Tardigrades of the Australian Antarctic Territories: the Windmill Islands, East Antarctica

Six species of tardigrades, Pseudechiniscus suillus, Macrobiotus sp., Hypsibius antarcticus, Ramajendas frigidus, Diphascon chilenense and Diphascon pingue were extracted from mosses and lichens from the ice-free regions of the Windmill Islands near Casey Base, East Antarctica. Significant positive associations were found between the three common species ( Pseudechiniscus suillus, Hypsibius antarcticus, Diphascon chilenense ) and bryophytes, whereas strong negative associations were found between these species and algae and lichens. There were additional interspecific associations between the common species of tardigrades as well as between tardigrades, nematodes and rotifers.     

Interspecific Association and Substrate Specificity in Tardigrades from Florida, Southeastern United States

The distribution of terrestrial tardigrades in the Gulf Coast states of the United States is poorly known. Only one species has been reported in Florida. In this study moss, liverwort, lichen and fern samples (47 identified species) from trees and shrubs were collected from all 67 Florida counties. These samples contained 20 species of tardigrade. All possible pairs of tardigrade species and tardigrade and substrate were tested for interspecific association. Only three significant negative and one positive interspecific association between tardigrades were detected. Evidence for substrate specificity was weak. Although some tardigrade species were significantly associated with mosses or foliose lichens in general, no significant association between a tardigrade species and a substrate species was detected.     

The Tardigrades of Emilia (Italy). III. Piane di Mocogno (Northern Apennines)

Samples of leaf litter, mosses and lichens were collected in a beech forest at Piane di Mocogno (Emilia, Italy), 1200 m asl. The tardigrade community of the leaf litter was similar to that found in this substrate in Italy and in the U.S.A. At Piane di Mocogno the species association within the leaf litter was different from that in mosses and lichens (which have similar fauna), confirming that very different communities characterise different substrates such as leaf litter and mosses. During this faunal analysis, six species of tardigrades were found for the first time in this area. The presence of Microhypsibius bertolanii (first record in leaf litter and in Italy) and Eohypsibius nadjae are note worthy. Ornamented eggs in an exuvium of Hypsibius cf.scabropygus were also recorded for the first time.     

Factors influencing the distribution of aquatic plant communities in Irish canals

Terrestrial tardigrades are often found in the lichens and mosses growing on trees and rocks. The assertion that tardigrades in these habitats are very patchy in their distribution has rarely been backed by quantitative sampling. This study assesses spatial variability in tardigrade populations inhabiting small patches (0.1 cm² to over 5 cm²) of moss and lichen on trees and rocks at three sites in the United States of America. Tardigrades were collected from four replicate rocks in the Ouachita Mountains of Arkansas, with 30 lichen patches collected on two adjacent boulders and 20 moss patches on a second pair of boulders. In Fort Myers and in Citrus Springs, Florida, 30 lichen patches per tree were collected from two pairs of trees. The tardigrades in each sample were extracted, mounted, identified, and counted. The variation in tardigrade abundance among lichen or moss patches within rocks or trees was very high; the only consistent pattern was that very small patches usually lacked tardigrades. Tardigrade diversity and abundance also varied greatly within sites when lichens and mosses of the same species from different rocks and trees were compared (in the most extreme case one tree had numerous individuals of two tardigrade species present while the other had almost no tardigrades). The results of this quantitative sampling support the assertion that tardigrades are very patchy in distribution. Given the considerable time investment required for the quantitative processing of tardigrade samples, this high spatial variability in tardigrade diversity and abundance requires that researches testing ecological hypotheses about tardigrade abundance check variability before deciding how many samples to take.     

