Temporal Fluctuations in the Population of Citrus Nematode (Tylenchulus semipenetrans) in the Pothowar Region of Pakistan
Temporal Fluctuations in the Population of Citrus Nematode (Tylenchulus semipenetrans) in the Pothowar Region of Pakistan
Muhammad Saeed1,2,*, Tariq Mukhtar1 and Malik Abdul Rehman3
1Department of Plant Pathology, Pir Mehr Ali Shah Arid Agriculture University, Rawalpindi
2Wheat Research Sub-Station, Murree
3Citrus Research Institute, Sargodha
ABSTRACT
The study of the population dynamics of citrus nematode (Tylenchulus semipenetrans) in a production area is required for the assessment of damaging potential of the nematode to citrus, identification of key factors that influence population densities, and to devise effective management strategies. In the present study, seasonal fluctuations in the population densities of T. semipenetrans were studied in two citrus orchards naturally infested with citrus nematode during the year 2014. The effect of soil temperature was also evaluated on the populations of the nematode. The nematode populations differed significantly at both the soil depths. The populations were significantly higher at a depth of 30 cm as compared to 45 cm throughout the year at both the orchards. Similarly, females per gram of roots also followed the same pattern. The number of nematodes in the soil and females in the roots were the higher during the months of April to June and August-September showing two peaks throughout the year. The regression analysis between temperature and number of nematodes in the soil and females in the roots showed highly significant results at both the orchards. A direct relationship was observed between nematode population and temperature. Maximum nematode and female populations were observed at a temperature ranging between 26°C to 29°C at a soil depth of 30 cm. On the other hand, minimum populations were recorded at a temperature range of 9°C to 12°C. Similar trends were observed at the soil depth of 45 cm. It is concluded from the present study that the management of nematode including application of nematicides should be started in the spring season, just prior to the first root flush, to protect the new roots from nematode infection.
Article Information
Received 26 December 2018
Revised 20 February 2019
Accepted 15 March 2019
Available online 28 August 2019
Authors’ Contribution
MS and TM designed the study, conducted the surveys, executed experimental work, analyzed the data and prepared the manuscript. MAR provided technical assistance. TM supervised the work.
Key words
Population dynamics, Seasonal fluctuations, Citrus nematode, Pathogenicity, Pothowar region.
DOI: http://dx.doi.org/10.17582/journal.pjz/2019.51.6.2257.2263
* Corresponding author: [email protected]
0030-9923/2019/0006-2257 $ 9.00/0
Copyright 2019 Zoological Society of Pakistan
INTRODUCTION
Citrus fruit ranks in the second position after grapes in the world production of fruits. About 73 million tons of citrus fruits are produced annually in all parts of the tropical world. Pakistan stands in the top ten citrus producing countries of the world with negligible exports. In Pakistan, citrus is the largest group of fruits produced over an area of 176.4 thousand hectares with an annual production of 1688.7 thousand tons. Botanically, citrus is named for the genus in the family Rutaceae and refers to all edible, rootstock and few ornamental species. Common edible fruits include sweet orange, mandarins, grapefruit, lemons, limes, pomelos while the main rootstock species are rough lemon and sour orange. Citrus is enjoyed primarily as either fresh fruit or in the form of juice.
Citrus is affected by large number of fungi (Fateh et al., 2017), bacteria (Aslam et al., 2017a, b, 2019a), nematodes (Hussain and Mukhtar, 2019; Kayani et al., 2017; 2018, 2019; Kayani and Mukhtar, 2018; Khan et al., 2017; Mukhtar et al., 2017a, b, 2018; Mukhtar, 2018; Tariq-Khan et al., 2017; Mukhtar and Kayani, 2019), mycoplasmas, viruses and viroids (Ashfaq et al., 2017) and insect pests (Javed et al., 2017a, b; Aslam et al., 2019b) which are considered to be the possible causes of citrus decline. Numerous nematode species are associated with the citrus rhizoshpere. To date, however, relatively few have been shown to be of economic importance. With the notable exception of Tylenchulus semipenetrans Cobb, most nematode species capable of damaging mature citrus tend to be regional or local problems, due either to edaphic conditions or to the natural distribution of a particular nematode. Citrus nematode causes slow decline of citrus and an estimated 7% loss of production (Ahmad et al., 2007; Mukhtar et al., 2006, 2007; Irshad et al., 2012). It often passes unnoticed because the above ground symptoms are not very specific or inconspicuous. The nematodes debilitate the plants and predispose them to other problems (Chaudhry et al., 1992). Being a semi-endoparasite, it grows and multiplies slowly and develops high populations which become problematic. Feeder roots are damaged, rotted and destroyed. Affected trees show reduced terminal growth, chlorosis and shedding of terminal leaves, dieback of branches and considerable reduction in number and size of fruits (Chaudhry et al., 1992). Roots show brownish discoloration and unusual adherence of soil particles at the root surface. Heavily infected fresh roots of citrus may harbor over a hundred nematodes per centimeter of root, causing numerous lesions. The uptake of water and minerals from the soil is reduced and secondary invasion of soil fungi such as Fusarium solani and F. oxysporum aggravate disease infestation.
