Geographical Distribution and Long-Term Monitoring of Physokermes hellenicus (Hemiptera: Coccomorpha: Coccidae) on Abies spp. (Pinales: Pinaceae) in Greece
by
, , and
Iosif Papanastasiou
1,2,*
,
Nickolas G. Kavallieratos
1,*
,
Georgios Th. Papadoulis
1,
Christina Emmanouil
3 and
Nikolaos G. Emmanouel
1 1
Laboratory of Agricultural Zoology and Entomology, Department of Crop Science, Agricultural University of Athens, 75 Iera Odos Street, 11855 Athens, Greece
2
Hellenic Agricultural Organization-DEMETER, 56–58 Kourtidou Street and Nirvana Street, 11145 Athens, Greece
3
School of Spatial Planning and Development, Aristotle University of Thessaloniki, University Campus, 54124 Thessaloniki, Greece
*
Authors to whom correspondence should be addressed.
Insects 2021, 12(11), 1001; https://doi.org/10.3390/insects12111001
Submission received: 4 October 2021
/
Revised: 31 October 2021
/
Accepted: 2 November 2021
/
Published: 6 November 2021
(This article belongs to the Collection Biology and Management of Sap-Sucking Pests)
Abstract
:Simple Summary
The scale Physokermes hellenicus (Kozár & Gounari) (Hemiptera: Coccidae) benefits apiculture because it supplies bees with honeydew in Greek fir forests. However, there is limited literature available on its geographical distribution and level of infestation. Thus, in the current study, we investigated these issues in several mountains of Greece. Additionally, P. hellenicus infestation in combination with its natural enemies and honeydew production was monitored for a long period in three (Menalon, Parnis and Tymfristos) highland bee foraging areas. Overall, there was an extensive geographical distribution of the scale, which was negatively correlated with the latitude of the surveyed areas. A decline in P. hellenicus infestation in Menalon resulted in a reduction in honeydew production by this scale.
Abstract
The scale Physokermes hellenicus (Kozár & Gounari) (Hemiptera: Coccidae) has been recently included in the Greek entomofauna as a beneficial honeydew species. However, there are no adequate data about its geographical distribution and degree of infestation. Therefore, a study was conducted to examine these parameters in fifteen mountains of Greece. Furthermore, the monitoring of P. hellenicus infestation was carried out over a six-year period with regard to natural enemies and honeydew presence at three mountains (i.e., Menalon, Parnis and Tymfristos) that are traditional honeybee foraging areas. An extensive geographical distribution of the scale was negatively correlated with the latitude. Over the period of the study, P. hellenicus infestation exhibited a decreasing trend in the three mountains, which was more obvious at Menalon. The abundance of natural enemies of P. hellenicus, their effectiveness on honeydew excretion and the fecundity of P. hellenicus are discussed. The reduction in the honey produced at the Menalon mountain (a protected designation of origin product) could be attributed to the reduced presence of P. hellenicus in the fir forest. Among the other identified arthropods, Dreyfusia nordmannianae Eckstein (Hemiptera: Adelgidae) is reported for the first time infesting Abies cephalonica (Pinales: Pinaceae) in Greece. Furthermore, this species is reported for the first time as a co-parasite with P. hellenicus on A. cephalonica in Greece. Since D. nordmannianae is a serious pest, additional research is needed to determine its status in Greek fir forest ecosystems.
1. Introduction
Over the last two decades, studies on scale insects (Hemiptera: Coccomorpha) of the Mediterranean basin have been intensified with remarkable findings [1,2,3,4,5]. In Greece, a total of 253 scale species have been identified so far [4]. However, many more species are expected to be discovered due to the diverse geographical terrain of Greece [2,4].
Female individuals of soft scale insects of the genus Physokermes (Hemiptera: Coccidae) resemble the axillary undeveloped shoots of plants commonly known as unarmored bud scale insects. They are herbivore oligophagous insects that settle either on foliage or on branches and infest tree species mainly of the genera Abies, Pinus, Picea, Pseudotsuga (Pinales: Pinaceae) and secondarily of the genera Tsuga and Juniperus (Pinales: Pinaceae) [6].
Genus Physokermes includes thirteen species, seven of which occur solely in the Palaearctic, four exclusively in the Nearctic region, one in both the Palaearctic and Nearctic and one species without a host record. Physokermes hemicryphus (Dalman) (Hemiptera: Coccidae) and P. piceae (Schrank) (Hemiptera: Coccidae) are the most cosmopolitan species as they have been recorded in 25 and 26 different countries, respectively [6,7,8,9]. In several countries such as Latvia, Lithuania, Serbia, Sweden and the USA, these insects are considered serious pests causing considerable primary damage on trees (i.e., reduction in shoot and needle growth, chlorosis and falling of leaves, drying of branches, partial or whole plant death). Furthermore, the production of sugary columnar excretions forms an ideal substrate for fungal growth, which can cause severe malfunction of photosynthesis and transpiration, decelerating the growth of infested plants [10,11,12,13,14,15]. Nevertheless, there are no data documenting that Physokermes spp. cause any growth malfunction to Abies spp. in Greece, even though they commonly occur on these tree species.
In contrast, Physokermes spp. constitute beneficial insects and are strongly connected with annual honey production in Greece [16]. Due to the construction of their mouthparts, they suck sap and excrete honeydew, which is used by bees to a large extent. Due to this valuable interaction, there is an increasing interest for data concerning new species of Physokermes, their distribution and natural enemies [9,16].
Hitherto, the studies dealing with the distribution of Physokermes spp. in Greek fir forests include four different species: P. hellenicus (Kozár & Gounari) (Hemiptera: Coccidae), P. hemicryphus, P. inopinatus (Danzig & Kozar) (Hemiptera: Coccidae) and P. piceae. According to Santas [17], P. hemicryphus has an extended distribution outspread in fir forests of Greece. The most frequent hosts are Abies cephalonica (Loudon) (Pinales: Pinaceae) and A. borissi-regis (Mattf.) (Pinales: Pinaceae). The author reported that this scale occurs on the mountains Ainos, Giona, Dirfis, Parnis, Parnon and Tymfristos as well as in the towns of Tripoli, Grevena and Lamia, on ornamental fir trees. Physkermes piceae has been recorded for the first the time by Santas [18], infesting fir trees of the genera Abies on the mountains of Giona and Parnassos. Many years later, the Hungarian spruce scale P. inopinatus was detected for the first time on A. cephalonica in a forest area of the Taygetus mountain (Peloponnese, southern Greece) [19]. Later, the new species P. hellenicus was found infesting A. cephalonica on mountains Ainos, Menalon and Panachaiko [9]. Recently, P. hellenicus was recorded on several mountains, i.e., Dirfys, Helmos, Heliconas, Kaliakouda, Parnis, Parnon, Taygetus, Parnon, Metsovo, Vardousia and Ziria [4,16,20], while P. picea was recorded on the Taygetus mountain [4]. Additionally, the genus Juniperus has been identified as a host plant of P. hellenicus on the Taygetus mountain [4].
In Greece, the honeydew honey from fir forests (Abies spp.) corresponds to 5–10% of the total annual production [9,18,21,22,23]. On the lush slopes of the mountain Menalon (Peloponnesus, southern Greece), honeybees mainly exploit the honeydews of P. hemicryphus in combination with excretions of the Eulecanium sericeum (Lindiger) (Hemiptera: Coccidae) and Mindarus abietinus (Koch) (Hemiptera: Aphididae) that infest native fir trees (A. cephalonica). The result of this interaction is the production of a honeydew honey that exhibits certain physicochemical characteristics [23,24]. This special fir honey, known as “Menalou Vanillia”, is one of the two types of honey that are officially recognized by Greek legislation as a product of protected designation of origin [25]. Its pearl–amber color, thick texture, buttery flavor and mild resinous aroma along with other special physicochemical parameters compose a unique product [23,26] that is highly acceptable by consumers. In the past, beekeepers believed that honey originating from the nectar of flowers is more attractive to consumers than the honey originating from the excreta of insects [27]. Today, this opinion has been altered in favor of honeydew honey instead of blossom honey due to the high antioxidant and antibacterial activity along with the great nutritional value of the former [28].
The occurrence of the recently described P. hellenicus was previously recorded in some locations mainly of southern Greece given with a short description of its biological cycle [4,9]. Later, information for the spectrum of natural enemies of P. hellenicus in Greece was provided [16]. Among Physokermes species, only P. hemicryphus has been studied for a ten-year period by Santas [17]. Based on the recent findings [16], we hypothesized that the presence of P. hellenicus is expanded in a larger geographical part of Greece. Therefore, the objective of the present study was to examine the relation between the infestation degree of fir nodes by P. hellenicus and its geographical distribution in Greece. Moreover, the infestation appearing at traditional honeybee forage areas on certain fir mountains of Greece has been monitored over a six-year period with regard to natural enemies and honeydew flow of P. hellenicus.
2. Materials and Methods
In 2013, an extended field sampling was conducted to detect and confirm the presence of P. hellenicus in the Greek mountains. During the period from April to May, 153 samples were collected from fir (Abies spp.) forests located on fifteen different mountains of northern (Agrafa (5 samples), Ano Vrontous (3 samples), Athamanika (4 samples), Olympus (1 sample), Central Pindos (7 samples)), central (Dirfis (8 samples), Helicon (4 samples), Parnis (12 samples), Tymfristos (26 samples), Vardousia (5 samples)) and southern (Helmos (5 samples), Menalon (40 samples), Parnon (13 samples), Ziria (Killini) (14 samples), Taygetus (6 samples)) Greece (Figure 1). Details of each sampling point are given in Table 1. The selected sampling period is considered to be ideal because the exoskeletons of the collected female adults were not yet sclerotized and their taxonomic characters are sufficiently distinguishable [9]. Each sample consisted of two 4yr. terminal branches (25–30 cm in length) of one fir tree that was collected with a telescopic tree pruner at a height of up to 3 m above the ground. The samples were separately kept inside polypropylene bags, labeled and transferred to the laboratory. Each branch was carefully examined using a Stemi 2000-C (Zeiss, Göttingen, Germany) stereoscope and entomological forceps. When adult females of P. hellenicus were found, the sample was characterized as positive; otherwise it was marked as negative for infestation. In addition, from each positive sample three female adults were stored in 95% ethanol for slide preparations. Slide-mounted specimens were prepared according to a modified method of Ben Dov and Hodgson [29]. The morphological identification was performed with an Axiostar plus trinocular microscope (Zeiss, Göttingen, Germany) at a magnification of 400× by following the key of Kozár et al. [9].
