寄生于洪湖经济鱼类鳃上的单殖吸虫包括二新种的描述

本文报告寄生于洪湖经济鱼类鳃上的单殖吸虫共60种,包括描述指环虫和三代虫各一新种,并有若干寄主新记录及长江流域新记录。     

寄生于洪湖经济鱼类鳃上的单殖吸虫包括二新种的描述

本文报告寄生子洪湖经济鱼类鳃上的单殖吸虫共60种,包括描述指环虫和三代虫各一新种,并有若干寄主新记录及长江流域新记录。       

鱼类三代虫研究进展

三代虫是一类常见的鱼类体表寄生虫,广泛寄生于各种鱼类,其危害近年有加剧之势,对鱼类养殖业造成较大威胁。本文从三代虫的分类方法、种群动态和引起寄主免疫反应等方面综述了鱼类三代虫研究现状及发展趋势。     

额尔齐斯河几种鱼类寄生三代虫种类鉴定及系统发育

对采自额尔齐斯河的银鲫(Carassius auratus gibelio Bloch)、东方欧鳊(Abramis brama orientalis Berg)、黏鲈(Gymnocephalus cernua Linnaeus)、金鳟(Oncorhynchus mykiss Walbaum)感染的三代虫(Gyrodactylus sp.)进行了研究, 通过几丁质结构的形态测量与比较, 初步鉴定寄生于银鲫的为细锚三代(G. sprostonae), 寄生东方欧鳊的为秀丽三代虫(G. elegans), 寄生黏鲈的为普氏三代虫(G. prostate), 寄生金鳟的为细鳞鲑三代虫(G. brachymystacis)。同时将测定的三代虫的ITS序列, 与GenBank上三代虫序列进行比对分析, 发现上述4种三代虫分别与细锚三代虫、秀丽三代虫、细鳞鲑三代虫、普氏三代虫的ITS同源性都在99.3%以上, 进一步验证了形态学的鉴定结果。系统发育分析显示细鳞鲑三代虫和细锚三代虫位于G. (Limnonephrotus)亚属的一枝, 秀丽三代虫和普氏三代虫位于G. (Gyrodactylus)亚属的一枝, 而此两亚属亲缘关系较远。     

寄生于罗非鱼的刺纹车轮虫种群分析及其寄主偏好性研究

文章在刺纹车轮虫Trichodina centrostrigata Basson, Van As & Paperna, 1983的重描述基础上, 基于形态学特征、分子特征及系统发育分析, 对其种群多样性及寄主偏好性进行了研究。结果表明, 刺纹车轮虫三个种群: Trichodina centrostrigata (KP295473)、Trichodina centrostrigata (W)和Trichodina centrostrigata (Q)在历经4年的时间里, 未发生明显的种群分化; 其次, 刺纹车轮虫与寄生于海水寄主的车轮虫聚支, 表明二者具有较近的亲缘关系; 再次, 刺纹车轮虫主要寄生于鲈形目的广盐性罗非鱼, 少数寄生于其他淡水鱼类, 具有较强的寄生特异性; 最后, 此研究中的寄主罗非鱼对于刺纹车轮虫具有100%的高感染率, 表明刺纹车轮虫为罗非鱼养殖业中一类潜在病害性微生物。     

我国内陆水体单殖吸虫的宿主特异性分析

报道我国内陆水体单殖吸虫的宿主特异性的研究。研究表明单殖吸虫有很强的宿主特异性,但不同种类的特异的有很大的判别。从目前已有的记录来看,６０％以上的单殖吸虫中只有１种宿主,约７５％的单殖吸虫的宿主仅为１属,超过９７％的单殖吸虫的宿主在１科之内。没有１种单殖吸虫可生于超过３个料的宿主中,但大钩指环虫可在２３属３３种宿主中寄生。在科和发放持异性水平,以锚首虫科和指环虫科单殖吸虫的特异性较强,三代虫科次之     

人工扩繁管氏肿腿蜂的蜂种复壮研究

利用中间寄主黄粉甲Tenebrio molitor L.蛹大量扩繁管氏肿腿蜂Scleroderma guani Xiao et Wu经多代后寄生效果下降,系由蜂种退化所致:利用一种中间寄主导致蜂种的营养来源单一;采用同一种群的蜂及较低的蜂虫比造成近亲繁殖。据此设计复壮措施:利用自然寄主回接、杂交和控制交尾方式。结果表明:(1)回接1代,其子代蜂种的寄生率和寄生成功率分别提高26%和28%~33%。(2)用外缘蜂种与本群蜂种杂交,其子代蜂的发育历期比对照少4d,寄生率和寄生成功率分别提高22%和17%。(3)控制交尾方式促进蜂种复壮。     

