| Citation: |
Jin-Ming Zhao, Yun Fang, Yu-Hai Ma, Yue-Hua Sun. 2017: The importance of willow to the Chinese Grouse: evidence from analysis on their breeding territories at Lianhuashan, China. Avian Research, 8(1): 32. DOI: 10.1186/s40657-017-0090-5
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The habitat features of breeding territory have important adaptive significance for the survival and reproduction of territory holders. The Chinese Grouse (Tetrastes sewerzowi) is a rare and endemic species with relatively small distribution range and decreasing population trend. It is important to elucidate breeding territory habitat requirements of the Chinese Grouse for habitat management and conservation actions.
Using radio-telemetry and field observations, we determined the core areas of 65 breeding territories of males. Two to three samples were selected in each core breeding territory as used sites and compared with nearby sites with no grouse occurrence using logistic regression.
Our model showed a high accuracy in prediction of core breeding territory used by males, which preferred stands with more small deciduous trees (0.5 m ≤ height < 5 m), more small willow trees (Salix spp., 0.5 m ≤ height < 5 m), greater willow cover, and greater herb cover. The number of small willow trees had the greatest influence on males' core breeding territory selection. Dense shrubs were also chosen compared with unused sites. Tall conifer trees was an important determinant in the distribution of Chinese Grouse at the landscape scale, and was relatively important in the univariate model, but not included in our final multivariable model.
Male Chinese Grouse established territories at sites with abundant food resources. At the landscape scale, the Chinese Grouse occurred in alpine conifer forest. At the territory scale, small willow trees had the most important effect on males' core breeding territory selection. We suggest that the forest gaps in dense conifer forest are important for improving the occurrence of willows and facilitating breeding territory establishment for the Chinese Grouse.
Genetic diversity is the basis for evolutionary potential and environmental adaptability of species, hence recognizing the genetic background of a target species is extremely important (Frankham et al., 2002). The genetic structure of the population of a species depends on both historical events and current processes (Avise, 1994). A good understanding of the genetic structure of populations can support the design of an effective conservation program for a species (Zhang et al., 2010).
The Hooded Crane (Grus monacha) is a large migratory wading bird, designated as vulnerable in the IUCN Red List (IUCN, 2011), and as a First-class National Protected Wild Animal species in China. During the past two decades, due to habitat loss, hunting, pollution, pesticides and human activities, the population of the Hooded Crane has undergone a precipitous decline (BirdLife International, 2001).
The cranes winter in Japan, South Korea and China (BirdLife International, 2001). The lakes and coastal intertidal zones in the middle and lower reaches of the Yangtze River are major wintering areas for these birds. Delany and Derek (2006) estimate that there are about 1000–1500 individuals of this species wintering in China. The main wintering sites are Shengjin Lake (about 300) (Xu et al., 2006) and Caizi Lake (276) (Zhang, 2006a) in Anhui, Poyang Lake (255) in Jiangxi (Ji and Zeng, 2006) and Chongming Dongtan in Shanghai (about 130) (Zhang, 2006b). However, more recently, due to human disturbances, lake wetlands have become seriously degraded and habitats for the wintering population are constantly losing (Wang and Yan, 2002). The status of the population has become of major concern. In order to improve conservation of wintering populations, it is necessary to have a more thorough knowledge about the status of both their habitat and genetic background.
Non-invasive sampling is an important approach for studying conservation genetics of endangered wildlife (Li et al., 2001). Faecal sampling is one of the simplest non-invasive sampling methods with minimal impact on animals (Wang, 2001). At present, faecal DNA analysis has been successfully applied in studies of Otis tarda (Broderick et al., 2003; Idaghdour et al., 2003), Tetrao urogallus (Regnaut et al., 2006a, 2006b; Jancob et al., 2010), Ardeotis nigriceps (Ishtiaq et al., 2011), Grus janponensis (Honma et al., 2011), G. monacha (Dai and Zhou, 2011; Honma et al., 2011), G. vipio (Honma et al., 2011), as well as other threatened or endangered bird species.
In this study, using feces as sources of DNA samples, we analyzed the genetic diversity of Hooded Crane populations wintering in the major wetlands in the middle and lower reaches of the Yangtze River based on the mtDNA D-loop sequences. The objectives of this study were to understand the genetic diversity and structure of these populations and to accumulate basic data concerning the conservation genetics of the wintering populations.
