Pine shoot beetles, Tomicus yunnanensis Kirkendall and Faccoli and Tomicus minor Hartig (Col., Scolytinae), have been causing substantial mortality to Yunnan pine (Pinus yunnanensis Franch) in Yunnan, southwestern China, whereas only a few Armand pine (Pinus armandii Franch) were attacked by the beetles. In order to evaluate the suitability of P. armandii as host material for the two Tomicus, adults of both Tomicus were caged on living branches and felled logs of the two pines during shoot feeding and trunk attack phase, respectively. More beetles survived on the living branches of P. yunnanensis than on P. armandii. Tomicus yunnanensis and T. minor produced similar progeny in the logs of the two pines. The sex ratio and developmental period were not affected by host species, but the brood beetles emerging from Armand pine weighed less than those from Yunnan pine, suggesting that P. armandii are less suitable to be host of T. yunnanensis and T. minor.
1. Introduction
As the most important forest pests in southwestern China, pine shoot beetles, Tomicus yunnanensis Kirkendall and Faccoli and Tomicus minor Hartig (Col., Scolytinae), have killed more than 200 000 ha of Yunnan pine (Pinus yunnanensis Franch) in Yunnan province since early 1980s [1], of which T. yunnanensis is considered as a more serious species [2–4]. Since the morphology and gallery system of T. yunnanensis are very similar to Tomicus piniperda L., T. yunnanensis had long been confused with T. piniperda. Molecular and taxonomic studies have, however, demonstrated that T. piniperda is absent in Yunnan [3, 4]. Thus, the aggressive Tomicus species in Yunnan was a new undescribed species, and consequently T. yunnanensis was finally described and named in 2008 [3].
Like the pine shoot beetles in Europe, the life cycle of T. yunnanensis and T. minor is univoltine and contains two phases, a reproduction phase and a maturation feeding phase [5–7]. In Yunnan, adults of the two Tomicus species mate and lay eggs in the inner bark of trunks and large branches of living trees from November to May [6–8]. Larvae and pupae subsequently complete their development there. After emergence, the young adults fly to the crowns of host pine trees where they feed in the shoots and become sexually mature [2, 5, 9]. The main shoot-feeding phase lasts from May to November in Yunnan [5–7]. However, T. minor usually initiates its flight one or two weeks later than T. yunnanensis [1, 2]. Since T. minor usually attack trees that previously have been attacked by T. yunnanensis, it is regarded as a more secondary species in Yunnan [1–3].
P. yunnanensis and Armand pine (Pinus armandii Franch) are distributed at similar elevations. Armand pine often grows together with P. yunnanensis in Yunnan province, but P. armandii has rarely been attacked by T. piniperda and T. minor [7]. The reason for this is poorly understood, but it would be valuable to know if P. armandii really is more resistant to pine shoot beetle damage. In this study, we compared the suitability of P. armandii and P. yunnanensis for maturation feeding and breeding of the two Tomicus species.
2. Materials and Methods2.1. Origins of Pine Shoot Beetles
The pine shoot beetles were collected from Yunnan pine forests in Yiliang or Shilin County. We recognized the shoots containing maturation feeding beetles by their yellowish needles and then cut off the shoots 5–10 cm below the entrance holes by scissors. The shoots with beetles were collected from the forest a few days before the experiment started, and the beetles were peeled out of the shoots and identified to species under a stereoscope (Nikon SMZ). The Tomicus population in Shilin consisted of mostly T. yunnanensis, but a relatively high proportion of T. minor was found in Yiliang.
2.2. Shoot Cage Experiment
In order to assess the effect of tree species on the maturation feeding of pine shoot beetles, the shoot cage experiment was carried out in a mixed stand of P. yunnanensis and P. armandii in Kunming Tree Garden (25°07′′ N, 103°00′′ E, 1953 m above sea level). Most of the trees there were 4-5 m high and exhibited a healthy appearance. No damage history had been recorded. A total of 18 similar trees (nine P. yunnanensis and nine P. armandii) were selected. For each tree, a mid-crown branch with 20–30 current shoots was enclosed within a 2.0 m × 1.5 m net cage. On July 28, 2000, T. yunnanensis adults (10 beetles/cage) were released in six cages for each host species. T. minor adults were released in three cages for each pine species in the same way on October 24, 2000. The ends of all the cages were closed and fastened by string. On December 25, 2000, all the cages were cut off the trees and taken to the laboratory. The number of attacked shoots in each cage was counted. The numbers of beetles alive, killed by resin, dead from other reasons or missing were recorded. For each attacked shoot, the shoot diameter at entrance hole, the distance from entrance hole to the shoot tip, as well as the length of feeding tunnel (defined as the length from entrance hole to the end of the tunnel) were measured by ruler.