Subsequently, in order to monitor the life cycle of P. hellenicus, a sampling period was conducted at three different mountains from 2013 to 2018 at Parnis and Menalon, while it was conducted at Tymfristos from 2014 to 2018. At Menalon, there were ten sampling points (MO2, MO5, MO8, MO9, MO11, MO14, MO19, MO28, MO29, MO36) ranging in altitude from 947 to 1472 m. At Parnis, there were three sampling points (PA1, PA5, PA7) ranging in altitude from 1163 to 1276 m, and at Tymfristos there were three sampling points (TS24, TS25, TS26) ranging in altitude from 912 to 1267 m. Differences in the number of sampling points among mountains were based on the fact that the sizes of fir vegetation were different (Menalon > Parnis = Tymfristos) These mountains (and their sampling points) were selected on the basis of the following criteria: (i) the presence of P. hellenicus scales; (ii) sampling from a range of different altitudes; (iii) the fact that areas around the sampling sites are representative forage areas for bees in southern and central Greece; (iv) our previous findings [16]. Only Parnis is excluded from the third criterion where honeybee colonies were forbidden temporarily for foraging due to a disastrous fire in 2007. The sampling period was held from January 2013 to December 2018. Samples were collected every 30 days in January, February, March, October, November and December and every 20 days in April, May, June, July, August and September.
The following parameters were recorded during stereoscopical observations in the laboratory: (a) the age and number of nodes of the fir branches; (b) the number of female individuals inside the node, their stage of life cycle, the presence of honeydew (three categories were set to evaluate honeydew quantity: absence of honeydew, one drop of honeydew behind the insect and many drops all over the insect and the node) and the period of honeydew flow; (c) the activity of natural enemies (monitored as suggested by Papanastasiou et al. [16]); (d) the presence/absence of male individuals alive on the foliage. Slide-mounted specimens were prepared and examined microscopically for the study of the life cycle. Finally, any other arthropod was collected for identification. During the survey, images were captured with a Nikon Coolpix 4500 digital camera (Tokyo, Japan).
To study the degree of infestation, the percentage of infestation [I(%)] of each positive sample was calculated on the basis of the formula: Ι(%) = (ΝΙ × 100)/ΝΤ, where ΝΤ is the total number of nodes and ΝΙ is the number of infested nodes with P. hellenicus individuals. To study the role of the latitude and altitude of the sampling point in the preference of the insect, a multiple linear regression analysis for infestation (dependent variable) against the latitude and altitude (independent variables) of sampling points was performed at a level of significance a = 0.05 using the extension XLSTAT Ver. 2021.2 from Microsoft Excel [30]. To study the degree of infestation [I(%)] at the three mountains, i.e., Menalon (6yr.), Parnis (6yr.) and Tymfristos (5yr.), a trend analysis was performed using MS Excel 2010.
To study the activity of natural enemies [E(%)] of the adult females, the percentage [E(%)] was calculated on the basis of the formula E(%) = (FE × 100)/FT. FE is the number of adult females with natural enemies and FT is the total number of adult females. Data on the activity of natural enemies were analyzed by using a two-way AΝOVA with the activity of natural enemies as the dependent variable. Mountain and natural enemies (i.e., parasitoids, predators) were the main effects. Healthy adult female individuals were also considered in the analysis. Means were separated by the Tukey–Kramer honestly significant difference (HSD) test at 0.05 probability [31] using JMP 14 software (SAS Institute Inc. Cary, NC, USA) [32]. Prior to the analysis, data were transformed according to arcsin of square root to normalize variances and standardize means [33]. To study the activity of natural enemies [E(%)] at the three mountains, i.e., Menalon (6yr.), Parnis (6yr.) and Tymfristos (5yr.), a trend analysis was performed using MS Excel 2010.
To study the presence of honeydew of female individuals, the percentage [H(%)] was calculated on the basis of the formula H(%) = (IH × 100)/IT, where IH is the number of female individuals with honeydew and IT is the total number of female individuals. To study the presence of honeydew at the three mountains, i.e., Menalon (6yr.), Parnis (6yr.) and Tymfristos (5yr.), a trend analysis was performed using MS Excel.
3. Results
On the basis of morphological identification [9], only P. hellenicus individuals were detected. The examination revealed 111 positive (72.5%) samples out of 153 samples regarding the presence of P. hellenicus. No infestation was recorded at the sampling points of mountains Athamanika, Ano Vrontous and Pindos (central). Among positive samples, the mean value of the percentage infestation [Ι(%)] ranged from 18% at the mountain Menalon to 2.2% at the mountain Dirfys. The highest and the lowest values (different than zero) were recorded at mountains Parnon (PS12: 57.6%) and Parnis (PA3: 0.8%), respectively (Table 1). The multiple linear regression analysis (Equation model: Infestation = 171.2 − 4.3 × latitude + 0.003 × altitude; R2 = 0.154) showed a statistically significant contribution of latitude (p < 0.0001), while altitude did not show any significance (p = 0.436) (Figure 2A,B).
During the monitoring of P. hellenicus life cycle at the three sampled mountains (Menalon, Parnis, and Tymfristos), the mean number of the examined nodes per year and per sampling point on the mountains Menalon, Parnon and Tymfristos was 746, 755 and 727, respectively. Their age ranged from the current year (0yr. old) up to 4yr. old. The majority of them (42.4%) belonged to the current year nodes followed by the 1yr. old (28%), the 2yr. old (16.8%), 3yr. old (8.8%) and the lowest (4%) to 4yr. old nodes.
The examination of the samples revealed the following stages of P. hellenicus. Inside the nodes: 1st instar larvae-crawlers (L1), 2nd instar female larvae (L2 ♀), 3rd instar female larvae (L3 ♀), transitional stage between 3rd instar female larvae and female adult (L3→adult ♀), female pre-reproductive adult (adult-pre ♀), female reproductive adult (adult ♀), matured eggs (eggs) and dead female adult of previous generation (adult old ♀). At the foliage: 1st instar larva-crawlers (L1), immature stages of male individuals (L2 ♂, prepupae ♂ and pupae ♂), adult male (adult ♂) and empty waxy covers of males (test). Physokermes hellenicus completed one generation per year on all sampled mountains. Hibernation was performed at L3 ♀ and L2 ♂ stages for the female and male individuals, respectively. Almost 70% of female individuals were found inside the current and 1yr. old nodes. Female larvae of the 2nd instar were the most rarely observed among all female developmental stages. The highest total number of female individuals (20,299) was observed at the mountain Menalon and the lower (1799) at mountain Tymfristos (Table 2).
During our study, the infestation [Ι(%)] of P. hellenicus reached very high values, i.e., 100% at Menalon and 95.2% at Parnis (Table 3.). However, when taking into account all the sampling points, the higher mean value of the infestation was observed in 2013 at mountains Parnis (37.8%) and Menalon (30.6%), while in 2015 it was observed at Tymfristos (11.5%).
Interestingly, the infestation exhibited a decrease at Menalon and Tymfristos, reaching 3.8 and 5% in 2018, respectively. The analysis at the three mountains during the sampling period revealed a negative trend according to the estimated equation models in Menalon (infestation = −5.9879 × year + 12083; R2 = 0.9392), Parnis (infestation = −1.8073 × year + 3672.4; R2 = 0.4834) and Tymfristos (infestation = −1.4211 × year + 2873.8; R2 = 0.8179) (Figure 3).
Observations on natural enemies revealed that their activity against female individuals of P. hellenicus was stereoscopically detectable from April to October. Furthermore, several adult ♀ individuals were covered with a grimy dark green to black soot outside, which resembled sooty mold fungus, and they were rotten inside, usually with dead eggs (Figure 4A–C). Although the cause of this situation was not defined, due to the considerable numbers observed, these individuals were counted and classified into an additional group labeled as “undefined”. The percentage of the activity of natural enemies [E(%)] of ♀ adults exhibited mean values that ranged from 10.7% (in 2017) to 55.9% (in 2014) at Menalon, from 33.0% (in 2015) to 55.8% (in 2014) at Parnis and from 23.9% (in 2016) to 33.2% (in 2018) at Tymfristos (Figure 5). The analysis in Menalon during the sampling period revealed a negative trend according to the equation model: activity of natural enemies = −7.2633 × year + 14,672; R2 = 0.5951, while at the other two mountains the patterns were different (Parnis: activity of natural enemies = −0.0604 × year + 163.62; R2 = 0.0002, Tymfristos: activity of natural enemies = −1.7816 × year − 3565.1; R2 = 0.5439) (Figure 5).
All main effects and the associated interactions were significant (Table 4). At Menalon, the parasitoid Pseudorhopus testaceus (Ratzeburg) (Hymenoptera: Encyrtidae) (14.0%), the predators (9.2%) and the “undefined” factor (11.3%) were significantly higher than the parasitoids Anthribus fasciatus Förster (Coleoptera: Anthibidae) (4.6%) and Microterys lunatus (Dalman) (Hymenoptera: Encyrtidae) (3.7%) (Table 5). At Parnis, P. testaceus (17.5%) was significantly higher than the other natural enemies. At Tymfristos, P. testaceus (10.2%) was significantly higher than A. fasciatus (0.5%) and M. lunatus (3.0%). Anthribus fasciatus was significantly lower at Tymfristos (0.5%) than at Parnis (6.4%) and at Menalon (4,6%). In total, the mean activity of natural enemies exhibited higher values at Menalon (42.8%) and Parnis (43.5%) than at Tymfristos (26.1%).
