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Chilean journal of agricultural research

versión On-line ISSN 0718-5839

Chilean J. Agric. Res. v.69 n.2 Chillán jun. 2009 

Chilean Journal of Agricultural Research 69(2):160-170 (April-June 2009)


Life Table Parameters and Consumption Rate of Cydnodromus picanus Ragusa, Amblyseius graminis Chant, and Galendromus occidentalis (Nesbitt) on Avocado Red Mite Oligonychus yothersi (McGregor) (Acari: Phytoseiidae, Tetranychidae)

Parámetros de Tabla de Vida y Tasa de Consumo de Cydnodromus picanus Ragusa, Amblyseius graminis Chant y Galendromus occidentalis (Nesbitt), sobre la Arañita Roja del Palto Oligonychus yothersi (McGregor) (Acari: Phytoseiidae, Tetranychidae)

Tommy Rioja S.1*, and Robinson Vargas M.2

1 Pontificia Universidad Católica de Valparaíso, Facultad de Agronomía, Casilla 4-D, Quillota, Chile. * Corresponding author (
2 Instituto de Investigaciones Agropecuarias, Centro Regional de Investigación La Cruz, Casilla 3, La Cruz, Chile. (
Received: 17 January 2008.
Accepted: 19 May 2008.


The avocado red mite Oligonychus yothersi (McGregor) is the major leaf pest in Chile’s avocado orchards. Itaffects leaf physiology and makes it necessary to seek new natural enemies to interact with low population densities of O. yothersi. The potentiality of three predator mites: Cydnodromus picanus Ragusa, Amblyseius graminis Chant, and Galendromus occidentalis (Nesbitt) was evaluated under laboratory conditions (27 ± 1.93ºC, 87 ± 3.61% H.R. and 16:8 (L:D) photoperiod) on avocado leaf disks Persea americana Mill. var. Hass (Ø = 5 cm) by separately feeding eggs, immature,  and adult females of O. yothersi, and registering postembryonic development, consumption, as well as life table parameters. The postembryonic development of C. picanus was significantly lower (5.46 days) compared to both A. graminis (7.33 days) and G. occidentalis (8.69 days) which were fed with immature O. yothersi. The life table parameters of C. picanus were net reproductive rate R0 = 25.41, finite rate of increase λ = 1.29, and Mean Generation Time T = 12.46. The Net Intrinsic Rate of Increase (rm) was significantly higher for C. picanus (rm = 0.25) in contrast with G. occidentalis (rm = 0.19), while A. graminis showed rm = -0.06 indicating that its population didn’t have descendants. Under laboratory conditions, rm registered by C. picanus is an indicator of its predatory potential to control O. Yothersi.  It can be assumed that the pest population reduction pattern could be maintained under field conditions.

Key words: postembryonic development, predation, pollen, biological control.


En Chile la arañita roja del palto Oligonychus yothersi (McGregor) es la plaga más importante a nivel foliar en huertos comerciales afectando la fisiología de la hoja, siendo necesario la búsqueda de nuevos enemigos naturales que interactúen a bajas densidades poblacionales de O. yothersi. Se evaluó en condiciones de laboratorio (27±1,93ºC, 87±3,61 % H.R. y un fotoperíodo de 16:8 (L:O)) sobre discos de hojas de palto Persea americana Mill. var. Hass (Ø = 5 cm)  la potencialidad de 3 ácaros depredadores Cydnodromus picanus Ragusa, Amblyseius graminis Chant y Galendromus occidentalis (Nesbitt), suministrando huevos, inmaduros y hembras adultas de O. yothersi separadamente, registrando desarrollo postembrionario, consumo y parámetros de tabla de vida. El desarrollo postembrionario de C. picanus fue significativamente menor (5,46 días) en comparación a A. graminis (7,33 días) y G. occidentalis (8,69 días) al ser alimentados con inmaduros de O. yothersi. Los parámetros de tabla de vida de C. picanus fueron tasa neta de reproducción R0 = 25,41, tasa finita de crecimiento λ = 1,29 y tiempo generacional T = 12,46. La tasa intrínseca de crecimiento (rm) fue significativamente mayor para C. picanus (rm = 0,25) frente a G. occidentalis (rm = 0,19), mientras que A. graminis presentó una rm = -0,06 indicando que su población no tiene descendencia. El rm registrado por C. picanus en condiciones de laboratorio es un indicador del potencial que tiene como depredador sobre O. yothersi, y permite suponer que en condiciones de campo el patrón de reducción poblacional de la plaga podría mantenerse.

