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Volume 3 Issue 2
May  2012
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Article Contents
Abstract
Introduction
Study area and methods
Results
Discussion
Acknowledgements
Acknowledgements
References
Langyu GU, Yang LIU, Ning WANG, Zhengwang ZHANG. 2012: A panel of polymorphic microsatellites in the Blue Eared Pheasant (Crossoptilon auritum) developed by cross-species amplification. Avian Research, 3(2): 103-107. DOI: 10.5122/cbirds.2012.0010
Citation: Langyu GU, Yang LIU, Ning WANG, Zhengwang ZHANG. 2012: A panel of polymorphic microsatellites in the Blue Eared Pheasant (Crossoptilon auritum) developed by cross-species amplification. Avian Research, 3(2): 103-107. DOI: 10.5122/cbirds.2012.0010
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A panel of polymorphic microsatellites in the Blue Eared Pheasant (Crossoptilon auritum) developed by cross-species amplification

  • 1.

    MOE Key Laboratory for Biodiversity Sciences and Ecological Engineering, College of Life Sciences, Beijing Normal University, Beijing 100875, China

  • 2.

    Computational and Molecular Population Genetics, Institute of Ecology and Evolution, University of Bern, Baltzerstrasse 6, 3012, Bern, Switzerland

More Information
  • Corresponding author:

    Zhengwang ZHANG, E-mail: zzw@bnu.edu.cn

  • *Yang Liu
    Present address: State Key Laboratory of Biocontrol and School of Life Sciences, Sun Yat-Sen University, Guangzhou 510275, China

  • Received Date: 03 Mar 2012
  • Accepted Date: 09 May 2012
  • Available Online: 24 Apr 2023
    Graphical Abstract
    • Abstract

  • Polymorphic microsatellites are among the versatile genetic markers in molecular ecology studies. In contrast to de novo isolation of microsatellites from target species, cross-species amplification is a cost-effective approach for a fast development of microsatellite markers from closely related taxa. In our study, we cross-amplified a panel of polymorphic microsatellite markers for the Blue Eared Pheasant (Crossoptilon auritum), a species endemic to China of considerable conservation concern. We obtained 11 polymorphic microsatellite markers selected from 112 candidate loci, originally isolated from other Galliforme species. This panel of makers has shown moderate to high levels of polymorphism and include a Z-chromosomal linkage locus. We carried out preliminary analyses of parentage among captive individuals with a known pedigree using this new panel of microsatellites. Our results suggest that the high utility of these markers may be powerful tools for studies in conservation genetics of eared-pheasants and other endangered Galliforme species.

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  • Similarities and differences for resource requirements are key factors affecting coexistence of sympatric species (Johnson, 2000). When resources are rich different species, completely overlapping in their niche, might be found in the same area (Zhang and Jiang, 1997). However, sympatric species might separate at least in one niche for coexistence if resources were to become scarce (Munday et al., 2001), resulting in coexisting species developing their own strategies for niche separation, such as spatial separation (May, 1973; Jenni, 1993).

    Roosting strategies of birds show how they select and use spatial resources at night, including roosting behavior and roost selection (Cody, 1985). Birds, daily active, cannot be aware of potential dangerous situations, which lead them often to be exposed to dangers during nighttime because of poor visibility (Chamberlain et al., 2000). A suitable roosting habitat not only retains a desirable temperature for birds, but also protects them from predation (Cody, 1985). Therefore, the selection of a roosting habitat affects the fitness of birds (Cody, 1985; Elmore et al., 2004). So far, many studies reporting roosting site selection of rare pheasants, have focused primarily on roosting behavior and site selection. Some characteristics have been commonly recognized for avian roosting, i.e., birds prefer to stay in areas with steep terrain and high tree cover (Kelty and Lustick, 1977; Cody, 1985). However, there are obvious interspecific differences in tree species for roosting, height of perching branch and canopy of perching position (Ding et al., 2002; Jia et al., 2005; Shao and Hu, 2005; Jiang et al., 2006; Lu and Zheng, 2007). From the study of roosting habitat selection by Tetraonidae, it has been shown that the structure of trees, microhabitat of perching position and terrain characteristics are factors mainly affecting roosting habitat selection in avian species (Godfrey, 1970; Korhonen, 1980). But few of these studies compared the roosting strategies of different species in the same area.