2.3. Breeding Experiments
On December 26, 2000, three P. yunnanensis and three P. armandii trees of similar size were felled in a naturally generated mixed stand in Yiliang County. The lower stem section of each tree was cut into four 50 cm-long logs and placed in 80 × 70 cm net cages. A total of 12 cages were used, six of these each contained two logs of P. yunnanensis or P. armandii, and were divided into two groups, each group containing three P. yunnanensis cages and three P. armandii cages. On December 27, twenty pairs of unsexed T. yunnanensis adults were released to each cage in the first group, and an unsexed mixture of the two Tomicus-species (11 pairs of T. minor and nine pairs of T. yunnanensis) was released to the second group of cages.
After beetles were released, all the logs were checked during the entire experimental period. The new entrance holes were marked and counted twice a week. On Mar. 30, 2001, the new brood adults started emerging. Then the emerging beetles were collected at different intervals ranging from one day to several days. We measured the diameter of each log on April 20. After measurement, we carefully peeled off the outer bark of each log and counted the number of egg galleries constructed by T. yunnanensis and T. minor, respectively. For each egg gallery, we measured gallery length and counted the number of larvae, pupae, and adults remaining in the phloem. The brood production was obtained by summing up the number of emerged adults and brood remaining in the galleries. The brood adults from the second group were identified to species under stereoscope. On April 28, the collected beetles of T. yunnanensis or T. minor were separately dried for each sampling occasion at 60°C for 8 hours, and the dry body weight of the beetles collected at different dates was weighed in 10-beetle samples using an electronic balance.
2.4. Data Analysis
Data were analyzed using the statistics program “StatPac for windows” (StatPac Inc., 1999). All the means were given as mean ± SD (standard deviation) and compared by Student’s t-test. The percentage data was compared by Chi-square test.
3. Results3.1. Maturation Feeding
The status of pine shoot beetles that were caged in the branches of two pine species was identified as alive, killed by resin, dead from other reasons, or missing at the inspection. Although a few beetles of both species survived on both host species (Table 1), the Tomicus species performed differently on the two hosts. The survival rate of both Tomicus species on P. yunnanensis was two-fold higher than on P. armandii. Correspondingly, the mortality of T. yunnanensis and T. minor on P. armandii (63% and 73% resp.) was somewhat higher than on P. yunnanensis (42% and 50% resp.). Significantly more beetles feeding on P. armandii were killed by resin than that feeding on P. yunnanensis (X2= 5.44–9.31, P<0.05). In addition, T. yunnanensis excavated twofold more tunnels on P. yunnanensis than on P. armandii (t=4.45, P<0.01), and the tunnels by both Tomicus species on P. yunnanensis were longer than on P. armandii (t = 4.28–5.61, P<0.01) (Table 2), indicating that the beetles were more adapted to their principal host than to P. armandii in the shoot feeding phase.
The performance of Tomicus yunnanensis and T. minor in the caged shoots of Pinus armandii and P. yunnanensis in Kunming. 60 T. yunnanensis adults were released into the 6 shoot cages on July 28, and 30 T. minor adults were released into 3 cages on October 24, for each tree species. The performances of the beetles were checked on December 25, 2000.
Tomicus species
Pinus species
Number of beetles (percentage)
Total
Alive
Killed by resin
Dead from other reasons
Missing
T. yunnanensis
P. yunnanensis
60
13 (21.7)
1 (1.7)
24 (40.0)
22 (36.6)
P. armandii
60
7 (11.7)
12 (20.0)
26 (43.3)
15 (25.0)
Chi-square analysis of 2 × 4 contingency table
X2 = 12.5, d.f. = 3, P=0.006
T. minor
P. yunnanensis
30
8 (26.7)
1 (3.3)
14 (46.7)
7 (23.3)
P. armandii
30
4 (13.3)
8 (26.7)
14 (46.7)
4 (13.3)
Chi-square analysis of 2 × 4 contingency table
X2 = 7.60, d.f. = 3, P=0.055
Feeding tunnels by Tomicus yunnanensis and T. minor in the caged shoots of Pinus armandii and P. yunnanensis in Kunming. Ten T. yunnanensis adults were released into each cage on July 28, and 10 T. minor adults were released into each cage on October 24. The data were collected on December 25, 2000 and are expressed as means ± 1SD. Means followed by the different letters in a column are significantly different at P<0.05 by t-test.
