/1986-1988 | Pomelo/Citrus maxima | 71.4 | [ |
| Guizhou/1986-1988 | Sweet orange/Citrus sinensis Osbeck | 1.7 | [ |
| Guizhou/1986-1988 | Bitter orange/Citrus aurantium L. | 0.7 | [ |
| Guizhou/1960s-1970s | Citrus spp. | Avg. 20 | [ |
| Guizhou/1980s | Citrus spp. | Avg. 5 - 8 | [ |
| Guizhou/1987 | Citrus spp. | 5 - 8 | [ |
| Guizhou/1995 | Citrus spp. | 11.9 | [ |
| Guizhou/1994-1996 | Citrus spp. | 20 - 40 | [ |
| Guizhou/1990s | Citrus spp. | Avg. 70 - 80 up to 100 | [ |
| Hubei/1980-1987 | Citrus tangerina | 30 (early mature varieties); 5 (late mature varieties) | [ |
| Hubei/1980-1987 | Sweet orange/Citrus sinensis Osbeck | 40 - 78.9 | [ |
| Hubei/1980-1987 | Pomelo/Citrus maxima | 40 - 78.9 | [ |
| Hubei/1980-1987 | Medicinal Citron/Citrus medica L. | 40 - 78.9 | [ |
| Hubei/1990s | Citrus spp. | Ave. 10 - 20; severe 60 - 90 | [ |
| Hubei/1995 | Citrus spp. | Ave. 30 - 50; up to 90. | [ |
| Hubei/2006 | Sweet orange/Citrus sinensis Osbeck | 40.7 | [ |
| Hubei/2006 | Satsuma mandarin/Citrus unshiu Marcovitch | 26.3 | [ |
| Hubei/2006 | Robertson navel orange/Citrus sinensis Osbeck | 20.7 | [ |
| Hubei/2005 | Navel orange/Citrus sinensis Osbeck | 78.5 | [ |
| Hubei/2005 | Sweet orange/Citrus sinensis Osbeck | 63.6 | [ |
| Hubei/2005 | Satsuma mandarin/Citrus unshiu Marcovitch | 45.8 | [ |
| Hubei/2012 | Citrus spp. | Ave. 0.56; Less than1 | [ |
| Hubei/2006 | Citrus spp. | 40 - 70 | [ |
| Hunan/1950s | Citrus spp. | Ave. 20 - 30; up to 80 | [ |
| Hunan/2010 | Sweet orange/Citrus sinensis Osbeck | 63 | [ |
| Hunan/2010 | Satsuma mandarin/Citrus unshiu Marcovitch | 22 (early mature varieties) | [ |
| Hunan/2010 | Ponkan/Citrus poonensis Hort. ex Tanaka | 6 | [ |
| Hunan/2010 | Sweet orange/Citrus sinensis Osbeck | 63 | [ |
| Hunan/2010 | Wenzhou orange/Citrus unshiu Marcovitch | 22 | [ |
|---|---|---|---|
| Hunan/2010 | Ponkan/Citrus poonensis Hort. ex Tanaka | 6 | [ |
| Hunan/2010-2012 | Sweet orange/Citrus sinensis Osbeck | 100 | [ |
| Hunan/2010-2012 | Satsuma mandarin/Citrus unshiu Marcovitch | 55 - 80 | [ |
| Hunan/2010-2012 | Ponkan/Citrus poonensis Hort. ex Tanaka | 50 | [ |
| Sichuan/1982-1992 | Citrus spp. | Avg. 20 - 30 | [ |
| Sichuan/1997-2001 | Citrus spp. | 20 - 30, up to 70 - 80 | [ |
| Henan/1988 | Satsuma mandarin/Citrus unshiu Marcovitch | 1.2 - 10.5, avg. 5.9 | [ |
| Henan/1988 | Citrus tangerina | 1.2 - 10.5, avg. 5.9 | [ |
| Shaanxi/2013 | Satsuma mandarin/Citrus unshiu Marcovitch | 12 | [ |
| Shaanxi/2013 | Citrus erythrosa Tanaka | 5 - 7.2 | [ |
| Host-Common Name/Scientific name | Host-environment (Wild/nature/cultivated) | References |
|---|---|---|
| Sweet orange/Citrus sinensis Osbeck | Cultivated | [ |
| Citrus sinensis × Citrus maxima | Cultivated | [ |
| Bitter/sour orange/Citrus aurantium L. | Cultivated | [ |
| Citrus junos | Cultivated | [ |
| Citrus tangerina | Cultivated | [ |
| Citrus limon (L.) Burm. f. | Cultivated | [ |
| Pomelo/Citrus maxima (Burm) | [ | |
| Satsuma mandarin/Citrus unshiu Marcovitch | Cultivated | [ |
| Ponkan/Citrus poonensis Hort. ex Tanaka | Cultivated | [ |
| Grapefruit/Pomelo/Citrus paradisi Macf | Cultivated | [ |
| Mandarin orange/Citrus reticulata Blanco cv. Tankan | Cultivated | [ |
| Kumquat/Fortunella margarita (Lour.) Swingle | Cultivated | [ |
| Medicinal Citron/Citrus medica L. | Nature | [ |
| Citrusvesscosa | Nature | [ |
| Poncirus trifoliata (L.) Raf. | Wild | [ |
| Citrus | Fruit Infestation Rates (%), based on six studies | |||||