    Hume's Pheasant (Syrmaticus humiae), listed as globally near-threatened (Birdlife International, 2008) and the Silver Pheasant (Lophura nycthemera), which is not threatened, are found in sympatry in the Dazhong Mountain of Yunnan Province, southwestern China (Li et al., 2006). So far, no comparative analysis of roosting site of the sympatric pheasants has been described in detail. In this study, we investigated the night roosting habitat characteristics of Hume's Pheasant and Silver Pheasant and compared their roosting site strategies. Multiple statistics, Matryoshka and habitat classification-tree were used to analyze roosting habitat selection in the spring. We also discuss the mechanism how the pheasants choose roosting sites at night.

    Study area

    Dazhong Mountain (24°43′32″–25°01′10″N, 100°44′28″–100°57′42″E) is a part of the Ailaoshan National Nature Reserve, located in the southwestern part of Nanhua County, Chuxiong Prefecture in central Yunnan Province, China (Fig. 1). This area lies at the juncture of the central Yunnan Plateau, Hengduan mountains and the southern tip of the Qinghai-Tibetan Plateau, comprising mid-alpine mountains and valleys caused by age-old movements in the earth's crust. These upward movements of the earth led to modified soils and climate regimes which in turn have affected vegetation and species diversity and distribution. Pinus yunnanensis and scrub forests dominate in areas below 1500 m, semi-moisture broadleaf evergreen forests and deciduous broadleaf forests are found at elevations between 1500–2400 m and the vegetation above 2400 m comprises mid-alpine broadleaf evergreen and Pinus armandii forests (Wang, 2000).

    Figure  1.  Map showing landform of Dazhong Mountain, a part of the Ailaoshan National Nature Reserve, Yunnan Province. The red irregular rectangle shows the study area.
    DownLoad: Full-Size Img PowerPoint

    Data collection

    Field data were collected from February to April, 2004 in the Dazhong Mountain.

    Three transects (at elevations of 2400, 2450 and 2500 m), 4–6 km long (the transects were often beyond the boundary of the natural reserve) were established in the study area where Hume's Pheasant and Silver Pheasant occur in sympatry. Both pheasants often appeared near roosting sites at dawn and dusk (06:30–09:30 and 17:00–19:00 hours) (Li et al., 2006). When they came to roost or flew away from the roosting tree, a loud sound, "pupu…" caused by fanning their wings, could be heard and their roost could be identified easily. If these sounds could not be heard, we used flashlights to look directly for the pheasants and confirmed roosting trees at night, or indirectly identify the roosting trees by searching for faecal in the morning according to the amount and their freshness under the roosting trees. The faecal of the two pheasants could be distinguished by visual observations: the faecal of Hume's Pheasant is a cone-shaped black leptospira with white uric acid crystals at the larger ends; in comparison, that of the Silver Pheasant is blank and columnar with white uric acid crystals covering the surface. The faecal volume of the Silver Pheasant is larger than that of Hume's Pheasant.

    Following the methods of Young et al. (1991), plots of 10 m × 10 m were established with roosting trees as centers. Twenty-two factors, referring to bird roost selection, were measured, given the instructions of Zheng (1995). These factors can be categorized into three groups:

    1) Macro-habitat characteristics. Elevation (EL), aspect (AS), slope (SL), vegetation types (VT), distance to water (DSW) and distance to roads (DSR). EL, AS and SL were measured by compass and DSW and DSR by a measuring tape.

    2) Vegetation characteristics. Canopy tree density (CTD), canopy tree cover (CTC), average height of canopy tree (AHCT), average diameter at breast height of canopy tree (ADBH), shrub density (SD), shrub cover (SC), average height of shrubs (AHS), herb cover (HC) and leaf litter cover (LLC).

