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Article

Syringophilid Quill Mites Obey Harrison’s Rule

by
Lajos Rózsa
1,*,
Mónika Ianculescu
2 and
Martin Hromada
3,4
1
Institute of Evolution, HUN-REN Centre for Ecological Research, Konkoly-Thege Street 29-33, H-1121 Budapest, Hungary
2
Hungarian Department of Biology and Ecology, Babeș-Bolyai University, Clinicilor Str. 5-7, 400006 Cluj-Napoca, Romania
3
Laboratory and Museum of Evolutionary Ecology, Department of Ecology, Faculty of Humanities and Natural Sciences, University of Presov, 080-01 Prešov, Slovakia
4
Faculty of Biological Sciences, University of Zielona Góra, Prof. Z. Szafrana 1, 65-516 Zielona Góra, Poland
*
Author to whom correspondence should be addressed.
Diversity 2024, 16(9), 516; https://doi.org/10.3390/d16090516
Submission received: 9 July 2024 / Revised: 17 August 2024 / Accepted: 19 August 2024 / Published: 29 August 2024
(This article belongs to the Section Animal Diversity)
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Abstract

:
Harrison’s Rule (HR) postulates a positive allometry between host and parasite body sizes. We tested HR for Syringophilid quill mites parasitizing birds. Using host body mass and parasite body length as size indices, this pattern was absent in the Syringophilidae family and the Syringophilinae subfamily as a whole. However, when considering the parasite genera as units of study, as proposed originally by Harrison, we found that host body mass positively correlates with both male and female parasite body length in seven genera (Aulobia, Aulonastus, Neoaulonastus, Picobia, Neopicobia, Syringophilopsis, and Torotrogla). Most of these relationships were non-significant. On the contrary, male and female Syringophiloidus mites exhibited negative relationships with host mass (both non-significant). This apparent contradiction disappeared when we applied wing length as an index of host body size. Since species of this genus are specific to the host flight feathers (secondaries and also primaries), wing length is a more meaningful index of host body size than body mass. Overall, most cases corresponded to the positive direction predicted by Harrison when examined on the genus level. This finding also implies a surprising reliability of the genus concept, at least in this group of ectoparasites.

1. Introduction

Body size is a fundamental property of organisms that affects most aspects of their metabolism, behavior, and ecological relationships. For example, body size is directly related to fecundity. In comparisons across large phylogenetic distances, the fecundity of larger-sized animal taxa tends to be lower [1,2]. On the contrary, in intraspecies comparisons, larger organisms usually give birth to more offspring [3,4]. In parasites, larger body size associated with increased metabolism and higher fecundity can also cause the higher virulence of infections [5].
More than a century ago, Launcelot Harrison published an article about the feather lice of kiwis, with a voluminous explanation of his views about the coevolution of birds and lice [6]. He mostly speculated about the phylogenetic relationship between rails (Rallidae) and kiwis (Apterygidae), which he erroneously presumed due to the presence of the Rallicola spp. lice they are both infested by. Hidden in this lengthy and somewhat rambling text, he stated the following:
…in general, when a genus is well distributed over a considerable number of nearly related hosts, the size of the parasite is roughly proportional to the size of the host…
Briefly, he recognized a positive relationship between host and parasite body sizes in comparisons across species, presumed that the hosts are “nearly related,” and that the parasites are congeneric. Unfortunately, “near relatedness” is not well defined, and similarly, the genus concept is also an arbitrary taxonomic artifact rather than an objective criterium. Later authors called this relationship “Harrison’s Rule” (HR), although this is more a hypothesis than a rule. Several studies verified it for diverse parasite taxa [7,8,9,10,11,12,13].
Our present study aims to test HR using a taxon of a most severely space-limited avian ectoparasites, the quill mites (Syringophilidae). They are prostigmatic mites (Acari: Acariformes: Prostigmata) strictly associated with avian (Vertebrata: Aves) hosts. Their ancestors presumably appeared on feathered dinosaurs in the Early Jurassic [14,15]. All species live and reproduce inside the feather quills (calamus) [16]. Due to a basal divergence at an early stage of their evolution, they are divided into two subfamilies, which exhibit different anatomic site (or “niche”, in a certain sense) specificity on the host body surface [17]. Species of the subfamily Syringophilinae mainly inhabit the quills of secondaries. There can be two deviations from this niche: relatively small-bodied species tend to also infest the wing coverts, while large ones can be found in the primaries. (Some small-bodied Syringophiline genera, such as AulonastusNeoaulonastus, and some others, may infest wing coverts and also body feathers [18]). By contrast, representatives of the subfamily Picobiinae always infest the quills of body feathers (except for Calamincola [19], which is not included in the present study).
Quill mites live a peculiar way of life. A fertilized female (or rarely two of them) enters a developing feather’s calamus through the superior umbilicus opening [20]. This opening closes soon, and the female will produce a single (rarely more) male and several female offspring in this enclosed capsule. Then, the brother(s) fertilizes the sisters, and the next generation still lives enclosed in the same quill. After the grandchildren of the founding mother also fertilized each other, and mites basically fill the whole cavity of the calamus, fertilized females disperse to search for developing new feathers either on the same host or on another individual [16,21].
Thus, these parasites live a strictly space-limited life. If they grow too large, they die due to the lack of enough space in the enclosed capsule of the feather quill. Conversely, if they are too small, they cannot pierce the quill wall with their mouthparts to obtain nutrients from the surrounding tissues [18]. The presumed strict optimization of their body size makes them an optimal choice to test HR.
Syringophilid mites have a haplodiploid sex determination system [22]. Several species appear to lack male individuals, possibly parthenogenetic, or the rare males may be unknown due to sampling bias. Consequently, they are highly inbred and, therefore, almost totally free of sexual selection pressure, although male vs. female body sizes are still affected by different selection pressures [23]. For this reason, below we analyze the host–parasite body size allometry separately for male and female quill mites.

