Avian Abundance, Diversity and Conservation Status in Etago Sub-County Kisii County Kenya

Bird’s species diversity and abundance are being threatened due to agricultural activities and anthropogenic practices which causes habitat destruction and fragmentation. Understanding how avian species respond to habitat destruction is important towards development of effective measures to ensure that the environment is protected. A study on avian abundance, diversity and conservation status was conducted in Etago Sub-County, Kisii County Kenya from September 2018 to February 2019. Point counts and time species counts were used to carry out birds’ survey to determine their abundance and diversity in the secondary forest, sugarcane plantations, human settlement and mixed firms. A total of 4992 individuals were observed and recorded in the entire study area. The human settlement had the highest density of 1.664 ± 0.18 birds/ha followed by sugarcane plantation with 1.092 ± 0.16 birds/ha and Nyangweta secondary forest was third with 0.0819 ± 0.13. Mixed firms had the least density of 0.95 ± 0.017 bird/ha. Further Dunn’s multiple comparisons test showed that Mixed farming and forest had no significant difference and had mean rank difference of 11.37. In mixed farming vs human settlement there was a significant difference with a mean rank difference of 57.38; in mixed farming vs sugarcane farms there was no significant difference; in the four habitats, 114 species of birds were cumulatively recorded. Out of these, 106 species were recorded in the secondary forests, 98 human settlement and 87 species in the sugarcane plantations and 55 in mixed farms. There was a significant difference in bird diversity in the four habitats where Secondary forest had the highest diversity of 3.85 and sugarcane plantations had a diversity of 3.71 while human settlement and mixed firms had lower diversities of 2.6 and 2.5 respectively (df1 = 2, df2 = 0.0 F = 0.00001, P = 0.00001).


Introduction
Highlands and Mountains are known for sheltering high diversity of birds with many coexisting species within habitat types [1]. Forest is the most important habitat for birds by sustaining around 85% of all bird species while only 45% of all bird species have adapted to human modified habitats [2] [3]. Human activities such as farming, settlement, charcoal making, pole cutting, and firewood collection have contributed in removal of forests (degradation) which has expansively damaged the natural habitat of birds, affecting their variety and variability [4].
Birds are very noticeable and form an integral part of the ecosystem. Birds occupy many trophic levels in a food chain ranging from consumers to predators. Their occurrences have been helpful as ecological health indicator, plant pollinators particularly of trees with sturdy, brightly coloured flowers [5] and seed dispersal that is Frugivorous birds assist in the natural regeneration by dispersing seeds [6] as well as pest controller [7]. Furthermore they form part of the attractive vertebrates which are enjoyable to watch because of their distinctive colors, showy display, also distinctive songs and calls.
Avian species diversity is a function of the number of species present (species richness or number of species) and the evenness with which the individuals are dispersed among these species (species evenness, species equitability, or abundance of each species) [8]. According to [9] [10] this definition may be the best one available at the moment [11]. They emphasized that the concept of species diversity should be restricted to this extent if it should have any useful meaning.
There have been two approaches to measuring avian species diversity, both of which incorporate information on the number of species (species diversity) and the relative abundances of individuals within each species (species abundance) [10]. One method has been to construct mathematical indices broadly known as diversity indices and the other involves comparing observed patterns of species abundance to theoretical species abundance models. Species diversity indices take two aspects of a community into account, namely species richness and evenness or equitability (the distribution of abundance among the species) [10].
The combined effect of landscape degradation caused by agricultural development, forestry practices together with accelerated climate change is the greatest current menace to biodiversity [12]; Millennium Ecosystem Assessment 2005 [13].
In Kenya habitat fragmentation is a paradigm of three main effects: degradation of habitat quality; separation of habitat fragments by anthropogenic matrix (e.g. pasture lands and settlements) and increased intensity of edge effects [14] Habitat changes migrants [15]. The main effect to less diverse and range-restricted birds, rainforest specialists and altitudinal habitat fragmentation and degradation is the reduction of population size and an increased vulnerability to extinction [15]. This exposes risk to many tropical species, as in Kenya, forest habitats have already been drastically altered by human activities and most of the natural Species abundance is a component of biodiversity and refers to how common or rare a species is relative to other species in a defined location or community.
Species abundances tend to conform to specific patterns that are among the best-known and most-studied patterns in macro ecology. Usually species abundances are described for a single trophic level. Because such species occupy the same trophic level they will potentially or actually compete for similar resources.
For example, species abundances might describe all terrestrial birds in a forest community. A number of factors are known to affect bird species abundance in any natural ecosystem.
According to Bird life International's World Bird Data base, land use practices are the biggest source of threat to bird species listed as threatened, and that this is substantially more important for species in developing than developed countries [17]. Most research on farmland in the tropics has been in the form of comparative studies between more natural areas and adjacent farmland [18], and investigating the effect of adjacent farmland and savanna on populations of birds in fragmented natural habitat [19] [20].
Therefore in understanding the threat of land use patterns on biodiversity in Kisii County and Etago Sub-County in particular, the assessment of birds' diversity and abundance is crucial. This could contribute to their conservation and protection. Pursuant to that, this study will examine the diversity, abundance and conservation status. Generally the specific objective of the study was 1) to determine the abundance of birds in various habitat types in Etago Sub-County The area is selected because of its vast array of land use practises. The site is chosen based on visual determination of the intensity of various land use practices like agriculture and forested land in order to cover a bigger range of anthropogenic affected areas, the map ( Figure 1) is a section of Etago Sub-County.