The study of the population dynamics of citrus nematode in a production area is required for the assessment of damaging potential of the nematode to citrus, identification of key factors that influence population densities, and to devise effective management strategies. In the present study, seasonal fluctuations in the population densities of T. semipenetrans were studied in two citrus orchards naturally infested with citrus nematode during the year 2014. The effect of soil temperature was also evaluated on the populations of the nematode.
Table I.- Population dynamics of citrus nematode (Tylenchulus semipenetrans) during the year 2014 at Site 1 (UAAR).
Date of sampling |
Nematodes at soil depth of |
Females at soil depth of |
||
30 cm |
45 cm |
30 cm |
45 cm |
|
1st January |
280 |
195 |
8 |
5 |
16th January |
308 |
185 |
12 |
8 |
1st February |
399 |
265 |
14 |
9 |
16th February |
449 |
285 |
14 |
9 |
1st March |
669 |
443 |
21 |
14 |
16th March |
759 |
485 |
24 |
16 |
1st April |
1289 |
795 |
39 |
25 |
16th April |
1361 |
927 |
45 |
29 |
1st May |
1550 |
996 |
56 |
36 |
16th May |
1800 |
1180 |
56 |
37 |
1st June |
1692 |
1045 |
53 |
34 |
16th June |
1472 |
1011 |
50 |
33 |
1st July |
1401 |
910 |
40 |
26 |
16th July |
1301 |
846 |
44 |
29 |
1st August |
1291 |
820 |
41 |
27 |
16th August |
1191 |
792 |
43 |
28 |
1st September |
1458 |
1099 |
54 |
35 |
16th September |
2024 |
1127 |
58 |
38 |
1st October |
1949 |
500 |
26 |
17 |
16th October |
1433 |
396 |
19 |
12 |
1st November |
711 |
358 |
16 |
10 |
16th November |
301 |
300 |
18 |
12 |
1st December |
284 |
172 |
11 |
7 |
16th December |
218 |
152 |
3 |
2 |
Table II.- Population dynamics of citrus nematode (Tylenchulus semipenetrans) during the year 2014 at Site 2 (Khanpur).
Date of sampling |
Nematodes at soil depth of |
Females at soil depth of |
||
30 cm |
45 cm |
30 cm |
45 cm |
|
1st January |
336 |
212 |
11 |
7 |
16th January |
380 |
238 |
13 |
8 |
1st February |
516 |
324 |
17 |
11 |
16th February |
532 |
336 |
18 |
11 |
1st March |
770 |
484 |
26 |
16 |
16th March |
858 |
540 |
30 |
19 |
1st April |
1450 |
914 |
52 |
33 |
16th April |
1380 |
868 |
51 |
32 |
1st May |
1864 |
1174 |
64 |
40 |
16th May |
1910 |
1204 |
65 |
41 |
1st June |
1916 |
1208 |
68 |
43 |
16th June |
1848 |
1164 |
64 |
40 |
1st July |
1510 |
952 |
50 |
32 |
16th July |
1492 |
940 |
49 |
31 |
1st August |
1632 |
1028 |
56 |
35 |
16th August |
1650 |
1040 |
57 |
36 |
1st September |
1822 |
1148 |
63 |
40 |
16th September |
1942 |
1224 |
65 |
41 |
1st October |
880 |
554 |
31 |
20 |
16th October |
810 |
510 |
29 |
18 |
1st November |
568 |
358 |
21 |
13 |
16th November |
618 |
390 |
22 |
14 |
1st December |
436 |
274 |
16 |
10 |
16th December |
284 |
178 |
11 |
7 |
Materials and Methods
The fluctuations in the populations of citrus nematode in soil and roots were studied in two naturally infested citrus orchards in the Pothowar Region of Pakistan. The orchards were located at the University of Arid Agriculture Rawalpindi and Khanpur which were about 60 kilometers away from each other. The orchards were under cultivation for the last 15 years. Root and soil samples were taken from these two citrus orchards at 15 days interval from January 2014 to December 2014 as described by Iqbal et al. (2014a). Samples were collected from five randomly selected plants from each orchard, each weighing about 1 kg with the help of soil sampler at the depths of 30 and 45 cm from root zone. The samples from each tree were placed in polyethylene bags separately. Samples of feeder roots were also taken. Soil temperature was recorded at the time of sampling. Samples were taken at a distance of 120 cm from the tree trunks. The samples were immediately brought to the laboratory and processed for further evaluation (Iqbal et al., 2004a).
Juveniles of T. semipenetrans were extracted from the soil samples by modified Whitehead and Hemming tray method (Whithead and Hemming, 1965). One gram of fresh feeder roots from each sample was taken out and carefully washed under gentle stream of water to remove soil particles, stained in acid fuchsin lactophenol. The stained roots were macerated in a blender for 30 seconds. The root suspensions were sieved through 100 and 325 mesh sieves into beakers. The materials were then centrifuged to concentrate the females in a volume of 10 ml. The suspensions from each sample were placed in counting dishes and females were counted under stereomicroscope and expressed as number of females per gram of roots (Iqbal et al., 2014a).