Honeydew production is mainly secreted by adult female individuals (96%), while the remaining (4%) amount is secreted by all the other stages (Table 6). The period of honeydew production lasted for about 14 weeks at Menalon, Parnis and Tymfristos. Initially, females excreted honeydew at low quantities (from 15th to 19th week of the year), which was then followed by an increase and reaching a peak (from 20th to 25th week of the year), and finally there was a decrease gradually to zero (from 26th to 31st week of the year) (Figure 6).
The lowest values of honeydew presence [H(%)] were recorded at Parnis (5.5%) in 2017 and at Menalon (7.5%) and Tymfristos (6.8%) in 2018. The analysis at the three mountains during the sampling period according to the equation models revealed a negative trend in Menalon (honeydew presence = −1.0576 × year + 2144.2; R2 = 0.39) and Timfrystos (honeydew presence = −1.5999 × year + 3239.3; R2 = 0.3956), while in Parnis no trend was observed (honeydew presence = 0.1415 × year − 274.28; R2 = 0.007) (Figure 7).
Natural enemies demonstrated a strongly negative impact on P. hellenicus honeydew production. On all mountains, the examined parasitized ♀ adults were found to produce lower honeydew amounts than the non-parasitized ones. In the case of M. lunatus, the percentage of ♀ adults with honeydew was extremely low (1.06%), while this percentage approached zero when ♀ adults were parasitized by A. fasciatus and the undefined factor. Furthermore, no honeydew was observed in the case of the presence of P. testaceus (Table 4).
Several arthropods were isolated from the collected fir tree samples. Nine of them were identified at species level while eleven were identified at genus level (Table 7). In addition, arthropods of the following orders were found: Diptera (Parnis), Psocoptera (Menalon, Parnis, Tymfristos and Parnon), Hemiptera of the family Ptininae (Parnis), Lepidoptera of the family Tortritidae (Menalon), Pseudoscorpionida (Parnis) and mites of the family Oribatidae (Menalon, Parnis, Tymfristos).
During the current survey, alive individuals of the silver fir wooly adelgid Dreyfusia nordmannianae Eckstein (Hemiptera: Adelgidae) were isolated for first time on A. cephalonica in Greece (Figure 8A,B), occurring in several survey sites of the different mountains (i.e., Menalon: MO8, MO9, MO11, MO14, MO28, MO29 and MO36; Parnis: PA1, PA5 and PA7; and Tymfristos: TS24, TS25 and TS27) and in all sampling years. Sistens were located on young needles and inside the nodes (Figure 8C). Occasionally, adelgid individuals were observed to live together inside the node with P. hellenicus (Figure 8D). Nymphs overwintered either inside fir nodes or in the base of fir needles. When they became mature, they started to deposit brown eggs in groups (Figure 8E,F).
4. Discussion
Our findings indicate that P. hellenicus was not detected only in Ano Vrontous, Athamanika and Pindos (northern Greece) out of the fifteen sampling mountains. Our extensive research in the Greek mountains revealed that in all positive sampling points, among Physokermes species, only P. hellenicus has been identified. This fact confirms the findings of our former study, which was conducted in fewer geographic areas [16]. However, it comes in contrast to the only previous study of Physokermes spp. across Greek mountains [17], where P. hemicryphus was found to be the most widespread species. Further comparison of our results with those of Santas [17] is not possible since no reference to slide-mounted specimens is provided. A newer survey on the scale insect fauna of Greece revealed that P. hemicryphus occurs in two areas of southern Greece, i.e., the mountain Taygetus on Juniperus sp. and Kalamata on Abies sp. [4]. Concerning P. inopinatus, there is only one record from the mountain Taygetus [19], which might be considered as a misidentification taking into account the recent data of the description of P. hellenicus (personal communication with Dr E. Szita). Physokermes picea on Abies sp. corresponds to a single record from mountains Parnassos and Giona in central Greece on fir trees [18] and to a recent record from the mountain Taygetus [4]. Although P. hellenicus is characterized as a Greek endemic species [2], it has also been reported to infest Abies spp. in forest and urban locations of Turkey [34,35,36].
The results of our study indicate a negative significant impact of latitude on the infestation level among the different sampled mountains. This finding could be attributed to the different environmental conditions between northern and southern areas. Indeed, the distribution of scale insects can be affected by climate variables (i.e., temperature seasonality, maximum temperature of the warm period, minimum temperature of the cold period, precipitation), vegetation, the structure of terrain and altitudes [37]. Northern latitudes consequently could adversely affect life stages, especially the crawlers, which are quite sensitive [38]. The highest number of female individuals has been observed on the 1-year-old nodes of the fir samples. More than half of the total number of female individuals has been detected on the current and 1-year-old nodes. Crawlers move robustly and settle towards the preferred feeding sites on young vegetation that has fully developed before the dispersal period [39]. Among female stages, the most rarely observed is the 2nd instar female larva. A similar observation has also been recorded in Ankara (Turkey) [35].
The fecundity of P. hellenicus exhibits variable ranging patterns as it has been previously reported from Greece, i.e., 100 to 230 eggs [9], and Turkey, i.e., 41 to 273 eggs [35]. However, there is no reference whether fecundity is affected by the activity of natural enemies. In a previous study, Papanastasiou et al. [16] documented that P. testaceus and A. fasciatus are able to suppress the reproductive potential of P. hellenicus in Greece. Moreover, the introduction of the relative species Anthribus nebulosus Förster (Coleoptera: Anthribidae) in Virginia (USA) caused a reduction in the populations of P. inopinatus and P. piceae [40]. In the present study, P. testaceus appeared to be the most abundant natural enemy of P. hellenicus in Greece, as reported in our previous study [16]. Additionally, P. testaceus constitutes an important natural enemy of other Physokermes species such as P. hemicryphus in Greece and Serbia [15,17] and P. piceae in Serbia [12,41]. Recently, a trophic interaction among P. hemicryphus, P. testaceus and A. nebulosus has been described in Serbia [41], a relation that should be also investigated in the case of P. hellenicus.
As it is indicated from the trend analysis, a gradual decrease in the infestation of fir nodes by P. hellenicus was recorded on Menalon. A similar reduction had been observed on Parnis until 2016, followed by a small increase over the next two years. At these two mountains, the maximum activity of natural enemies on female individuals in 2014 reached 56% of P. hellenicus individuals. On Tymfristos, the infestation exhibited a mild reduction from 2015 to 2018, where the activity of natural enemies did not exceed 34% of P. hellenicus individuals. Parasitoids, predators and entomopathogenic fungi in combination with abiotic (climatic) conditions are crucial factors that can regulate soft scale populations [42,43]. Although in the present study no climatic data were collected, it seems that the synthesis of the spectrum of natural enemies led to an essential decrease in the numbers of P. hellenicus in the investigated areas, especially on the mountain Menalon. A similar reduction in the population of P. hemicryphus was recorded due to the activity of natural enemies during an 8-year monitoring period in Greek mountains [17].
Scale insects can cohabit with microorganisms such as bacteria and fungi that improve their metabolic capacities, cover their certain diet requirements and make them resistant against life stresses, i.e., insect foes, toxic plant compounds and high temperatures [44]. Nevertheless, there are microorganisms, such as fungi, that can be lethal since they cause dramatic changes to the microbiota of scales [45]. In the present study, numerous adult female individuals of P. hellenicus (categorized as undefined) were found dead and partially covered by a dark green (fungus-like) microorganism, as in the case of wax scale insect Ericerus pela (Chavannes) (Hemiptera: Coccidae) [45]. Further studies are necessary to clarify the cause of this important finding, which could be useful for the improvement of our knowledge on natural enemies and their interactions as well as for the development of biological control programs against scale insects.
For a prolific honeydew flow, which can vary from year to year, a large population of the involved insects is needed [46]. Apparently, the vitality and the abundance of P. hellenicus are important for the presence of honeydew. The majority of the adult females of P. hellenicus infested by natural enemies were unable to produce honeydew drops, with the exception of those that were infested by M. lunatus [16]. Our results showed a reduction in the honeydew presence that may be attributed to the activity of natural enemies. Although these results can support the low formation of the fir honey “Menalou Vanillia” in the last few years in Greece [16], further investigation is considered necessary to clarify this issue. The main species that interfered with the production of this special type of honeydew honey is P. hellenicus rather than the relative P. hemicryphus, as was previously thought [9,17,22,23,24]. The lower P. hellenicus infestation of fir trees on the mountain Tymfristos suggests their limited contribution to the production of fir honeydew honey in central Greece. Furthermore, the detection of other important honeydew insects, such as E. sericeum, Cinara pectinatae (Nördl.) (Hemiptera: Aphididae), Marchalina hellenica (Gennadius) (Hemiptera: Margarodidae) and M. abietinus, in Greek mountains indicates their involvement in the production of fir honey, but without their contribution being known due to the lack of available published data. Interestingly, the insects related to honeydew honey can leave their genetic fingerprints inside honey [47]. Moreover, certain sugars, amino acids and inorganic ions contained in honey can be suitable markers for distinguishing the honeydew honeys derived from botanical (involving plants) and zoological (involving honeydew insects) origins [48]. Combined analyses of the DNA of honeydew insects that is included in various types of honey with the chemical composition of these types may assist in shedding light on their authentication credits.
Unlike many European countries, there are no published studies available regarding the potential adverse effects on the growth and health of fir trees infested by honeydew scale insects in forest areas of Greece. It seems that their natural enemies exert efficient pressure and maintain their population at a non-devastating level. Apparently, fir trees exist in harmony with Physokermes spp. in Greek forests, an issue that contributes significantly to the nutrition of honeybees.