|---|---|---|---|---|---|---|
| [ | [ | [ | [ | [ | [ | |
| Navel Orange | 63 | 100 | 100 | 40.7 | N/A | The papers stated that sweet orange suffered the highest fruit infestation, but no data provided |
| Ponkan | 6 | 50 | 3.0 | N/A | 0 | |
| Mandarin | 18 | 55 | 74.7 | 20.7 | 0 | |
| Bingtang Orange (C. sinensis (Linn.) Osbeck cv. Bing Tang) | 22 | 70 - 80 | 77.2 | N/A | N/A | |
| Dahong Orange (C. sinensis (Linn.) Osbeck cv. Da Hong) | N/A | 72 - 75 | N/A | N/A | N/A | |
| Jinch Orange (C. sinensis (Linn.) Osbeck cv. Jincheng) | N/A | N/A | N/A | N/A | 1.7 | |
| Early Ripening Satsuma | 22 | 60 - 68 | 73.2 | 26.3 | N/A | |
| Pomelo | N/A | N/A | 52.6 | N/A | 71.4 | |
| Sour orange | N/A | N/A | 99.3 | N/A | 0.7 | |
* reference cited.
Citrus maxima, to a Chinese sweet orange cultivar Jincheng orange judging by fruit infestation rates [
No study has ever been undertaken to investigate the roles of chemical and visual cues on host selection, although the color and shape of trapping devices have been studied for attracting the pest in China and Bhutan [
Area-wide pest management or integrated pest management is not commonly adopted in China, with the exception of few large cooperative orchards in the major export citrus production counties such as Shimen in Hunan and Pinghe in Fujian. Instead, growers use one or more of the options discussed below for management of B. minax. There is no report of using biological control against the pest. Two studies indicated that natural enemies such as spiders and wasps had few impacts on the population of B. minax [
Fruit bagging is not a common practice in citrus groves. Exceptions can be found in those high value groves such as pomelo and lime. Few studies have ever been conducted using this approach for managing B. minax [
This practice is common in well-managed citrus groves. The fallen and hanging infested fruits are collected in large bags. These bags with the infested fruits are subjected to various treatments, ranging from heat treatment (by exposing the bags under the sun), boiling, deep bury, to burning [
As stated earlier, the majority of the overwintering B. minax pupae stay in soil at depths of 4 - 6 cm. Raking and/or shallow plowing in fall/winter can expose the pupae to the cold winter temperature, and natural enemies such as birds [
B. minax feeds on citrus fruits only, so theoretically, making citrus fruits unavailable during the egg-laying season can disrupt the entire population in the area. Of course, this option can be valid only under certain special circumstances such as:
1) Replanting or re-grafting citrus plants for the entire grove or area. Growers may replant the entire grove for disease management or changing to a market favorite variety [
2) Spraying plant growth regulators to end fruiting season before B. minax oviposition. Ethrel spraying is a common way to force citrus fruit falling prematurely [
3) Seasonable avoidance by planting late ripening cultivars [
Mass-trapping and foliar insecticide spraying are the predominant approach to managing B. minax in China.
Food based lures are extensively used in citrus groves in China. These lures are primarily for mass-trapping efforts only, often used together with insecticide application. Color sticky spheres are being used in recent years in limited groves only. Preliminary studies have been conducted to discover sex pheromones and citrus plant volatiles for attraction of B. minax.