Samples were collected from four wintering Hooded Crane populations (Fig. 1). Before faecal samples were collected, the foraging areas and overnight roosts of the cranes were observed with binoculars or telescopes. The minimum distance among individual birds observed was about 1–2 m. Fresh faecal samples were collected immediately after the cranes flew away to their foraging ground or the next morning at the overnight roosts. In order to avoid that each sample came from the same bird, we collected samples at each sampling location only once, with a minimum distance between samples of at least 2 m. We used disposable PE gloves to collect samples, which were placed into 50 mL centrifuge tubes and then 2 to 3 times its volume of absolute ethyl ethanol was added to preserve the samples. A total of 221 faecal samples were collected, consisting of 84 samples from Shengjin Lake (SJ), 61 from Caizi Lake (CZ), 30 from Poyang Lake (PY) and 46 from Chongming Dongtan (DT).
In addition, nine down feather samples from wintering cranes in Shengjin Lake and four muscle samples from dead birds found in the Shengjin Lake National Nature Reserve during 2008–2011 were collected. The feather and muscle samples were placed at −20℃.
DNA was extracted from faecal samples using the improved method of Guanidine Thiocyanate and Glass Milk (Reed et al., 1997; Dai and Zhou, 2011). After DNA was extracted, 70% ethanol was added to wash it 2–3 times. After air drying, 50 µL of ddH2O was added. DNA from each faecal sample was extracted repeatedly four times, after which the extracted DNA was pooled and purified (Zhao et al., 2005; Regnaut et al., 2006b). DNA extraction from feather and muscle samples was carried out using the conventional but improved Protease-Phenol/Chloroform method (Sambrook et al., 1989; Zan et al., 2008).
LC16004 (5′-GAG CCC TAG AAA ACA AAA TA-3′), LC16575 (5′-ACA AAA GAA ACC CCC AAA CTC A-3′) and HC01342 (5′-AAG AAT TCT GCG GAT ACT TGC ATG T-3′) were chosen as primers for the amplification of DNA D-loop sequences of mitochondria of Hooded Cranes (Hasegawa et al., 1999). The PCR mix (50 µL) comprised of 3−5 µL of an extract, 0.2 µM of each primer, 0.4 mg/mL of BSA and 1 × EasyTaq PCR SuperMix (Trans). Cycling parameters consisted of an initial denaturation at 94℃ for 3 min followed by 35 amplification cycles of 45 s at 94℃, 1 min at 58℃ and 1 min at 72℃ with a terminal cycle of 10 min at 72℃ (Hasegawa et al., 1999). The amplified products were detected with a gel imager after electrophoresis for 30 min at 120 V with 1.5% EB-agarose gel. Finally, a two-way sequencing was performed on the purified PCR products (Sangon Biotech (Shanghai) Co., Ltd.).
MtDNA D-loop sequences of two Hooded Cranes wintering in Japan were obtained from GenBank (AB017625 and AB023813). The SeqManII program from the DNASTAR software package (Burland, 2000) was used to match the coupled sequences of one sample and compared them with the sequences from GenBank in order to confirm the target sequences. A total of 72 mtDNA D-loop sequences were obtained for genetic analysis. The sequences were aligned using the Clustal W in MEGA4.0 software (Tamura et al., 2007); haplotypes were identified by DAMBE (Xia and Xie, 2001). We had submitted the data from these haplotypes to GenBank and received the accession numbers (JQ015266-JQ015288).
As the representatives of the Japanese wintering population (JA), the two sequences obtained from GenBank were analyzed. Haplotype (h) and nucleotide diversities (π) were calculated using Dnasp5.10 software (Rozas et al., 2003). Genetic differences between populations (FST) were obtained by analysis in Arlequin3.11 software (Excoffier et al., 2005), Tajima's D (Tajima, 1989) and Fu's FS (Fu, 1997) tests were performed by Dnasp5.10 (Rozas et al., 2003). The validity of the estimated demographic model was tested via Arlequin3.11 (Excoffier et al., 2005) from the distribution of a SSD test between the observed and an estimated mismatch distribution (Bootstrap test with 1000 replicates). We estimated the time since population expansion according to the relation t = τ/2μk, where τ is the relative measure of the time since population expansion, calculated from the data, μ the rate of mutation and k the length of the sequence (Rogers et al., 1992).
Phylogenetic analyses of different haplotypes were performed in MEGA4.0 (Tamura et al., 2007). Neighbor-joining (NJ) trees were constructed based on the Kimura 2-parameter Distance (Bootstrap test with 1000 replicates); simultaneously, we took G. grus homologous sequences as the outgroup (GenBank FJ769849). A haplotype network diagram was constructed using the Median-joining method by Network4.600 (www.fluxusengineering.com).
