Effects of water mites on the damselfly Ceriagrion tenellum

1. Water mite parasitism is expected to have an important effect on damselfly survivorship and reproductive success, because mites drain considerable amounts of body fluids from their hosts. This study tests the effect of water mite parasitism in a marked population of the damselfly Ceriagrion tenellum during 1995 (individuals marked as mature adults) and 1996 (individuals marked as tenerals).
2. Almost all teneral individuals were parasitized (98%) and mites were aggregated strongly on some individuals. Parasite load increased during the season.
3. Parasites had no effect on the probability of recapture of hosts as mature adults. The average daily survival rate of lightly- and heavily-parasitized individuals, estimated with Jolly's stochastic method, did not differ significantly.
4. In 1995 parasites had a significant effect on host mating success. The probability of mating was about 25% lower for heavily-parasitized males than for lightly-parasitized males. Lightly-parasitized males also mated more times than heavily-parasitized males, even if heavily-parasitized males lived longer. In 1996, parasitism did not have an effect on male mating success. In both years mites had no effect on female lifetime mating success.
5. These results indicate that water mite parasitism does not reduce damselfly survivorship, but it could reduce male mating success in some circumstances. Further long-term studies are needed, especially in populations with a lower incidence of parasitism.     

Mating status, immune defence, and multi-parasite burden in the damselfly Coenagrion armatum

Immunity and reproductive effort are both physiologically costly and often a trade-off between these functions has been shown. In studies with damselflies, parasite load has been associated with fitness costs, such as reductions in mating success, male condition, and survival. Although each individual may be simultaneously infected by various parasite species, most studies have concentrated on the effects of a single parasite taxon. We examined natural ecto- and endoparasite infection levels in male Coenagrion armatum (Charpentier) (Odonata: Coenagrionidae) damselflies in relation to their mating status, fat reserves, and ability to further mount an immune response, measured as encapsulation of an experimentally introduced foreign object. Encapsulation response was lower for mated (paired) males than for single males and declined with increasing water mite abundance. Mated males had fewer water mites than single males. Male weight or fat reserves did not explain variation in encapsulation response. The number of gregarine gut parasites was not related to the level of encapsulation response and did not differ between mated and single males. However, there was a negative correlation between mite abundance and gregarine load. Our data suggest that current mite infection may compromise a male's resistance against further infections by pathogens and parasites, and there may be a trade-off between reproductive effort and encapsulation response in male C. armatum .     

Spatio-temporal population genetic structure of the parasitic mite Spinturnix bechsteini is shaped by its own demography and the social system of its bat host

Information about the population genetic structures of parasites is important for an understanding of parasite transmission pathways and ultimately the co-evolution with their hosts. If parasites cannot disperse independently of their hosts, a parasite's population structure will depend upon the host's spatial distribution. Geographical barriers affecting host dispersal can therefore lead to structured parasite populations. However, how the host's social system affects the genetic structure of parasite populations is largely unknown. We used mitochondrial DNA (mtDNA) to describe the spatio-temporal population structure of a contact-transmitted parasitic wing mite ( Spinturnix bechsteini ) and compared it to that of its social host, the Bechstein's bat ( Myotis bechsteinii ). We observed no genetic differentiation between mites living on different bats within a colony. This suggests that mites can move freely among bats of the same colony. As expected in case of restricted inter-colony dispersal, we observed a strong genetic differentiation of mites among demographically isolated bat colonies. In contrast, we found a strong genetic turnover between years when we investigated the temporal variation of mite haplotypes within colonies. This can be explained with mite dispersal occuring between colonies and bottlenecks of mite populations within colonies. The observed absence of isolation by distance could be the result from genetic drift and/or from mites dispersing even between remote bat colonies, whose members may meet at mating sites in autumn or in hibernacula in winter. Our data show that the population structure of this parasitic wing mite is influenced by its own demography and the peculiar social system of its bat host.     