    3) Perch characteristics. Tree species (TS), tree height (TH), diameter at breast height (DBH), perch height (PH), obtained by tape measure, angle between perching branch and stock (APS), obtained by goniometer, cover over perch (COP), crown size (CS) (i.e., umbriferous crown area of roost tree, assumed to be elliptical or round).

    Data processing

    Resource selection index

    A chi-square test and Ivlev's Resource Selection Index (RSI) were used to analyze the selection by the pheasants of two factors, i.e., roost tree species and vegetation type (Ivlev, 1961; Manly et al., 2002). Ivlev's Resource Selection Index is defined as:

    Ei=(RiNi)/(Ri+Ni) (1)

    where resource utilization (Ri) represents the actual frequency of utilization of resource i by animals (here referring to birds) in a given period, resource availability (Ni) represents the availability of resource i by birds and the resource selection index (Ei) indicates whether the bird selects the resource i. If Ei = 0, the birds have no preferential selection for resource i and is expressed as "0"; if Ei < 0, birds avoid resource i, expressed as "−"; if Ei > 0, the birds prefer to select resource i and is expressed as "+" (Ivlev, 1961).

    Principal component analysis for roosting habitat factors

    The other 20 quantitative factors were analyzed by t-test to compare mean differences between the two species. Since the data should be normally distributed, slope and aspect have been transformed either by an arcsine or a logarithmic transformation before analysis (Manly et al., 2002). Principal component analysis (PCA), a multivariate technique that produces a simplified, reduced expression of the original data with complex relationships, has been widely applied in studies of wildlife habitats (Fowler et al., 1998). All quantitative variables were analyzed via PCA based on their correlation matrix with a varimax rotation to screen out the key factors in roosting habitat selection of Hume's Pheasant and Silver Pheasant.

    All statistics were analyzed by SPSS 13.0 for windows.

    Habitat classification-tree

    A habitat classification-tree was constructed from the result of multiple statistics for roosting habitat and the theory of Matryoshka, who developed a system of habitat classification for a complete multi-scale habitat study. Habitat selection in birds can be divided in several levels, from macrohabitat to microhabitat (Hanski, 2006). This kind of system not only shows species requirements at each layer but also reveals which layer is destroyed. Simultaneously, the definition of habitat layer can be used for comparing the differences and similarities of congeneric species, which provides evidence to ascertain whether habitats overlap or are separated in any given layer.

    Twenty roosting trees for each pheasant species were found in the field; in total forty utilization plots were established.

    Vegetation type and roosting trees

    For vegetation type, both pheasants selected moist evergreen broadleaf forests in the middle-mountain as their roosting sites (Table 1). In the twenty trees, chosen by Hume's Pheasant for roosting, ten (50%) were oak species (Lithocarpus xylocarpus, L. truncates and L. cleistocarpus), five (25%) were Pinus armandi trees, two (10%) were Ternstroemia gymnanthera and the others (15%) were Lyonia ovalifolia, Gaultheria leucocarpa var. crenulata and Alnus nepalensis, in total eight tree species. For Silver Pheasant, twelve roosting trees (60%) were oak species (Lithocarpus xylocarpus, L. truncatus and L. echinophorus), two (10%) were Camellia oleifera and the other six (30%) were Castanopsis megaphylla, Lyonia ovalifolia, Rhododendron delarayi, Gaultheria forrestii var. forrestii, G. leucocarpa var. crenulata and Cerasus serrulate trees, i.e., ten species in total. Oak was the main tree species for roosting. There were no significant difference in the preference for oak as roosting tree between the two pheasants (χ2 = 0.4, df = 1, p > 0.05).

    Table  1.  Comparison of roosting habitat vegetation type between the two pheasants based on Resource Selection Index
    Factor i Ni Ri Ei Selective
    S L S L S L
    Vegetation type MEBF 0.49 0.78 1.00 0.23 0.34 + +
    DBF 0.05 0.00 0.00 −1.00 −1.00
    PYF 0.46 0.22 0.00 −0.35 −1.00
    Note: S, Syrmaticus humiae; L, Lophura nycthemera; DBF, deciduous broadleaf forest; MEBF, middle-mountain, moist evergreen broadleaf forest; PYF, Pinus yunnanensis forest; +, observed usage is significantly higher than expected; 0, observed usage is almost equal to expected; −, observed usage is significantly lower than expected; other abbreviations are the same as in Eq. (1).
     | Show Table
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    Comparison of roosting habitat factors

    There were highly significant differences in the height of roosting trees, perch height and elevation (Table 2). The differences of diameter at breast height, canopy tree density, herb coverage and distance to water were significant (Table 2). Except for these seven habitat factors, there were no clear statistical differences in the other thirteen factors (Table 2).