A Large-scale, Multihabitat Inventory of the Phylum Tardigrada in the Great Smoky Mountains National Park, USA: A Preliminary Report

An All Taxa Biodiversity Inventory (ATBI) is underway in the Great Smoky Mountains National Park (GSMNP), with the goal of attempting to identify all species of life in the 2000 km² park. The GSMNP is a hotbed of biodiversity, a U.N. Biosphere Reserve, and one of the largest protected, deciduous forests in the temperate world. We have completed two field seasons of work on the tardigrades in the park (2001–2002). As of July 2003, we have collected 420 samples from soil/decomposed leaf litter, lichens and mosses on trees, and stream sediment and periphyton. A few samples from caves, bird nests, and lichens/mosses on rocks were also collected. Samples were taken from within permanent plots established for the ATBI, representing the major biological communities of the GSMNP. Tardigrades were extracted from samples using centrifugation with Ludox AM™, individually mounted on microscope slides in Hoyer’s medium, and studied with phase contrast and DIC microscopy. We have examined 1524 slides from 60 samples as of July 2003. Prior to our work, only three species of tardigrades had been previously reported from a few samples in the park. We have now recorded 42 species, 8 of which we believe may be new to science. Species richness estimates were calculated using EstimateS 6 software for each of the major tardigrade habitats. Overall, we predict that there are 47 to 76 species in the GSMNP, with generally similar species richness in soil, lichen, moss, and stream habitats. Species richness estimates were also used to determine that the number of tardigrade species was greater in mosses at breast height on trees than in mosses at the base of trees.     

Tardigrades of Louisiana and Arkansas, United States of America

The distribution of tardigrades in the states of the southern United States is poorly known. There are no published records from the state of Louisiana, while in Arkansas only one species has been reported. Samples of mosses and lichens from trees and rocks were collected from three sites in central and southern Louisiana and six sites in western Arkansas. Leaf litter samples were collected from one site in Louisiana. Nine species of tardigrade were found in Louisiana and 22 in Arkansas. The number of species per sample ranged from one to six.     

The tardigrades of Emilia (Italy). II. Monte Rondinaio. A multihabitat study on a high altitude valley of the northern Apennines

We investigated a small valley of glacial origin in the northern Apennines (Italy). A multihabitat study was performed on the mosses and lichens on rocks, temporarily submersed mosses, beech litter, grass turf and sediments from pools, ponds and streams. A few species colonized more than one habitat. Several species were typical of high altitudes or latitudes, some were rare, and two, Hypsibius pradellii sp. nov. and Diphascon (Diphascon) secchii sp. nov. , were new to science.     

青藏高原东缘亚高山针叶林和采伐迹地中藓类生长速率及其影响因子

利用红油漆标记法,对青藏高原东缘地区壤塘林业局二林场亚高山采伐迹地和云杉(Picea)原始林中的6种藓类近一个生长季的生长速率进行了研究。结合原地同时进行的微气候观测,分析了气候因子和藓类生长速率之间的相关度。这6种藓类中,有5种在原始林和采伐迹地都出现,只有绢藓(Entodon conncinus)仅在采伐迹地出现。不同物种和不同生境条件下藓类的生长速率都不相同。塔藓(Hylocomium splendens)的茎生长速率最大,而阿萨姆曲尾藓(Dicranum assamicum)生长速率最小。生境对塔藓、阿萨姆曲尾藓和细叶羽藓(Thuidium lepidoziaceum)的生长速率影响很大,它们在林内比在采伐迹地生长快。锦丝藓(Actinothuidium hookeri)和垂枝藓(Rhytidiadelphus triquetrus)的生长速率中等并且对生境不敏感。据此可以将藓类分成生境敏感型和不敏感型。微气候5~7月分析显示林内比采伐迹地的辐射通量低,并且更为干燥。但是早上林内的蒸汽压亏缺(Vapor pressure deficit, VPD)一直比采伐迹地低。林内较低的蒸汽压亏缺和较低的辐射通量使其成为更有利于藓类的生长场所。对于那些生境类型不敏感的藓类,微地形的效应也许抵消了这种大生境的效应。藓类的生理生态特征如变水(Poikilohydry)特征等对其在严酷气候条件下的生存和生长起着重要的作用。如同积温一样,藓类的生长速率同样可以指示生境的适宜度, 因为其生长和蒸汽压亏缺紧密相关,是温度和湿度的函数,而这两个因素对于川西亚高山地区森林人工更新时幼苗的建植极为关键。因此藓类的生长状况可以作为指示适宜植树生境的指标。     