Palabras clave: desarrollo postembrionario, depredación, polen, control biológico.


The Persea americana Mill. (Lauraceae), avocado is the second most cultivated fruit tree in Chile after vineyards, and covers an area of 39 302.59 ha of which 56% is concentrated in the Valparaíso Region (INE, 2007). Furthermore, Chile is the second world exporter of avocados, mainly the Hass variety, with approximately 165 000 t exported during the 2006-2007 season (Comité de Paltas, 2007).

Nevertheless, there is an economic loss associated with exports because of the presence of pests such as Pseudococcus longispinus (Targioni & Tozzetti) (Hemiptera: Pseudococcidae), P. calceolariae (Maskell) (Hemiptera: Pseudococcidae), Hemiberlesia lataniae (Signoret) (Hemiptera: Diaspidiae), and Heliothrips haemorrhoidalis (Bouché) (Thysanoptera: Thripidae) (SAG, 2007). The most important economic avocado pest at a foliar level is Oligonychus yothersi (McGregor) (Acari: Tetranychidae) (Altieri and Rojas, 1999), commonly known as the avocado red mite, and var. Hass is the most susceptible to be attacked by this tetraniquid. Oligonychus yothersi provokes a decrease in photosynthetic rate, stomatal conductance, and transpiration, negatively affecting the physiology of the avocado leaves (Schaffer et al., 1986). This has a direct consequence on the quality of the fruit and crop yield (Palevsky et al., 2007a), the same as for O. perseae Turttle, Baker and Abbatiello (Acari: Tetranychidae) found in California, USA (Kerguelen and Hoddle, 2000; Takano-Lee and Hoddle, 2002).

The natural enemies associated with O. yothersi in avocado orchards in the Province of Quillota are Stethorus histrio Chazeau (Coleoptera: Coccinellidae) and Oligota pygmaea Solier (Coleoptera: Staphylinidae), density-dependent generalist predators. Both coleoptera present natural colonization in the orchard only when the pest population increases (Obrycki and Kring, 1998; Kishimoto, 2003) without exerting the necessary regulation to avoid damage produced by the red mite at the leaf physiological level. This makes it necessary to incorporate new predators to the system to interact with low O. yothersi population densities in the Chilean avocado orchards managed with biological control agents.

The most important predators of phytophagous mites in the world belong to the Phytoseiidae (Shrewsbury and Hardin, 2003) family which are easily adaptable to perturbed habitats and intensely managed as is the case of fruit orchards (Croft and Luh, 2004). The generalist species do not require large mite pest population densities to be established in an orchard, and migrate to other places through aerial dispersion if they lack prey (Colfer et al., 2003; Tixier et al., 2006). In the absence of phytophagous mites, the generalists have the capacity to use food alternatives such as pollen grains, fungi spores, insects in the immature stages, plant nectar, and exudates (Croft et al., 2004; Nomikou et al., 2005; Bouras and Papadoulis, 2005).

To include new natural enemies in a biological control system, it is fundamental to know their biological and ecological characteristics. The potential of the predators on their prey (De Vis et al., 2006b) can be estimated through population models and the construction of life tables, thus obtaining data about survival, longevity, reproduction, and descendants of the arthropod populations  (Yu et al., 2005; Gabre et al., 2005; Yang and Chi, 2006; Ozman-Sullivan, 2006; Ferrero et al., 2007). Food quality has a great influence on the formulation of biological parameters since it is indispensable to recognize the predator’s consumption in each stage of the pest in order to predict its effectiveness as a natural enemy (Kishimoto 2003; Gotoh et al., 2006; Collier et al., 2007), and potential impact on the prey (Hosseini et al., 2005).