番石榴实蝇寄主选择性试验

番石榴实蝇Bactrocera correcta(Bezzi)是一种为害多种水果的害虫,近年来在云南的元江暴发成灾。本试验选择番石榴实蝇的常见寄主:梨、芒果、苹果、桃、橙及芒果的不同品种进行室内试验,比较番石榴实蝇雌虫产卵对寄主的选择性及不同寄主对番石榴实蝇生长发育的影响。结果显示,番石榴实蝇雌虫对5种供试水果的寄生选择性大小依次为桃>梨>芒果>橙>苹果;番石榴实蝇对芒果不同品种的寄生选择性为三年芒>台农行1号>虎豹牙>胭脂芒>鹰嘴芒;番石榴实蝇在不同寄主上的蛀果期(卵及幼虫的历期)具有极显著的差异,以寄生桃和芒果的最短;从梨和苹果上饲养出的蛹最轻,且极显著低于其它寄主上饲养出来的蛹重;苹果上寄生的番石榴实蝇蛹重与蛀果期呈显著的正相关,而寄生梨的番石榴实蝇蛹重与蛀果期呈极显著的负相关。结果表明,番石榴实蝇雌虫产卵对不同寄主或同一寄主不同品种有明显的选择性,且该选择行为与其后代的生长发育有关。     

二种寄生蜂寄生对不同虫龄小菜蛾精巢的影响

为探明寄生蜂引起寄主寄生性去势的机制,本文选取携带不同多分DNA病毒(Polydnavirus,PDV)的2种内寄生蜂与共同寄主小菜蛾Plutella xylostella(L.)为寄生体系,研究不同虫龄小菜蛾被寄生后雄性生精细胞、精子束形态和精巢发育体积变化,系统比较寄生性去势程度和分别拥有2类PDV的寄生蜂在寄主精子发生和形成过程中的作用。结果表明:携带Bracovirus PDV的菜蛾盘绒茧蜂Cotesiave stalis(Haliday)或拥有Ichvovirus PDV的半闭弯尾姬蜂Diadegma semiclausum Hellén寄生对不同虫龄小菜蛾的精子发生和形成过程均产生明显的抑制作用,表现为不能产生精子束或精子束数量减少,但抑制程度以寄生低龄寄主时最明显。2种蜂寄生均能抑制小菜蛾精巢体积的增长,但对低龄寄主的抑制程度明显强于高龄寄主,寄生性去势程度取决于寄生时寄主虫龄。相比而言,寄生不同虫龄小菜蛾时,茧蜂引起小菜蛾寄生性去势的程度均强于姬蜂。     

红脉穗螟寄生蜂寄主选择研究

[目的]优化红脉穗螟寄生蜂繁育技术,为该虫的生物防治提供参考。[方法]通过室内饲养研究了红脉穗螟幼虫寄生蜂褐带卷蛾茧蜂和蛹寄生蜂周氏啮小蜂(海南种)对4种昆虫的寄生效果,并对最佳接种比例进行筛选。[结果]褐带卷蛾茧蜂对大蜡螟幼虫寄生效果优于米蛾幼虫,且对黄粉虫和大麦虫幼虫不表现寄生特性,褐带卷蛾茧蜂和大蜡螟幼虫的最佳接种比例为1∶1和2∶1,其中在2∶1接种比例处理中的寄生率和单寄主产蜂量分别为76.67%和34.60头;4种昆虫蛹均可用于繁育周氏啮小蜂,从寄主的繁育成本和寄生效果分析,以黄粉虫蛹效果较最佳,接种蜂虫比以2∶1为宜,此时的单寄主产蜂量为148.60头。[结论]寄主和接种比例不同会影响寄生蜂的寄生效果,本研究中褐带卷蛾茧蜂适宜寄主为大蜡螟,最优蜂虫比为1∶1和2∶1,周氏啮小蜂(海南种)适宜寄主为黄粉虫,最优接种蜂虫比为2∶1。     

Experimental infections of the monogenean Gyrodactylus turnbulli indicate that it is not a strict specialist