One other outcome of our study that is worth noting was the identification of D. nordmannianae for first time on A. cephalonica at several sampling points. This record provides evidence of a possible extended distribution of D. nordmannianae in Greek mountains, but its population density still remains unknown. As far as we know, the distribution of D. nordmannianae covers areas from 52° N in the north (Poland) to 40° N in the south (northern border of Greece) and from 5° E in the west (western Alps) to 27° E in the east (Romania, Bulgaria) [49]. This tiny cryptic aphid is a serious pest of the Nordmann fir Abies nordmanniana (Steven) Spach (Pinales: Pinaceae), which is the main cultivated tree for Christmas in Central and Northern Europe [50], leading to severe losses in plantations [51,52,53]. Usually, D. nordmannianae infestation causes disorders in the whole plant, especially in stems and leaves [49]. The fact that D. nordmannianae has no parasitoids in nature [50] should not be overlooked since an outbreak may alter the balance of forest ecosystems in the Greek mountains.
5. Conclusions
To conclude, the results of this study revealed that the scale P. hellenicus is the most widespread among Physokermes species found on fir forests in Greece. Based on this exhaustive investigation at several mountains of southern, central and northern Greece, it becomes evident that climate differences associated with latitude have a significant negative effect on the infestation of fir nodes by P. hellenicus. Among the observed natural enemies, the polyembryonic wasp P. testaceus was the most abundant in Greece. Additionally, numerous adult female individuals of P. hellenicus with dead eggs covered with a fungus-like microorganism have been described for the first time. Further research is needed to enrich our knowledge on natural enemies. Furthermore, the aphid D. nordmannianae has been reported for the first time in Greece co-parasitizing A. cephalonica with P. hellenicus. As D. nordmannianae is a serious pest of fir trees, additional research is needed to determine its population density on Greek fir forest ecosystems. Our results suggest that the reduction in the protected designation of origin honey produced in Menalon could be attributed to the low observed P. hellenicus infestation of fir trees in that area.
Author Contributions
Designed research, I.P.; methodology, I.P. and N.G.E.; data curation, I.P.; formal analysis, I.P. and N.G.K.; performed research, I.P.; writing—review and editing, I.P., N.G.K., G.T.P., C.E. and N.G.E.; supervision, N.G.E.; funding acquisition, I.P. and N.G.E. All authors have read and agreed to the published version of the manuscript.
Funding
This study was partially funded in the frame of the project “Genetic identification of honeydew insects’ populations” (Regulation (EU) No 1308/2013) (Ministry of Rural Development and Food of the Hellenic Republic).
Institutional Review Board Statement
Not applicable.
Informed Consent Statement
Not applicable.
Data Availability Statement
Data are contained within the article.
Acknowledgments
We thank Eva Szita, Academy of Science, Plant Protection Institute, Budapest, Hungary, for the verification of the identification of slide-mounted specimens of P. hellenicus samples and Jan Havelka, Institute of Entomology, Biology Centre CAS, České Budĕjovice, Czech Republic, for the identification of the slide-mounted specimens of D. nordmannianae.
Conflicts of Interest
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
References
- Milonas, P.; Kozar, F.; Kontodimas, D. List of scale insects of Greece. In Proceedings of the XI International Symposium on Scale Insect Studies, Lisbon, Portugal, 24–27 September 2007; Branco, M., Franco, J.C., Hodgson, C.J., Eds.; Oeiras ISA Press: Lisbon, Portugal; pp. 143–147. [Google Scholar]
- Pellizzari, G.; Chadzidimitriou, E.; Milonas, P.; Stathas, G.J.; Kozár, F. Check list and zoogeographic analysis of the scale insect fauna (Hemiptera: Coccomorpha) of Greece. Zootaxa 2015, 4012, 57–77. [Google Scholar] [CrossRef] [PubMed]
- Kaydan, M.B.; Benedicty, Z.K.; Kiss, B.; Szita, É. A survey of scale insects in soil samples from Europe (Hemiptera: Coccomorpha). Zookeys 2016, 565, 1–28. [Google Scholar]
- Szita, É.; Fetykó, K.G.; Benedicty, Z.K.; Kozár, F.; Partsinevelos, G.; Milonas, P.; Kaydan, M.B. Data on the scale insect (Hemiptera: Coccomorpha) fauna of Greece, with description of two new species. Zootaxa 2017, 4329, 463–476. [Google Scholar] [CrossRef]
- Porcelli, F.; Pellizzari, G. New data on the distribution of scale insects (Hemiptera: Coccomorpha). Bull. Soc. Entomol. Fr. 2019, 124, 183–188. [Google Scholar] [CrossRef]
- García Morales, M.; Denno, B.D.; Miller, D.R.; Miller, G.L.; Ben Dov, Y.; Hardy, N.B. ScaleNet: A Literature-Based Model of Scale Insect Biology and Systematics. Database. Available online: http://www.scalenet.info (accessed on 20 August 2021).
- Gill, R.J. The Scale Insects of California: Part 1. The Soft Scales (Homoptera: Coccoidea: Coccidae); California Department of Food and Agriculture: Sacramento, CA, USA, 1988. [Google Scholar]
- Kozár, F.; Ben Dov, Y. Zoogeographical Considerations and Status of Knowledge of the Family. In Soft Scale Insects: Their Biology, Natural Enemies and Control. World Crop Pests, 7A; Ben Dov, Y., Hodgson, C.J., Eds.; Elsevier: Amsterdam, The Netherlands, 1997; pp. 213–228. [Google Scholar]
- Kozár, F.; Gounari, S.; Hodgson, C.; Fetyk, K.; Goras, G. A new species of Physokermes Targioni Tozzetti (Hemiptera: Coccoidea: Coccidae) from Greece. Zootaxa 2012, 3566, 23–38. [Google Scholar]
- Furniss, M.M. Observations on an introduced bud scale, Physokermes hemicryphus (Homoptera: Coccidae), infesting Norway spruce in Idaho. Can. J. For. Res. 2004, 34, 1348–1352. [Google Scholar] [CrossRef]
- Gertsson, C.; Isacsson, G. Gransköldlöss (Hemiptera: Coccoidea, genus Physokermes) in south Sweden. Entomol. Tidskr. 2012, 133, 121–128. [Google Scholar]
- Graora, D.; Spasić, R.; Mihajlović, L. Bionomy of spruce bud scale, Physokermes piceae (Schrank) (Hemiptera: Coccidae) in the Belgrade area, Serbia. Arch. Biol. Sci. 2012, 64, 337–343. [Google Scholar] [CrossRef]
- Miezite, O.; Okmanis, M.; Indriksons, A. Assessment of sanitary conditions in stands of Norway spruce (Picea abies Karst.) damaged by spruce bud scale (Physokermes piceae Schrnk.). iForest. 2013, 6, 73–78. [Google Scholar] [CrossRef]
- Gedminas, A.; Lynikienè, J.; Marciulynas, A.; Povilaitienè, A. Effect of Physokermes piceae Schrank. on shoot and needle growth in Norway spruce stands in Lithuania. Balt. For. 2015, 21, 162–169. [Google Scholar]
- Simonović, M.; Dervišević, M.; Graora, D. Bionomy of small spruce bud scale, Physokermes hemicryphus (Dalman) (Hemiptera: Coccidae) in Serbia. Pestic. Phytomed. 2018, 33, 89–96. [Google Scholar] [CrossRef] [Green Version]
- Papanastasiou, I.; Kavallieratos, N.G.; Saitanis, C.J.; Chatzaki, M.; Papadoulis, G.T.; Emmanouel, N.G. Parasitoids and predators of Physokermes hellenicus (Hemiptera: Coccomorpha: Coccidae) in Greece. J. Econ. Entomol. 2018, 111, 1121–1130. [Google Scholar] [CrossRef] [PubMed]
- Santas, L.A. Physokermes hemicryphus (Dalman) a fir scale insect useful to apiculture in Greece. Entomol. Hell. 1988, 6, 11–21. [Google Scholar] [CrossRef] [Green Version]
- Santas, L.A. Species of honeydew producing insects useful to apicu1ture in Greece. Entomol. Hell. 1989, 7, 47–48. [Google Scholar] [CrossRef] [Green Version]
- Stathas, G.J.; Kozár, F. First record of Physokermes inopinatus Danzig & Kozár 1973 (Hemiptera: Coccidae) in Greece. Hell. Plant Prot. J. 2010, 3, 7–8. [Google Scholar]
- Papanastasiou, I.; Evangelou, V.; Papoutsis, L.; Bouga, M.; Emmanouil, N. Molecular taxonomy of the genus Physokermes (Hemiptera: Coccidae) species in Greece, based on mtDNA sequencing data. J. Apic. Res. 2018, 57, 479–483. [Google Scholar] [CrossRef]
- Thrasyvoulou, A.; Manikis, J. Some physicochemical and microscopic characteristics of Greek unifloral honeys. Apidologie 1995, 26, 441–452. [Google Scholar] [CrossRef] [Green Version]
- Bacandritsos, N.; Sabatini, A.G.; Papanastasiou, I.; Saitanis, C. Physico-chemical characteristics of Greek fir honeydew honey from Marchalina hellenica (Gen.) in comparison to other Mediterranean honeydew honeys. Ital. J. Food Sci. 2006, 18, 21–31. [Google Scholar]
- Manikis, I.; Vartani, S.; Dimou, M.; Thrasyvoulou, A. Sugar analysis of “Menalou vanilia” fir honey. Artic. J. ApiProd. ApiMed. 2011, 3, 101–103. [Google Scholar] [CrossRef]
- Santas, L.A. Insects producing honeydew exploited by bees in Greece. Apidologie 1983, 14, 93–103. [Google Scholar] [CrossRef] [Green Version]
- Hellenic Ministry of Agriculture Acknowledgment of protection of the product with the name of origin “Honey Fir-Menalon-Vanilia” Origin from the mountain Menalon. Hell. Government Gazette 1994, B, 10.