This study evaluated the demographic parameters and the consumption of Cydnodromus picanus, Amblyseius graminis, and Galendromus occidentalis on distinct stages of O. yothersi, first under laboratory conditions to identify the red mite’s potential predators which would eventually be included in integrated pest management plans.


Species studied. Three phytoseiid species were selected and evaluated as potential predators of the avocado red mite based on biological and ecological characteristics. Cydnodromus picanus Ragusa (Parasitiforms: Phytoseiidae) is a type III generalist phytoseiid from the Pica zone (20º15' S; 69º20' O), Tarapacá Region (Ragusa et al., 2000) which is able to withstand great thermal oscillations during throughout the day with scarce environmental humidity, and survive food scarcity. Amblyseius graminis Chant (Parasitiforms: Phytoseiidae) is a type III generalist phytoseiid (Croft et al., 2004) collected on redstem stork's bill (Erodium cicutarium (L.) L'Hér. (Geraniaceae) in avocado orchards in the La Cruz zone (32º49' S; 71º17' O), Valparaíso Region. Galendromus (Metaseiulus) occidentalis (Nesbitt) (Parasitiforms: Phytoseiidae) is a type II specialist phytoseiid (Blackwood et al., 2004) collected on walnut trees Juglans regia L. (Juglandaceae) (Ragusa and Vargas, 2002) in Los Andes locality (32º49’ S; 70º35’ O), Valparaíso Region, and is a known mite predator of the Oligonychus genus (Shrewsbury and Hardin, 2003).

Site and study materials. The life table and consumption assays were carried out in the laboratories of Instituto de Investigaciones Agropecuarias (INIA) La Cruz, Valparaíso Region, between January and September 2007. Using a data logger, the Petri dish micro-climatic conditions were registered inside the laboratory, thereby obtaining a temperature of 27 ± 1.93 ºC, relative humidity of 87 ± 3.61%, and a 16:8 (L:D) photoperiod for all the assays. These micro-climatic conditions were used to register the maximum biological potential of the predatory species since these are susceptible to low humidity in the egg stage (De Vis et al., 2006a). The experimental observations were carried out every 24 h with a 40X stereoscopical magnifying glass (Zeiss Stemi, Germany). An adhesive (Point sticken blue, Point Chile S.A.) was used to avoid the mites from escaping.

Breeding of the avocado red mite. Oligonychus yothersi were bred massively on avocado leaves var. Hass, Oliveira et al. (2001) with a modified methodology using plastic containers (29 cm x 7 cm x 39.5 cm) at a temperature of 27 ± 2 ºC, relative humidity of 50 ± 10%, and a 16:8 (L:D) photoperiod. The micro-climatic conditions were registered with a digital thermo-hygrometer.

Phytoseiid breeding. The three predatory species selected were obtained in the phytoseiid breeding room located in the INIA La Cruz facilities. Subsequently, gravid females of this species were moved to the assay laboratory where they were bred on avocado leaf disks var. Hass infested with O. yothersi inside plastic containers (57 x 42 x 19 cm) opened at the top and covered with muslin to avoid contamination of the predatory mite populations. The assays were carried out with eggs laid by the first-generation females.

Postembryonic development. Egg-adult development was determined for each species of phytoseiid. Thirty gravid females were taken from each species and each female was placed inside an avocado leaf disk var. Hass (Ø = 5 cm) confined with adhesive (sticken). They were eliminated after 5 h, leaving 1 egg per disk (1 egg = 1 replicate), and registering the duration of each developmental stage of the phytoseiid through the exuvium. Longevity of unmated individuals was obtained by making available, on a daily basis, ten 24-h-old eggs, 10 mobile immature individuals (protonymphs and deutonymphs), and five O. yothersi adult females. Daily consumption was registered for each phytoseiid.

Avocado (Persea americana Mill.) (Lauraceae) var. Hass and Hirschfeldia incana (L.) hoary mustard (Brassicaceae) pollen was evaluated as alternative food to verify the survival of the species when facing a scarcity of prey. Daily, avocado var. Hass and H. incana pollen was provided separately by means of a fine brush, along with registering postembryonic development and predator longevity. Water was provided by cotton threads through a hole in the leaf for assays with pollen, as well as for those without food supply.