The full-length of 72 D-loop sequences of the four Hooded Crane wintering populations from the middle and lower reaches of the Yangtze River was restricted between 1103 and 1104 bp containing 26 variable sites (2.4%), consisting of eight parsimony-informative sites, 16 singleton sites, one deleted site and one inserted site. The base composition analysis of D-loop sequences of Hooded Cranes showed the following: the average contents of A, G, C and T bases were 30.48%, 14.77%, 25.55% and 29.20% respectively; the content of A + T (59.68%) was higher than that of G + C (40.32%).
A total of 23 haplotypes were defined (Table 1). Among these, H03 was the haplotype shared by all four populations wintering in China; H05 was shared by CZ, PY and DT, H06 by CZ, SJ and DT, H11 by CZ, SJ and PY, while H01, H02, H07 and H10 were shared by CZ and SJ. The remaining haplotypes were unique to each population, among which three haplotypes were from CZ, nine from SJ and three from DT.
| Haplotype | GenBank accession number | Population | Total | ||||
| Shengjin Lake (SJ) | Caizi Lake (CZ) | Poyang Lake (PY) | Chongming Dongtan (DT) | ||||
| H01 | JQ015266 | 3 | 1 | 4 | |||
| H02 | JQ015267 | 1 | 1 | 2 | |||
| H03 | JQ015268 | 10 | 12 | 4 | 3 | 29 | |
| H04 | JQ015269 | 1 | 1 | ||||
| H05 | JQ015270 | 1 | 3 | 1 | 5 | ||
| H06 | JQ015271 | 1 | 3 | 2 | 6 | ||
| H07 | JQ015272 | 1 | 3 | 4 | |||
| H08 | JQ015273 | 1 | 1 | ||||
| H09 | JQ015274 | 1 | 1 | ||||
| H10 | JQ015275 | 2 | 2 | 4 | |||
| H11 | JQ015276 | 1 | 1 | 1 | 3 | ||
| H12 | JQ015277 | 1 | 1 | ||||
| H13 | JQ015278 | 1 | 1 | ||||
| H14 | JQ015279 | 1 | 1 | ||||
| H15 | JQ015280 | 1 | 1 | ||||
| H16 | JQ015281 | 1 | 1 | ||||
| H17 | JQ015282 | 1 | 1 | ||||
| H18 | JQ015283 | 1 | 1 | ||||
| H19 | JQ015284 | 1 | 1 | ||||
| H20 | JQ015285 | 1 | 1 | ||||
| H21 | JQ015286 | 1 | 1 | ||||
| H22 | JQ015287 | 1 | 1 | ||||
| H23 | JQ015288 | 1 | 1 | ||||
| Total | 28 | 27 | 8 | 9 | 72 | ||
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Haplotype diversities of the mitochondrial control region for the four wintering populations of the Hooded Crane in China ranged between 0.679–0.889 with the maximum occurring in the DT population (h = 0.889 ± 0.091) and the minimum in the PY population (h = 0.679 ± 0.122). Although the haplotype diversities were relatively high, the nucleotide diversities were low (between 0.00071–0.00295) with the maximum occurring in the DT population (π = 0.00295 ± 0.00094) and the minimum in the PY population (π = 0.00071 ± 0.00018). The average haplotype diversity and nucleotide diversity for the four wintering populations was h = 0.823 ± 0.042 and π = 0.00157 ± 0.00021 respectively (Table 2).
| Population | n | Haplotype diversity h | Nucleotide diversity π | Tajima's D test | Fu's FS test |
| SJ | 28 | 0.870 ±0.058 | 0.00171 ±0.00027 | -1.86644* | -12.83357** |
| CZ | 27 | 0.792 ±0.074 | 0.00123 ±0.00020 | -1.07116 | -6.64340** |
| PY | 8 | 0.679 ±0.122 | 0.00071 ±0.00018 | 0.06935 | -0.22360 |
| DT | 9 | 0.889 ±0.091 | 0.00295 ±0.00094 | -1.77149* | -0.974 |
| Total | 72 | 0.823 ±0.042 | 0.00157 ±0.00021 | -2.10951* | -19.351** |
| * 0.01 < p < 0.05; ** p < 0.01. | |||||
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Population differences (FST), based on the frequency of the haplotype distribution, showed that the genetic difference between the CZ and Japanese populations was the largest (0.60057) and that between the SJ and PY populations the lowest (−0.00261) (Table 3). On the whole, the values of FST among the four wintering populations in China were lower than those of the Japanese population.