Parasites represent a threat to endangered fish species, particularly when the parasite can host switch and the new host is vulnerable. If the parasite is highly host specific then successful host switching should be a rare occurrence; however, the host range of many parasites which are assumed to be specialists has never been tested. This includes the monogenean Gyrodactylus turnbulli, a well-studied ectoparasite found caudally on its known host, the guppy, Poecilia reticulata. In this study, we monitored parasite establishment and reproduction on a range of poeciliids and more distantly related fish. Individually maintained fish were experimentally infected with a single parasite and monitored daily to establish whether G. turnbulli could survive and reproduce on other fish species. Gyrodactylus turnbulli can infect a wider range of hosts than previously considered, highlighting the fact that host specificity can never be assumed unless experimentally tested. Our findings also have significant implications for parasite transmission to novel hosts and provide further insight into the evolutionary origins of this ubiquitous group of fish pathogens. Previous molecular evidence indicates that host switching is the key mechanism for speciation within the genus Gyrodactylus. Until recently, most Gyrodactylus spp. were assumed to be narrowly host specific. However, our findings suggest that even so-called specialist species, such as G. turnbulli, may represent a threat to vulnerable fish stocks. In view of the potential importance of host switching under artificial conditions, we propose to describe this as 'artificial ecological transfer' as opposed to 'natural ecological transfer', host switching under natural conditions.     

Experimental infections with the tropical monogenean,Gyrodactylus bullatarudis: Potential invader or experimental fluke?

Introduced exotic species have the potential to spread their associated parasites to native species which can be catastrophic if these hosts are immunologically naïve to the novel parasite. The guppy (Poecilia reticulata) has been disseminated worldwide outside of its native habitat and therefore could be an important source of infection to native fish species. Its parasite fauna is dominated by the ectoparasitic monogeneans, Gyrodactylus turnbulli and Gyrodactylus bullatarudis. The current study tested the host specificity of G. bullatarudis by experimentally infecting a range of isolated fish hosts, including temperate species. Surprisingly, the parasite was capable of establishing and reproducing, for several days, on the three-spined stickleback when transferred directly to this host. We also established that G. bullatarudis could be transmitted under aquarium conditions at both 25 °C and 15 °C. At the higher temperature, the parasite was even capable of reproducing on this atypical host. The implications of these findings are discussed in terms of host specificity, host switching and climate change.     

Nominal species of the genus Gyrodactylus von Nordmann 1832 (Monogenea: Gyrodactylidae), with a list of principal host species

The total diversity of the monogenean genus Gyrodactylus is evaluated. There are 409 potentially valid species names within the genus, recorded from c. 400 host species. Five species have been placed within Fundulotrema and an additional 51 Gyrodactylus species names represent synonyms, nomina nuda or have been reassigned to other non-viviparous monogenean genera. While the majority of Gyrodactylus species (59%) are recorded from single hosts, some have a much broader broad range.     

Host specificity dynamics: observations on gyrodactylid monogeneans

The directly transmitted viviparous gyrodactylids have high species richness but low morphological and biological diversity, and many species are recorded from only a single host. They therefore constitute a guild of species ideal for studies of the evolutionary significance of host specificity. The group has the widest host range of any monogenean family, being found on 19 orders of bony fish. However, individual species range from narrowly specific (71% of 402 described species recorded from a single host) to extremely catholic (Gyrodactylus alviga recorded from 16 hosts). Gyrodactylid-host interactions extend from 60 mya (G. lotae, G. lucii) down to 150 years (G. derjavini on Oncorhynchus mykiss). Co-evolution with the host is comparatively rare within the gyrodactylids, but host switching or ecological transfer is common, and has been facilitated by the mixing of fish strains that followed glaciation. In this review, we consider the factors responsible for gyrodactylid specificity patterns, using examples from our work on salmonid gyrodactylids including G. salaris, responsible for major epidemics on wild Atlantic salmon (Salmo salar) in Norway since 1975, and G. thymalli from grayling and G. derjavini from trout.G. salaris has a wide host range with highest population growth rates on Norwegian salmon strains. However, growth rates are variable on both host strains and species, because of the multitude of micro- and macro-environmental factors influencing parasite mortality and fecundity. A better predictor of performance is the proportion of fishes of a strain which are innately resistant to the parasite, a measure which is negatively correlated with the time to peak infection in a host strain. Population growth rate is also negatively correlated with age of infection; the initial rate, therefore, predicts best the suitability of a fish as host for G. salaris. The host response to gyrodactylids appears to be the same mechanism in all salmonids with innate resistance as one end of a spectrum, but influenced by stress and probably under polygenic control. Hybrid experiments show that performance of G. salaris on a host is heritable, and usually intermediate between that of the parents. This host response mechanism, coupled with the initial parasite population growth on a fish, determines the host specificity, i.e. whether the fish will be susceptible, a responder or innately resistant. The use of population growth rate parameters allows comparison of different hosts as a resource for a gyrodactylid. In the case of G. salaris, East Atlantic and Baltic strains of Atlantic salmon are core hosts, but other salmonids can physiologically sustain infections for considerable periods, and may be important in parasite dispersal and transmission. A further group of non-salmonid fishes are unable to sustain G. salaris reproduction, but can act as transport hosts.Population growth parameters are very labile to stressors and environmental factors, particularly temperature and salinity, and also other aspects of host ecology and water quality. These factors may also influence the spectrum of hosts that can be infected under particular conditions, and probably favoured ecological transfer of gyrodactylids between host species in periglacial conditions. G. salaris may still be undergoing post-glacial range expansion (aided by anthropogenic spread) as shown by the increase in the species range over the last 25 years. The origin of G. salaris, G. teuchis and G. thymalli is discussed in relation to glacial refugiums during the last ice age.     

