Biodiversity Data Journal 11: e95670 OO) doi: 10.3897/BDJ.11.e95670 open access Research Article Understorey bird assemblages in selected environmentally sensitive areas (ESA) of Selangor, Peninsular Malaysia Kaviarasu Munian*$, Nur Aina Amira Mahyudin?, Shahfiz Mohammad Azman* + Zoology Branch, Forest Biodiversity Division, Forest Research Institute Malaysia (FRIM), 52109, Kepong, Selangor Darul Ehsan, Malaysia § Environmental Management and Conservation Research Unit (eNCORe), Faculty of Applied Sciences and Technology, Universiti Tun Hussein Onn Malaysia (Pagoh Campus), 84000, Muar, Johor Darul Ta'zim, Malaysia Corresponding author: Kaviarasu Munian (kaviarasu@frim.gov.my) Academic editor: Krizler Tanalgo Received: 26 Sep 2022 | Accepted: 31 Mar 2023 | Published: 05 Apr 2023 Citation: Munian K, Mahyudin NAA, Azman SM (2023) Understorey bird assemblages in selected environmentally sensitive areas (ESA) of Selangor, Peninsular Malaysia. Biodiversity Data Journal 11: e95670. https://doi.org/10.3897/BDJ.11.e95670 Abstract Environmentally Sensitive Areas (ESA) refer to areas that are of critical importance in terms of ecosystem services such as goods, services and life-support systems, such as water purification, pest control and erosion regulation. In addition, they also refer to areas that harbour the wealth of the nation’s biodiversity. However, the classification of ESA in Malaysia is incomprehensible and lacks weightage on biological elements as the current Classification is more centred on physical attributes. In order to enhance the existing Classification of ESA by introducing biological elements, biological data are urgently required, especially for forest reserves and protected habitat. Hence, we conducted understorey birds surveys in three ESA rank Il permanent forest reserves, located in northern Selangor as baseline information to strengthen the ESA classification. The surveys were carried out using mist-netting in three 400 m x 200 m plots. Alpha diversity indices were calculated and showed a significant difference in terms of diversity, composition and biomass of understorey birds between investigated sites. Analysis of similarity (ANOSIM) showed that bird assemblages from forest reserves designated as ESA rank Il in Selangor, based on disturbances levels, have weakly diverged and SIMPER © Munian K et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. 2 Munian K et al analysis has identified six species that contributed to 60% of the differences amongst the bird assemblages. The finding provides the first insight into understorey birds of the study sites and the importance of conserving and preserving ESA of permanent forest reserves, especially the small and fragmented forests. Keywords avifauna, biomass, conservation, diversity, permanent forest reserves Introduction Anthropogenic disturbances resulting in habitat loss, reduction and extinction of biodiversity impose immense pressures on the integrity of natural ecosystems and jeopardise the quality of basic needs, such as clean air and water (Herrera-Silveira and Morales-Ojeda 2009, Dearborn and Kark 2010). Comprehensive landscape planning is vital to create a quality environment as most of the ecosystem services are dependent on the land cover which is influenced, to a large extent, by land use (Festus 2014). Negative impacts induced by human activities should be mitigated urgently with integrated approaches and techniques to ensure the sustainable use of natural resources and functions of ecological services (Ignatieva et al. 2010). One of the land-use-based approaches that are being practised worldwide is the implementation of Environmentally Sensitive Areas (ESA). This concept was first introduced in the United Kingdom through the Agriculture Act 1986, where specific environments of national interest, such as areas of importance to environmental health and areas threatened by farming practices (MAFF 1989) were targeted. In the USA, ESA refers to a piece of land set aside to protect particular natural environments, such as recreational areas, wilderness areas, wildlife refuges and historic sites (Watson et al. 1995). Malaysia employs a similar ESA approach and its definition depends on the type of governance framework. The Department of Environment (DoE) describes ESA as an area that requires special attention before the approval of development in a particular place and adjacent areas (Jabatan Alam Sekitar 1993). The Department of Town and Country Planning Peninsular Malaysia (PLANMalaysia) expounds ESAs from a land-use planning perspective and defines them as “...a special area that is very sensitive to any form of change to its ecosystem due to natural processes or activities in or around it, either directly or indirectly, where its level of sensitivity is determined based on the integration of elemental features like disaster risk, life support value as well as the value of the area's natural treasure and heritage” (Jabatan Perancangan Bandar dan Desa 2017). In 1998, the National Physical Plan identified ten categories of landscapes that fall under ESA and these include forest reserves, highlands and slopes, catchment areas and wildlife protection (Jabatan Perancangan Bandar dan Desa 1998), thus forming an integrated network of ESAs with its major functions being the provision of life support services and heritage values, as well as risk-associated hazards. Implementation of ESA in Malaysia became mandatory with the Second and Third National Physical Plans (NPP) requiring Understorey bird assemblages in selected environmentally sensitive areas ... 