    Table  2.  Roosting habitat characteristics and their comparison between two pheasants
    Habitat characteristics Factor types Roosting habitat (mean ± SE) t-test (two-tailed)
    S L t p
    Roost tree DBH 18.5±5.3 27.5±5.1 −2.586 0.014*
    Crown size 32.2±5.6 31.2±12.6 0.099 0.922
    Height 8.1±1.5 11.3±1.5 −3.100 0.004**
    Roost branch Height 3.6±0.6 6.4±0.8 −5.894 0.000**
    APS 94.7±5.6 92.0±5.0 0.765 0.449
    COP 79.3±5.9 76.5±7.5 0.624 0.537
    Tree layer Density 25.0±8.0 38.9±10.7 −2.180 0.036*
    AHCT 8.2±1.1 9.3±0.8 −1.747 0.089
    ADBH 11.4±2.0 12.6±1.9 −0.876 0.387
    Cover 60.7±6.3 66.8±5.2 −1.557 0.128
    Shrub layer Cover 17.7±7.4 11.9±4.8 1.374 0.177
    AHS 1.5±0.3 1.7±0.2 −1.216 0.231
    Density 9.9±6.5 4.9±0.9 1.613 0.123
    Herb layer LLC 82.2±4.7 86.3±3.5 −1.466 0.151
    HC 10.5±7.0 2.3±3.3 2.214 0.035*
    Macrohabitat DSR 34.4±7.9 57.4±29.9 −1.561 0.133
    DSW 39.3±11.2 72.5±23.8 −2.642 0.014*
    Aspect 11.8±34.8 29.3±12.3 −0.993 0.331
    Slope 31.2±4.8 30.1±3.5 0.371 0.712
    Elevation 2421.6±16.8 2465.3±23.3 −3.189 0.003**
    Note: S, Syrmaticus humiae; L, Lophura nycthemera; ADBH, average diameter at breast height of canopy trees; AHCT, average height of canopy trees; AHS, average height of shrubs; APS, angle between perching branch and stock; COP, cover over perch; DBH, diameter at breast height; DSR, distance to road; DSW, distance to water; HC, herb coverage; LLC, leaf litter coverage; * p < 0.05; ** p < 0.01; other abbreviations are the same as for Table 1.
     | Show Table
    DownLoad: CSV

    Principal component analysis for roosting habitat factors

    Given the results of PCA, the unique factors affecting only the roosting habitat of Hume's Pheasant were slope, aspect, angle between perch and stock, shrub density and distance to water. Elevation and canopy tree cover were unique factors only affecting the Silver Pheasant. Two factors, leaf litter coverage and distance to roads, had roughly the same effect on roosting of the two pheasants; the values of these factors were reversed. Furthermore, only five factors of roosting trees and shrubs that affected the roosting habitat of the two pheasants are ordered in the same sequence, while the sequence of the other eight factors contributed alternately (Table 3).