- Pita Calvo, C.; Vázquez, M. Differences between honeydew and blossom honeys: A review. Trends Food Sci. Technol. 2017, 59, 79–87. [Google Scholar] [CrossRef]
- Kunkel, H. Scale insect honeydew as forage for honey production. In Soft Scale Insects: Their Biology, Natural Enemies and Control. World Crop Pests, 7A; Ben Dov, Y., Hodgson, C.J., Eds.; Elsevier: Amsterdam, The Netherlands, 1997; pp. 291–302. [Google Scholar]
- Pita Calvo, C.; Vázquez, M. Honeydew honeys: A review on the characterization and authentication of botanical and geographical origins. J. Agric. Food Chem. 2018, 66, 2523–2537. [Google Scholar] [CrossRef]
- Ben Dov, Y.; Hodgson, C.J. Collecting and mounting. In Soft Scale Insects: Their Biology, Natural Enemies and Control. World Crop Pests, 7A; Ben Dov, Y., Hodgson, C.J., Eds.; Elsevier: Amsterdam, The Netherlands, 1997; pp. 389–395. [Google Scholar]
- Addinsoft XLSTAT Statistical and Data Analysis Solution. Long Island, NY, USA. Available online: https://www.xlstat.com/en/ (accessed on 15 June 2021).
- Sokal, R.R.; Rohlf, F.J. Biometry; Freeman and Company: New York, NY, USA, 1995. [Google Scholar]
- SAS Institute Inc. Using JMP 14; SAS Institute Inc.: Cary, NC, USA, 2018. [Google Scholar]
- Zar, J.H. Biostatistical Analysis; Pearson Upper: Saddle River, NJ, USA, 2010. [Google Scholar]
- Ülgentürk, S.; Dokuyucu, Ö. Pest species of Coccoidea (Hemiptera: Coccomorpha) in forest of Turkey. Turk. J. For. 2019, 20, 482–491. [Google Scholar] [CrossRef]
- Ülgentürk, S. Biology, natural enemies and the distribution of Physokermes hellenicus Kozàr & Gounari (Hemiptera: Coccidae) in Turkey. Entomologica 2018, 47, 71–75. [Google Scholar]
- Ülgentürk, S.; Cosic, B.; Özdemir, I.; İpek, A.; Sorkun, K. Honeydew producing insects in some forests of Turkey and their potential to produce of honeydew honey. Balt. For. 2020, 26, 397. [Google Scholar] [CrossRef]
- Wei, J.; Niu, M.; Feng, J. Diversity and distribution patterns of scale insects in China. Ann. Entomol. Soc. Am. 2016, 109, 405–414. [Google Scholar] [CrossRef]
- Marotta, S. General life history. In Soft Scale Insects: Their Biology, Natural Enemies and Control. World Crop Pests, 7A; Ben Dov, Y., Hodgson, C.J., Eds.; Elsevier: Amsterdam, The Netherlands, 1997; pp. 251–256. [Google Scholar]
- Greathead, D.J. Crawler behaviour and dispersal. In Soft Scale Insects: Their Biology, Natural Enemies and Control. World Crop Pests, 7A; Ben Dov, Y., Hodgson, C.J., Eds.; Elsevier: Amsterdam, The Netherlands, 1997; pp. 339–342. [Google Scholar]
- Kosztarab, M.; Kozar, F. Introduction of Anthribus nebulosus (Coleoptera: Anthribidae) in Virginia for control of scale insects: A review. Va. J. Sci. 1983, 34, 223–236. [Google Scholar]
- Dervišević, M.; Stojanović, A.; Simonović, M.; Graora, D. First report of tritrophic relationships among soft scale Physokermes hemicryphus (Dalman, 1826) (Hemiptera), polyembryonic parasitoid Pseudorhopus testaceus (Ratzeburg, 1848) (Hymenoptera) and the predator Anthribus nebulosus Forster. Acta Zool. Bulg. 2019, 71, 305–307. [Google Scholar]
- Rosado, J.F.; Bacci, L.; Martins, J.C.; Silva, G.A.; Gontijo, L.M.; Picanço, M.C. Natural biological control of green scale (Hemiptera: Coccidae): A field life-table study. Biocontrol Sci. Technol. 2014, 24, 190–202. [Google Scholar] [CrossRef]
- Rodrigues Silva, N.; de Oliveira Campos, S.; de Sá Farias, E.; de Souza, T.C.; Martins, J.C.; Picanço, M.C. Relative importance of natural enemies and abiotic factors as sources of regulation of mealybugs (Hemiptera: Pseudococcidae) in Brazilian coffee plantations. Ann. Appl. Biol. 2017, 171, 303–315. [Google Scholar] [CrossRef]
- Rosenblueth, M.; Martínez Romero, J.; Tabita Ramírez Puebla, S.; Vera Ponce de León, A.; Rosas Pérez, T.; Bustamante Brito, R.; Rincón Rosales, R.; Martínez Romero, E. Endosymbiotic microorganisms of scale insects. TIP Rev. Espec. Cienc. Quim. Biol. 2018, 21, 53–69. [Google Scholar]
- Sun, T.; Wang, X.Q.; Zhao, Z.L.; Yu, S.H.; Yang, P.; Chen, X.M. A Lethal fungus infects the Chinese white wax scale insect and causes dramatic changes in the host microbiota. Sci. Rep. 2018, 8, 5324. [Google Scholar] [CrossRef] [PubMed]
- Crane, E.; Walker, P. Important honeydew sources and their honeys. Bee World 1985, 66, 105–112. [Google Scholar] [CrossRef]
- Utzeri, V.J.; Schiavo, G.; Ribani, A.; Tinarelli, S.; Bertolini, F.; Bovo, S.; Fontanesi, L. Entomological signatures in honey: An environmental DNA metabarcoding approach can disclose information on plant-sucking insects in agricultural and forest landscapes. Sci. Rep. 2018, 8, 9996. [Google Scholar] [CrossRef] [Green Version]
- Shaaban, B.; Seeburger, V.; Schroeder, A.; Lohaus, G. Suitability of sugar, amino acid, and inorganic ion compositions to distinguish fir and spruce honey. Eur. Food Res. Technol. 2021, 247, 879–888. [Google Scholar] [CrossRef]
- CABI. Dreyfusia nordmannianae (silver fir adelges). In Invasive Species Compendium; CAB International: Wallingford, UK; Available online: http://www.cabi.org/isc (accessed on 15 August 2021).
- Ravn, H.P.; Havill, N.P.; Akbulut, S.; Foottit, R.G.; Serin, M.; Erdem, M.; Mutun, S.; Kenis, M. Dreyfusia nordmannianae in Northern and Central Europe: Potential for biological control and comments on its taxonomy. J. Appl. Entomol. 2013, 137, 401–417. [Google Scholar] [CrossRef]
- Jacobsen, F. Juletræer og klippegrønt (Christmas trees and greenery). In Skoven og dens Dyrkning, Dansk Skovforening; Henriksen, H.A., Ed.; Ny Nordisk Forlag Arnold Busk: Copenhagen, Denmark, 1988; pp. 607–636. [Google Scholar]
- Larsen, J.B.; Nielsen, U.B.; Møller, I.S. Nordmannsgran-proveniensvariation, forædling og frøkildevalg. Dan. Skovbr. Tidsskr. 1997, 82, 203–2013. [Google Scholar]
- Xu, J.; Budde, K.B.; Hansen, O.K.; Thomsen, I.M.; Ravn, H.P.; Nielsen, U.B. Do silver fir woolly adelgids (Dreyfusia nordmannianae) facilitate pathogen infestation with Neonectria neomacrospora on Christmas trees (Abies nordmanniana)? For. Ecol. Manag. 2018, 424, 396–405. [Google Scholar] [CrossRef]
Figure 1.
Map of Greece with the sampled mountains: Agrafa—1, Ano Vrontous—2, Athamanika—3, Dirfis—4, Helicon—5, Helmos—6, Menalon—7, Olympus—8, Parnis—9, Parnon—10, Pindos (central)—11, Taygetus—12, Tymfristos—13, Vardousia—14 and Ziria (Killini)—15.
Figure 1.
Map of Greece with the sampled mountains: Agrafa—1, Ano Vrontous—2, Athamanika—3, Dirfis—4, Helicon—5, Helmos—6, Menalon—7, Olympus—8, Parnis—9, Parnon—10, Pindos (central)—11, Taygetus—12, Tymfristos—13, Vardousia—14 and Ziria (Killini)—15.
Figure 2.
Percentage infestation [I(%)] of fir tree (Abies spp.) samples by P. hellenicus, per sampled mountain, against latitude (A) and altitude (B) of sampling points at different mountains of Greece.
Figure 2.
Percentage infestation [I(%)] of fir tree (Abies spp.) samples by P. hellenicus, per sampled mountain, against latitude (A) and altitude (B) of sampling points at different mountains of Greece.
Figure 3.
Percentage infestation [I(%)] (mean ± SE) of Abies spp. nodes by P. hellenicus during the sampling period 2013–2018 at Menalon and Parnis and 2014–2018 at Tymfristos. Red, blue and green lines indicate the trends of mean values of Menalon, Parnis and Tymfristos, respectively.
Figure 3.
Percentage infestation [I(%)] (mean ± SE) of Abies spp. nodes by P. hellenicus during the sampling period 2013–2018 at Menalon and Parnis and 2014–2018 at Tymfristos. Red, blue and green lines indicate the trends of mean values of Menalon, Parnis and Tymfristos, respectively.
Figure 4.