3 each State in the Peninsular to identify such areas in their respective jurisdiction in order to ensure more sustainable development. ESAs under NPP has three ranks, i.e. ESA Rank |, I] and Ill (Table 1). Its implementation is guided by a comprehensive set of guidelines for the conservation and development planning issued for each of the ten categories (Jabatan Perancangan Bandar dan Desa 2017). Arising from this, all the States in the Peninsular have included ESAs in their State Structural Plan and local plans. Table 1. ESA ranks based on the 2™ National Physical Plan of Malaysia. Rank Descriptions ESA Rank No development, agriculture or logging shall be permitted, except for low-impact nature tourism, I research and education. ESA Rank No development or agriculture. Sustainable logging and low impact nature tourism may be permitted I subject to local constraints. ESA Rank Controlled development whereby the type and intensity of the development shall be strictly controlled ll depending on the nature of the constraints. The identification of the Malaysian ESA is primarily based on physical attributes, such as degree of slope, elevation and risk of hazards with no biological or ecological component included (Shahfiz et al. 2021). Clearly, there is a need to improve this glaring omission, in order to meet its prescribed aim. When considering the inclusion of biological and ecological components for strengthening the ESA classification, data on species diversity, abundance, distribution, species composition or types of assemblages and threat status are the logical first requirements. Yet, such biological information in Malaysia is still scarce and requires continuous documentation on various aspects of biological components. Hence, this study was conducted on bird diversity in the State of Selangor, aiming to establish such data. Birds are essential to the ecosystem because they serve as pollinators and seed dispersers (Nason 1992). Furthermore, birds are good predictors of the current state of the forests' well-being (Zakaria et al. 2005) including disturbance (Barlow et al. 2006), floral composition and food availability because they are highly sensitive to changes in vegetation structure and composition (Barlow et al. 2006, Zakaria et al. 2013). Furthermore, they can signify long-term environmental disturbances, such as urbanisation, air pollution and landscape alteration (Sidra et al. 2015). The State of Selangor, being the most populous and advanced state in Peninsular Malaysia, is home to a remarkable number of bird species, accounting for 74% of the total bird species found in the entire country. Amongst these bird species, 38 are globally- threatened, including the Mountain Peacock-pheasant (Polyplectron inopinatum), Short- toed Coucal (Centropus rectunguis), Masked Finfoot (Heliopais personatus) and Helmeted Hornbill (Rhinoplax vigil), as identified by Clements et al. (2021). As of 2021, the estimated human population of Selangor is approximately 6.5 million. With a high rate of urbanisation, Selangor has witnessed significant development, including high-rise buildings, highways and industrial complexes. Hence, there is a potential risk of significant impact on the biodiversity within the State. High-paced developments can cause habitat loss, 4 Munian K et al fragmentation and degradation, which can lead to a decline in the number and diversity of species. Therefore, it is important to implement effective conservation measures and sustainable development practices to mitigate the potential negative impacts of these developments on the biodiversity of Selangor, especially on the bird diversity. However, data on the bird diversity, composition and distribution are still scarce across the forest reserves in Selangor. To initiate the inclusion of biodiversity into ESA, this understorey bird study aimed to: (1) document the species richness in three ESA sites within Selangor; (2) compare the diversity, composition and biomass of bird assemblages between ESAs; and (3) investigate the differences in bird assemblages with other ESA Forest Reserves in Selangor, based on land-use changes. Materials and Method Study Sites For the present study, three ESA sites were chosen - Bukit Kutu Forest Reserve (BKFR), Gading Forest Reserve (GFR) and Bukit Tarek Forest Reserve Extension (BTE). These sites are lowland tropical rainforests that have an elevation range of 100 m up to 1650 m above sea level. The sites selected for the present study are in ESA Rank II under the State Structural Plan of Selangor 2020. [__] State boundary [7] Selangor State Park @ Pict 1. Gading FR 2. Bukit Tarek Tambahan FR 3. Bukit Kutu FR 0 5 10 i5km — << Figure 1. EES] Locations of study sites of understorey birds in Gading Forest Reserve, Bukit Kutu Forest Reserve and Bukit Tarek Forest Reserve (E). Amongst the selected sites, Bukit Kutu Forest Reserve (BKFR) is situated along the Titiwangsa Range and is surrounded by other forest reserves like Semangkok FR and Batang Kali FR. It covers an area of 6,452 ha of lowland and hill dipterocarp forest with an Understorey bird assemblages in selected environmentally sensitive areas ... 5 elevation ranging from 250-1053 m a.s.I. Established as a wildlife reserve in 1992, it was later gazetted as a part of the Selangor State Park (SSP). BKFR is a popular destination for hikers and visitors and there are a few Orang Asal villages located at its entry. The study plot in BKFR comprises a mixture of forest trees and fruit trees, such as durians (Durio spp.), jackfruit (Artocarpus heterophyllus), mangosteen (Garcinia mangostana) and rambutan (Nephelium lappaceum) that are cultivated for sale. Another selected site, Gading Forest Reserve (GFR), is one of the largest forest complexes in Selangor and is situated along the Titiwangsa Range. It covers an area of about 19,034.8 ha and the highest peak is about 1650 m. The plots in GFR and BKFR are located approximately 20 km apart and connected via Semangkok Forest Reserve (west- south of GFR). GFR is double-gazetted as a part of the Selangor State Park and is an important water catchment area that is entirely protected. GFR is predominantly covered with dense and matured vegetation of lowland and hill dipterocarps. There is no development or agriculture activity within a 0.5 km radius of the study plot. Finally, Bukit Tarek Forest Reserve Extension (BTE) abuts Bukit Tarek FR and is located 10 km south of GFR and 15 km west of BKFR. It covers an area of 3,560 ha of forest that is significantly fragmented and surrounded by rubber and palm-oil plantations. Unlike BKFR and GFR, BTE is located outside the Selangor State Park (Fig. 1). Understorey bird inventory We defined understorey as the strata under the forest canopy with height from forest ground up to 5-6 m. We conducted the understorey bird inventory from early 2016 until April 2019. A total of ten mist-nets sized (12 x 2.5 m) were deployed in a 400 x 200 m plot in each study site in the respective forest reserve. Each sampling session was conducted for five consecutive days (duration) and a total of seven sampling sessions were carried out within each plot. Each mist-net was fixed to a pair of collapsible poles with heights of 3-5 m. All the nets were fixed at potential fly paths within the plot. Each net was checked every two hours starting from 06:30 to 11:00 hours and then from 19:30 to 22:30 hours daily. The total effort for the mist-net was 2,800 net hours per site. All captured birds were carefully removed from the mist-net and temporarily placed in a cloth bag _ prior examination. Then, the captured birds were measured morphologically and weighed, identified up to species level, photographed and released back to the point of capture to reduce disturbance of their daily routines. The recorded measurements were tarsus length, bill length, bill width, bill depth, head bill, total length, tail length, wing length, wingspan and weight body. Bird classification and nomenclature follow Jeyarajasingam and Pearson (2012) and Robson (2020). Several specimens were curated representing each species that were recorded. The specimens were stored in 70% ethanol and deposited into the Zoological Collection of Forest Research Institute Malaysia (FRIM), Kuala Lumpur. This research was approved by the Department of Wildlife and Parks (DWNP) Peninsular Malaysia under research permit P9.2/21/2023. 6 Munian K et al Species diversity, composition and biomass An individual-based rarefaction curve was plotted for the three study sites to determine the completeness of the sampling efficiency (Gotelli and Colwell 2001). We chose an individual-based- instead of a sample-based approach because our primary interest was to estimate and compare species richness (the total number of species at a particular site) rather than species density (the number of species per unit area) (Colwell et al. 2012). We calculated and compared species diversity for understorey birds in the three sites using four different indices, namely, species richness, Shannon-Wiener diversity, Evenness and Dominance. We used the Chao 1 estimator to evaluate the total species richness expected in an area which includes species that are not caught during the survey in each study site. We also conducted t-test analysis for Shannon-Wiener and Simpson indices to explain the differences in species composition between sites. To compare the biomass of understorey birds amongst study sites, the birds were first categorised into three trophic guilds, namely omnivorous, insectivorous and frugivorous. Then, we multiplied the mean live weight of each species with the number of individuals found in the respective sites (Johnson et al. 2011). Table 2. The locations and details of three selected environmentally sensitive areas and additional forest reserves located in Selangor. The level of disturbance in study sites and additional forest reserves were categorised, based on following four major activities: 1 = villages, 2 = hiking/tourist spot, 3 = mixture vegetation and 4 = oil palm/rubber plantation. Sites Coordinates Study Activities Level of alolala Disturbance GFR 3°37'43.35"N, Present Study Fair 101°37'16.64"E BTE 3°31'22.86"N, VY VV Poor 101°36'27.00"E BKFR 3°33'20.8"N, Vv Mild 101°44'19.5"E Sg Lalang FR 2°57'N, 101°54'09"E Lim et al. (2009) VV Mild Sg Congkak Recreational Forest 3°12'42.32"N, Bakri et al. (2016) V Fair 101°50'36.46"E Bukit Broga FR 2°57'N, 101°54'09"E Lim et al. (2009) Vv Vv V Poor Hulu Langat FR (Pangsun and ~— 3°13'N, 101°52'E ShafawatiandMd- Vv Vv Mild Gunung Nuang) Nor (2009) Understorey bird assemblages in selected environmentally sensitive areas ... 7 Comparison of understorey bird assemblage We compared the current findings with other bird assemblages from four other Forest Reserves in Selangor. These Reserves are ESA Rank II in the Selangor State Structural Plan (SSP). We categorised each Reserve based on the types of human activities that occur in and adjacent to the Reserves. The highest level of disturbance was given to BTE and Bukit Broga FR, followed by BKFR and Sg Lalang FR in decreasing order (Table 2). The presence/absence data for birds in these four sites were acquired from secondary sources. An analysis of similarity (ANOSIM), based on presence/absence, was performed to test the patterns of species composition amongst the seven Forest Reserves, based on three categories. The ANOSIM procedure is a non-parametric permutation test that is analogous to an ANOVA for similarity matrices (Clarke and Warwick 2001) to test whether predefined classes differ in mean similarities/dissimilarities. A similarity percentage (SIMPER) analysis was also used to examine the contribution of each species towards the differences detected in the comparison between the Forest Reserves. All the analysis were conducted using R package Vegan (Oksanen et al. 2019) and iNext Package (Chao et al. 2014, Hsieh et al. 2020) in Rstudio platform (RStudio Team 2021). Results Species diversity, composition and biomass A total of 225 individuals, from 67 species and 23 families, were captured with the highest number recorded in GFR (131 individuals from 46 species), followed by BIE (54 individuals from 33 species) and BKFR (40 individuals from 22 species) (Table 3). Of the 67 species recorded, two species were categorised as Vulnerable (VU), 13 were Near Threatened (NT) and the rest were Least Concern (LC) under the IUCN Red List of Threatened Species (IUCN 2022). Table 3. Understorey bird diversity and numbers recorded in GFR, BTE and BKFR and their IUCN Red List status. Birds from additional four Forest Reserves were indicated based on presence and absence data (X/-=presence/absence). SCFR= Sg Congkak Recreational Forest, BBFR= Bukit Broga Forest Reserve, SLFR= Sg Lalang Forest