2. Materials and Methods

We used the total body length (μm) measurements of male and female quill mites gathered from the taxonomic literature. Data from the holotype specimens were used whenever possible. Otherwise, we calculated the average of the extreme values of the paratype series. Picobiine species may have two alternative female morphologies. Some of the “normal” (non-physogastric) females may develop a physogastric morphology characterized by a greatly enlarged abdomen, containing a few, but huge, eggs. We only considered the “normal” (non-physogastric) female size and excluded data on the much less frequent physogastric morphs. Note that the species descriptions are based on preparations embedded in Canada balsam on microscopic slides. Therefore, they may not reflect the true body length of living parasites, but rather the size of almost two-dimensional arbitrary preparations. Thus, their apparent body length may partially depend on the pressure exerted on the cover glasses when preparing the microscopic slides. From this point of view, it is important to note that most of the species involved in the present study were described by a relatively small group of authors who closely collaborate with each other, which may make their preparation techniques more homogenous than in most other ectoparasite taxa where species are described by many different authors working independently of each other. Data were obtained from species descriptions [24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73,74,75,76,77,78,79,80,81,82,83,84,85,86,87,88,89,90,91,92,93,94].
First, we intended to test HR at levels above the genus level, the Syringophilidae family, and the Syringophilinae and Picobiinae subfamilies, and then to test it at the genus level. Further, we tested male and female parasite body sizes separately. Therefore, we included only those genera for which both male and female body length, and host body mass, were known for an appropriate number of species (>5, an arbitrary limit). This criterion excludes parthenogenetic species [22] or those whose males we do not know. Overall, we considered eight genera and 110 species in the present study, which significantly overlap with those in our recent study [19] on sexual size dimorphism, with new data from more recent species descriptions added. We consider this set of species a random sample representing the Syringophilidae family as a whole.
Host species were identified by the host designated as the type host in the taxonomic literature. Their mean body size was quantified as the mean body mass (g) obtained from the literature [95]. We also gathered data for wing length (the longest primary, in mm) from [96] for the hosts of Syringophiline species but not for the Picobiines which infest contour feathers. Body mass data were lacking for some, and wing length data were lacking for several host species. All body length, body mass, and wing length data were log-transformed. Then, we applied Type-1 linear regressions to test whether host body size measures predict parasite body size.

3. Results

When including all species of the Syringophilidae family or narrowing it to the Syringophilinae subfamily, we obtained only non-significant negative trends for both the female and male parasites. By contrast, the length of Picobiinae species is related positively with host body mass, a significant relationship in males (Figure 1, Table 1).
When analyzing all the parasite genera separately, as advised originally by Harrison [6], we documented mostly positive relationships between host and parasite body sizes. Eight quill mite genera were involved in the present study, one of which yielded an opposite result; both male and female Syringophiloidus mites exhibited non-significant negative relationships with host mass. The other seven genera showed positive host–parasite body size allometries, as predicted by HR, both for males and females, even though most of these relationships were statistically non-significant (Table 2). Considering only the directions of these relationships, the probability that the relationships of at least seven out of eight genera lead to the same direction is p = 0.0703 (like the probability of obtaining seven or eight identical results after tossing a coin eight times, from the binomial distribution). When considering the probability of obtaining at least seven-to−one in a predicted direction (predicted by HR), this probability is halved (p = 0.03515).
We do not know exactly the reason why Syringophiloidus exhibited a different (although non-significant) relationship to host body mass. However, since this genus inhabits the flight feathers (mostly secondaries, but sometimes also primaries) of host birds, we tested whether the size of these feathers would be more suitable indices of host body size. We found wing length (mm) data for an appropriate number of species (>6) in only three Syringophiline genera: Syringophiloidus, Syringophilopsis, and Torotrogla. We found a positive relationship between host wing length and parasite body length in all these genera, in both males and females, even though all six relationships were statistically non-significant (Figure 2, Table 2).