Dead-rotten adult female P. hellenicus with fungus on its surface: (A) dorsal view, (B) ventral view and (C) dead eggs of P. hellenicus inside the dead body of P. hellenicus.
Figure 4.
Dead-rotten adult female P. hellenicus with fungus on its surface: (A) dorsal view, (B) ventral view and (C) dead eggs of P. hellenicus inside the dead body of P. hellenicus.
Figure 5.
Activity of natural enemies [E(%)] (mean ± SE) of adult females of P. hellenicus during the sampling period 2013–2018 at Menalon and Parnis and 2014–2018 at Tymfristos. Red, blue and green lines indicate the trends of mean values of Menalon, Parnis and Tymfristos, respectively.
Figure 5.
Activity of natural enemies [E(%)] (mean ± SE) of adult females of P. hellenicus during the sampling period 2013–2018 at Menalon and Parnis and 2014–2018 at Tymfristos. Red, blue and green lines indicate the trends of mean values of Menalon, Parnis and Tymfristos, respectively.
Figure 6.
Mean value of the alive female adults of P. hellenicus inside nodes of Abies spp. during the entire sampling period at Menalon, Parnis and Tymfristos per week of the year and per amount of honeydew (* = one drop of honeydew behind the insect, ** = many drops diffusible all over the insect).
Figure 6.
Mean value of the alive female adults of P. hellenicus inside nodes of Abies spp. during the entire sampling period at Menalon, Parnis and Tymfristos per week of the year and per amount of honeydew (* = one drop of honeydew behind the insect, ** = many drops diffusible all over the insect).
Figure 7.
Percentage of honeydew presence [H(%)] of P. hellenicus female individuals during the sampling period 2013–2018 at Menalon and Parnis and 2014–2018 at Tymfristos. Red, blue and green lines indicate the trends of mean values of Menalon, Parnis and Tymfristos, respectively.
Figure 7.
Percentage of honeydew presence [H(%)] of P. hellenicus female individuals during the sampling period 2013–2018 at Menalon and Parnis and 2014–2018 at Tymfristos. Red, blue and green lines indicate the trends of mean values of Menalon, Parnis and Tymfristos, respectively.
Figure 8.
(A) Slide-mounted specimen of the 1st instar larva of the neosisten of D. nordmannianae, (B) slide-mounted specimen of mature larva of D. nordmannianae, (C) first instar larva of the overwintering neosisten of D. nordmannianae, (D) living mature larva of D. nordmannianae and P. hellenicus inside the node of Abies spp., (E) and (F) living mature larva of D. nordmannianae deposits clusters of brownish-orange eggs.
Figure 8.
(A) Slide-mounted specimen of the 1st instar larva of the neosisten of D. nordmannianae, (B) slide-mounted specimen of mature larva of D. nordmannianae, (C) first instar larva of the overwintering neosisten of D. nordmannianae, (D) living mature larva of D. nordmannianae and P. hellenicus inside the node of Abies spp., (E) and (F) living mature larva of D. nordmannianae deposits clusters of brownish-orange eggs.
Table 1.
Coordinates of sampling points and percentage infestation [I(%)] of Abies spp. samples by P. hellenicus.
Table 1.
Coordinates of sampling points and percentage infestation [I(%)] of Abies spp. samples by P. hellenicus.
| Sampled Mountain | Sampling Code | Latitude | Longitude | Altitude (m) | Infestation (%) |
|---|---|---|---|---|---|
| 1. Agrafa | AG1 | N 39°04′04.2″ | E 021°32′50.7″ | 1145 | 1.3 |
| AG2 | N 39°06′06.4″ | E 021°36′40.7″ | 715 | 7.2 | |
| AG3 | N 39°08′47.1″ | E 021°36′48.8″ | 856 | 14.9 | |
| AG4 | N 39°07′50.3″ | E 021°38′40.1″ | 879 | 4.3 | |
| AG5 | N 39°08′13.9″ | E 021°40′13.3″ | 1371 | 2.3 | |
| 2. Ano Vrontous | VS1 | N 41°16′32.4″ | E 023°38′55.9″ | 1307 | 0 |
| VS2 | N 41°15′56.8″ | E 023°39′18.7″ | 1318 | 0 | |
| VS3 | N 41°15′33.7″ | E 023°39′11.8″ | 1295 | 0 | |
| 3. Athamanika | AA1 | N 39°35′01.1″ | E 021°02′30.4″ | 959 | 0 |
| AA2 | N 39°34′58.4″ | E 021°02′06.3″ | 975 | 0 | |
| AA3 | N 39°34′56.6″ | E 021°01′47.4″ | 998 | 0 | |
| AA4 | N 39°34′52.2″ | E 021°01′18.2″ | 1088 | 0 | |
| 4. Dirfis | DS1 | N 38°36′03.3″ | E 023°51′09.7″ | 874 | 0 |
| DS2 | N 38°36′01.9″ | E 023°51′41.9″ | 940 | 0 | |
| DS3 | N 38°35′55.0″ | E 023°51′50.8″ | 953 | 0 | |
| DS4 | N 38°35′59.7″ | E 023°52′09.0″ | 1012 | 0 | |
| DS5 | N 38°36′12.6″ | E 023°52′16.1″ | 980 | 0 | |
| DS6 | N 38°35′55.8″ | E 023°52′21.2″ | 923 | 0 | |
| DS7 | N 38°35′56.4″ | E 023°52′46.2″ | 834 | 0 | |
| DS8 | N 38°35′55.8″ | E 023°52′40.1″ | 867 | 17.2 | |
| 5. Helicon | ES1 | N 38°23′35.6″ | E 022°49′53.7″ | 792 | 11.4 |
| ES2 | N 38°22′17.5″ | E 022°47′40.9″ | 910 | 20.7 | |
| ES3 | N 38°19′27.8″ | E 022°51′05.5″ | 977 | 11.8 | |
| ES4 | N 38°19′15.9″ | E 022°52′15.4″ | 902 | 15.5 | |
| 6. Helmos | HS1 | N 38°01′00.8″ | E 022°10′31.7″ | 1434 | 23.0 |
| HS2 | N 37°59′25.7″ | E 022°08′37.3″ | 1155 | 21.3 | |
| HS3 | N 38°00′26.1″ | E 022°08′22.3″ | 1230 | 12.5 | |
| HS4 | N 37°53′55.5″ | E 022°11′51.6″ | 1226 | 2.0 | |
| HS5 | N 38°00′47.5″ | E 022°09′27.0″ | 1192 | 17.8 | |
| 7. Menalon | MO1 | N 37°34′38.7″ | E 022°17′19.9″ | 1056 | 0.8 |
| MO2 | N 37°34′23.1″ | E 022°16′42.7″ | 947 | 6.9 | |
| MO3 | N 37°35′38.5″ | E 022°14′09.1″ | 1053 | 6.1 | |
| MO4 | N 37°36′19.5″ | E 022°13′30.6″ | 1104 | 1.6 | |
| MO5 | N 37°37′15.6″ | E 022°13′27.3″ | 1139 | 24.1 | |
| MO6 | N 37°37′46.8″ | E 022°12′56.1″ | 1164 | 22.0 | |
| MO7 | N 37°38′03.9″ | E 022°12′41.7″ | 1281 | 20.4 | |
| MO8 | N 37°38′24.7″ | E 022°12′25.1″ | 1317 | 46.2 | |
| MO9 | N 37°38′57.4″ | E 022°12′03.4″ | 1241 | 27.2 | |
| MO10 | N 37°39′38.2″ | E022°11′57.3″ | 1175 | 13.4 | |
| MO11 | N 37°40′31,6″ | E022°12′21.4″ | 1174 | 32.1 | |
| MO12 | N 37°40′58.5″ | E 022°12′32.0″ | 1277 | 10.4 | |
| MO13 | N 37°40′39.5″ | E 022°13′16.2″ | 1409 | 6.0 | |
| MO14 | N 37°40′24.4″ | E022°14′00.4″ | 1472 | 16.8 | |
| MO15 | N 37°39′53.4″ | E 022°15′06.3″ | 1557 | 18.8 | |
| MO16 | N 37°38′43.3″ | E 022°16′03.1″ | 1542 | 6.6 | |
| MO17 | N 37°37′51.0″ | E 022°16′11.1″ | 1404 | 18.2 | |
| MO18 | N 37°37′37.9″ | E 022°15′53.7″ | 1295 | 20.0 | |
| MO19 | N 37°37′28.9″ | E 022°16′49.8″ | 1129 | 12.9 | |
| MO20 | N 37°37′47.2″ | E 022°18′08.1″ | 939 | 0.0 | |