Fertility and longevity. Thirty females of known age were placed in avocado var. Hass leaf disks (1 female = 1 replicate), integrating a male for 24 h every 7 days. Each female was given 15 mobile immature O. yothersi (protonymphs and deutonymphs). The phytoseiid eggs were counted and eliminated, recording longevity, fecundity, and consumption of the gravid females. To obtain descendants and the proportion of sexes, 10 females were randomly selected from the previous 30. Thus, the eggs of each female were counted and deposited on 10 infested Petri dishes with all the O. yothersi stage, respectively, thus recording data about fertility and proportion of sexes for the females of each species.

Statistical analysis. A completely random design was applied with 30 replicates per experiment. Postembryonic development, longevity, and consumption data were transformed by (Steel and Torrie, 1985). Subsequently, ANOVA and Tukey test (p < 0.05) were applied to evaluate the influence of food on postembryonic development and phytoseiid consumption.

The following were the calculated life table parameters (SAS Institute, 2007): (1) Net reproductive rate,

R0 =Σ, being the number of females that produce a female during a generation or during their lifespan (Rabinovich, 1980); (2) Intrinsic rate of increase, rm being the maximum exponential multiplication rate of a whole population, and calculated as 1= Σ lxmxexp(-rm) Birch, 1948); (3) Finite rate of increase, λ = exp (rm) being the number of females that produce one female per day (Birch, 1948); and (4) Generation time, T = Σ Xxmx being the time that passes between first and next generation oviposition (Rabinovich, 1980).

The Jacknife nonparametric resampling method was used to compare the parameters of the life table between species, estimating the mean, variance, and standard error (Meyer et al., 1986; La Rossa and Kahn, 2003) with the LIFETABLES software, SAS (Maia et al., 2000), and SAS® (SAS Institute, 2007). The biological parameters were subsequently compared with the Tukey test (P < 0.05).


The time of postembryonic development of C. picanus observed was less compared to the other two predatory species (F = 134.54, df = 2, p < 0.01) when fed mobile immature O. yothersi (Table 1). With regard to the longevity of phytoseiids fed with mobile immature O. yothersi, C. picanus showed a greater duration of the adult stage than A. graminis and G. occidentalis, thus indicating that the supply of O. yothersi protonymphs and deutonyphs had a positive influence on the postembryonic development of C. picanus (F = 167.30, df = 2, p < 0.01). In relation to the percentage of immature phytoseiids that developed to the adult stage, a survival rate of 100% was registered for C. picanus, 86% for G. occidentalis, and only 10% for A. graminis.

Table 1. Duration of postembryonic development and longevity (in days) of Cydnodromus picanus, Amblyseius graminis, and Galendromus occidentalis fed with Oligonychus yothersi in different stages.

By feeding O. yothersi eggs, the postembryonic development of C. picanus and A. graminis increased with respect to the predators fed with immature red mites, whereas G. occidentalis only reached the larval stage. Furthermore, C. picanus showed a 13% survival rate and A. graminis 6.6% in the immature stage (Table 1). It was confirmed that in the immature stage, C. picanus, A. graminis, and G. occidentalis do not consume adult females of the avocado red mite (Table 1).

Using avocado var. Hass pollen, the duration of the postembryonic development was found to be shorter for A. graminis than C. picanus (F = 27.55, df = 1, p < 0.01). Regarding longevity of the evaluated species, A. graminis individuals were significantly more long-lived (F = 148.18, df = 1, p < 0.0001) than C. picanus. Survival of immature phytoseiids that reached the adult stage was not significantly different between A. graminis (66.6%) and C. picanus (43.3%) (F = 3.38, df = 1, p = 0.0713), though G. occidentalis did not consume pollen and only developed to the larval stage (Table 2).

Table 2. Influence of diet on duration of postembryonic development and longevity (in days) of Cydnodromus picanus, Amblyseius graminis, and Galendromus occidentalis.