Micro-distribution of Soil Inhabiting Tardigrades (Tardigrada) in a Sub-alpine Coniferous Forest of Japan

Micro-distribution of soil inhabiting tardigrades was studied in a sub-alpine coniferous forest (alt. 1,840 m a. s. l.) on the eastern slope of Mt. Yatsugatake, Central Japan. Eight cylindrical soil samples were taken from the forest floor. Each sample was divided into 10 slice samples of 1 cm thick. Tardigrades were extracted from samples by Baermann funnels, identified to specific level and counted. The average number of tardigrades in the study site is 74,058/m². High densities sometimes occurred at depths greater than 5 cm. Consequently for investigating tardigrade populations, 5cm depth core sampling is insufficient in this type of habitat. Composition of the main groups of species reveals that shallow layers (1, 2 or 3 cm depth) are frequently dominated by the Diphascon-group. Macrobiotus-group species generally occurred in higher abundance in the deeper layers. It is very interesting that there are some different patterns of soil micro-distribution in tardigrade species.     

Tardigrades of the Taimyr peninsula with descriptions of two new species

This is the first report on tardigrades from the Taimyr peninsula. Seventy-one species of tardigrades were recorded, new to Russian fauna and two of which are new to science. Diphascon boreale sp. nov. is closely related to D. brevipes (Marcus, 1936) but easily distinguished from it by claw structure and the absence of cuticular bars on the legs. Isohypsibius roberti sp. nov. belongs to the elegans group of the genus Isohypsibius ; it diners from other species in the group by having a long and thin buccal tube and large lunulae with small teeth on leg IV. The eggs of Ramazzottius montivagus are here described for the first time. The almost complete absence of tardigrades in and around Norilsk is noted. This is related to the heavy industrial pollution from a local nickel-copper plant.     

Tardigrade Fauna of the Region between Oka and Volga Rivers (Russia) and Patterns of their Distribution in Substrates and Habitats

The region between the Oka and Volga rivers has been largely neglected with respect to tardigrade biodiversity. In the present study a total of 21 species from 7 genera, 3 families, 2 orders and only 1 class of tardigrades were present, and some of their ecological preferences were noted. The tardigrades in the studied region were mainly cosmopolitan. Eurytopic, hygrophilic and xerophilic species were common while obligate freshwater species were not found. There is a marked similarity in the tardigrade fauna within similar habitats from different locations within the region.     

The Ecological Distribution of Tardigrades in Newfoundland

The ecological distribution of tardigrades on the island of Newfoundland, Canada is greatly affected by both abiotic and biotic factors. Altitude and type of bedrock are major determining factors in tardigrade distribution while both moisture content of the environment and rate of dessication of the mosses and lichens in which they live appear to be other factors contributing to their distribution. A number of cases of apparent competitive exclusion and inter-specific competition have been noted which probably also affect tardigrade distribution.     

The toughest animals of the Earth versus global warming: Effects of long‐term experimental warming on tardigrade community structure of a temperate deciduous forest

Understanding how different taxa respond to global warming is essential for predicting future changes and elaborating strategies to buffer them. Tardigrades are well known for their ability to survive environmental stressors, such as drying and freezing, by undergoing cryptobiosis and rapidly recovering their metabolic function after stressors cease. Determining the extent to which animals that undergo cryptobiosis are affected by environmental warming will help to understand the real magnitude climate change will have on these organisms. Here, we report on the responses of tardigrades within a five‐year‐long, field‐based artificial warming experiment, which consisted of 12 open‐top chambers heated to simulate the projected effects of global warming (ranging from 0 to 5.5°C above ambient temperature) in a temperate deciduous forest of North Carolina (USA). To elucidate the effects of warming on the tardigrade community inhabiting the soil litter, three community diversity indices (abundance, species richness, and Shannon diversity) and the abundance of the three most abundant species (Diphascon pingue, Adropion scoticum, and Mesobiotus sp.) were determined. Their relationships with air temperature, soil moisture, and the interaction between air temperature and soil moisture were tested using Bayesian generalized linear mixed models. Despite observed negative effects of warming on other ground invertebrates in previous studies at this site, long‐term warming did not affect the abundance, richness, or diversity of tardigrades in this experiment. These results are in line with previous experimental studies, indicating that tardigrades may not be directly affected by ongoing global warming, possibly due to their thermotolerance and cryptobiotic abilities to avoid negative effects of stressful temperatures, and the buffering effect on temperature of the soil litter substrate.     