Temporal change in mite abundance and its effect on barn swallow reproduction and sexual selection

The tropical fowl mite Ornithonyssus bursa parasitizing barn swallows Hirundo rustica in a Danish population demonstrated a dramatic change in abundance during 1982–2000. Prevalence of mites in nests showed a decrease from 66% in 1987 to a minimum of 1% in 1999. Two parasite manipulation experiments of barn swallow nests in 1988 and 1999 revealed a strong effect of parasites on host reproductive success in the first year (with an average reduction in seasonal reproductive success of 30% when 50 mites were added to nests as compared with controls), but only a weak effect the last year. This pattern was paralleled by a positive relationship between reduction in host reproductive success between egg laying and fledging and mite prevalence during different years of the study period. Mite abundance on adult hosts was negatively related to tail length of males (a secondary sexual character) at the peak of mite abundance in 1988, while that relationship became weaker in the beginning of the 1990s and disappeared at the end of the 1990s. Assortative mating with respect to mite loads in the 1980s also disappeared in the 1990s. Mean tail length of male hosts increased by 1.3 standard deviations during the study period because of changes in phenotype‐dependent patterns of mortality outside the breeding season. This microevolutionary change in mean male phenotype of the host was accompanied by a correlated response in mite abundance. These results are consistent with the hypothesis that the host has become more resistant to the mite during the study period, and that the mite from earlier playing an important role in natural and sexual selection of the host now is of little importance.     

Female biased parasitism and the importance of host generation overlap in a sexually transmitted parasite of beetles

Sexual transmission is a widespread means of infection, but apart from those in humans, the ecology of sexually transmitted organisms is not well known. In this study, we present an ecological study of a sexually transmitted mite, Parobia husbandi Seeman and Nahrung (Acari: Podapolipidae), that lives beneath the elytra of Chrysophtharta agricola (Chapuis) (Coleoptera: Chrysomelidae). In each of 2 yr, prevalence of mites on beetles began each spring at about 10-20% but gradually increased to 80-100% by late summer. Overlap of adult beetle generations at this time (i.e., the parental generation mating with the F1 generation) is essential for the persistence of these mites. Mites exhibited temporal change in their spatial distribution on beetles; these changes were probably a response to beetle activity (e.g., emergence from diapause) and the need for dispersal from parental to F1 generation beetles. Prevalence and mean intensity of mites was higher on female beetles compared with male beetles. Female bias of sexually transmitted infection has been predicted in animals but hitherto observed only in primates. We speculate that variable male mate-finding success is the cause of these sex-based differences of mite infections, and that female bias in sexually transmitted disease (STD) infection will be widespread in the animal kingdom.     

Cover Caption

Spider mites are notorious agricultural pests worldwide. A male adult of Tetranychus truncatus is waiting for mating with a female. Spider mites harbor diverse bacterial communities, whose structure could be affected by many factors. We found that host species is the primary determinant of the microbiome composition of spider mites. Also, the microbiome of spider mite feces potentially reflects the gut bacterial community in spider mites (see pages 859‐868). Photo provided by Xiao‐Yue Hong of Nanjing Agricultural University, China.     

Possible ecological consequences of heterospecific mating behavior in two tetranychid mites

Interspecific mating between the two-spotted spider mite,Tetranychus urticae Koch, and the Banks grass mite,Oligonychus pratensis (Banks), was documented using laboratory populations. The incidence of mating betweenT. urticae males andO. pratensis females was 26.0%, while that for the reciprocal mating was 18.8%. The incidence of mating was affected by both male and female species. Such matings may have several important ecological consequences. Interspecific matings resulted in all-male progenies. Thus, progeny sex ratios may be distorted by misdirected mating behavior. In addition, heterospecific mating resulted in lower fecundity than conspecific matings in the two-spotted spider mite, although not in the Banks grass mite. Aerial dispersal behavior of the two-spotted spider mite was also affected. Under crowded conditions and deteriorating resource quality, female mites exhibit an aerial dispersal posture that helps them to become airborne, and allows them to disperse long distances. Forty-two percent ofT. urticae females that mated with conspecific males exhibited this dispersal behavior, compared to only 3.6% for virgin females. The incidence of aerial dispersal behavior for females that mated with heterospecific males was intermediate (27.3%). The effects of these behavioral alterations on male and female fitness may depend on the population structure and resource distribution.     