Using H. incana pollen, egg-adult development was observed to be less for A. graminis than C. picanus (F = 177.21, df = 1, p < 0.01), although longevity was significantly greater for A. graminis (F = 345.48, df = 1, p < 0.0001) than C. picanus. Furthermore, A. graminis showed a 60% survival rate of individuals in the immature stage that developed into the adult stage, whereas C. picanus registrered a statistically similar 46.6% (F = 1.05, df = 1, p = 0.3087) (Table 2).

In terms of C. picanus longevity, a significant difference was obtained for the individuals fed with mobile immature red mites (60.03 days) as compared with administering an exclusive diet of avocado var. Hass pollen (40.46 días) (F = 62.74, df = 1, p < 0.0001) and H. incana (22.5 días) (F = 251.41, df = 1, p < 0.0001), thus indicating that these two latter diets are a feeding alternative when prey is scarce. On the other hand, A. graminis registered a significantly greater longevity when fed avocado var. Hass pollen (78.10 días) (F = 91.36, df = 1, p < 0.l0001) and H. incana (84.94 días) (F = 86.85, df = 1, p < 0.0001) compared with feeding on mobile immature red mites (18 days) (Table 1, Table 2).

On a water diet, C. picanus and A. graminis developed up to the protonymph stage. In contrast, G. occidentalis only reached the larval stage. Furthermore, C. picanus showed a longer duration in the protonymph stage compared with A. graminis (F = 1158.03, df = 1, p < 0.01) (Table 2).

As for depredation on immature O. yothersi, G. occidentalis registered consumption of the avocado red mite in the larval stage although C. picanus and A. graminis did not present depredation in this stage (F = 457.40, df = 2, p < 0.01), indicating that G. occidentalis needs to be fed to continue its postembryonic development. On the other hand, C. picanus and G. occidentalis registered less depredation in the protonymph stage than  A. graminis (F = 32.58, df = 2, p < 0.01), a behavior also observed in deutonymphs (F = 13.77, df = 2, p < 0.01). Nevertheless, unmated C. picanus adults showed a greater depredation rate compared with unmated A. graminis and G. occidentalis adults (F = 71.96, df = 2, p < 0.01) (Table 3).

Table 3. Total consumption by Cydnodromus picanus, Amblyseius graminis, and Galendromus occidentalis of mobile immature Oligonychus yothersi during postembryonic development and longevity of predator mites.

A greater depredation rate of mated A. graminis females on immature O. yothersi was observed as compared with C. picanus and G. occidentalis (F = 306.67, df = 2, p < 0.01) (Table3).

Life table parameters
Cydnodromus picanus females showed gradual mortality over time in contrast with A. graminis and G. occidentalis which concentrated almost 80% mortality in 7 days (Figure 1). Furthermore, greater longevity was noted for A. graminis (25.7 días) and C. picanus (25.43 días) females in contrast with G. occidentalis (22.56 días) (F = 5.44, df = 2, p = 0.006). The three survival curves recorded for the distinct species were type I, thus indicating that mortality was mainly concentrated in long-lived individuals (Rabinovich, 1980).

Figure 1. Survival curve of mated female Cydnodromus picanus, Amblyseius graminis, and Galendromus occidentalis fed with mobile immature Oligonychus yothersi.


There is no significant difference in the oviposition rate between the evaluated phytoseiid species (F = 1.47, df = 2, p = 0.236) (Figure 2). Comparing female fertility, C. picanus had a higher value than G. occidentalis and A. graminis whose eggs were almost entirely infertile (Figure 3).

Figure 2. Female fertility of Cydnodromus picanus, Amblyseius graminis, and Galendromus occidentalis fed with mobile immature Oligonychus yothersi.


Figure 3. Mean female fecundity of Cydnodromus picanus, Amblyseius graminis, and Galendromus occidentalis fed with mobile immature Oligonychus yothersi.