    Table  3.  Principal component analysis for roosting habitat factors used by the two pheasants
    Factor Factor type Factor loading
    PC1 PC2 PC3 PC4 PC5 PC6
    S L S L S L S L S L S L
    Roost tree DBH 0.92 0.84 0.02 0.11 −0.09 0.01 −0.08 0.15 0.21 0.14 −0.02 −0.24
    Crown size 0.89 0.82 −0.01 −0.26 −0.09 −0.02 −0.07 0.24 0.21 0.16 0.14 0.11
    Height 0.83 0.84 −0.09 0.39 −0.20 0.15 −0.16 0.16 0.26 −0.07 −0.24 0.05
    Roost branch Height 0.64 0.40 −0.07 0.54 −0.37 0.62 −0.26 0.00 0.19 0.07 −0.09 −0.21
    APS 0.00 −0.16 0.83 0.00 0.10 −0.15 0.22 0.11 −0.12 −0.01 0.15 −0.20
    COP 0.13 −0.16 0.48 −0.01 −0.08 0.60 −0.10 0.08 0.34 0.61 0.71 0.25
    Tree layer Density −0.27 −0.07 0.17 −0.55 0.80 −0.12 0.05 −0.22 −0.42 0.73 0.04 −0.15
    AHCT 0.27 0.17 −0.06 0.92 0.14 0.04 −0.05 0.21 0.89 0.02 0.09 −0.22
    ADBH 0.40 −0.14 −0.04 0.65 −0.16 0.59 0.02 0.32 0.84 0.02 0.04 0.18
    Cover 0.49 0.17 0.22 −0.01 0.43 0.81 −0.22 0.27 −0.36 −0.04 0.42 −0.29
    Shrub layer Cover −0.18 0.30 −0.06 0.02 0.07 0.21 0.94 0.89 −0.11 0.02 −0.02 0.01
    AHS −0.08 0.29 0.20 0.14 0.12 0.09 0.83 0.78 0.23 0.28 0.04 −0.32
    Density −0.12 0.56 −0.51 −0.11 0.04 0.36 0.75 0.33 −0.22 0.13 0.07 0.12
    Herb layer LLC −0.22 0.00 −0.22 −0.75 0.83 0.06 0.14 0.19 0.14 −0.05 0.04 0.18
    HC −0.02 −0.61 0.13 −0.15 0.00 −0.13 −0.12 −0.16 0.12 0.33 −0.88 0.55
    Macrohabitat DSR 0.08 0.02 −0.82 −0.17 −0.13 −0.08 0.15 −0.08 0.10 −0.09 0.04 0.92
    DSW −0.06 −0.45 0.18 −0.29 0.72 −0.10 0.08 −0.31 0.20 −0.17 −0.23 0.46
    Aspect −0.34 0.43 0.27 −0.40 −0.11 0.51 0.03 −0.33 0.17 0.41 0.74 −0.19
    Slope −0.03 −0.23 0.70 0.22 −0.47 0.26 −0.17 −0.37 0.14 0.32 0.28 −0.41
    Elevation 0.31 −0.19 −0.11 0.04 0.05 0.04 0.00 −0.08 −0.08 0.89 −0.07 0.26
    Percentage of variance explained (%) 18.1 18.6 13.3 15.1 12.8 11.8 12.2 11.6 11.9 11.4 11.3 10.9
    Cumulative percentage (%) 18.1 18.6 31.4 33.7 44.2 45.5 56.3 57.1 68.2 68.5 79.5 79.4
    Abbreviations are the same as for Tables 1 and 2.
     | Show Table
    DownLoad: CSV

    Habitat classification-tree

    Based on the results of RSI, t-tests and PCA, a habitat classification-tree for the two pheasants at Dazhong Mountain was established. There are several separations in the roosting habitat of the two pheasants, from macrohabitat to microhabitat (Table 4).

    Table  4.  Habitat classification-tree for roosting habitat of two pheasants
    Habitat factors Classification feature of habitat
    Macrohabitat 1. MEBF ………………………………………………….. 2
    2a. Slope 31.2, Aspect 11.8, DSW 39.3 m,
    DSR 34.4 m …………………………………………. S
    2b. Elevation 2465 m, DSR 57.4 m ………….. L
    Tree layer 3. AHCT > 8.2 m, ADBH > 11.4 m …………… 4
    4a. Density 25 tubes per m2 …………………… S
    4b. Density 39 tubes per m2, Cover 66.8 … L
    Shrub layer 5. Cover > 11.9, AHS > 1.5 ……………………… 6
    6a. Density 10 tubes per m2 …………………… S
    6b. Density 5 tubes per m2 …………………….. L
    Herb layer 7a. HC 10.5, LLC big ……………………………….. S
    7b. HC 2.6, LLC small ………………………………. L
    Roost tree 8. Oak, Crown size > 31.2 ……………………….. 9
    9a. DBH 18.5 cm, Height 8.1 m ……………….. S
    9b. DBH 27.5 cm, Height 11.3 m …………….. L
    Roosting branch 10. COP > 76.5 ……………………………………… 11
    11a. Height 3.6 m, APS 94.7 ………………….… S
    11b. Height 6.4 m …………………………………… L
    Abbreviations are the same as for Tables 1 and 2.
     | Show Table
    DownLoad: CSV