The role of body size in host specificity: reciprocal transfer experiments with feather lice

Although most parasites show at least some degree of host specificity, factors governing the evolution of specificity remain poorly understood. Many different groups of host-specific parasites show a striking correlation between parasite and host body size, suggesting that size reinforces specificity. We tested this hypothesis by measuring the relative fitness of host-specific feather lice transferred to pigeons and doves that differ in size by an order of magnitude. To test the general influence of size, we transferred unrelated groups of wing and body lice, which are specialized for different regions of the host. Lice were transferred in both directions, from a large native host species, the rock pigeon (Columba livia), to several progressively smaller hosts, and from a small native host species, the common ground dove (Columbina passerina), to several larger hosts. We measured the relative fitness (population size) of lice transferred to these novel host species after two louse generations. Neither wing lice nor body lice could survive on novel host species that were smaller in size than the native host. However, when host defense (preening behavior) was blocked, both groups survived and reproduced on all novel hosts tested. Thus, host defense interacted with host size to govern the ability of lice to establish on small hosts. Neither wing lice nor body lice could survive on larger hosts, even when preening was blocked. In summary, host size influenced the fitness of both types of feather lice, but through different mechanisms, depending on the direction of the transfer. Our results indicate that host switching is most likely between hosts of similar body size. This finding has important implications for studies of host-parasite coevolution at both the micro- and macroevolutionary scales.     

Spatial and temporal variation in host–parasitoid interactions: leafcutter ant hosts and their phorid parasitoids

1. Parasitoid–host interactions are important components of ecological communities. Although parasitoid–host interactions are strongly shaped by evolutionary history, the abundance of both the parasitoid and the host may have a role in determining the nature of the interaction once phylogenetic relationships are considered. 2. Leafcutter ants are hosts of phorid parasitoids and represent a well‐defined and specialised module within a larger network of ant–symbiont interactions. A low specificity host taxa and a positive association between host abundance and parasitoid interaction frequency were expected due to the close phylogenetic relatedness of the hosts. 3. The interactions among all species of leafcutter ants and their parasitoids were quantified in two localities with different species richness. This study also characterised the spatial‐temporal variability of these interactions, determined the patterns of parasitoid specificity and host selection, and tested for an association between host abundance and parasitoid interaction frequency. 4. Contrary to expectation, most parasitoid species were highly specialised and interaction frequency for parasitoid species was not related to host abundance. All host ant species were attacked by more than one phorid species. Some phorid species used more than one host species and showed preference for the same species over space and time, suggesting that there are physiological and/or behavioural restrictions on host use. 5. These results show that there is a tendency for specialisation even when hosts are highly similar in their ecology. From a biological control perspective, these parasitoids may be effective candidates, due to the high specificity of some species and little host‐use variation through time.     