The life table parameters of the three phytoseiids fed with immature O. yothersi showed that C. picanus showed higher R0, rm, and λ than G. occidentalis (F = 233.58, df = 3, p < 0.0001; F = 2390.05, df = 3, p < 0.0001; F = 215.61, df = 3, p < 0.0001; F = 2127.12, df = 3, p < 0.0001), whereas A. graminis revealed R0 = 0.27 indicating that the population of this specie decreases over time (Table 4). The biological parameters of C. picanus show that the population grew 25.41 times in 12.46 days (T), and for each female of the actual generation there will be 25.41 females in the next generation. Furthermore, for each female present on a given day, there will be almost 1.29 (λ) females the next day. Therefore, at any particular point in time, the number of females in the C. picanus population will increase at such a rate that a population growth of 25% (rm) is expected from one day to the next. Moreover, comparing R0, rm, T, and λ of C. picanus with O. yothersi, it is observed that only the latter attains a higher R0 (F = 233.58, df = 3, p < 0.0001), while the predator registered higher rm and λ. In addition, generation time was significantly lower for C. picanus (F = 215.61, df = 3, p < 0.0001) demonstrating that it multiplied more rapidly than the red mite population (Table 4).

Table 4. Life table parameters of the Cydnodromus picanus, Amblyseius graminis, Galendromus occidentalis predator mites, and the avocado red mite Oligonychus yothersi.


Consumption records during the postembryonic development of the three phytoseiids in the O. yothersi egg, immature, and adult female stages indicated that protonymphs and deutonymphs of the avocado red mite are differentially predated by C. picanus, A. graminis, and G. occidentalis. This influenced the depredation rate by, morphology, prey stage, and the predators’ mouth parts (Croft et al., 2004), since the integuments of O. yothersi adult females are more difficult to penetrate than those of immature prey (Kishimoto y Takagi, 2001; Furuichi et al., 2005).

Regarding consumption, Ragusa et al. (2000) established that C. picanus fed with Tetranychus urticae C.L. Koch (Tetranychidae) eggs reach the adult stage in approximately 4 days, demonstrating a positive influence of this prey in the development of the phytoseiid compared with O. yothersi. This would be explained by T. urticae egg morphology: spherical and easy to handle by the phytoseiids. In contrast, O. yothersi eggs adhere to the surface of the avocado leaf making it difficult to capture, and consequently less attractive as food (Vantornhout, 2006).

The established classification with regard to alternative food was confirmed by pointing out C. picanus and A. graminis as type III generalists and G. occidentalis as a recognized type II specialist preferring the Oligonychus genus (Croft et al., 2004; Shrewsbury and Hardin, 2003). Both generalists would be more adapted to conditions of food scarcity than G. occidentalis which need to feed on mites in order to develop. Ragusa et al. (2000) gave Oxalis sp. and Ricinus sp. pollen to C. picanus exhibiting survival rates of 52% and 44%, respectively in the immature stage. When fed with avocado var. Hass pollen, 43.3% of the population survived, converting it into an ideal alternative food in the absence of the red mite, and demonstrating another comparative advantage over G. occidentalis.  It is also worth mentioning that G. occidentalis in commercial orchards is easily displaced by type III generalist phytoseiids. Slow and smaller-sized, it can also be transformed into prey for phytoseiids, and easily depredated by coleopters belonging to the Stethorus and Oligota genera (Colfer et al., 2003). Therefore, possible field releases of G. occidentalis could only be carried out when the O. yothersi population is high in the orchard, without being able to avoid the physiological damage provoked by the red mite on avocado leaves.

When O. yothersi population density is low and within a context of habitat management, it would be possible to carry out preventive releases of C. picanus starting in September using H. incana pollen, as well as avocado pollen, as an alternative food, since this Brassicaceae is associated to avocado orchards in the Valparaíso Region and could be used as a refuge in hillside commercial plantations (Bouras and Papadoulis, 2005; Palevsky et al., 2007b).