    Selection and separation in roosting trees and habitat

    The reason for the two pheasants roosting together was that they have the same crucial requirements and selection in habitat factors. In the spring, both Hume's Pheasant and the Silver Pheasant prefer roosts in moist evergreen broadleaf forests in the middle-mountain (Table 1) over other vegetation types. Deciduous broadleaf and Pinus yunnanensis forests in the Dazhong Mountain could not supply suitable coverage and temperatures for avian roosts, because dominant trees are sparse and crown closure is low. Therefore, these two pheasants simultaneously choose the same vegetation type and roosting trees in this area. The fact that birds favor trees which supply suitable shelter for safety and warmth as roosting place in their distribution area had been shown in previous studies (Ding et al., 2002; Jia et al., 2005; Shao and Hu, 2005; Jiang et al., 2006; Lu and Zheng, 2007).

    Based on the results of t-tests, there were significant differences in tree diameters at breast height, height of trees and perch height (Table 2). The values of these three factors selected by the Silver Pheasant were much larger than those of Hume's Pheasant. These separations avoided their competition for roosting in the same tree; thus the optimal spatial use of roosting trees by the two species was established. Moreover, there are still some other separations of habitat factors, such as canopy tree density, herb coverage, elevation and distance to water (Table 3), which reflect the different responses of the two pheasants to the same vegetation structure and terrain. For example, the Silver Pheasant seems to prefer denser tree canopy, higher herb coverage, farther distance to water and higher elevation than Hume's Pheasant. Although Hume's Pheasant and the Silver Pheasant lived sympatrically, their ecological niches separated in spatial dimensions and the habitat classification-tree reflects this separation (Table 4). Therefore, the same macrohabitat can accommodate several species with similar niches.

    Interspecific differences in pheasant roosting strategy

    The requirements of the two birds for safety differ in their roosting strategy. Safe shelters for roosts were composed of trees and shrubs of high density, perching position of high cover and terrain (Cody, 1985). Based on PCA, the position of roosting trees and shrub characteristics selected by the two pheasants were in the same or similar selection sequence; but characteristics of roosting branch selection in the two pheasants had different sequences. Slope was a unique factor only affecting Hume's Pheasant and tree canopy was unique only to the Silver Pheasant. The different requirements of pheasants for safety are reflected by selection of ecological factors and their order of priority (Table 3). Higher roosting branches and larger distances greatly decreases attacks from nocturnal animals (Prionailurus bengalensis, Mustela sibirica), which reflects an anti-predator strategy on a vertical spatial scale, used for roosting by both pheasants in Dazhong Mountain. However, the selection of other habitat factors reflects a difference in safety strategy of the two pheasants, i.e., slope was a unique factor only affecting Hume's Pheasant. The steeper the slope, the more chances for birds to escape by gliding. Therefore, the means for easy escape is one of the important factors affecting security of Hume's Pheasant. This fact was confirmed by the study of roost site selection in Chrysolophus pictus (Cong and Zeng, 2008). Tree canopy is a factor only affecting the Silver Pheasant. The higher the tree canopy, the smaller the danger for pheasants from predation. Hence, increasing the height of cover in the environment is still the main strategy for roost security of the Silver Pheasant. Briefly, for its safety strategy, Hume's Pheasant adopted primarily a way of "uneasily found habitat cover plus easy escape". The Silver Pheasant employed solely a way of "uneasily found habitat cover".

