Study site

Our fieldwork was carried out during April 2000 - August 2003 in the Dongzhai National Nature Reserve (31°40′N/114°24′E), located on the northern slopes of the Dabie Mountain range in the Henan Province of central China. The area comprises the major portion of the eastern distribution of Reeves's pheasant in China (Zheng & Wang 1998, Xu et al. 2007a). A 400-ha portion of the core area at Baiyun was selected as the study area (Xu et al. 2007a, 2009). The natural vegetation of this reserve is characterised by mature forests dominated by oaks Quercus spp., masson pine Pinus massoniana, dyetree Platycarya strobilacea, beautiful sweetgum Liquidambar formosana and Hupeh rosewood Dalbergia hupeana (Song & Qu 1996, Xu et al. 2007a, 2009). The study area suffered from serious habitat loss in the past, and presently the remaining forest fragments are surrounded by agricultural land and human infrastructure (Song & Qu 1996).

Capture and radio-tracking

We captured 17 male Reeves's pheasants during territorial establishment in April and May using a live decoy surrounded by about 30-foot hold traps (Xu et al. 2009). Each captured bird was then fitted with a coloured plastic leg band and a necklace radio-transmitter (Biotrack Ltd, UK) with frequencies between 216.00 and 217.00 MHz. The transmitter mass (16 grams) was < 2% of average pheasant body mass (Xu et al. 2009).

Radio-tagged pheasants were located using a portable TR-4 receiver (Biotrack Ltd, UK) and a Telonics hand-held three-element Yagi antenna (Biotrack Ltd, UK). We obtained bird locations once or twice each day by triangulation from permanent reference points within a randomly selected two-hour segment, between 05:00 and 19:30 or by direct observation. In most instances (> 95%) the distance from the observer to the pheasant was < 200 m. The time between consecutive radio-locations averaged 12 hours (range: 8-16 hours), normally resulting in two observations/day (Xu et al. 2009). Bird relocations were also divided into the four seasons (Xu et al. 2007a, 2009): spring (March-May), summer (June-August), autumn (September-November) and winter (December-February).

Determination of forest edges

We created digital habitat maps of the study area with a scale of 1:10,000 based on remote sensing images from September 1999 (Xu et al. 2006) and a 1:10,000 digital vegetation map of Baiyun (Xu et al. 2007a). We pooled the conifer-broadleaf mixed forest, naturally occurring broadleaf forest, mature pine plantation and mature Chinese fir plantation (Xu et al. 2007a) as woodlands. We defined forest edge types by resolution power of the images, existing plant species and their coverage and possible effects of the habitat on Reeves's pheasants based on the literature. As a result, the edge types in our study included shrubby vegetation, farmlands, unpaved roads and residential areas:

Data analyses

We used the Euclidean distances approach (Conner & Plowman 2001) to assess edge-use by Reeves's pheasant in the four seasons. We generated 100 random locations for the study area using ArcView 3.2. We obtained distances from radio-locations of each individual and the random locations in the study area to different types of forest edges in each season, which were considered vectors of (u_i) and (r_i), respectively. We defined distance to a forest edge type as the distance of radio-locations or random points to the nearest forest edge of this type. When a radio-location or random location was located within a forest edge, we defined the distance as being zero. We created a vector of ratios (d_i) for each animal in each season by dividing each element in u_i by the corresponding element in r_i within each season. The expected value of each element in d_i is 1.0 under the null hypothesis of no edge selection. We calculated the mean of the d_i in each season as a vector of ρ.

We used MANOVA to determine if ρ, differed from a vector of 1 (Conner et al. 2003), and we considered non-random edge-use to have occurred if ρ differed from a vector of 1. We determined the significance levels for winter by randomisation tests because of small sample size (Edgington 1995). To determine which edge types were used disproportionately, we tested each element within ρ to determine if it differed from 1 using a pair-wise t-test. If an element in ρ was < 1, then the corresponding edge type was preferred; if an element in ρ was > 1, then the corresponding forest edge type was avoided. Moreover, the elements in ρ provide ranking of different types of forest edge use. The edge with the lowest value was preferred the most, whereas the element with the largest value was used least. Additionally, we also used pair-wise comparisons to compare relative use among edge types.