| SJ | CZ | PY | DT | |
| SJ | ||||
| CZ | −0.00237 | |||
| PY | −0.00261 | −0.00106 | ||
| DT | 0.01191 | 0.01384 | 0.02013 | |
| JA | 0.52552** | 0.60057** | 0.59739* | 0.32440 |
| * 0.01 < p < 0.05; ** p < 0.01. | ||||
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According to the NJ tree, its construction based on the Kimura 2-parameter Distance, the haplotypes of Hooded Cranes were mixed in the gene-tree without significant geographic differentiation (Fig. 2). The differentiation between haplotypes was small, with its result supported by network diagram analyses (Fig. 3). From the network construction of haplotypes, it can be observed that the haplotypes of the SJ population are more widely distributed; most of the mutations were one-step mutations, where the number of mutation steps between adjacent haplotypes H07 and H24 was the largest (7 steps).
The mismatch distribution of the Chinese populations appeared to be a unimodal shape (Fig. 4). Tajima's D and Fu's FS were both significantly negative (D = −2.10951, p < 0.05; FS = −19.351, p < 0.01) (Table 2), indicating that population expansion had occurred in the history of the Hooded Crane population. Demographic parameters estimated by mismatch analyses corresponded to a null model of population range expansion (τ > 0, θ1 > θ0) that could not be rejected (p-values of SSD and Harpending's Raggedness index were 0.604 and 0.530 respectively).
Nucleotide diversity (π) is an important indicator for measuring mtDNA genetic diversity of populations, because it takes into account the proportions of each mtDNA haplotype in populations (Nei, 1987). In our study, the nucleotide diversity (0.00157 ± 0.00021) was lower when compared to other cranes, such as G. japonensis (Hasegawa et al., 1999), G. leucogeranus (Ponomarev et al., 2004), G. canadensis (Rhymer et al., 2001) and G. americana (Glenn et al., 1999). It suggests that the genetic diversity of the Hooded Crane is relatively poor.
The results of the high haplotype diversity (0.823 ± 0.042) and low nucleotide diversity (0.00157 ± 0.00021) in the Hooded Crane populations suggest that it may be in a period of rapid increase in size starting from a small effective population. Furthermore, the mismatch distribution (Fig. 4) and neutrality tests (D= −2.10951, p < 0.05; FS = −19.351, p < 0.01) show that the population experienced expansion. To our knowledge, no detailed molecular clock calibrates the Hooded Crane mtDNA D-loop sequence. Divergence rates for the Cyt b gene in cranes is 0.7%–1.7% per million years (Krajewski and King, 1996). The mutation rate of the D-loop gene is approximately 2.8–5 times faster than that of other gene segments (Avise et al., 1987), so we estimated that the time since the population started to expand was about 8900–38000 years ago (τ = 1.676). These events occurred during a relatively limited time period, enough to increase haplotype diversity, but insufficient to improve nucleotide diversity.
In natural populations, genetic structures will change significantly by a decline in the size of a population as well as by habitat fragmentation. Furthermore, increased inbreeding and genetic drift will result in the loss of genetic heterogeneity and diversity (Li et al., 2000). In our study the FST values, obtained from multiple comparisons showing no significant genetic differences, were detected among the four wintering populations of the Hooded Crane in China (Tables 3). Their lack of phylogeographic structures (Fig. 2 and 3) indicate that close relations exist among these wintering populations. The reason may be that they originate from the same breeding ground, or that the strong flying ability of migratory birds is not subject to geographical isolation (Crochet, 2000). Some studies have proven that migratory birds have difficulty in forming population subdivisions, such as the Ciconia boyciana (Zan et al., 2008), Locustella pryeri sinensis (Zhang et al., 2010), Branta bernicla hrota (Harrison et al., 2010), Limosa limosa limosa (Trimbos et al., 2011) and several other migratory birds.
It must be noted that there are significant genetic differences between the Chinese and Japanese populations of the Hooded Crane (Table 3), suggesting that there may be some degree of genetic differentiation between them. However, due to the small number of birds in the Japanese population sample, it is necessary to increase the number of samples in order to increase our knowledge about the genetic differentiation of these cranes. Furthermore, due to this limited number of samples and the possibility of repeated faecal collection, the information obtained may be of limited value. It becomes therefore necessary to collect more samples and as well to use SSR for individual identification and analysis of genetic structures in any future study.
In this study, we have come to the realization that the genetic diversity of this species is poor. In recent years, human activities have given rise to habitat loss, pollution and pesticides, which has resulted in a decline in the size of our Hooded Crane population (IUCN, 2011). In general, the main reason for loss of genetic diversity in a species is a small or declining population. Inbreeding and loss of genetic diversity are inevitable in small populations of threatened species (Frankham et al., 2002). Over the short term, a poor genetic background would lower the fertility and survival rate of species; in the long run, loss of genetic diversity will diminish the capacity of populations to evolve in response to environmental change (Zan et al., 2008).