Data Collection
The belt transect was chosen as sampling units due to the open nature of much of the area [21]. Prior to field surveys the study area was stratified into habitats 1) sugarcane firms 2) secondary forests 3) areas under human settlement and 4) mixed farming. A sample area of 1 × 1 km square was picked at random from each of the four study areas. Those selected areas were further sub-divided into 0.5 × 0.5 km smaller study areas and a total of 3 belts were laid down randomly within the small study areas. The areas consist of a mosaic of many different habitats and field types so in order to limit the habitats surveyed per transect, transects were restricted to 100 M by 50 M in size. This involved moving along a pre-determined route and all birds seen or heard were recorded and the perpendicular distance of each to the point of observation (plots). The program GPS Utility was used to place transects within each site. Each start point being at least 50 M away from the nearest neighbour in order to avoid crossing of transects.
Sites were chosen randomly to distribute visiting time equally across all transects. All birds observed were identified and the number in the group recorded.

Data Analysis
Data from the field was looked into, in the case where data deviated from the normal distribution appropriate intervention method was applied. Data on Open Journal of Ecology abundance was tested for normality and then was subjected to square root transformation to normalize it then the formula was applied to determine relative density. A probability of Type I error of 0.95 (α = 0.05 or less) was accepted as significant (unless otherwise noted). The data was analyzed using SPSS and R-program [22].
Data on avian species diversity in the four habitats was calculated using the Shannon diversity (H) index. Species richness is a biologically appropriate measure of alpha (α) diversity and is usually expressed as number of species per sample unit [23]. The Shannon diversity index (H) was calculated using the fol- Relative abundance of a species is the abundance of a species divided by total abundance of all species. It is based on the assumption that the more frequently a species is seen the more abundant it is (Bibby, Martin, & Marsden, 2002). For every habitat, relative abundance of each species was calculated as follows Number of birds of each species 100% Number of birds of each species

Avian Abundance
A total of 4920 birds of different species were recorded on 4 sites surveyed. Most of the species were dominant in almost all study sites and 3 species taking higher numbers were noted. The average density of the three most common species was highest with Nyangweta taking 1230, sugarcane plantation taking 1340, human settlement taking 1390 and mixed farming taking 960 respectively. Human settlement, sugarcane plantation and Nyangweta took the lion share of the average density with mixed farming taking the lowest. Human settlement had the highest mean with a density of 1.664 ± 0.18 birds/Ha. Then it was followed by sugarcane farms with a density of 1.092 ± 0.16 birds/Ha. Nyangweta secondary forest came third with a mean density of 0.9819 ± 0.13 birds/Ha. Mixed farms had the lowest density/Ha of 0.95 ± 0.17 birds/Ha ( Figure 2).
The densities of bird species/Ha were also analyzed in every study site and the following were obtained: 1) Nyangweta In Nyangweta the Common Bulbul (Pycnonotus barbatus) and Tropical Boubou (Laniarius aethopicus) had the highest abundance with a density of 8 ± 0.2471 birds/Ha, followed by Common Fiscal (Lanius collaris) at 7 ± 0.1340, African Paradise Flycatcher (Terpsiphone viridis) 6 Figure 3.

3) Human Settlement
In human settlement the Baglafecht Weaver (Ploceus baglafech) had the highest abundance with a density of 7 ± 0.3845 birds/Ha. This was followed by Com-

Bird's Species Diversity
In the four habitats, H range was between 2.5 and 3.85. Shannon diversity index was higher in secondary forest (H = 3.85) than in other study sites. Secondary forest was diverse with more different and number of bird species compared to other habitats. A further post hoc Turkey's pairwise comparison test showed that the Nyangweta secondary forest had the highest diversity with a diversity index of 3.85, Human settlement followed with a diversity index of 3.71. Sugarcane plantation and mixed farming were third and fourth with an index of 2.8 and 2.5 respectively. As shown in Figure 5.