4. Discussion

Regarding the Syringophilid family as a whole, we see a negative relationship between host weight (g) and mite body length, contrary to HR. However, any scientific hypothesis can only be complete when its range of validity is determined. Harrison talked about comparisons across congeneric parasite species infecting similar hosts, even though subsequent authors often tested HR on taxa above the generic level with various results [7,8,10,11,12].
At the genus level, all genera, both males and females, exhibited a positive relationship between host mass and parasite length, except for the genus Syringophiloidus. In the case of three of these genera, host body size was also quantified as wing length, and all of them—including Syringophiloidus—obeyed HR. It is plausible to conclude that wing length is a better index of host body size than body mass for mites which inhabit the quills of wing flight feathers (mostly secondaries, but also primaries).
Generally speaking, the covariation of two animal traits should be analyzed by applying a phylogenetic control so as to separate phylogenetic artifacts (effects of conservative traits shared through common ancestry) from coordinated changes in the two traits occurring repeatedly in several independent cases along the phylogeny [97]. However, the present study involves a host trait which evolved along the host phylogeny and a parasite trait which evolved along the parasite phylogeny. Contrary to the classical hypotheses by Fahrenholz [98], host and parasite phylogenies are rarely similar and almost never identical [99], as was also shown for Syringophilopsis quill mites and their hosts [100]. Though it is theoretically possible to simultaneously control for the phylogenetic effects of both phylogenies [101], we chose a much simpler approach because we had too little information about the parasite phylogeny.
The method we used was to demonstrate that the relationship between the host and parasite traits repeats itself over and over again within each parasite genera, independently of each other. Thus, presuming that these genera are monophyletic taxa, our analysis corresponds to the basic logic of a phylogenetically controlled comparative analysis projected onto the parasite phylogeny.

5. Conclusions

Species descriptions usually attract rather few readers and a few citations. Our study above exemplifies an unusual utilization of such studies; we used species descriptions as the source of primary information on the body sizes of species. This approach is most appropriate for taxa where most species descriptions have been prepared by one author, or at least a small group of collaborating authors, using a standard preparation and measurement methodology, like in the case of quill mites.
Our results also indicate an unexpected reliability of the genus concept. Taxonomic ranks above the species level do not exist in nature, nor do they have any general definition. Despite that, Harrison declared that his observation was valid for genera but not necessarily for hierarchical levels above that. Although the genera we analyzed above were non-existent in Harrison’s age, his delineation of the range of validity is nicely supported by our present results.
The adaptive mechanism yielding the host–parasite body size allometry has yet to be fully understood. Host body size sets an upper limit on parasite body size, especially when parasites occupy narrowly space-limited anatomical structures. On the other hand, possible parasite body sizes also have a lower limit, which has rarely been considered [10]. Overall, it seems likely that host body size is typically constrained by environmental (like climatic, etc.) effects and phylogenetic constraints. In contrast, parasite body size tends to track that of the host within its own phylogenetic constraints [102].

Author Contributions

L.R., conceptualization, formal analysis, writing—review and editing, supervision; M.I., resources, data curation, writing—original draft preparation; M.H., writing—review and editing, supervision, funding acquisition. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Research, Development, and Innovation Fund of Hungary, grant number K143622; the National Research, Development, and Innovation Office of Hungary, grant number (RRF-2.3.1-21-2022-00006); the Agency of the Ministry of Education, Research and Sport of the Slovak Republic and the Slovak Academy of Sciences VEGA 1/0876/21; and by the Slovak Research and Development Agency under the contract APVV-22-0440.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

The original contributions presented in the study are included in the article; further inquiries can be directed to the corresponding author.

Acknowledgments

We thank all the authors of the species descriptors on which the present study was based.

Conflicts of Interest

The authors declare no conflicts of interest.