Food-based lures. Food-based lures are the only type of lures used in the field. The most common food-based lures are hydrolyzed proteins, waste brewer's yeasts, and sugar + vinegar mix [
As mentioned above, Jufengâ fruit fly lure is a commonly used fruit fly lure in China. The efficacy of this product is disputable, based on grower’s experience and the results from the studies cited above. However, one study claimed that 1:2 (Jufengâ lure solution: water) diluted solution of the product had the best B. minax attraction, compared to 2:1 solution, 100% Jufengâ solution, or sugar-vinegar-Chinese liquor mixture [
We conducted a two-year study comparing the performance of nine common tephritid fruit fly lures for B. minax attraction. The study was conducted in four groves across China’s major citrus production region. The preliminary results suggested that two most common parapheromone lures―cuelure and methyl eugenol had no effect on B. minax, and that other food-based lures, ranging from H-protein, and yeast, to sugar-vinegar mixture performed poorly in attracting B. minax (Xia, unpublished data).
| Lure | No. of B. minax (entire season)* |
|---|---|
| 5% H-protein | 82.7 cd |
| 5% Sugar | 76.0 d |
| 5% Sugar + 5% Chinese liquor | 63.6 e |
| 5% Sugar + 5% Vinegar | 77.0 d |
| 5% Sugar + 5% H-protein | 103.0 c |
| 5% Sugar + 5% Orange Juice | 82.3 cd |
| 5% Sugar + 5% Vinegar + 5% Chinese liquor | 90.0 c |
| 5% Vinegar + 5% Chinese liquor + H-protein | 179.7 b |
| 5% Orange + 5% H-protein + 5% Chinese liquor | 273.7 a |
| 5% Sugar + 5% Orange Juice + 5% H-protein | 256.3 a |
| 5% Sugar + 5% Vinegar + 5% Chinese liquor + 5% H-protein | 141.3 bc |
* Statistical significance at P < 0.05.
One small study tried to link trapping efficacy of lures against B. minax to the actual field population [
Color sticky spheres. Color sticky spheres are being increasingly used for B. minax pest management in recent years [
Sex pheromone and citrus plant chemicals. Preliminary work has been carried out in China to discover a female sex pheromone and plant volatiles that might improve lure efficacy. This work is summarized in
Since B. minax is an oligophagous insect, feeding on the fruits of Rutaceae plants only, citrus plant volatiles may play a critical role in B. minax host finding and oviposition behavior. A recently published laboratory study revealed that female adults were attracted to nonanal, citral, limonene and linalool from citrus fruits (
Foliar spraying of insecticide during the early adult stage around late April to May is one of the most common B. minax management options in China. Commonly used insecticides are organophosphates such as trichlorfon and/or pyrethroids such as deltamethrin. These insecticides are usually applied weekly using backpack or small mechanical sprayers. Unfortunately, in spite of the numerous publications on the topic [
| Odor source | Lab Bioassay | Field Evaluation | Ref. | ||
|---|---|---|---|---|---|
| method | response | method | response | ||
| Rectum extract1 | Wind tunnel | Males responded to female’s extracts, not vice versa | Field cage | B. minax flied surrounding the cage, but none inside | [ |
| Filter paper treated with Female rectum extract | EAG & 500 ml Bottle | Males responded to female’s extract | N/A | N/A | [ |
| Rectum extract (4, 10, 15-day-old adults of both sex | EAG | Both males and females responded highly to the 15-day-old fly’s extracts of rectum extracts of the opposite sex and the same sex | Field trap | 15-day-old females rectum extracts had the high attraction to both males and females (see | [ |
| Rectum extracts of mating females and males2 | Y tube | Males shows strong reaction to extracts of females | N/A | N/A | [ |
| Plant volatiles/oils of citrus fruits | Y tube | Females are attracted to nonanal, citral, limonene and linalool | N/A | N/A | [ |
12,6-di-tert-butyl-p-cresol (BHT); 2Undecanol.
| Lure or extracts | Average trapping number | Sex ratio (female/male) |
|---|---|---|
| Female rectum extracts | 40.67 ± 2.21 a | 0.82:1 |
| Male rectum extracts | 5.33 ± 0.80 c | 2.56:1 |
| Hydrolyzed protein | 24.25 ± 1.96 b | 4.71:1 |
| Sugar solution with wine vinegar mixture | 1.00 ± 0.17 c | 3.00:1 |
| Control (n-Hexane) | 0c | - |
*Statistical significance at P < 0.05.
| % fallen fruit due to B. minax | ||||
|---|---|---|---|---|
| SiteTrt | I | II | III | Ave |
| Trichlorfon | 11.0 | 9.0 | 13.0 | 11.0 |
| Fipronil | 4.0 | 2.5 | 3.2 | 3.2 |
| Water | 19.0 | 24.0 | 21.3 | 21.3 |
there was no explanation on the differences such as B. minax population among the three test sites, or statistical analysis of the results.