Occurrence of protandry and a female-biased sex-ratio in a sponge-associated water mite (Acari: Unionicolidae)

The sex ratio of aUnionicola crassipes-type mite from a pond in Alberta, Canada, was found to be significantly female-biased at the time of adult emergence. Male mites emerged earlier, but were later surpassed in number by the females. This protandry seems more likely to be due to the smaller size of the males and hence their faster developmental rate than to any mating advatage the male mites gain by early emergence. It is possible that group selection acting on the productivity of mite colonies with different proportions of low-sex-ratio producers has selected for female-bias. Water mites are not known to exhibit any atypical modes of reproduction (e.g.arrhenotoky), nor is it known whether pre-adult maleU. crassipes have a greater mortality rate than females, so the mechanism behind the skewed ratio is not known.     

Parasites physically block host copulation: a potent mechanism of parasite-mediated sexual selection

Research on the role of parasites in sexual selection has focusedmainly on host mate choice favoring relatively unparasitizedmales. But parasites can also generate variance in host reproductivesuccess by influencing the ability of individual hosts to directlycompete among themselves for mates or fertilizations, a subjectarea that has received far less attention. We demonstrate experimentallythat parasitism by mites can drive sexual selection by way ofa novel mechanism involving male competition: physical inhibitionof host copulation. Mite resistance in natural populations isheritable, emphasizing the evolutionary potential of parasite-mediatedsexual selection in this system and indicating that femalesshould be receiving indirect fitness benefits as a result ofthis process. We show that parasitism by mites, Macrochelessubbadius, reduces mating success of male Drosophila nigrospiracula.Smaller males were more strongly compromised, identifying hostbody size as a tolerance trait. As parasite load increased,the rate at which males attempted to copulate but failed becauseof obstruction by mites increased. When mites were removed frominfested males, host mating success was restored. Thus, thephysical presence of the mites per se generates differentialmating success, in this case by interrupting the normal flowof mating behaviors. This study elucidates a potent mechanismof parasite-mediated sexual selection in a system wherein parasiteresistance is demonstrably heritable, and as such expands ourunderstanding of the evolutionary potential of sexual selection.     

Age,Experience and Sex – Do Female Bulb Mites Prefer Young Mating Partners?

In species where advancing sire age is associated with decreased progeny fitness, female resistance to mating with old partners can be expected to evolve. In polyandrous species, such resistance may be contingent on female mating experience: virgins should be relatively indiscriminate to ensure egg fertility, whereas non‐virgins can be expected to base their re‐mating decisions on the age of their previous versus potential new partners, and ‘trade‐up’ if previously mated with old males. Here, we tested these predictions using a promiscuous and relatively long‐living bulb mite (Rhizoglyphus robini), in which old sire age is associated with decreased fecundity of daughters. In a fully factorial design, we applied two male treatments, young and old, and three female treatments, virgin, previously mated to an old male and previously mated to a young male. Consistent with earlier studies, we observed a reduced mating success of old males. However, we found no support for attributing this result to female discrimination, as female behavior in response to male mounting attempts was not affected by the age of the suitor, or by its interaction with the age of the female’s previous mate. Interestingly, females were passive during 93% of male mounting attempts observed, suggesting that once they are located by a male, they exert little control over copulation. Old males had lower mate‐searching activity and were less efficient in obtaining matings (lower success rate per mounting attempt), suggesting a decreased mate‐securing ability because of aging. Overall, our results suggest that in bulb mites, male ability to secure mates declines with age, whereas they do not support the prediction that females actively discriminate against old partners.     