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Diversity 16 00516 g001
Figure 1. (a) The relationship between host and parasite body sizes in the Syringophilidae family; (b) the relationship between host and parasite body sizes in the Picobiinae subfamily (a subset of the species of (a)). Note that the trendlines signify statistically non-significant tendencies (except for Picobiine males). (Light: females; dark: males).
Figure 1. (a) The relationship between host and parasite body sizes in the Syringophilidae family; (b) the relationship between host and parasite body sizes in the Picobiinae subfamily (a subset of the species of (a)). Note that the trendlines signify statistically non-significant tendencies (except for Picobiine males). (Light: females; dark: males).
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Figure 2. In the case of Syringophiloidus spp., host body mass (a) appears to be an inferior index of host body size as compared to host wing length (b). This is plausible, considering that these mites mostly inhabit the host flight feathers (secondaries and also primaries). Note that the trendlines signify statistically non-significant tendencies. (Light: females; dark: males).
Figure 2. In the case of Syringophiloidus spp., host body mass (a) appears to be an inferior index of host body size as compared to host wing length (b). This is plausible, considering that these mites mostly inhabit the host flight feathers (secondaries and also primaries). Note that the trendlines signify statistically non-significant tendencies. (Light: females; dark: males).
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Table 1. Linear regressions between host body mass and parasite body length measures at the family and subfamily levels. * Indicates p < 0.05.
Table 1. Linear regressions between host body mass and parasite body length measures at the family and subfamily levels. * Indicates p < 0.05.
Taxon, SexNSlopeConf. Interval of SlopeR2p (Deviation
from Horizontal)
Syringophilidae females110−0.0405−0.1033, 0.02230.01500.2031
Syringophilidae males110−0.0233−0.0839, 0.03730.00540.4466
Syringophilinae females88−0.0300−0.0994, 0.03940.00860.3915
Syringophilinae males88−0.0233−0.0954, 0.04870.00480.5207
Picobiinae females220.0764−0.0267, 0.17940.10680.1377
Picobiinae males220.08770.0268, 0.14860.31090.0070 *
Table 2. Linear regressions between host body size measures (body mass or wing length) and parasite body length at the genus level. * Indicates p < 0.05.
Table 2. Linear regressions between host body size measures (body mass or wing length) and parasite body length at the genus level. * Indicates p < 0.05.
Log (Body Mass)NSlopeConf. Interval of SlopeR2p (Deviation
from Horizontal)
Aulobia spp. females80.2234−0.2456, 0.69250.18460.2880
Aulobia spp. males80.50990.1318, 0.88800.64470.0164 *
Aulonastus spp. females70.0346−0.0213, 0.09040.33630.1723
Aulonastus spp. males70.0209−0.0550, 0.09680.09100.5108
Neoaulonastus spp. females60.0237−0.0700, 0.11740.10970.5213
Neoaulonastus spp. males60.0316−0.1561, 0.21920.05160.6650
Picobia spp. females150.0619−0.0822, 0.20600.06210.3704
Picobia spp. males150.0918−0.0042, 0.18790.24710.0594
Neopicobia spp. females70.1003−0.0616, 0.26230.33650.1722
Neopicobia spp. males70.08190.0176, 0.14610.68170.0221 *
Syringophiloidus spp. females26−0.0190−0.0627, 0.02460.03260.3772
Syringophiloidus spp. males26−0.0043−0.0500, 0.04130.00160.8460
Syringophilopsis spp. females310.06710.0119, 0.12230.17550.0190 *
Syringophilopsis spp. males310.06070.0110, 0.11050.17690.0185 *
Torotrogla spp. females100.0248−0.0809, 0.13050.03530.6033
Torotrogla spp. males100.0632−0.0108, 0.13720.32670.0843
log (wing length)
Syringophiloidus spp. females170.0423−0.1526, 0.23720.01410.6503
Syringophiloidus spp. males170.1256−0.0875, 0.33870.09520.2283
Syringophilopsis spp. females170.0447−0.1526, 0.24200.01530.6362
Syringophilopsis spp. males170.1383−0.0566, 0.33320.13230.1512
Torotrogla spp. females70.0711−0.3973, 0.53950.02960.7124
Torotrogla spp. males70.1740−0.0820, 0.43000.37910.1410
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Rózsa, L.; Ianculescu, M.; Hromada, M. Syringophilid Quill Mites Obey Harrison’s Rule. Diversity 2024, 16, 516. https://doi.org/10.3390/d16090516

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Rózsa L, Ianculescu M, Hromada M. Syringophilid Quill Mites Obey Harrison’s Rule. Diversity. 2024; 16(9):516. https://doi.org/10.3390/d16090516

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Rózsa, Lajos, Mónika Ianculescu, and Martin Hromada. 2024. "Syringophilid Quill Mites Obey Harrison’s Rule" Diversity 16, no. 9: 516. https://doi.org/10.3390/d16090516

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Rózsa, L., Ianculescu, M., & Hromada, M. (2024). Syringophilid Quill Mites Obey Harrison’s Rule. Diversity, 16(9), 516. https://doi.org/10.3390/d16090516

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