Sterile insect technique (SIT). Using SIT for managing B. minax was once a national priority project in the late 1980s to the early 1990s. Several sterile insect release studies have been carried out in Guizhou province. These studies were primarily conducted by a team of scientists from the Institute of Nuclear Applications, China Academy of Agricultural Sciences & the Institute of Nuclear Applications, Zhejiang Academy of Agricultural Sciences [
Technical obstacles were the major challenge [
As discussed above, B. minax is not on the list of domestic quarantine pests in China [
So far, study of phytosanitary measures of B. minax has focused primarily on two approaches: irradiation and cold treatment.
The impacts of irradiation on B. minax larvae inside of citrus fruits (a mix of pomelo and sweet orange) have been studied. Zhao et al. [
Although we don’t know precisely how B. minax reacts to cold treatment, there is strong evidence that this pest should be amongst the coldest tolerant Bactrocera species. First, as discussed earlier, the distribution of this species is primarily in the temperate area of south central China; second, several small-scale studies indicate that B. minax can survive freezing temperatures for days. Fan et al. [
In summary, irradiation treatment appears to be a more promising B. minax phytosanitary treatment, compared to the prospect of cold treatment.
Few studies were conducted using heat treatment as an option of B. minax phytosanitary treatment. Liu et al. [
The risk of introducing B. minax into other major citrus production regions of the world rises significantly as China expands its fresh citrus market globally, as well as the exponentially increasing number of travelers from and into China. International collaboration is essential to minimize the risk, and smooth the fresh citrus trade and human traffic. Based on the review above, we identified some critical scientific and technological gaps in preventing the invasion of this destructive pest. These gaps include:
Although a number of phytosanitary treatment studies of B. minax had been conducted in China, these studies were preliminary and small-scale. Among the measures studied, irradiation shows great promise. International collaborative work between China and the potential import countries is critical to validate the efficacy of the treatment, as well as the potential impact on fruit quality. Significant progress has been made in recent years in understanding the efficacy of irradiation against tephritid fruit flies inside fresh fruits, as well as the impact of irradiation on fruit quality [
There are not sufficient data to make a decision regarding a cold treatment schedule suitable for B. minax phytosanitary treatment. As discussed earlier, this species might be among the most cold-tolerant Bactrocera fruit fly.
Heat treatment remains an option. Schedule T106-a-4 (43.3˚C for 6 h) results in 100% mortality for Anastrapha species [
The US citrus industry has faced a series of severe pest invasions in recent years, and the invasion of B. minax would have a devastating impact on the industry. An effective lure is the first necessary tool once an invasion fruit fly occurs. Many of the successful eradications of invasive Bactrocera in the US can be credited to having potent lures which can detect the invasive pest at very low population levels. In the case of B. minax, the role of an effective lure can be more significant in the early response and eradication program, compared to the invasions of other tephritid fruit flies such as B. dorsalis or Ceratitis capitata. SIT can be deployed for eradication of B. dorsalis or C. capitata. However, there is no case of using SIT for the univoltine, oligophagous tephritid fruit flies such as B. minax, primarily due to the challenge in mass rearing these pests.
This review reveals that there is no effective lure for early detection and emergency response. Unless more potent lures are available, the risk of the pest’s ability to spread and establish the US, as well as in world’s other major citrus regions, is substantial.
Since there is no internationally recognized phytosanitary treatment available for B. minax, delimiting B. minax pest free areas can play a critical role in promoting safe trade and safeguarding. B. minax is not reported in four southern citrus provinces in China. However, it is premature to say that these provinces are B. minax pest free areas. Determining B. minax pest free areas can be especially challenging. Trapping for this species is not very effective, so fruit sampling might be necessary to ensure the quality of the survey work. We are not aware that any effort has ever taken in determining B. minax pest free areas in China. This work has to follow an internationally recognized approach such as ISPM No 26 [
Authors wish to thank Drs. Ken Bloem, Karl Suiter, Roger Magarey, Yu Takeuchi, and Ms. Sarah Marnell for technical assistance and/or review this writing. This work is partially funded by USDA―Animal and Plant Health Inspection Service―Plant Protection and Quarantine―Science & Technology.
Xia, Y., Ma, X.L., Hou, B.H. and Ouyang, G.C. (2018) A Review of Bactrocera minax (Diptera: Tephritidae) in China for the Purpose of Safeguarding. Advances in Entomology, 6, 35-61. https://doi.org/10.4236/ae.2018.62005