Tomicus species
Cages
Pinus species
Tunnel no cage−1
Tunnel length (mm) cage−1
T. yunnanensis
6
P. yunnanensis
16.5 ± 3.7 a
24.5 ± 19.5 a
6
P. armandii
7.5 ± 3.3 b
7.9 ± 5.2 b
T. minor
3
P. yunnanensis
12.0 ± 2.0 a
16.1 ± 8.7 a
3
P. armandii
11.0 ± 6.4 a
9.3 ± 3.3 b
3.2. Oviposition and Brood Production
During reproduction phase, the female adults of either T. yunnanensis or T. minor excavated similar numbers of egg galleries in the logs of P. yunnanensis and P. armandii (Table 3). The brood production of the two beetles was also similar in the two hosts. These results suggest that the oviposition and brood production of T. yunnanensis and T. minor do not differ that much in the logs of the two hosts.
Oviposition and brood development of Tomicus yunnanensis and T. minor in the logs of Pinus armandii and P. yunnanensis in laboratory condition, after 11 pairs of T. minor and 9 pairs of T. yunnanensis were introduced to each cage with two logs of P. yunnanensis or P. armandii. Gallery and brood production data were collected from three replicates. Larval tunnel gallery−1 and gallery length were the mean from all the egg galleries appeared in the logs (number in the bracket). Data are expressed as means ± 1SD. Means followed by the different letters in a column are significantly different at P<0.05 by t-test.
Pinus species
Tomicus species
Galleries m−2
Brood production m−2
Larval tunnel gallery−1
Gallery length cm
P. yunnanensis
T. yunnanensis
83.4 ± 12.4 a
1449.9 ± 96.3 a
29.1 ± 6.9 a
6.75 ± 4.2 a (68)
T. minor
36.80 ± 14.6 b
338.6 ± 36.2 b
9.2 ± 3.1 b
6.18 ± 3.59 a (30)
P. armandii
T. yunnanensis
86.8 ± 9.1 a
1693.2 ± 166.7 a
22.4 ± 4.5 a
5.02 ± 2.50 a (68)
T. minor
20.43 ± 7.6 b
268.2 ± 23.2 b
13.1 ± 2.2 b
4.08 ± 1.85 a (16)
Tomicus minor seemed to be in an inferior position in the competition with T. yunnanensis. After the mixture of two beetle species, composed of 55% T. minor and 45% T. yunnanensis, was released in the cages, the resulting egg galleries of T. minor occupied only 24.4% and 19.0% of the total attack density in P. yunnanensis and P. armandii, respectively. Correspondingly, the brood production of T. minor was only 18.9% and 13.7% of the total brood production in P. yunnanensis and P. armandii logs, respectively (Table 3).
3.3. Developmental Period
To investigate the influence of host species on the developmental period of the Tomicus, we estimated the speed of brood development of T. yunnanensis under laboratory conditions by counting the days from median attacking date to the median date of emergence (Table 4). The developmental period of T. yunnanensis was 89 days on P. yunnanensis, and 93 days on P. armandii, demonstrating that the developmental period of T. yunnanensis was nearly similar in the logs of two host species.
Developmental periods of Tomicus yunnanensis in logs of Pinus armandii and P. yunnanensis in laboratory condition. The developmental periods were estimated from the median date of entering (50% entrance holes existed) to the median date of emergence (50% of new generation emerging from brood logs).
Host species
Median date of attack
Median date of emerging
Developmental period, days
P. yunnanensis
Jan. 4
Apr. 3
89
P. armandii
Jan. 8
Apr. 12
93
3.4. Size of Emerging Beetles
In addition to developmental period, we also investigated the effect of host species on the size of emerging beetles, by comparing the dry weight of T. yunnanensis emerging from the logs of the two hosts. The result indicated that T. yunnanensis adults reared on P. yunnanensis were heavier than those reared on P. armandii (data not shown). In addition, the dry weight of T. yunnanensis brood adults was strongly related to the date of emergence. The weights of brood adults bred on both P. yunnanensis and P. armandii decreased with time after the initial brood emergence date, indicating an effect of intraspecific competition or deteriorating food quality (Figure 1).
Mean dry weight of emerging Tomicus yunnanensis reared on Pinus yunnanensis (a) and P. armandii (b) related to days post the initiation of brood adult emergence. Each dot represents the average adult weight for a 10-beetle sample.