    The requirement for optimum temperature cannot be neglected in the roosting strategy of the two birds. A suitable roosting temperature is maintained by trees and shrubs by avoiding wind and rain (Kelty and Lustick, 1977; Cody, 1985). According to our PCA, shrub characteristics selected by the two pheasants were in the same order of selection and tree factors alternately appeared in their selection order. Aspect was a unique factor affecting the roosting selection only in Hume's Pheasant (Table 3). The function of tree factors contributed the same effects to both pheasants, which might imply that tree factors are the most important for keeping warm when roosting. Shrub density contributed to maintaining roosting temperatures (Moore, 1945), so these factors were selected by both pheasants. Different slope aspects provided different macroclimates. The leeward aspect provides more suitable temperatures for roosting than the windward aspect during the night (Cody, 1985). The aspect selected by Hume's Pheasant was leewards. Aspect seems therefore an auxiliary factor for keeping warm, used by Hume's Pheasant except for vegetation. In brief, for the tactics of keeping warm, Hume's Pheasant selected mainly a method of suitable vegetation, supplemented by topography. The Silver Pheasant chose uniquely the manner of suitable vegetation.

    We are specially thankful to the entire staff of Dazhong Mountain Station and the Nanhua Administration Bureau of the Ailaoshan National Nature Reserve, which supplied logistical support for the field investigation. Mr. D. Ji, a student of Southwest Forestry College, helped with the collection of some field data. This study was financed by the Wildlife Conservation Program of the State Forestry Administration of China in 2009.

    The study was supported by the National Key Project of the Scientific and Technical Supporting Programs Funded by the Ministry of Science and Technology of China (2012BAC01B06) and the National Natural Science Foundation of China (No. 30570234). We thank Jiliang Xu, Xinli Zhao, Jiang Chang and Ying Liu for the collection of samples, as well as administrations of the Yinchuan Zoo in Ningxia Autonomous Region, the Xining Zoo in Qinghai Province, the Linxia Dongjiao Zoo in Gansu Province and the Beijing Wildlife Park and Beijing Zoo for providing samples. We thank Xinli Zhao for providing unpublished markers from Crossoptilon mantchuricum and Shou-Hsien Li for providing unpublished markers from Syrmaticus mikado. We thank Lu Dong, Xiangjiang Zhan, Ning Wang and Yingying Liu for guidance with data analysis.