Reserve and HLFR= Hulu Langat Forest Reserve (Pangsun and Gunung Nuang). Species Common Name BTE GFR BKFR SCRF BBFR SLFR HLFR IUCN Status Accipitriformes Spilornis cheela Crested Serpent-eagle 0 0 0 - X X - LC Nisaetus cirrhatus Changeable Hawk-eagle 0 0 0 - - X - LC Nisaetus alboniger Blyth's Hawk-eagle 0 0 0 - - X - LC Species Accipiter gularis Bucerotiformes Bucerotidae Buceros rhinoceros Rhinoplax vigil Anorrhinus galeritus Berenicornis comatus Rhabdotorrhinus corrugatus Caprimulgiformes Apodidae Apus affinis Rhaphidura leucopygialis Cypsiurus balasiensis Caprimulgidae Lyncornis temminckii Caprimulgus macrurus Caprimulgus affinis Hemiprocnidae Hemiprocne longipennis Hemiprocne comata Podargidae Batrachostomus javensis Columbiformes Columbidae Chalcophaps indica Treron curvirostra Treron vernans Macropygia unchall Munian K et al Common Name Japanese Sparrowhawk Rhinoceros Hornbill Helmeted Hornbill Bushy-crested Hornbill White-crowmed Hornbill Wrinkled Hornbill Little Swift Silver-rumped Spinetail Asian Palm-swift Malay Eared-nightjar Large-tailed Nightjar Savanna Nightjar Grey-rumped Treeswift Whiskered Treeswift Horsfield's Frogmouth Common Emerald Dove Thick-billed Green- pigeon Pink-necked Green- pigeon Barred Cuckoo-dove BTE GFR BKFR 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 1 6 1 0 0 0 0 0 0 0 0 0 SCRF BBFR SLFR ; x x : : X : : x : : X ; : X : X X é X X : X X 2 4 : : X X : x x : : Xx X X X - X X 7 xX c HLFR IUCN Status - LC Understorey bird assemblages in selected environmentally sensitive areas ... Species Coraciiformes Alcedinidae Alcedo peninsulae Alcedo meninting Actenoides concretus Ceyx erithaca Lacedo pulchella Halcyon coromanda Todiramphus chloris Coraciiformes Meropidae Merops philippinus Merops viridis Nyctyornis amictus Cuculiformes Cuculidae Centropus sinensis Phaenicophaeus curvirostris Cacomantis sepulcralis Cuculus micropterus Cacomantis sonneratii Cacomantis merulinus Chrysococcyx xanthorhynchus Surniculus lugubris Phaenicophaeus diardi Common Name Malay Blue-banded Kingfisher Blue-eared Kingfisher Rufous-collared Kingfisher Rufous-backed Kingfisher Banded Kingfisher Ruddy Kingfisher Collared Kingfisher Blue-tailed Bee-eater Blue-throated Bee-eater Red-bearded Bee-eater Greater Coucal Chestnut-breasted Malkoha Rusty-breasted Cuckoo Indian Cuckoo Banded Bay Cuckoo Plaintive Cuckoo Violet Cuckoo Square-tailed Drongo- cuckoo Black-bellied Malkoha BTE GFR BKFR 0 0 3 1 0 0 1 1 1 0 1 2 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 SCRF BBFR SLFR : ; Xx X : X X ; X : X X 2 Xx 2 : : Xx : X X Xx : X : X X : X X : X Xx : X x : x x : Xx X : . Xx HLFR IUCN Status 10 Species Rhinortha chlorophaea Zanclostomus javanicus Falconiformes Falconidae Microhierax fringillarius Falco peregrinus Galliformes Phasianidae Gallus gallus Argusianus argus Gruiformes Rallidae Amaurornis phoenicurus Passeriformes Aegithinidae Aegithina viridissima Aegithina lafresnayei Alcippeidae Alcippe peracensis Calyptomenidae Calyptomena viridis Campephagidae Pericrocotus igneus Lalage fimbriata Pericrocotus flammeus Cisticolidae Orthotomus atrogularis Orthotomus sutorius Prinia rufescens Munian K et al Common Name Raffles's Malkoha Red-billed Malkoha Black-thighed Falconet Peregrine Falcon Red Junglefowl Great Argus White-breasted Waterhen Green lora Great lora Mountain Fulvetta Green Broadbill Fiery Minivet Large Cuckooshrike Scarlet Minivet Dark-necked Tailorbird Common Tailorbird Rufescent Prinia BTE GFR BKFR 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 1 4 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 SCRF BBFR SLFR : : X : : X : Xx - : 4 < : : X X i : : X X : Xx X : : Xx HLFR IUCN Status - LC - LC Understorey bird assemblages in selected environmentally sensitive areas ... Species Orthotomus sericeus Orthotomus ruficeps Prinia flaviventris Chloropseidae Chloropsis cochinchinensis Chloropsis cyanopogon Chloropsis sonnerati Dicaeidae Prionochilus percussus Prionochilus maculatus Dicaeum trigonostigma Dicaeum chrysorrheum Dicaeum minullum Dicaeum everetti Dicruridae Dicrurus aeneus Dicrurus annectens Dicrurus paradiseus Dicrurus macrocercus Dicrurus remifer Estrildidae Lonchura striata Eurylaimidae Eurylaimus javanicus Common Name Rufous-tailed Tailorbird Ashy Tailorbird Yellow-bellied Prinia Blue-winged Leafbird Lesser Green Leafbird Greater Green Leafbird Crimson-breasted Flowerpecker Yellow-breasted Flowerpecker Orange-bellied Flowerpecker Yellow-vented Flowerpecker Plain Flowerpecker Brown-backed Flowerpecker Bronzed Drongo Crow-billed Drongo Greater Racquet-tailed Drongo Black Drongo Lesser Racquet-tailed Drongo White-rumped Munia Banded Broadbill BTE GFR BKFR 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 1 3 2 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 1 2 1 1 0 0 0 0 0 0 0 0 0 0 0 0 SCRF BBFR SLFR : X oak Xx x : X X X ; X : X Xx X : X : Xx oat Xx 2 : X HLFR IUCN Status X LC - LC - LC 12 Species Eurylaimus ochromalus Corydon sumatranus Psarisomus dalhousiae Hirundinidae Hirundo rustica Hirundo tahitica Laniidae Lanius tigrinus Irenidae lrena puella Monarchidae Terpsiphone paradisi Hypothymis azurea Motacillidae Motacilla cinerea Muscicapidae Anthipes solitaris Copsychus saularis Cyornis banyumas Cyornis brunneatus Cyornis glaucicomans Cyornis rufigastra Cyornis magnirostris Cyornis concretus Cyornis rubeculoides Cyornis tickelliae Munian K et al Common Name Black-and-yellow Broadbill Dusky Broadbill Long-tailed Broadbill Barn Swallow Tahiti Swallow Tiger Shrike Asian Fairy-bluebird Asian Paradise Flycatcher Black-naped Monarch Grey Wagtail Rufous-browed Flycatcher Oriental Magpie Robin Hill Blue Flycatcher Brown-chested Jungle- flycatcher Chinese Blue-flycatcher Mangrove Blue- flycatcher Large Blue-flycatcher White-tailed Flycatcher Blue-throated Flycatcher Tickell's Blue Flycatcher BTE GFR BKFR 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 2 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 1 0 1 0 0 1 0 0 0 0 0 (oo) (oo) (oo) SCRF BBFR SLFR HLFR IUCN Status - NT X LCLC Understorey bird assemblages in selected environmentally sensitive areas ... Species Ficedula dumetoria Ficedula