1) Bird Species Richness per Habitat
Bird species richness, were summarized and equated amongst the four habitats (Nyangweta, Sugarcane plantation, Human settlement and Mixed farming). Bird's species richness was computed using birds' recorded by TSC. A total of 492 birds cumulatively documented in the four habitats using TSC's. From all these, 104 species were recorded in Nyangweta, 87 in sugarcane plantations, 98 in human settlement and 70 in mixed farming. 105 species (78.25%) were observed in at least two of the four habitats and a total 52 species (25.00%) were observed across the four habitats. Nyangweta forest had the highest species richness at 104 species (78.25%) ( Table 4).

2) Species Cumulative Curve
This simple test aimed to bring out how close the total numbers of species recorded during the study were to the potential total number of species actually in the study area. The species discovery curves of Nyangweta, sugarcane plantation, human settlement and mixed farming areas were as per the begun day one to day fifteen respectively where increased searches was unlikely to record new additional species in the three fragments ( Figure 6).   In Etago Sub-County 114 species of birds were observed out of which 15 species were Afrotropical migrants, 13 species were Palearctic migrants, 6 species were both Palearctic and Afrotropical migrants and 71 species were residents.

3) Forest Dependency
The study area had highest number of forest visitor standing at 60%, followed by non-forest birds at 27%, forest generalist at 10% and forest specialist were least at 3%.

Avian Abundance
The trend indicated high avian abundance in areas with heavily induced human  [26]; [27] also found similar result and concluded that high abundance in the settlement and sugarcane plantations were triggered by habitat heterogeneity such as grasslands, trees and gardens trees established by humans. It was observed that during the entire period of study, human settlement and sugar firms had high avian density. This could be explained by the fact that these areas are open in nature and had plenty of food and cover for different species of birds [27] [28]. Forest habitat had a few individuals recorded; the least number could be due to forest degradation through tree logging, cutting of building materials, collection of firewood and charcoal making which affect forest birds

Avian Diversity
The findings from this study agree with many other studies [24]; Chace and Walsh, 2006 [25]; that higher vegetation cover supports higher diversity of birds.
The highest diversity observed in forest was more likely because of well sufficient vegetation cover than in the settlement and farmland which has been affected by land use changes [29]. The highest species diversity indicates a complex community in which a high degree of species interaction is possible contrary to higher abundance and dominance observed in settlement and farmland, which implies that few species pre-dominate the habitats. Though farmland showed less diversity, higher dominance was due to persistence of native and generalist species like a large number of Tropical Boubou (Laniarius aethopicus) (Chance and Walsh, 2006 [26]). On the other hand, the higher richness in the forest is supported by continuation of vegetation which reduces the impact of predation to adult birds, young and eggs. The case is different to highly interfered habitat like settlement and farmland [30]. Avian species richness was highest in Nyang- Habitat loss and degradation are considered major causes of avian species decline (Coulson & Crockford, 1995). In Etago Sub-County deforestation, encroachment of grassland in swamps and protected areas and human settlement were found to be the major threats to avian abundance and diversity. As expected [31] (Gaston, 1994), such gap formation and habitat reduction had a direct effect on the bird species. Such an observation on a sedentary, territorial and habitat specific species like forest specialist would mean that, continued pressure on the species' preferred habitat will be reflected with an increased competition for resources.
Diamond (1975) claims that, patterns in distribution of species over geographic locations or habitat types have been interpreted as evidence of competition. Intraspecific competition potentially has a negative effect on the excluded members [32], by forcing them to locate territories in areas that may be less suitable.
For example forest specialist species have greatly reduced in number due to forest disturbance and this species could have migrated to other habitats with less disturbance and low competition. Such poor habitats will offer less supply of resources, reducing their reproductive and survival success and present more chances of loss by predation and hunting, leading to a decline in the species population size.
Although some species have become very successful as a result of shifts in land-use activities [33] many species of birds have suffered due to such a shift and human disturbance within their habitat. [5] [34] found such changes affecting Tambourine Dove home range and cover. The same was evident with M.
sharpie [32]. The consequences of habitat loss are thus clearly evident.

Conclusions
The findings of this study show that areas with heavily induced human activities like sugarcane plantations and human settlement areas indicated high avian abundance. This could have been attributed to the fact that human-disturbed areas provide heterogeneous habitats which attract human tolerant avian species. The high density of birds per hector in human settlement and sugarcane farms could also be attributed to the fact that this areas were open in nature and had plenty of food and cover for different species of birds.
The study also showed that forested areas like Nyangweta forest had high avian diversity and this was attributed to sufficient vegetation cover. High diversity was also an indicator of complex avian communities within the forest in which there was high degree of species interaction.
From the findings in this study it is evident that there was variation in avian abundance in different land use types. It was also clear that increased land use Open Journal of Ecology intensity altered avian diversity. It can also be concluded that vegetation played a major role in diversity and density patterns of avian communities across the land use types.