Carbohydrate localization on Gyrodactylus salaris and G. derjavini and corresponding carbohydrate binding capacity of their hosts Salmo salar and S. trutta

The congeners Gyrodactylus salaris and G. derjavini are specific ectoparasites of Atlantic salmon Salmo salar and brown trout S. trutta, respectively. To elucidate the involvement of lectin-carbohydrate interactions in this host specificity, carbohydrates on the tegument of the two species and the corresponding lectin activity of their hosts have been studied. Carbohydrate composition on the tegument differed significantly between the two gyrodactylids. Three of four commercially available peroxidase-labelled lectins with primary affinity towards D-mannoside, D-GalNAc and L-fucose bound more strongly to G. derjavini than to G. salaris. Lectins with an affinity towards D-mannoside and D-GalNAc bound significantly stronger to the cephalic lobes on G. derjavini compared to the tegument and sheaths of the hamuli. One brown trout strain and three different salmon strains were tested for lectin activity in skin and plasma. Two Baltic salmon strains and one strain from the Atlantic region were included. Brown trout differed significantly from the salmon strains when skin samples were tested for D-GalNAc activity. Lectins binding to other carbohydrates showed trends for similar host differences. The implications of carbohydrate-lectin interactions for host specificity in gyrodactylids are discussed.     

Host-plant specificity and specialization in eriophyoid mites and their importance for the use of eriophyoid mites as biocontrol agents of weeds

Eriophyoid mites, which are among the smallest plant feeders, are characterized by the intimate relationships they have with their hosts and the restricted range of plants upon which they can reproduce. The knowledge of their true host ranges and mechanisms causing host specificity is fundamental to understanding mite-host interactions, potential mite-host coevolution, and diversity of this group, as well as to apply effective control strategies or to use them as effective biological control agents. The aim of this paper is to review current knowledge on host specificity and specialization in eriophyoid mites, and to point out knowledge gaps and doubts. Using available data on described species and recorded hosts we showed that: (1) 80% of eriophyoids have been reported on only one host species, 95% on one host genus, and 99% on one host family; (2) Diptilomiopidae has the highest proportion of monophagous species and Phytoptidae has the fewest; (3) non-monophagous eriophyoids show the tendency to infest closely related hosts; 4) vagrant eriophyoids have a higher proportion of monophagous species than refuge-seeking and refuge-inducing species; (5) the proportions of monophagous species infesting annual and perennial hosts are similar; however, many species infesting annual hosts have wider host ranges than those infesting perennial hosts; (6) the proportions of species that are monophagous infesting evergreen and deciduous plants are similar; (7) non-monophagous eriophyoid species have wider geographic distribution than monophagous species. Field and laboratory host-specificity tests for several eriophyoid species and their importance for biological control of weeds are described. Testing the actual host range of a given eriophyoid species, searching for ecological data, genetic differentiation analysis, and recognizing factors and mechanisms that contribute to host specificity of eriophyoid mites are suggested as future directions for research.     

Integrating phylogenetic and ecological distances reveals new insights into parasite host specificity

The range of hosts a pathogen infects (host specificity) is a key element of disease risk that may be influenced by both shared phylogenetic history and shared ecological attributes of prospective hosts. Phylospecificity indices quantify host specificity in terms of host relatedness, but can fail to capture ecological attributes that increase susceptibility. For instance, similarity in habitat niche may expose phylogenetically unrelated host species to similar pathogen assemblages. Using a recently proposed method that integrates multiple distances, we assess the relative contributions of host phylogenetic and functional distances to pathogen host specificity (functional–phylogenetic host specificity). We apply this index to a data set of avian malaria parasite (Plasmodium and Haemoproteus spp.) infections from Melanesian birds to show that multihost parasites generally use hosts that are closely related, not hosts with similar habitat niches. We also show that host community phylogenetic ß‐diversity (Pßd) predicts parasite Pßd and that individual host species carry phylogenetically clustered Haemoproteus parasite assemblages. Our findings were robust to phylogenetic uncertainty, and suggest that phylogenetic ancestry of both hosts and parasites plays important roles in driving avian malaria host specificity and community assembly. However, restricting host specificity analyses to either recent or historical timescales identified notable exceptions, including a ‘habitat specialist’ parasite that infects a diversity of unrelated host species with similar habitat niches. This work highlights that integrating ecological and phylogenetic distances provides a powerful approach to better understand drivers of pathogen host specificity and community assembly.     

Pathogenomics of Xanthomonas: understanding bacterium-plant interactions

Xanthomonas is a large genus of Gram-negative bacteria that cause disease in hundreds of plant hosts, including many economically important crops. Pathogenic species and pathovars within species show a high degree of host plant specificity and many exhibit tissue specificity, invading either the vascular system or the mesophyll tissue of the host. In this Review, we discuss the insights that functional and comparative genomic studies are providing into the adaptation of this group of bacteria to exploit the extraordinary diversity of plant hosts and different host tissues.