Population and risk assessment of sympatric pheasant species in Palas Valley, Pakistan

The effects of stocking density on growth, morphological development, behavior, and welfare parameters in pheasants (Phasianus colchicus)

In pheasants, which are generally raised in large flocks, stocking density is important for their growth and development, normal behavior and welfare. But there is still a lack of information on the optimum stocking density for game birds. This research was conducted on a total of 200 pheasants to examine the effects of low (5 pheasant/m2) and high (10 pheasant/m2) stocking density rearing practices on body weight, morphological development, behavioral characteristics and welfare parameters such as foot-pad dermatitis and plumage quality. When we look at the study results, it was determined that the density of stocking did not make a difference in the first 13 weeks of age, but pheasants reared at low density at the ages of 14-16 weeks reached higher body weight. In terms of body weight at 14, 15, and 16 weeks, the low stocking density group had an average of approximately 41, 71, and 94 g higher than the high stocking density group, respectively (p<0.05). It had been found that low density provides better morphological development. The low group was found to be significantly higher than the high group in terms of ornithological size, wingspan, back length, tail length, head length and head width, 5.9 cm, 2 cm, 1.3 cm, 7.6 cm, 1.7 mm and 1 mm, respectively (p<0.05). Since the animals in the low group had more individual space, they had the opportunity to perch and therefore exhibit more passive behavior. On the other hand, pheasants in the low group exhibited higher levels of aggressive behavior (p<0.05). More foraging behavior was observed in the higher group and the low-density group consumed more feed in the 14th week (p<0.05). But no significant differences were detected between groups in terms of feed consumption in other weeks (p>0.05). A 1.12 point higher score was calculated in the low group compared to the high group, especially in terms of tail feather quality, and as a result, pheasants reared in low stocking density had better plumage quality (p<0.05). It had been determined that as the stocking density decreases in the rearing of pheasants, they exhibit easier flight and roosting behaviors and therefore they were less affected by feather pecking behavior and had better feather quality. In addition, it had been determined that pheasants grow and develop better in this group, which had more rest opportunities. In conclusion, rearing at low stocking density is recommended for better fattening performance and better welfare conditions.

Shifts in the Distribution Range and Niche Dynamics of the Globally Threatened Western Tragopan (Tragopan melanocephalus) Due to Climate Change and Human Population Pressure

The impact of a changing climate, particularly global warming, often harms the distribution of pheasants, particularly those with limited endemic ranges. To effectively create plans of action aimed at conserving species facing threats such as the Western Tragopan, (Tragopan melanocephalus; Gray, 1829; Galliformes, found in the western Himalayas), it is crucial to understand how future distributions may be affected by anticipated climate change. This study utilized MaxEnt modeling to assess how suitable the habitat of the targeted species is likely to be under different climate scenarios. While similar studies have been conducted regionally, there has been no research on this particular endemic animal species found in the western Himalayas throughout the entire distribution range. The study utilized a total of 200 occurrence points; 19 bioclimatic, four anthropogenic, three topographic, and a vegetation variable were also used. To determine the most fitting model, species distribution modeling (SDM) was employed, and the MaxEnt calibration and optimization techniques were utilized. Data for projected climate scenarios of the 2050s and 2070s were obtained from SSPs 245 and SSPs 585. Among all the variables analyzed; aspect, precipitation of coldest quarter, mean diurnal range, enhanced vegetation index, precipitation of driest month, temperature seasonality, annual precipitation, human footprint, precipitation of driest quarter, and temperature annual range were recognized as the most influential drivers, in that order. The predicted scenarios had high accuracy values (AUC-ROC > 0.9). Based on the feedback provided by the inhabitants, it was observed that the livability of the selected species could potentially rise (between 3.7 to 13%) in all projected scenarios of climate change, because this species is relocating towards the northern regions of the elevation gradient, which is farther from the residential areas, and their habitats are shrinking. The suitable habitats of the Tragopan melanocephalus in the Himalayan region will move significantly by 725 m upwards, because of predicted climate change. However, the fact that the species is considered extinct in most areas and only found in small patches suggests that further research is required to avert a further population decline and delineate the reasons leading to the regional extinction of the species. The results of this study can serve as a foundation for devising conservation strategies for Tragopan melanocephalus under the changing climate and provide a framework for subsequent surveillance efforts aimed at protecting the species.