EFFECT OF ECTOPARASITIC MITES ON SEXUAL SELECTION IN A SONORAN DESERT FRUIT FLY

We conducted a field study and a laboratory experiment to test whether ectoparasitic mites, Macrocheles subbadius, generate parasite-mediated sexual selection in the Sonoran desert endemic fruit fly, Drosophila nigrospiracula. Male flies gather on the outer surfaces of necrotic saguaro cacti where they engage in male–male competitive interactions and vigorous female-directed courtship. At these sites, operational sex ratios were significantly skewed toward males. The degree to which mites were aggregated among flies varied across the 25 fly populations sampled. The degree of mite aggregation across fly populations was strongly positively related to the mean number of mites per fly (intensity of infestation). Both the intensity and prevalence of infestation (fraction of flies infested) increased with the age of the cactus necrosis. Infested flies of both sexes were significantly less likely to be found in copula than uninfested flies, and mean intensity of infestation was significantly more pronounced in noncopulating than in copulating flies. The effect of attached mites on copulatory success exhibited dose-dependency, and this effect was more stringent in males: males or females with more than two and four mites, respectively, were never found in copula. The magnitude of parasite-mediated sexual selection was estimated for 12 fly populations by calculating selection differentials for each sex separately. The relation between intensity of infestation and magnitude of parasite-mediated sexual selection was stronger in males but significant for both sexes. We also assayed copulatory success of field-caught males in the laboratory, both during infestation and after experimental removal of mites. Males infested with two mites copulated less frequently than uninfested individuals, and in mating trials after mites had been removed, previously infested males copulated as many times as flies with no history of infestation. These findings, and the lack of difference in the number of mite-induced scars on copulating and single individuals in nature, strongly suggest that the reduced copulatory success of infested flies is attributable to an effect of mites per se, rather than to a character correlated with parasitism or previous parasite infestation.     

Ectoparasitism in mothers causes higher positional fluctuating asymmetry in their sons: implications for sexual selection

Random deviations from perfect bilateral symmetry, fluctuating asymmetry, arise from developmental instability. I tested experimentally whether parasitism in female Drosophila nigrospiracula increases fluctuating asymmetry in male offspring. I also developed a novel measure for estimating developmental instability in a meristic trait called positional fluctuating asymmetry, which is based on the difference in the position of thoracic bristles between the right and left sternopleuron. I expected this measure to be a more sensitive indicator of developmental instability than the traditional numerical fluctuating asymmetry, because the latter is based on the difference in the actual presence or absence of bristles. Female flies burdened with hematophagous mites, Macrocheles subbadius (Macrochelidae), produced sons with significantly higher positional fluctuating asymmetry than did females carrying no mites. This effect, which may have resulted from impaired provisioning of oocytes by infested females, was dose dependent and magnified in the progeny of younger (18-20 d) versus older (30-32 d) females. This apparent magnification resulted from a slight but not significant increase in asymmetry of offspring of the older and unparasitized females. In contrast, the same mite loads had no effect on offspring numerical fluctuating asymmetry. If low-positional fluctuating asymmetry males enjoy a mating advantage, then with appropriate genetic variability, sexual selection could drive the evolution of host resistance in host populations. However, variability in neither kind of asymmetry influenced male mating success in nature. Thus, although male positional fluctuating asymmetry is causally associated with parasitism via maternal effects, asymmetry-based sexual selection is unlikely to influence the evolution of mite resistance in D. nigrospiracula. The value of the sensitivity afforded by positional fluctuating asymmetry is discussed in the context of sexual selection and conservation biology.     

Mating behavior of the predatory mite <Emphasis Type="Italic">Kampimodromus aberrans</Emphasis> (Acari: Phytoseiidae)

The mating behavior of the predatory mite Kampimodromus aberrans was studied in the laboratory at a constant temperature of 25± 1 °C and a photoperiod of 16:8 (L:D). Forty pairs of newly emerged virgin females and unmated males, were maintained separately on leaf discs and their mating behavior, was observed continuously under a stereomicroscope. The mean time until first contact of female and male individuals was approximately 8.2 min. After the first contact the male moved to the top of the female’s dorsum and subsequently underneath her in approximately 1.7 min and then the paired mites walked around on the leaf surface for approximately 7.5 min. Afterwards, the mites remained still in the mating position, i.e. the male beneath the female for an average period of 230.5 min. After mating, most of the females had one spermatophore in one of their spermathecae, whereas a few had one spermatophore in both spermathecae.     