| MO21 | N 37°32′58.2″ | E 022°11′56.0″ | 1143 | 0.0 | |
| MO22 | N 37°33′34.9″ | E 022°11′09.4″ | 1304 | 2.1 | |
| MO23 | N 37°34′01.2″ | E 022°10′15.1″ | 1339 | 2.1 | |
| MO24 | N 37°34′39.3″ | E 022°09′47.2″ | 1242 | 0 | |
| MO25 | N 37°35′59.7″ | E 022°09′36.4″ | 1202 | 5.7 | |
| MO26 | N 37°36′43.3″ | E 022°09′18.6″ | 1142 | 36.6 | |
| MO27 | N 37°37′12.6″ | E 022°08′37.3″ | 1174 | 20.0 | |
| MO28 | N 37°37′37.3″ | E 022°09′20.8″ | 1145 | 20.6 | |
| MO29 | N 37°38′35.3″ | E 022°09′46.0″ | 1002 | 26.3 | |
| MO30 | N 37°39′13.9″ | E 022°09′36.4″ | 1004 | 15.6 | |
| MO31 | N 37°39′48.8″ | E 022°07′57.5″ | 1121 | 26.2 | |
| MO32 | N 37°40′41.2″ | E 022°07′06.1″ | 1265 | 36.2 | |
| MO33 | N 37°41′26.4″ | E 022°06′33.8″ | 1219 | 33.5 | |
| MO34 | N 37°42′08.3″ | E 022°06′31.3″ | 1162 | 9.5 | |
| MO35 | N 37°39′35.3″ | E 022°06′52.7″ | 1133 | 45.6 | |
| MO36 | N 38°54′23.4″ | E 021°54′18.5″ | 1136 | 35.2 | |
| MO37 | N 37°40′03.1″ | E 022°07′40.3″ | 1109 | 33.6 | |
| MO38 | N 37°42′02.7″ | E 022°06′06.7″ | 1103 | 32.0 | |
| MO39 | N 37°42′03.9″ | E 022°08′13.9″ | 1183 | 4.0 | |
| MO40 | N 37°47′16.4″ | E 022°15′05.8″ | 782 | 25.0 | |
| 8. Olympus | OS1 | N 39°58′09.4″ | E 022°31′18.2″ | 1277 | 7.6 |
| 9. Parnis | PA1 | N 38°10′10.3″ | E 023°43′27.9″ | 1163 | 14.5 |
| PA2 | N 38°10′06.1″ | E 023°43′58.9″ | 1187 | 10.3 | |
| PA3 | N 38°10′21.5″ | E 023°44′29.4″ | 1140 | 0.8 | |
| PA4 | N 38°10′44.4″ | E 023°44′11.5″ | 1045 | 7.0 | |
| PA5 | Ν 38°10′13.3″ | E 023°44′11.6″ | 1195 | 31.2 | |
| PA6 | N 38°10′28.2″ | E 023°43′54.9″ | 1243 | 0 | |
| PA7 | N 38°10′22.1″ | E 023°43′52.0″ | 1276 | 20.2 | |
| PA8 | N 38°10′51.0″ | E 023°43′42.1″ | 1063 | 7.9 | |
| PA9 | N 38°10′49.0″ | E 023°43′02.8″ | 1115 | 4.3 | |
| PA10 | N 38°10′42.9″ | E 023°42′33.6″ | 1119 | 6.9 | |
| PA11 | N 38°10′32.1″ | Ε 023°42′02.5″ | 1081 | 1.5 | |
| PA12 | N 38°09′57.7″ | E 023°42′08.2″ | 1020 | 0 | |
| 10. Parnon | PS1 | N 37°11′06.0″ | E 022°32′34.6″ | 912 | 4.8 |
| PS2 | N 37°11′17.6″ | E 022°33′26.3″ | 1023 | 13.5 | |
| PS3 | N 37°11′28.5″ | E 022°34′25.8″ | 1008 | 0.0 | |
| PS4 | N 37°11′07.7″ | E 022°34′45.2″ | 1082 | 24.2 | |
| PS5 | N 37°10′16.1″ | E 022°35′47.7″ | 1080 | 3.1 | |
| PS6 | N 37°10′02.7″ | E 022°35′57.7″ | 1113 | 8.1 | |
| PS7 | N 37°09′43.5″ | E 022°35′56.9″ | 1212 | 5.9 | |
| PS8 | N 37°11′55.2″ | E 022°34′32.9″ | 1100 | 7.2 | |
| PS9 | N 37°12′43.2″ | E 022°34′16.2″ | 1243 | 10.4 | |
| PS10 | N 37°12′53.6″ | E 022°34′25.1″ | 1216 | 29.6 | |
| PS11 | N 37°13′27.1″ | E 022°33′50.6″ | 1148 | 12.3 | |
| PS12 | N 37°19′40.7″ | E 022°34′44.8″ | 871 | 57.6 | |
| PS13 | N 37°19′53.2″ | E 022°35′15.2″ | 914 | 26.0 | |
| 11. Pindos (central) | PI1 | N 39°30′22.7″ | E 021°32′25.5″ | 1079 | 0 |
| PI2 | N 39°32′46.7″ | E 021°28′15.3″ | 1215 | 0 * | |
| PI3 | N 39°32′24.6″ | E 021°28′12.5″ | 1191 | 0 | |
| PI4 | N 39°36′45.4″ | E 021°29′45.5″ | 982 | 0 | |
| PI5 | N 39°30′52.7″ | E 021°30′06.5″ | 1204 | 0 * | |
| PI6 | N 39°31′11.6″ | E 021°26′38.6″ | 1064 | 0 | |
| PI7 | N 39°29′45.4″ | E 021°32′37.2″ | 974 | 0 | |
| 12. Taygetus | TG1 | N 36°58′03.2″ | E 022°23′55.5″ | 839 | 0 |
| TG2 | N 36°58′01.3″ | E 022°23′17.5″ | 904 | 10.2 | |
| TG3 | N 36°57′50.6″ | E 022°22′54.1″ | 1053 | 0 | |
| TG4 | N 36°57′34.7″ | E 022°23′17.4″ | 1215 | 0 | |
| TG5 | N 36°57′13.1″ | E 022°22′57.1″ | 1254 | 47.6 | |
| TG6 | N 36°53′51.8″ | E 022°19′17.9″ | 1408 | 29.8 | |
| 13. Tymfristos | TS1 | N 38°54′35.0″ | E 021°54′47.8″ | 906 | 13.8 |
| TS2 | N 38°54′23.4″ | E 021°54′18.5″ | 1025 | 4.6 | |
| TS3 | N 38°53′44.0″ | E 021°53′16.1″ | 1146 | 0.0 | |
| TS4 | N 38°53′31.0″ | E 021°52′36.9″ | 1158 | 1.5 | |
| TS5 | N 38°53′30.2″ | E 021°52′18.8″ | 1045 | 0.0 | |
| TS6 | N 38°54′03.0″ | E 021°50′34.7″ | 954 | 9.8 | |
| TS7 | N 38°53′35.8″ | E 021°45′52.5″ | 790 | 2.7 | |
| TS8 | N 38°52′09.9″ | E 021°45′05.9″ | 717 | 4.5 | |
| TS9 | N 38°50′11.5″ | E 021°43′41.0″ | 816 | 4.7 | |
| TS10 | N 38°44′17.9″ | E 021°39′09.9″ | 837 | 2.5 | |
| TS11 | N 38°44′00.8″ | E 021°39′06.6″ | 803 | 8.1 | |
| TS12 | N 38°44′51.7″ | E 021°38′47.2″ | 962 | 5.9 | |
| TS13 | N 38°45′17.1″ | E 021°38′38.5″ | 1093 | 21.5 | |
| TS14 | N 38°44′34.4″ | E 021°38′15.6″ | 1287 | 5.5 | |
| TS15 | N 38°44′17.6″ | E 021°38′29.5″ | 1355 | 21.4 | |
| TS16 | N 38°52′55.8″ | E 021°52′44.1″ | 1292 | 0.0 | |
| TS17 | N 38°52′05.5″ | E 021°52′19.8″ | 1359 | 0.0 | |
| TS18 | N 38°51′52.1″ | E 021°51′24.5″ | 1418 | 0.0 | |
| TS19 | N 38°51′18.4″ | E 021°51′00.5″ | 1542 | 1.2 | |
| TS20 | N 38°50′24.6″ | E 021°50′19.6″ | 1464 | 2.2 | |
| TS21 | N 38°49′28.0″ | E 021°50′25.5″ | 1456 | 10.5 | |
| TS22 | N 38°48′25.3″ | E 021°50′09.2″ | 1407 | 3.9 | |
| TS23 | N 38°48′03.3″ | E 021°50′50.1″ | 1202 | 14.3 | |
| TS24 | N 38°50′28.8″ | E 021°43′33.1″ | 912 | 12.9 | |
| TS25 | N 38°52′38.3″ | E 021°47′24.0″ | 1042 | 15.2 | |
| TS26 | N 38°49′08.3″ | E 021°49′47.5″ | 1267 | 22.6 | |
| 14. Vardousia | VA1 | N 38°41′47.1″ | E 022°01′46.2″ | 1288 | 0 |
| VA2 | N 38°42′17.3″ | E 022°01′54.2″ | 1171 | 0 | |
| VA3 | N 38°42′57.9″ | E 022°01′19.9″ | 1134 | 0 | |
| VA4 | N 38°43′18.3″ | E 022°00′55.9″ | 830 | 0 | |
| VA5 | N 38°53′03.2″ | E 022°03′04.2″ | 782 | 24.1 | |
| 15. Ziria (Killini) | ZA1 | N 38°01′11.3″ | E 022°24′12.0″ | 1209 | 21.9 |
| ZA2 | N 38°00′12.8″ | E 022°23′33.4″ | 1075 | 8.2 | |
| ZA3 | N 37°59′39.3″ | E 022°22′21.7″ | 953 | 20.3 | |
| ZA4 | N 37°55′50.2″ | E 022°16′49.6″ | 883 | 9.7 | |
| ZA5 | N 37°55′35.8″ | E 022°17′00.9″ | 883 | 3.9 | |
| ZA6 | N 37°55′31.4″ | E 022°17′16.2″ | 883 | 0 | |
| ZA7 | N 37°52′37.3″ | E 022°21′26.7″ | 986 | 0 | |
| ZA8 | N 37°52′05.3″ | E 022°21′53.1″ | 1045 | 20.7 | |
| ZA9 | N 37°51′57.7″ | E 022°21′56.2″ | 1063 | 23.7 | |
| ZA10 | N 37°51′44.3″ | E 022°22′56.5″ | 855 | 0 | |
| ZA11 | N 37°51′31.8″ | E 022°22′59.2″ | 741 | 22.1 | |
| ZA12 | N 37°51′29.8″ | E 022°15′01.0″ | 1175 | 7.2 | |
| ZA13 | N 37°58′53.8″ | E 022°27′50.0″ | 1132 | 4.8 | |
| ZA14 | N 37°58′42.0″ | E 022°34′07.4″ | 931 | 2.8 |
An asterisk (*) indicates those sampling points where only dead adults of P. hellenicus were found.