mugimaki Ficedula superciliaris Larvivora cyane Kittacincla malabarica Enicurus leschenaulti Enicurus ruficapillus Eumyias thalassinus Myiomela leucura Monticola solitarius Muscicapa dauurica Muscicapa sibirica Muscicapa williamsoni Nectariniidae Aethopyga temminckii Aethopyga saturata Anthreptes simplex Anthreptes rhodolaemus Arachnothera affinis Arachnothera flavigaster Arachnothera chrysogenys Arachnothera modesta Arachnothera longirostra Arachnothera robusta Chalcoparia singalensis Cinnyris jugularis Common Name Rufous-chested Flycatcher Mugimaki Flycatcher Ultramarine Flycatcher Siberian Blue Robin White-rumped Shama White-crowned Forktail Chestnut-naped Forktail Verditer Flycatcher White-tailed Blue Robin Blue Rock-thrush Asian Brown Flycatcher Dark-sided Flycatcher Brown-streaked Flycatcher Temminck's Sunbird Black-throated Sunbird Plain Sunbird Red-troated Sunbird Streaky-breasted Spiderhunter Spectacled Spiderhunter Yellow-eared Spiderhunter Grey-breasted Spiderhunter Little Spiderhunter Long-billed Spiderhunter Ruby-cheeked Sunbird Olive-backed Sunbird BTE GFR BKFR 0 0 1 0 0 0 0 0 0 3 6 1 1 2 0 0 3 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 2 4 13 6 1 0 0 0 0 0 0 0 0 SCRF BBFR SLFR HLFR IUCN Status - X LC - X LC - X LC - X LC LC - - LC X X NT X - LC - X LC - - LC - - LC - - LC : x NE X - LC - - LC x : LC X - NT X X LC X - LC X - LC - X LC X X LC X X LC X - LC - X LC 13 14 Species Kurochkinegramma hypogrammica Leptocoma brasiliana Leptocoma sperata Oriolidae Oriolus xanthonotus Paridae Melanochlora sultanea Pellorneidae Malacocincla abbotti Malacopteron albogulare Malacocincla sepiaria Pellorneum capistratum Pellorneum malaccense Pellorneum nigrocapitatum Malacopteron cinereum Malacopteron magnirostre Pellorneum rostratum Pellorneum tickelli Phylloscopidae Phylloscopus borealis Phylloscopus coronatus Pycnonotidae Alophoixus bres Brachypodius atriceps lole charlottae lole propinqua Pycnonotus simplex Munian K et al Common Name Purple-naped Sunbird Van Hasselt's Sunbird Purple-throated Sunbird Dark-throated Oriole Sultan Tit Abbott's Babbler Grey-breasted Babbler Horsfield's Babbler Rufous-browed Babbler Short-tailed Babbler Black-capped Babbler Scaly-crowned Babbler Moustached Babbler White-chested Babbler Buff-breasted Babbler Arctic Warbler Eastern Crowned Warbler Brown-cheeked Bulbul Black-headed Bulbul Buff-vented Bulbul Grey-eyed Bulbul Cream vented Bulbul BTE GFR BKFR 2 2 0 0 1 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 3 0 0 1 0 0 1 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 3 0 0 6 0 0 2 0 5 5 0 SCRF BBFR SLFR HLFR IUCN Status X LC LC X LC X LCLC Understorey bird assemblages in selected environmentally sensitive areas ... Species Ixidia cyaniventris Ixos malaccensis Ixos mceclellandii Brachypodius priocephalus Alophoixus tephrogenys Tricholestes criniger Alophoixus ochraceus Pycnonotus plumosus Euptilotus eutilotus Hemixos flavala Pycnonotus brunneus Pycnonotus finlaysoni Pycnonotus pallidus Pycnonotus zeylanicus Ixidia erythropthalmos Ixidia squamata Alophoixus phaeocephalus Rubigula melanictera Rhipiduridae Rhipidura perlata Rhipidura albicollis Scotocercidae Abroscopus superciliaris Sittidae Sitta frontalis Stenostiridae Culicicapa ceylonensis Sturnidae Common Name Grey-bellied Bulbul Streaked Bulbul Mountain Bulbul Grey-headed Bulbul Grey-cheeked Bulbul Hairy-backed Bulbul Ochraceous Bulbul Olive-winged Bulbul Puff-backed Bulbul Ashy Bulbul Red-eyed Bulbul Stripe-throated Bulbul Puff-throated Bulbul Straw-headed Bulbul Spectacled Bulbul Scaly-breasted Bulbul Yellow-bellied Bulbul Black-capped Bulbul Spotted Fantail White-throated Fantail Yellow-bellied Warbler Velvet-fronted Nuthatch Grey-headed Canary- flycatcher BTE GFR BKFR 0 1 0 0 0 0 0 0 0 1 4 0 0 2 0 8 3 1 0 1 0 1 5 1 0 1 0 0 0 0 2 1 1 0 0 0 0 0 0 0 0 0 1 2 0 0 0 0 0 12 /1 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 2 0 SCRF BBFR SLFR - X - X X X Xx Es X X X X X 2 X X X X - X X X - X - X HLFR IUCN Status - NT - NT - LC - NT X LC X LC X CR X LC - LCLC 15 16 Species Aplonis panayensis Gracula religiosa Timaliidae Erythrogenys hypoleucos Pomatorhinus schisticeps Stachyris nigricollis Stachyris maculata Stachyris nigriceps Cyanoderma erythropterum Macronus ptilosus Stachyris poliocephala Mixornis gularis Vangidae Philentoma pyrhoptera Hemipus picatus Hemipus hirundinaceus Tephrodornis virgatus Vireonidae Erpornis zantholeuca Zosteropidae Zosterops everetti Piciformes Indicatoridae Indicator archipelagicus Megalaimidae Munian K et al Common Name Asian Glossy Starling Common Hill Myna Large-scimitar Babbler White-browed Scimitar- babbler Black-throated Babbler Chestnut-rumped Babbler Grey-throated Babbler Chestnut winged Babbler Fluffy-backed Tit- babbler Grey-headed Babbler Pin-striped Tit-babbler Rufous-winged Philentoma Bar-winged Flycatcher- shrike Black-winged Flycatcher-shrike Large Woodshrike White-bellied Erpornis Everett's White-eye Malaysian Honeyguide BTE GFR BKFR 0 1 0 0 0 0 0 0 0 0 0 0 1 0 0 1 0 0 0 0 0 2 3 0 1 2 0 0 0 4 1 0 0 0 2 2 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 SCRF BBFR SLFR HLFR IUCN Status : : : LC X X X LC NT NT NT - X - LC X X - LC X X - LC NT Understorey bird assemblages in selected environmentally sensitive areas ... Species Psilopogon chrysopogon Psilopogon mystacophanos Psilopogon australis Caloramphus fuliginosus Picidae Blythipicus rubiginosus Blythipicus pyrrhotis Chrysophlegma mentale Chrysophlegma miniaceum Chrysocolaptes validus Hemicircus concretus Hemicircus sordidus Meiglyptes tukki Meiglyptes tristis Micropternus brachyurus Picus puniceus Sasia abnormis Psittaciformes Psittacidae Loriculus galgulus Strigiformes Strigidae Bubo sumatranus Common Name Gold-whiskered Barbet Red-throated Barbet Blue-eared Barbet Brown Barbet Maroon Woodpecker Bay Woodpecker Checker-throated Woodpecker Banded Woodpecker Orange-backed Woodpecker Red-crested Woodpecker Grey-and-buff Woodpecker Buff-necked Woodpecker White-rumped Woodpecker Rufous Woodpecker Crimson-winged Woodpecker Rufous Piculet Blue-crowned Hanging- parrot Barred Eagle-owl BTE GFR BKFR 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 