Mated A. graminis females showed a high rate of total consumption, but their eggs were infertile with no descendants over time compared with C. picanus that hatched almost 100% of its eggs. Regarding this phenomenon, several authors have pointed out a likeness to 'kidnapping” or extraction of secondary metabolites from plants, that is, specialist phytophages such as O. yothersi would be extracting alelochemicals from the avocado which would then be stored in their bodies as a defense against their predators, thus affecting in distinct ways the three evaluated phytoseiid species (Aregullín and Rodríguez, 2003; Collier et al., 2007; Zhu-Salzman et al., 2008). For this reason, it is necessary to carry out studies to confirm the presence of these toxic substances found in the red mite and predators. On the other hand, phytophages that have a broad range of host plants do not have the capacity to extract these toxic substances (Trigo, 2000; Termonia et al., 2001). Nishida (2002) points out that these substances extracted from the plants are biochemically transformed before being stored in the bodies of lepidopters. It must also be mentioned that endosymbiontic fungi are present in the plants and influence the tri-trophic interactions (plant-pest-natural enemy), affecting predator development, survival, and reproduction for the production of toxic alkaloids (mycotoxins) (De Sassi et al., 2006).

It must be mentioned that studies evaluating predators based on consumption or female fertility rates do not determine a potential control of the pest and provide incomplete information. High consumption rates do not imply high female fertility and fecundity, since A. graminis showed higher consumption and an oviposition rate similar to C. picanus and G. occidentalis. However, evaluating fecundity, C. picanus had a higher mean of eggs able to develop to the adult stage. It is therefore necessary to determine key biological parameters in ideal conditions to observe the biotic potential of the species of interest.

Establishing life and fecundity tables of predators and prey are fundamental to evaluate the efficiency and potentiality of a natural enemy on a specific pest (Naranjo, 2001; Gabre et al., 2005; Vantornhout et al., 2005; Ozman-Sullivan, 2006; Collier et al., 2007; Reis et al., 2007; Ferrero et al., 2007; Broufas et al., 2007). The above-mentioned information along with consumption registers generate assumptions of potential predator efficiency in the orchard (Chi and Yang, 2003; Kishimoto, 2003; Hosseini et al., 2005; Gotoh et al., 2006). This knowledge is relevant particularly for the assessment of natural enemies that are commercially produced (O’Neil et al., 1998).

In reference to the biological parameters, intrinsic rate of increase (rm) indicates the capacity of the population to multiply in one generation, relating net reproductive rate (R0) on generation time (T) (Rabinovich, 1980), implying the potential control of a natural enemy on a specific pest (Persad y Khan, 2002; Kontodimas et al., 2007). In theory, associating predator intrinsic rate of increase on the prey intrinsic rate of increase, shown by the equation rm predator/rm pest ≥ 1, will indicate an efficiency potential to regulate the pest population. Other important parameters must also be considered such as longevity, predatory capacity, and early prey detection ability in selecting efficient biological control (Fiaboe et al., 2007). Cydnodromus picanus achieved a higher rm than the red mite, signifying that this population has the capacity to control O. yothersi across generations, that is, this species of phytoseiid is an efficient natural enemy of the phytophage mite, and its potential use should be evaluated in the integrated management of avocado mites.

Regarding phytoseiid field releases, all the factors that can influence its effectiveness on a specific phytophage mite must be considered, such as domatia of the host plant (morphological structures of the leaf: depressions, tricomes, cavities between the midrib, and secondary veins that provide refuge for the predator mites generating mutualism) (Matos et al., 2004), chaetotaxia of the predator (length of the dorsoventral setae) (Croft et al., 2004), alternative food availability (Bouras and Papadoulis, 2005), host plant, and leaf area (Collier et al., 2007).


Given the phytoseiid species under evaluation: C. picanus, A. graminis, and G. occidentalis, it can be concluded that:

- C. picanus and G. occidentalis complete their postembryonic development and are able to reproduce by feeding on immature avocado red mites in laboratory conditions, both considered as potential predators of O. yothersi. However, G. occidentalis requires prey in the larval stage for its development and without using alternative food.

- A. graminis has no descendants when feeding on mobile immature O. yothersi. However, its population could be increased in the orchard through a habitat management program since it survives by feeding on avocado var. Hass and H. incana pollen as alternative food.

- A new predator-prey interaction was established under laboratory conditions (C. picanus-O. yothersi). Field releases in the spring of C. picanus upheld its potentiality as a predator of the avocado red mite in the context of Integrated Pest Management.


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