Table 2.
Total number of nodes of Abies spp. per age class, and female individuals of P. hellenicus contained in nodes at mountains Menalon, Parnis and Tymfristos during the entire experimental period.
Table 2.
Total number of nodes of Abies spp. per age class, and female individuals of P. hellenicus contained in nodes at mountains Menalon, Parnis and Tymfristos during the entire experimental period.
| Class of Age Nodes | ||||||
|---|---|---|---|---|---|---|
| Sampled Mountain | Nodes/Female Individuals | 0 | 1 | 2 | 3 | 4 |
| Menalon | nodes | 18,722 | 12,414 | 7674 | 4112 | 1858 |
| female individuals | 5595 | 8074 | 4232 | 1825 | 573 | |
| Parnis | nodes | 5614 | 3942 | 2492 | 1347 | 559 |
| female individuals | 4731 | 5283 | 2803 | 1203 | 392 | |
| Tymfristos | nodes | 4929 | 3071 | 1691 | 812 | 406 |
| female individuals | 678 | 815 | 237 | 62 | 7 | |
Table 3.
Maximum values of percentage infestation [I(%)] of Abies spp. nodes by P. hellenicus.
| Sampling Points | Sampling Years | |||||
|---|---|---|---|---|---|---|
| 2013 | 2014 | 2015 | 2016 | 2017 | 2018 | |
| MO2 | 26.0 | 23.1 | 12.3 | 11.1 | 0.0 | 0.0 |
| MO29 | 57.4 | 50.0 | 45.1 | 19.5 | 34.3 | 5.3 |
| MO19 | 23.4 | 25.0 | 17.3 | 9.1 | 10.6 | 0.0 |
| MO36 | 37.3 | 60.0 | 68.1 | 55.0 | 9.5 | 21.3 |
| MO5 | 36.7 | 36.4 | 19.6 | 12.8 | 0.0 | 0.0 |
| MO28 | 64.8 | 70.8 | 24.6 | 7.1 | 0.0 | 0.0 |
| MO11 | 86.3 | 90.0 | 64.0 | 40.6 | 11.4 | 21.2 |
| MO9 | 87.9 | 82.8 | 45.7 | 20.9 | 14.6 | 10.3 |
| MO8 | 100.0 | 75.0 | 30.4 | 51.9 | 2.4 | 4.1 |
| MO14 | 59.2 | 48.9 | 52.6 | 41.7 | 13.7 | 32.1 |
| PA1 | 29.5 | 23.0 | 22.6 | 26.1 | 34.9 | 53.6 |
| PA5 | 95.2 | 76.9 | 46.9 | 48.9 | 53.3 | 51.5 |
| PA7 | 91.8 | 81.0 | 50.0 | 37.0 | 51.3 | 84.6 |
| TS24 | - | 22.9 | 19.7 | 21.3 | 13.5 | 12.1 |
| TS25 | - | 12.5 | 22.0 | 14.9 | 13.1 | 6.1 |
| TS26 | - | 25.0 | 41.3 | 14.0 | 17.1 | 10.0 |
Where dashes exist no material was collected.
Table 4.
ANOVA parameters of main effects and associated interaction for the activity of natural enemies [E(%)] of P. hellenicus in three mountains of Greece (error DF = 78).
Table 4.
ANOVA parameters of main effects and associated interaction for the activity of natural enemies [E(%)] of P. hellenicus in three mountains of Greece (error DF = 78).
| Source | DF | F | p |
|---|---|---|---|
| Mountain | 2 | 4.1 | 0.0211 |
| Natural enemies | 5 | 393.2 | <0.0001 |
| Mountain x natural enemies | 10 | 9.1 | <0.0001 |
Table 5.
Mean values (±SE) of the activity of natural enemies [E(%)] of P. hellenicus in three mountains of Greece.
Table 5.
Mean values (±SE) of the activity of natural enemies [E(%)] of P. hellenicus in three mountains of Greece.
| Mountain | |||||
|---|---|---|---|---|---|
| Natural Enemies | Menalon | Parnis | Tymfristos | F | p |
| Healthy | 57.2 ± 1.8 Ab | 56.5 ± 2.6 Ab | 73.9 ± 2.9 Aa | 13.3 | 0.0007 |
| A. fasciatus | 4.6 ± 0.5 Da | 6.4 ± 1.0 Ca | 0.5 ± 0.5 Db | 18.6 | 0.0002 |
| M. lunatus | 3.7 ± 0.5 D | 5.4 ± 1.2 C | 3.0 ± 0.4 C | 2.0 | 0.1797 NS |
| P. testaceus | 14.0 ± 1.1 Bab | 17.5 ± 0.1 Ba | 10.2 ± 0.6 Bb | 4.6 | 0.0308 |
| Predators | 9.2 ± 1.0 C | 8.3 ± 2.1 C | 7.1 ± 1.6 BC | 0.6 | 0.5499 NS |
| Undefined | 11.3 ± 1.0 BCa | 5.9 ± 0.7 Cb | 5.3 ± 0.6 BCb | 11.0 | 0.0016 |
| F | 245.3 | 103.1 | 172.4 | ||
| p | <0.0001 | <0.0001 | <0.0001 |
Within each column, means followed by the same uppercase letters do not differ significantly, for Menalon DF = 5, 59, for Parnis DF = 5,17, for Tymfristos DF = 5, 17; Tukey–Kramer HSD test at 0.05. Within each row, means followed by the same lowercase letters do not differ significantly, in all cases for DF = 2, 15; Tukey–Kramer HSD test at 0.05. Where no letters exist, no significant differences were noted (NS).
Table 6.
Number of P. hellenicus female individuals with honeydew at a parasitized and non-parasitized (healthy) status in three sampled mountains of Greece during the whole sampling period (2013–2018).
Table 6.
Number of P. hellenicus female individuals with honeydew at a parasitized and non-parasitized (healthy) status in three sampled mountains of Greece during the whole sampling period (2013–2018).
| Status | Healthy | A. fasciatus | M. lunatus | Undefined | |||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Mountain | M | P | T | M | P | T | M | P | T | M | P | T | |
| Life stage | L1 | 24 * | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
| L2 ♀ | 11 * | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | |
| L3 ♀ | 61 * | 2 * | 7 * | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | |
| L3→adult ♀ | 31 * | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | |
| adult-pre ♀ | 30 * | 2 * | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | |
| adult ♀ | 1050 * | 547 * | 113 * | 0 | 2 * | 0 | 11 * | 21 * | 1 * | 2 * | 1 * | 0 | |
| 829 ** | 460 ** | 73 ** | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | ||
The letters M, P and T correspond to mountains Menalon, Parnis and Tymfristos, respectively. The asterisks indicate the amount of honeydew (* = one drop of honeydew behind the insect, ** = many drops diffusible all over the insect).
Table 7.
Arthropods found on fir samples of south and central Greece.
| Species | Sampled Mountain |
|---|---|
| Coleoptera | |
| Phalacrus sp. (Phalacridae) | 7 |
| Protapion sp. (Apionidae) | 7 |
| Otiorrynchus raucus (Fabricius) (Curculionidae) | 7 |
| Sitona sp. (Curculionidae) | 12 |
| Harmonia sp. (Coccinellidae) | 12 |
| Altica sp. (Chrysomelidae) | 7 |
| Dermaptera | |
| Forficula sp. (Forficulidae) | 6, 7, 9, 13 |
| Hemiptera | |
| Coreus marginatus (L.) (Coreidae) | 12 |
| Cinara pectinatae | 13 |
| Dinaspidiotus abietis (Schrank) (Diaspididae) | 7, 9, 12 |
| Dinaspidiotus abieticola (Coroneos) (Diaspididae) | 7, 9, 12 |
| Dreyfusia nordmannianae | 7, 9, 13 |
| Eulecanium sericeum | 7, 9, 10, 12, 13 |
| Marchlina hellenica | 6, 7, 9 |
| Mindarus abietinus | 5, 7, 9, 10, 12, 13 |
| Lepidosaphes sp. (Diaspididae) | 7, 9 |
| Leucaspis sp. (Diaspididae) | 7, 9 |
| Pseudococcus sp. (Pseudoccocidae) | 7, 9 |
| Lepidoptera | |
| Eupithecia sp. (Geometridae) | 9 |
| Neuroptera | |
| Chrysoperla sp.(Chrysopidae) | 9, 12 |
Numbers 5, 6, 7, 9, 10, 12 and 13 correspond to sampled mountains Helicon, Helmos, Menalon, Parnis, Parnon, Taygetus and Tymfristos, respectively.
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Papanastasiou, I.; Kavallieratos, N.G.; Papadoulis, G.T.; Emmanouil, C.; Emmanouel, N.G. Geographical Distribution and Long-Term Monitoring of Physokermes hellenicus (Hemiptera: Coccomorpha: Coccidae) on Abies spp. (Pinales: Pinaceae) in Greece. Insects 2021, 12, 1001. https://doi.org/10.3390/insects12111001
AMA Style
Papanastasiou I, Kavallieratos NG, Papadoulis GT, Emmanouil C, Emmanouel NG. Geographical Distribution and Long-Term Monitoring of Physokermes hellenicus (Hemiptera: Coccomorpha: Coccidae) on Abies spp. (Pinales: Pinaceae) in Greece. Insects. 2021; 12(11):1001. https://doi.org/10.3390/insects12111001
Chicago/Turabian StylePapanastasiou, Iosif, Nickolas G. Kavallieratos, Georgios Th. Papadoulis, Christina Emmanouil, and Nikolaos G. Emmanouel. 2021. "Geographical Distribution and Long-Term Monitoring of Physokermes hellenicus (Hemiptera: Coccomorpha: Coccidae) on Abies spp. (Pinales: Pinaceae) in Greece" Insects 12, no. 11: 1001. https://doi.org/10.3390/insects12111001
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