SCRF BBFR SLFR X X - X X X X X X X X X - X - X X X X X - X - X X X - X HLFR IUCN Status - LC - NT 17 18 Munian K et al Species Common Name BTE GFR BKFR SCRF BBFR SLFR HLFR IUCN Status Otus lettia Collared Scops-owl 0 3 0 - - - - LC Otus sunia Oriental Scops-owl 0 1 0 - - - - LC Otus bakkamoena Indian Scops-owl 0 0 0 - X X X LC Otus spilocephalus Mountain Scops-owl 0 0 0 - - - - LC Phodilus badius Oriental Bay-owl 0 0 0 - - - X LC Trogoniformes Trogonidae Harpactes diardii Diard's Trogon 0 0 0 - - X - NT Harpactes duvaucelii Scarlet-rumped Trogon 0O 0 0 - - Xx X NT Harpactes kasumba Red-naped Trogon 0 0 0 - - - - NT Total Individuals 54 131 40 Based on the Shannon-Wiener index, GFR recorded the highest value (H = 3.43), followed by BTE with a value of H = 3.24 and BKFR gave the lowest value of H = 2.84). The index indicates that the community of understorey birds in GFR is abundant and evenly distributed amongst the species recorded compared to BKFR and BTE. Meanwhile, the understorey birds in BKFR were valued highest for Dominance (D = 0.0071) and Evenness indices (E = 0.815). The Evenness index varies from 0 (highest dominance by a single species) to 1 (all species have the same abundance) (Buzas and Hayek 2005). Interestingly, BTE recorded moderate values for the diversity indices investigated (H = 3.24, D = 0.054 and E = 0.774), even though the Forest Reserve is the most disturbed compared to other study sites (Table 4). Table 4. Diversity of understorey birds in three selected environmentally sensitive areas of permanent forest reserves in northern region of Selangor. Sites Relative Abundance (%) Richness (S) Shannon(H') Dominance(D) Evenness’ Chao 1 BTE 24 33 3.24 0.054 0.774 79 GFR 58.2 46 3.43 0.047 0.673 69.3 BKFR_ 17.8 21 2.84 0.071 0.815 34.2 By comparison between the observed and estimated species richness (based on the Chao 1 estimator), the efforts invested in the survey only managed to recover approximately 44% to 66% of species in all three study sites. The individual-based rarefaction curve also showed that it had yet to reach its asymptote indicating the effort in documenting the understorey birds in three sites was insufficient (Fig. 2). Understorey bird assemblages in selected environmentally sensitive areas ... 19 Method == interpolated Py o ™'' extrapolated ® 40 > 2 o Guides oO @ > BKFR f= nd BTE cre 0 100 200 Number of individuals Figure 2. EES] Individual-based rarefaction curves were constructed to evaluate the completeness of the survey carried out in three sites of ESA in Selangor, Malaysia and the curve revealed insufficient effort in documenting understorey birds as it had yet to reach its asymptote. Species under the family Pycnonotidae were the most abundant (14 species), followed by the family Muscicapidae with nine species and Timaliidae with six species. The most abundant species was Little Spiderhunter Arachnothera longirostra (10.2%), followed by Oriental Dwarf Kingfisher Ceyx erithaca (6.7%) and Yellow-Bellied Bulbul A/ophoixus phaeocephalus (5.7%). There are 13 single species (consisting of 5.8%) recorded out of a total 225 individuals. One-way ANOVA indicated that the abundances of understorey birds found in three sites were significantly different (F = 6.356, df = 126.4, p = 0.00234). In GFR, Rufous-backed Dwarf Kingfisher Ceyx erithaca made up the largest proportion (10.6%) of total individuals captured, followed by Little Spiderhunter Arachnothera longirostra (9.92%) and Yellow-Bellied Bulbul A/ophoixus phaeocephalus (9.12%). In BKFR, Little Spiderhunter Arachnothera longirostra made up 15.0% of the total individuals recorded, followed by the Green Broadbill Calyptomena viridis and Grey-headed Babbler Stachyris poliocephala, each with 10%. Composition of understorey birds in BTE was largely contributed by the Hairy-backed bulbul Tricholestes criniger (14.8%), Cream-vented Bulbul Pycnonotus simplex (9.2%) and Little Spiderhunter Arachnothera longirostra (7.2%). The percent biomass in three trophic guilds of understorey birds varied amongst the studied sites (Fig. 3). Almost half of the understorey bird biomass in GFR was contributed by omnivorous species, 30% by frugivorous birds and only 20% constituted by insectivorous birds. Unlike in BTE, 58% of biomasses of understorey birds recorded were 20 Munian K et al insectivorous birds, followed by omnivorous and frugivorous birds with approximately 29% and 22%, respectively. The biomass of understorey birds in BKFR was almost evenly distributed amongst omnivorous and insectivorous with 41% and 36%, while frugivorous birds only contributed about 22% of overall biomass in BKFR. 2500 ®@ Omnivorous ® Insectivorous 2000 ) Frugivorous 1500 1000 Biomass (g) 500 GFR BKFR Forest Reserves Figure 3. EES The distribution of biomass according to the omnivorous, insectivorous and frugivorous guilds in the three study sites. In general, the biomass of the omnivorous birds was the highest compared to other guilds. Comparison between Understorey Bird Assemblages ANOSIM analysis, based on the Bray-Curtis model, revealed a weak difference in bird assemblage composition, based on disturbances (Global R = - 0.0068, p-value = 0.483). Results of SIMPER showed that approximately 60% of the differences in assemblage composition were driven by six species, based on three levels of disturbances. They are Fluffy-backed tit babbler (Macronus ptilosus) which contributes the highest differences (25.4%), Fiery Minivet (Pericrocotus igneus) and Yellow-bellied Warbler (Abroscopus superciliaris)(16.7%) (Table 5). Table 5. SIMPER percentage (%) contribution of dominant bird species at various levels of disturbances. Taxon Av. dissim Contrib. % Cumulative % Fluffy-backed tit babbler (Macronus ptilosus) 20.84 25.45 25.45 Fiery Minivet (Pericrocotus igneus) 13.73 16.77 42.22 Yellow-bellied warbler (Abroscopus superciliaris) 13.7 16.73 58.95 Tiger shrike (Lanius tigrinus) 0.3429 0.4187 59.37 Understorey bird assemblages in selected environmentally sensitive areas ... 