Spermatozoa production in male <Emphasis Type="Italic">Varroa destructor</Emphasis> and its impact on reproduction in worker brood of <Emphasis Type="Italic">Apis mellifera</Emphasis>

Reproduction in Varroa destructor exclusively takes place within the sealed honey bee brood cell and is, therefore, limited by the duration of the postcapping period. Oogenesis, ontogenetic development and mating must be optimized to ensure the production of as many mated daughter mites as possible. One adult male mite has to mate with up to five sister mites and transfer 30–40 spermatozoa to each female. We analyzed the production and transfer of male spermatozoa during a reproductive cycle by counting all spermatozoa in the genital tracts of the male and daughter mites in 80 worker brood cells at defined times after cell capping. We could show that spermatozoa production in male mites is an ongoing process throughout their adult lifetime starting after the adult molt. The spermatozoa are transferred to the females in an early non-capacitated stage and require further maturation within the female’s genital tract. Our study points out that a Varroa male has at any time in the brood cell enough spermatozoa to inseminate all daughter mites but does not waste energy in producing a big surplus. In total one male produced, on average, 125 spermatozoa during a reproductive cycle in worker brood which is sufficient for successful matings with at least three daughter mites. Spermiogenesis in Varroa males represents therefore a further adaptation to the limited time available for reproduction.     

Male demographic constraints to extreme sex ratio in the twospotted spider mite

Summary Twospotted spider mites, Tetranychus urticae Koch are arrhenotokous. As a result of this genetic structure, primary and secondary sex ratios diverge from the 1:1 female:male ratio commonly found in diploid systems. Ratios vary, but 3:1 is the most common. The influence of life history parameters on spider mite sex ratio is unclear, although maternal genetic effects, resource quality and maternal age are known to play a role. An area that has not been studied is the relationship between male reproductive capabilities and spider mite sex ratio. A prior study on male reproduction in spider mites suggests that males have far too high a reproductive capacity to explain sex ratio patterns, but that study was not conducted under realistic mating conditions. Thus, this study was conducted to determine if there is a link between male reproduction and spider mite sex ratio. This was done by exposing males to various exposure regimes of females and recording the number of copulations, inseminations and daughters fathered by each male. Results include the following: i) males are most virile when one day old; ii) virgin males become nearly completely devoid of sperm (or other copulatory products) after about 15 matings and then take about four days to recover; and iii) the optimal number of matings per day (defined as that which produces the greatest number of daughters in the least number of inseminations) is four females per day. The principle conclusion is that although males have a high potential reproductive output, insemination quality is only high for the first four or five matings each day. Therefore, to ensure full inseminations of all daughters by sons, females are constrained to producing primary sex ratios of about 5:1 or less.     

Ectoparasites do not affect ejaculate volume in the dragonfly Coenagrion puella

Abstract. Imagoes of the dragonfly Coenagrion puella are parasitized frequently by ectoparasitic water mites. In an experimental study of the parasite load we examined the influence of parasite burden on host sperm volume. Infection with ectoparasitic water mites did not affect sperm volume in the seminal vesicle (ejaculate volume). It is concluded that water mite parasitism does not affect male fitness in C. puella by reducing sperm production.     

Feather mite abundance increases with uropygial gland size and plumage yellowness in Great Tits Parus major

Plumicolous feather mites are ectosymbiotic organisms that live on bird feathers. Despite their abundance and prevalence among birds, the ecology of the interaction between these organisms and their hosts is poorly known. As feather mites feed on oil that birds spread from their uropygial gland, it has been hypothesized, but never tested, that the number of feather mites increases with the size of the uropygial gland of their hosts. In this study the number of feather mites is considered with respect to uropygial gland size in a breeding population of Great Tits Parus major in order to test this hypothesis. As predicted, the number of feather mites correlated positively with the uropygial gland size of their hosts, showing for the first time that uropygial gland size can explain the variance in feather mite load among conspecifics. Previous studies relating feather mite load to plumage colour have suggested that feather mites may be parasitic or neutral. To confirm this, the yellowness of breast feathers was also assessed. However, the results ran in the opposite direction to that expected, showing a positive correlation between mite load and plumage yellowness, which suggests that further work is needed to give clear evidence for a specific nature of feather mites. However, Great Tits with higher mite loads had lower hatching and breeding success, which may support the idea that feather mites are parasites, although this effect must be taken with caution because it was only found in males. Age or sex effects were not found on the number of feather mites, and it is proposed that hormonal levels may not be sufficient to explain the variation in feather mite loads. Interestingly, a positive correlation was detected between uropygial gland size and plumage brightness, which could be a novel factor to take into account in studies of plumage colour.     