The linear relationships between mean monthly number of nematodes in the soil and females per gram of roots and mean monthly temperature were calculated in Microsoft Excel 2007 by taking mean monthly temperature as independent variable (x) and nematode and female numbers as dependent variables (y).
Results
The nematode populations differed significantly at both the soil depths. The populations were significantly higher at a depth of 30 cm as compared to 45 cm throughout the year at both the orchards. Similarly, females per gram of roots also followed the same pattern. The number of nematodes in the soil and females in the roots were the higher during the months of April to June and August, September showing two peaks throughout the year as shown in Tables I and II.
The regression analysis between temperature and number of nematodes in the soil and females in the roots showed highly significant results at both the orchards. A direct relationship was observed between nematode populations and temperature. Maximum nematode and female populations were observed at a temperature ranging between 26°C to 29°C at a soil depth of 30 cm. On the other hand, minimum population was recorded at a temperature range of 9°C to 12°C. Similar trends were observed at the soil depth of 45 cm as shown in Figure 1.
Discussion
Citrus nematode is widespread in the world. Since its first report in roots of citrus trees in California in 1912, its occurrence has been reported from all over the major citrus growing regions of the world. The population density of T. semipenetrans has been reported to fluctuate throughout the year (Sweelam, 1995; Singh, 1999; Sorribas et al., 2000) and often exhibits two distinct periods of growth (Duncan and Noling, 1987; Al-Qasem and Abu-Gharbieh, 1995). O’Bannon et al. (1972) found that peak populations developed during corresponding periods of increased root growth that occurred in April-May and November-December. Infection and subsequent population cycles are restricted to primary roots because citrus nematodes feed only in the cortex of primary roots (Van Gundy and Kirkpatrick, 1964). Vilardebo (1964), Iqbal et al. (2004a) and Al-Azzeh and Gharbieh (2005) also recognized two high and low population periods. Several other investigators observed some seasonal variations (Yokoo, 1964; Prasad and Chawla, 1965); however, Cohn (1966) found no correlation between population fluctuations in Israel. Duncan and Cohn (1990) found that population densities of citrus nematode generally increase in autumn and spring, presumably in response to flushes in the growth of new fibrous roots on which the nematode feeds. Duncan et al. (1993), however, found that root availability did not adequately explain population decline in nematode levels in summer, since root mass density increased by 75% during that period. Amylytic activity in homogenates of the juveniles of T. semipenetrans and reduced starch levels in the nurse cells compared to surrounding cortical cells suggest that starch is a nutrient source for the nematode (Cohn, 1965). Citrus fruits represent a major carbohydrate sink with which the nematode must compete. During summer, available carbohydrates in the roots are relatively low, which can be linked to nematode population decline due to high carbohydrate demand by fruit (Duncan and Eissenstat, 1993). Dry-matter accumulation by fruit is nearly complete by midsummer, coincident with the beginning of nematode population growth (Duncan et al., 1993).
Citrus nematode occurs over a wide range of soil conditions throughout the world. Certain soil factors readily influence infection and reproduction. Van Gundy et al. (1964) found that growth and reproduction of citrus nematodes occurred on citrus seedlings in soils containing 50% clay. The rate of reproduction, however, was significantly lower in soils of 50% clay than in soils containing 5, 15 or 30% clay. Generally, citrus nematode invasion and reproduction is slower in very sandy, coarse-textured soils than in other soil types (Vilardebo, 1963; Van Gundy et al., 1964; O’Bannon, 1968; Baines, 1974; Ahmad et al., 2007; Iqbal et al., 2007). Soils containing organic matter up to 9% favored infection and rapid increase in nematodes that resulted in early damage. Van Gundy (1958) found that organic debris created a thin protective cover over citrus roots that enhanced nematode infectivity. Soil type apparently has little influence on citrus nematode migration. Baines (1974) and Tarjan (1971) found that nematode mobility in various soils was limited. Pandey et al. (2004) observed fluctuation of T. semipenetrans populations at different soil pH levels. Maximum population of male was recorded at pH 7.4-7.6. Female population was the maximum at pH 7.8, and the larval population increased at pH 7.6. Maximum total population of the nematode was observed at pH 7.4-7.8; optimum pH for maximum population (male, female, larva, and total) was 7.6.
Conclusions
It is concluded from the present study that population of citrus nematode showed wide variations throughout the season. The number of nematodes in the soil and females in the roots were the higher during the months of April to June and August to September showing two peaks throughout the year corresponding to the appearance of new flushes. This means that the management of nematode including application of nematicides (Ahmad et al., 2004; Iqbal et al., 2004b, 2005a, b) should be started in the spring season, just prior to the first root flush, and continue during the growing season to protect the new roots from nematode infection.
Statement of conflict of interest
The authors declare no conflict of interest.
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