21 Taxon Av. dissim Contrib. % Cumulative % White-breasted Waterhen (Amaurornis phoenicurus) 0.3177 0.3879 59.75 Chestnut-naped Forktail (Enicurus ruficapillus) 0.2875 0.3511 60.11 Discussion Diversity, composition and biomass of understorey birds Based on the method of mist-netting, we managed to document 67 (Table 3) species of understorey birds in three ESA level II permanent Forest Reserves in Selangor. To the best of our knowledge, the species compilation presented here is the first insight for bird diversity in GFR and BTE. Some studies on vertebrates were done in BKFR in 1999 (e.g. Lim et al. (1999)) and as it is a wildlife reserve, we believe that documentation on vertebrates in BKFR might be collected by the Department of Wildlife and National Park (DWNP). The compilation of birds from these three Forest Reserves would serve as baseline information for relevant authorities in making tangible measures in conserving biodiversity. GFR recorded the highest Shannon diversity index compared to BKFR and BTE which is not entirely surprising noting that it is the largest forest complex in Selangor. The species- area relationship may explain more species richness found in GFR compared to BKFR and BTE as area increases diversity. Although the GFR was logged over 30 years ago, it appears to have the characteristics of an old growth stand due to the presence of large trees and a dense herbaceous vegetation ground layer. This could potentially provide more suitable sites for nesting and breeding, as well as a sufficient supply of food and protection from predators and harsh weather, according to studies by Reid et al. (2004), Diaz et al. (2005) and Husin and Rajpar (2015). Birds are known to be sensitive to alterations in their habitat and modifications to the landscape, as evidenced by studies by Sekercioglu et al. (2002), Raman (2006), Gomes et al. (2008) and Tscharntke et al. (2008). The diversity indices indicate lowest values for BKFR compared to BTE, which is much more significantly impaired. BKFR forest is still largely covered by intact vegetation and well protected mostly due to the presence of mixed vegetation and low impact of human activities. Such results may be attributed to the survey method. This study relied on mist- netting and the height of the pole was 3-5 m above the ground. The limited height and coverage of the net were inadequate to catch understorey birds that occupy different forest strata and the taller vegetation around the plots made use of only one trapping method less effective. Another variable that could affect the results is the size and behaviour of certain understorey birds (Blake and Loiselle 2001, Wang and Finch 2002). Simultaneous use of multiple approaches such as mist-netting, spot-mapping, point counts and observation of mixed species flocks, coupled with enough sample replication and extended sampling period, could improve the results (Gram and Faaborg 1997, Herzog et al. 2002, Derlindati and Caziani 2005). Based on estimated species richness by the Chao | estimator, the effort of sampling in the study only managed to document about 60% of the diversity in the study 22 Munian K et al sites. With a much longer period of sampling, the chances to document almost the actual diversity of the understorey birds would be increased. This was proven by local studies conducted in Peninsular Malaysia with prolonged periods of sampling (Johns 1996, Lambert 1997, Peh et al. 2005). Amongst the three sites, the BKFR had the most uniform spread of understorey birds. High species evenness residing in an ecosystem are represented by almost an equivalent proportion of all the species presented. The value of the Evenness index of almost one (E = 0.815) shows that the BKFR is ecologically stable in providing a vast range families of understorey birds inhabiting and surviving successfully. The family Pycnonotidae (bulbuls) had the highest number of species recorded in all study sites. A similar trend was also reported by Mansor and Sah (2012), Nor Hashim and Rani (2013), Rajpar and Zakaria (2014), Barlow and Peres (2016) and Shafie et al. (2018). Members of the Pycnonotidae family dominated the understorey habitat of Malaysia's tropical forest. They are generalist frugivorous species that are ecologically diverse and occupy a wide array of habitats (Ponpituk et al. 2020). The Bulbuls are particularly important in the Asian region for their role in seed dispersal, especially in habitats that are degraded (Sankamethawee et al. 2011, Corlett 2017, Shakya and Sheldon 2017). They have a high tolerance to temperature and light intensity, are well-known colonisers and prefer to inhabit logged-over forests (Mohd-Taib et al. 2018). The comparative abundance of this family in all three Reserves, in particular BTE, is an advantage as it is likely to play a key role in the regeneration and recovery of vegetation through seed dispersal. The assemblages in the three study sites were dominated by Little Spiderhunter (Arachnothera longirostra), Rufous-backed Kingfisher (Ceyx erithaca) and Yellow-Bellied Bulbul (Alophoixus phaeocephalus). The presence of Little Spiderhunter is common in tropical secondary forests where wild bananas (Musaceae) and gingers (Zingiberaceae) flourish and are eaten by birds (Nor Hashim and Ramli 2013). Little Spiderhunter is recorded from a variety of different habitats that provide a wide range of food sources, microhabitats and refuge from predation (Khan et al. 2008). The presence of Rufous- backed Kingfisher is largely linked to the presence of waterbodies, such as lakes and rivers. All the study plots were located at average distances from either small streams or fast-flowing rivers. The diet of Kingfisher mainly comprised small fishes, insects and other higher taxa bird species including frogs. The presence of a large network of rivers in the GFR directly contributes to the relatively high abundance of Rufous-backed Kingfisher compared to BITE, where only a moderately-sized stream flows through the Reserve. Yellow-bellied Bulbul is a generalist frugivorous occupying a vast range of habitats, such as pristine forests (Nor Hashim and Ramli 2013), secondary forests (Husin and Rajpar 2015), wetlands (Biun and Buang 2014) and palm-oil plantations (Amit et al. 2014). The species compositions between study sites are significantly different as shown by ANOVA analysis. Despite the majority composition was contributed by Little Spiderhunter Arachnothera longirostra, Rufous-backed Kingfisher Ceyx erithaca and Yellow-Bellied Bulbul Alophoixus phaeocephalus, BKFR was also presented by the Green Broadbill Calyptomena viridis and Grey-headed Babbler Stachyris poliocephala, both of which species were absent in BITE. Presence of these species indicates the evenness of composition of the understorey birds in BKFR. Additionally, these species are sensitive and Understorey bird assemblages in selected environmentally sensitive areas ... 