Survival and reproductive rate of mites in relation to resistance of their barn swallow hosts

Parasite resistance may act via a number of different mechanisms that regulate or control the survival and the reproductive rate of parasites. Observations and experiments were used to test for effects of host resistance on parasite survival and rate of reproduction. Natural levels of infestation of barn swallow Hirundo rustica nests by the tropical fowl mite Ornithonyssus bursa were positively related to brood size, inversely related to the length of the outermost tail feathers of male nest owners (a secondary sexual character) and affected by time of reproduction by the host. A mite inoculation experiment, in which 50 adult mites were introduced into nests during the laying period of the host, was used to test for differential survival and reproduction of mites as a function of host resistance. The relationship between survival and reproduction of parasites, male tail length and host resistance was investigated. There was a negative relationship between mite numbers per nest after fledging of nestlings and male tail length. This relationship was mainly caused by a reduction in the number of mites in the first and second nymph stage with increasing tail length of male hosts, implying a reduction in rate of reproduction of mites. The proportion of mites that had recently fed was inversely related to tail length of male hosts. The proportion of nymph stages was positively related to the proportion of mites that had recently had a blood meal. Parasite resistance of barn swallows to the tropical fowl mite thus appeared to act through increased mortality rate of adult and nymph stages of mites, and through reduced reproductive rates of mites on resistant hosts. This is the first study demonstating a direct relationship between fitness components of a parasite and the expression of a secondary sexual character of a host. Received: 11 January 2000 / Accepted: 22 March 2000     

Water mites as indicators of natural aquatic ecosystems of the coastal dunes of the Netherlands and northwestern France

A large number of coastal dune waters in the Netherlands and northwestern France have been investigated for the occurrence of water mites. Dune waters turned out to be very rich in water mite species. In the Dutch dunes, 110 species of water mites have been found; this is 50 % of the total number of water mite species present in the Netherlands. In the French dunes 64 species have been found. The water mites most characteristic of the coastal dunes are the temporary water species. Dune areas with a high-lying hinterland have a water mite composition much different from dune areas with a low-lying hinterland. This can be explained by the existence of a very different hydrology. During the last century human activity affected the ground water of dunes. Afforestation and extraction of ground water for drinking water purposes caused a lowering of the ground water table. As a result, many dune slacks dried out. Moreover, the infiltration of river water caused an eutrophication of the ground water. Nowadays, the dunes most rich in typical water mite species are the dunes in which neither infiltration of river water nor extraction for drinking water purposes, occur. It can be concluded that water mites are good indicators for dune areas with a natural hydrology.     

The effect of sub-floor heating on house-dust-mite populations on floors and in furniture

It is well known that dehydrating conditions for house dust mites can be created by simply raising the temperature, causing loss of body water and eventually death. Thus, it can be expected that conditions for dust mites are less favourable on floors supplied with sub-floor heating. This was examined in a study of 16 houses with sub-floor heating and 21 without. The pattern of changes in air humidity and temperature on the floors was investigated and compared to known data of the tolerance of dust mites. Also the resident mite populations were compared. Floors with sub-floor heating had, on average, fewer mites, but the difference with unheated floors was small. It was remarkable that mite numbers were also lower in upholstered furniture. Another important observation was that some houses with sub-floor heating had high mite numbers, indicating that this type of heating is compatible with a thriving mite population. Temperature and humidity conditions of heated floors may allow mites not only to survive, but also to remain active in winter. A moderate increase in temperature, a moderate decrease inf (absolute) air humidity, or a combination of both, will suffice to keep the humidity all winter below the Critical Equilibrium Humidity, the level of air humidity that is critical for mite growth and reproduction, hence for allergen production. However, it is argued that measures to suppress allergen production by house dust mites are likely to be far more effective if taken in summer rather than in winter. This revised version was published online in July 2006 with corrections to the Cover Date.