We also used the Neu et al. (1974) method, including a χ²-test of goodness-of-fit and a Bonferroni Z-statistic to test whether there were differences of the proportions between the radio-locations in an interval of distance from an edge (hereafter used proportions) and the area in the corresponding distance interval (hereafter available proportions) in each season. We considered the proportion of radio-locations within a given distance interval as used, and the proportion of the area in the corresponding distance interval as available. We arbitrarily classified the distances to the forest edges into seven intervals: 0-50 m (including 0 m, and the same to the following), 50-100 m, 100-150 m, 150-200 m, 200-250 m, 250-300 m and ≥ 300 m. We selected the 50-m interval because it has commonly been used in similar studies (Ortega & Capen 2002, Jensen & Finck 2004).

For all statistical tests, we used a probability of ≤0.05 as the significance level. We executed a randomisation test using psychStats (available at:  http://www.lcsdg.com/psychStats) online in 2006, and we carried out other statistical procedures using SPSS 10.0.1 for Windows (SPSS Inc. 1999).

Responses to different types of forest edges and seasonal variations

Male Reeves's pheasant (N = 17) used shrub edges, farmland edges, road edges and residential edges non-randomly in all four seasons (P < 0.01 in spring, summer and autumn, and P < 0.05 in winter). In spring and summer, male Reeves's pheasants associated with shrub and residential edges more than expected (P < 0.01) and used farmland edges and road edges in proportion to their availability. Pheasants used shrub edges more than expected in autumn and winter (P < 0.01), preferred farmland edges in winter (P < 0.05) and used the other two forest edges proportional to their availability in autumn and winter. Pair-wise comparisons indicated that shrub edges were preferred over farmland and road edges (P < 0.05), but were similar in preference to residential edges in spring. Shrub edges were preferred over farmland edges (P < 0.05), but were similar in preference to the other two types of forest edges in summer. All other habitat types were similar in preference in all seasons (Table 1).

Effects of edge distance on male Reeves's pheasants

The distributions of the relocations of males in relation to edge distance and edge types in four seasons were not uniform (Fig. 1). Male Reeves's pheasants used distance to shrub edges non-randomly in all seasons (χ²-test: P < 0.01 for all). They preferred distance to shrub edges < 100 m in all seasons, and avoided distance to shrub edges > 200 m except in autumn (Table 2). Pheasants usually avoided distance to farmland edges < 250 m in summer (χ²-test: P < 0.05; see Table 2), whereas they used it in proportion to its availability in the other three seasons. Moreover, males preferred a distance of < 100 m to road edges in spring (χ²-test: P < 0.05) and used it proportional to its availability in the other three seasons.

The pattern was more complicated for residential edges (see Table 2). Males used distance to this kind of edge non-randomly in spring, summer and autumn (χ²-test: P < 0.05 for all) and used it in proportion to its availability in winter. Pheasants appeared to prefer distances < 250 m in spring, between 50 and 300 m in summer and between 200 and 250 m in autumn, and it seemed that males preferred sites close to residential edges in spring, and then preferred to be further away from these edges as the seasons progressed.

Management implications

We present the first direct evidence on the response of male Reeves's pheasants to different types of forest edges in a fragmented forest landscape in central China. Because this species of pheasant responded differently to various types of edges in relation to seasons, by using a simple assessment or management framework for assessing habitat fragmentation and restoring habitat for this pheasant, we may have overlooked key information that might improve conservation strategies. Instead, incorporating landscape patterns in management and conservation will be critical for addressing the edge effects at landscape scales (Fletcher & Koford 2003, Sekercioglu & Sodhi 2007). For instance, the proximity between shrubby areas and forests should be considered in detail (Xu et al. 2007a) and it would be better if the shrub patches were ≤ 200 m wide.

Our results documented the spatio-temporal responses to different forest edges at local scale for one species, but the pattern found for Reeves's pheasant in this reserve may not be unique. There are 14 protected areas containing Reeves's pheasant in the Dabie Mountains, central China, including five national nature reserves and seven provincial nature reserves (Xu et al. 2007a). The protected areas are managed under similar regulations and frameworks. Additionally, responses to forest edges by golden pheasants in some national nature reserves in Guizhou and Shaanxi, China (Liang et al. 2003) were similar to those described here. Therefore, the spatio-temporal response pattern that we demonstrate here should be applicable to the protected areas. However, because our work was confined to a single study area over a relatively short time, it is entirely reasonable to monitor spatial responses to different kinds of forest edges over a longer term and at a larger and landscape scale.