Hooded Cranes depend strongly on their habitat. Their habitat should be a key consideration for the development of conservation and management strategies, not only in wintering areas but also in breeding and migration areas. Expanding their habitat is useful for restoring population size, as well as improving the adequacy of individual birds to avoid inbreeding and genetic drift. Sufficient time should be allotted to accumulate effective nucleotide variation to improve the genetic diversity and evolutionary potential of this population.
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| 1. | Jin-Ming Zhao, Chen Yang, Ying-Qiang Lou, et al. Nesting season, nest age, and disturbance, but not habitat characteristics, affect nest survival of Chinese grouse. Current Zoology, 2020, 66(1): 29. DOI:10.1093/cz/zoz024 |
| 2. | Mei Shi, Yun Fang, Jin-ming Zhao, et al. Egg laying and incubation rhythm of the Chinese Grouse (Tetrastes sewerzowi) at Lianhuashan, Gansu, China. Avian Research, 2019, 10(1) DOI:10.1186/s40657-019-0161-x |
| 3. | Jin-Ming Zhao, Yun Fang, Ying-Qiang Lou, et al. Brood rearing has an immediate survival cost for female Chinese Grouse Tetrastes sewerzowi. Journal of Ornithology, 2018, 159(4): 1019. DOI:10.1007/s10336-018-1578-4 |
Figures(3) / Tables(3)
| Haplotype | GenBank accession number | Population | Total | ||||
| Shengjin Lake (SJ) | Caizi Lake (CZ) | Poyang Lake (PY) | Chongming Dongtan (DT) | ||||
| H01 | JQ015266 | 3 | 1 | 4 | |||
| H02 | JQ015267 | 1 | 1 | 2 | |||
| H03 | JQ015268 | 10 | 12 | 4 | 3 | 29 | |
| H04 | JQ015269 | 1 | 1 | ||||
| H05 | JQ015270 | 1 | 3 | 1 | 5 | ||
| H06 | JQ015271 | 1 | 3 | 2 | 6 | ||
| H07 | JQ015272 | 1 | 3 | 4 | |||
| H08 | JQ015273 | 1 | 1 | ||||
| H09 | JQ015274 | 1 | 1 | ||||
| H10 | JQ015275 | 2 | 2 | 4 | |||
| H11 | JQ015276 | 1 | 1 | 1 | 3 | ||
| H12 | JQ015277 | 1 | 1 | ||||
| H13 | JQ015278 | 1 | 1 | ||||
| H14 | JQ015279 | 1 | 1 | ||||
| H15 | JQ015280 | 1 | 1 | ||||
| H16 | JQ015281 | 1 | 1 | ||||
| H17 | JQ015282 | 1 | 1 | ||||
| H18 | JQ015283 | 1 | 1 | ||||
| H19 | JQ015284 | 1 | 1 | ||||
| H20 | JQ015285 | 1 | 1 | ||||
| H21 | JQ015286 | 1 | 1 | ||||
| H22 | JQ015287 | 1 | 1 | ||||
| H23 | JQ015288 | 1 | 1 | ||||
| Total | 28 | 27 | 8 | 9 | 72 | ||
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| Population | n | Haplotype diversity h | Nucleotide diversity π | Tajima's D test | Fu's FS test |
| SJ | 28 | 0.870 ±0.058 | 0.00171 ±0.00027 | -1.86644* | -12.83357** |
| CZ | 27 | 0.792 ±0.074 | 0.00123 ±0.00020 | -1.07116 | -6.64340** |
| PY | 8 | 0.679 ±0.122 | 0.00071 ±0.00018 | 0.06935 | -0.22360 |
| DT | 9 | 0.889 ±0.091 | 0.00295 ±0.00094 | -1.77149* | -0.974 |
| Total | 72 | 0.823 ±0.042 | 0.00157 ±0.00021 | -2.10951* | -19.351** |
| * 0.01 < p < 0.05; ** p < 0.01. | |||||
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| SJ | CZ | PY | DT | |
| SJ | ||||
| CZ | −0.00237 | |||
| PY | −0.00261 | −0.00106 | ||
| DT | 0.01191 | 0.01384 | 0.02013 | |
| JA | 0.52552** | 0.60057** | 0.59739* | 0.32440 |
| * 0.01 < p < 0.05; ** p < 0.01. | ||||
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