4. Discussion
The pine shoot beetles T. piniperda and T. minor have been reported from a large number of pine species and other conifers as well [10], but the principal host for them in Europe is Scots pine (Pinus sylvestris L.). Since the accidental introduction into North America, T. piniperda has been reported from a number of North American pines since the 1990s [11–13]. Experiments in Sweden and France have shown successful development in several exotic pine hosts [14]. Although both T. piniperda and T. minor occur on the exotic host lodgepole pine (Pinus contorta Douglas ex Loudon) in Sweden [15], they perform less well in this host [16].
There is another pine shoot beetle species, Tomicus destruens Woll., in the Mediterranean area which biologically is more similar to T. yunnanensis than T. piniperda [3], and this species did better on local maritime than on boreal pine species in northern Italy [17]. In Portugal, Vasconcelos et al. found different host preferences between local populations of T. piniperda and T. destruens, that is, that northern populations preferred Aleppo pine (Pinus halepensis Miller) whereas southern populations preferred Italian stone pine (Pinus pinea L.) [18].
The shoot cage experiments showed that T. yunnanensis and T. minor are capable of feeding in the shoots of P. armandii, but more beetles died due to resin and other reasons on P. armandii than on P. yunnanensis. The resistance of conifers against invaders is mainly based on their ability to produce resin [19–22]. The resin of P. armandii was more abundant, and its concretionary speed was slower than P. yunnanensis [23]. In addition, the terpene compositions of the two pine species were also different. The shoot piths of P. armandii trees contain a lower proportion of α-pinene but a higher proportion of β-pinene than P. yunnanensis (Borg-Karlson, A.-K., unpublished data). The observation that more beetles were killed by resin on P. armandii might be due to the stronger physical repellency and sticky property of its resin and reflected a higher resistance of P. armandii to pine shoot beetles. In addition, the small shoot diameter of P. armandii might also contribute to high mortality of Tomicus in this pine species during maturation feeding.
The females of the two Tomicus-species accepted P. armandii as brood material, and the brood production of the two species was also similar in the two hosts, indicating that T. yunnanensis and T. minor could reproduce in the logs of P. armandii as well. However, T. yunnanensis oviposited later, and the brood development was somewhat slower on P. armandii than on P. yunnanensis, suggesting that this beetle preferred the last host. Similarly, Långström and Hellqvist found no variation on brood production and adult weight between T. piniperda beetles reared on lodgepole pine and those reared on Scots pine, but the development time of this beetle was longer on P. contorta than on P. sylvestris [16]. Führer and Mühlenbrock demonstrated that six-toothed spruce bark beetle (Pityogenes chalcographus L.) had similar brood production on its principal and secondary conifer hosts [24]. Differently, Cerezke showed that mountain pine beetle (Dendroctonus ponderosae Hopkins) was able to reproduce successfully in some pine species, but with a considerable variation in the brood production [25].
In our experiments the dry weight of T. yunnanensis brood adults emerged from Yunnan pine was higher than of those beetles that emerged from Armand pine. This observation might be due to qualitative differences in nutritional value and/or secondary metabolisms in the two hosts or just simply have resulted from the difference in phloem thickness of the two tree species. A similar pattern was found for the spruce bark beetle (Ips typographus L.) developing on its native host, Norway spruce [Picea abies (L.) Karsten], as compared to beetles emerging from an exotic host, sitka spruce [Picea sitchensis (Bong) Carrière] [26]. Since heavier bark beetles survive better than the lighter ones [27], and the fecundity of female bark beetles is related to the fat reserves available [28, 29], the lower body weight for T. yunnanensis bred from P. armandii could reduce survival of the beetles when they feed in the shoot and lead to less brood production later on. Långström and Hellqvist found that the weights of callow adults bred on both P. contorta and P. sylvestris decreased over the days following the initiation of brood emergence [16]. We found the same pattern in the present experiment, both on P. yunnanensis and P. armandii. This pattern indicates an intraspecific competition and/or a deteriorating food quality.
In conclusion, this study demonstrates that T. yunnanensis and T. minor can feed in the shoots and reproduce in the logs of P. armandii. The performance of the beetle species is, however, somewhat lower in Armand pine than in Yunnan pine, which may explain the beetles’ preference for the latter species. We suggest that a stronger defense in Armand pine may be the cause of this difference, and more experiments on host defenses are needed to assess the risk of T. yunnanensis and T. minor to P. armandii forests.
Acknowledgments
The present study was funded by European Union under its INCO program and the Natural Science Foundation of Yunnan, China. The authors sincerely thank Prof. Lisha Li for all of her support and Mr. Jiang Hu for his skilled assistance during experiments.
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