中国缓步动物门一新亚种及两新纪录种记述

报道了我国缓步动物门1新亚种Diphascon(Adropion)scoticum qinlingensis subsp.nov.和中国2新纪录Rictersius coronifer ( Richters, 1903) (Eutardigrada, Macrobiotidae)和 Diphascon scoticum Murray, 1905 (Eutardigrada, Hypsibiidae).新亚种主要以爪的主枝基部极度收缩区别于世界其他产地的标本(指名亚种).新亚种和新纪录均采自秦岭山区.     

Preliminary Studies of the Tardigrade Fauna of the Faroe Bank

Four cruises to the Faroe Bank have collected bottom samples for qualitative analysis of the meiofauna. The preliminary results show a very rich tardigrade fauna, with a large proportion of species new to science. At present 35 species of tardigrades belonging to 4 families (6 sub-families) have been found, of these are 22 new to science (63%). The 35 species comprise more than 20% of all known marine tardigrades. Halechiniscidae is represented by 30 species (1 Euclavarctinae, 11 Styraconyxinae, 12 Tanarctinae, 3 Halechiniscinae, 2 Florarctinae and 1Dipodarctinae). This family comprises 87.87% of the specimens sorted out so far. Specimens from the subfamilies Tanarctinae (46.63%) and Styraconyxinae (31.54%) are dominating. Batillipedidae is represented with 3species (8.63% of the specimens) and Coronarctidae (1.89%) and Stygarctidae (1.61%) with a single species each. Samples with similar sediment from 104—260 m depth have similar species distribution in the families. This implicates that the sediment is the key factor involved in the species distribution and that depth is less important. The calcareous sediment is a unique substrate and the tardigrade fauna of the Faroe Bank can be compared with that of sub-tropical and tropical coralline sand. The composition of species exhibits a strong taxonomic affinity with the tardigrade fauna from more southern latitudes, i.e. the Mediterranean Sea and the south-eastern coast of USA.     

Soil-inhabiting Tardigrade Communities in Forests of Central Japan

This study was carried out for the purpose of detecting the relationship between soil-inhabiting tardigrade communities and environmental factors of various forests. Nine forests in the southern part of Kanagawa Prefecture, Central Japan, were selected for this study. Four vegetation types were designated; broadleaved (evergreen/deciduous), coniferous and orchard. In these sites, dry weight of leaf litter, soil pH, soil hardness, soil moisture content and porosity ratio were measured. Wet soil faunal frequencies were also described. The Baermann funnel method was adopted for collecting tardigrades, and DIC microscopy was used for specific identification. To clarify the correlation between environmental variables and tardigrade faunae, multivariate analysis was applied. The tardigrade fauna occurred as two distinct groups. The first group primarily contained Macrobiotus species. The second group contained the genus Diphascon (e.g. D. nobilei, D. patanei, D. prorsirostre). An exception to this was D. pingue, included in the former. Most of the Diphascon species were concentrated in Nebu (coniferous forest site), while, Macrobiotus species were dominant in other sites. Distinct environmental factors could not be identified, but the nematodal frequency was recognized as the main factor in forming these groups. The uniqueness of Nebu, which does not correspond to large-scaled vegetational classification, was substantiated by statistical data. Nebu’s coniferous forest apparently has created a unique environment for sustaining rare species (Diphascon species). This study concluded that forests should be evaluated not only by the macroscopic factors, such as landscape, but also by the microscopic communities, such as those including the tardigrades.