    • References (29)
  • Barbará T, Palma-Silva C, Paggi GM, Bered F, Fay MF, Lexer C. 2007. Cross-species transfer of nuclear microsatellite markers: potential and limitations. Mol Ecol, 16: 3759–3767.
    Burt DW, Morrice DR, Sewalem A, Smith J, Paton IR, Smith EJ, Bentley J, Hocking PM. 2003. Preliminary linkage map of the Turkey (Meleagris gallopavo) based on microsatellite markers. Anim Genet, 34: 399–409.
    Chapuis MP, Estoup A. 2007. Microsatellite null alleles and estimation of population differentiation. Mol Biol Evol, 24: 621–631.
    Cheng HH, Levin I, Vallejo RL, Khatib H, Dodgson JB, Crittenden LB, Hillel J. 1995. Development of a genetic map of the chicken with markers of high utility. Poult Sci, 74: 1855–1874.
    Cheng TH. 1978. Fauna Sinica Series Vertebrata Aves Vol. 4: Galliformes. Science Press, Beijing.
    Dawson DA, Horsburgh GJ, Küpper C, Stewart IRK, Ball AD, Durrant KL, Hansson B, Bacon I, Bird S, Klein Á, Krupa AP, Lee JW, Martín-Gálvez D, Simeoni M, Smith G, Spurgin LG, Burke T. 2010. New methods to identify conserved microsatellite loci and develop primer sets of high cross-species utility – as demonstrated for birds. Mol Ecol Resour, 10: 475–494.
    Excoffier L, Laval G, Schneider S. 2005. ARLEQUIN (version 3.01): an integrated software package for population genetic data analysis. Evol Bioinform Online, 1: 47–50.
    Groenen MA, Cheng HH, Bumstead N, Benkel BF, Briles WE, Burke T, Burt DW, Crittenden LB, Dodgson J, Hillel J, Lamont S, Leon AP, Soller M, Takahashi H, Vignal A. 2000. A consensus linkage map of the chicken genome. Genome Res, 10: 137–147.
    Huang ZH, Liao XJ. 2010. Cross-species amplification and characterization of microsatellite DNA loci from Gallus gallus in Bambusicola thoracica. Chinese Birds, 1: 74–76.
    IUCN. 2011. IUCN Red List of Threatened Species. Version 2011.2. . Accessed 15 Ocotober 2009.
    Karl SA, Castro ALF, Lopez JA, Charvet P, Burgess GH. 2011. Phylogeography and conservation of the bull shark (Carcharhinus leucas) inferred from mitochondrial and microsatellite DNA. Conserv Genet, 12: 371–382.
    Kimball RT, Mary CMS, Braun EL. 2011. A macroevolutionary perspective on multiple sexual traits in the Phasianidae (Galliformes). Int J Evol Biol, 2011: 423938.
    Lamoreux JF, Morrison JC, Ricketts TH, Olson DM, Dinerstein E, McKnight MW, Shugart HH. 2006. Global test of biodiversity concordance and the importance of endemism. Nature, 440: 212–214.
    Lei FM, Lu TC. 2006. China Endemic Birds. Science Press, Beijing.
    Li ZG, Hu TH, Zhai H. 2009. Habitat selection in spring and summer of Blue-eared Pheasant in Helan Mountain National Nature Reserve. Chinese J Wildl, 30: 310–313. (in Chinese)
    Myers N, Mittermeier RA, Mittermeier CG, Fonseca GAB, Kent J. 2000. Biodiversity hotspots for conservation priorities. Nature, 403: 853–858.
    Ohlemüller R, Anderson BJ, Araújo MB, Butchart SHM, Kudrna O, Ridgely RS, Thomas CD. 2008. The coincidence of climatic and species rarity: high risk to small-range species from climate change. Biol Lett, 4: 568–572.
    Primmer CR, Moller AP, Ellegren H. 1996. A wide-range survey of cross-species microsatellite amplification in birds. Mol Ecol, 5: 365–378.
    Primmer CR, Painter JN, Koskinen MT, Palo JU, Merilä J. 2005. Factors affecting avian cross-species microsatellite amplification. J Avian Biol, 36: 348–360.
    Rice WR. 1989. Analyzing tables of statistical tests. Evolution, 43: 223–225.
    Segelbacher G, Paxton RJ, Steinbruck G, Trontelj P, Storch I. 2000. Characterization of microsatellites in capercaillie Tetrao urogallus. Mol Ecol, 9: 1919–1952.
    Sun YH, Jia CX, Fang Y, Zheng GM. 2005. Preliminary study on the incubation rhythms of the Blue-eared Pheasant at Lianhuashan, Gansu, China. Chinese J Zool, 40(4): 29–33. (in Chinese with English abstract)
    Wang J, Yang C, Zhu L, Jia CX, Sun YH. 2011. Sex-linkage identification of microsatellite TUT1. Chinese J Appl Environ Biol, 17: 404–406. (in Chinese with English abstract)
    Wang N, Liu Y, Zhang ZW. 2009. Characterization of nine microsatellite loci for a globally vulnerable species, Reeves's Pheasant (Syrmaticus reevesii). Conserv Genet, 10: 1511–1514.
    Wang N, Zhang ZW. 2009. The novel primers for sex identification in the brown eared-pheasant and their application to other species. Mol Ecol Resour, 9: 186–188.
    Wu YH, Liu NF. 2010. The biology research of Crossoptilon auritum. Forest By-prod Special China, 4: 99–102. (in Chinese)
    Zane L, Bargelloni L, Patarnello T. 2002. Strategies for microsatellite isolation: a review. Mol Ecol, 11: 1–16.
    Zheng GM. 2011. A Checklist on the Classification and Distribution of the Birds of China. 2nd edition. Science Press, Beijing.
    Zhou ZT, Zhang YY. 2009. Isolation and characterization of microsatellite markers for Temminck's Tragopan (Tragopan temminckii). Conserv Genet, 10: 1633–1635.
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