23 mainly recorded in primary forests (Ramly and Ramli 2009, Bing et al. 2013, Mohd-Taib et al. 2018) in Peninsular Malaysia suggesting that BKFR is capable of sheltering a wide range of understorey birds. While, in BTE, Hairy-backed bulbul Tricholestes criniger and Cream-vented Bulbul Pycnonotus simplex dominated the habitat. The biomass of understorey birds differed considerably amongst the three study sites. Overall, GFR has the largest abundance of understorey birds, followed by BKFR and BTE. Nevertheless, in the aspect of trophic guilds, the study shows that frugivorous birds were abundantly distributed compared to insectivorous and omnivorous birds. Similarly, the biomass of frugivorous birds in GFR was the highest compared to insectivorous and frugivorous. Frugivorous birds primarily feed on fruits such as figs, berries and fleshy fruits, although it was observed that many of these birds supplemented their diet with other animals, mainly insects. By comparison, GFR is denser in terms of vegetation and least impaired from disturbances. Morante-Filho et al. (2018) hypothesised that assemblages of frugivorous birds were affected by two factors: vegetation complexity and fruit availability. Habitats that are covered with more heterogeneous vegetation potentially provide more niches and offer more diverse ways to exploit different resources, such as nesting sites and shelter, while greater availability of resources engender higher species richness (Davies et al. 2007, Ferger et al. 2014). As the sampling period did not coincide with the fruiting season, the vegetation complexity might contribute to higher frugivorous birds in GFR. The biomass in BTE was dominated by insectivorous birds. BTE is bordered by plantations of palm oil and rubber. In fact, insectivorous birds are sensitive to habitat changes and disturbances were severally reported by studies in Malaysia (e.g. Moradi et al. (2008), Mansor and Sah (2012)). A high biomass of insectivorous birds was obtained in BTE as most of the mist-nets were placed inside the forest and not near to the forest edge or next to the areas occupied by the plantations. The study by Mansor and Sah (2012) identified that the higher density of insectivore understorey birds was confined to the forest interior compared to the forest edge. Apart from that, the availability of food resources in BTE might contribute to the high occurrence of insectivorous birds with the addition of more populations of invertebrates (e.g. insects) found in areas of palm oil and rubber plantations. Other trophic guilds, such as carnivores and piscivores were primarily represented by predator species such as eagles, owls and kingfishers. Broadly, the biomass of other guild birds was the lowest as these predators were present in low numbers. They are the top predators in the food chain (i.e. tertiary consumers); thus, their populations always remain low compared to those of the primary and secondary consumers in the ecosystem (Rajpar and Zakaria 2014). Comparison assemblage of understorey birds All the Forest Reserves included in the comparison were gazetted as ESA level Il of Permanent Forest Reserve under the Selangor Strategic Plan. Surprisingly, many of these Forest Reserves were logged (more than 30 years ago) and some were very recently cleared or open for development (mostly for palm oil plantations). Based on the ANOSIM analysis, there were no significant differences between the levels of disturbances 24 Munian K et al investigated. The lack of differences shown by ANOSIM indicates that the level of disturbances in the seven Forest Reserves did not influence the distribution of bird composition, bearing in mind that some Reserves, such as BTE and Bukit Broga FR, are fragmented forest patches. The negative value of ANOSIM was largely contributed by the differences in composition within an assigned group and less so by the differences between groups. This is because the information derived from published studies was subjected to distinct methods (Such as point count and direct observation) apart from using mist-netting which directly reflected the richness of birds found at each study site. Nevertheless, a distinct composition of birds at group level showed that the bird assemblages were much influenced by factors, such as microhabitat, vegetation heterogeneity and food resources. Hence, it might be appropriate to conclude that each forest reserve or habitat preserves its own diversity, regardless of landscape changes occurring within the habitat. Conclusion The study presented the first information on understorey birds in Bukit Tarek Forest Reserve Extension and Gading Forest Reserve together with previous research in Bukit Kutu Forest Reserve, all three of which were designated as Environmentally Sensitive Areas (ESA) Rank II in Selangor. A total of 67 species of avifauna were recorded with the highest diversity found in Gading Forest Reserve. The information collected through this study should partly serve as baseline information for developing biological attributes to be included in the ESA classification. Apart from that, the results could be used by the relevant authorities and stakeholders in managing these forest reserves soundly, based on scientific decisions and to ensure the preservation of biodiversity of avifauna. Acknowledgements This project was funded by the Ministry of Natural Resources, Environment and Climate Changes under projects RMk-11 (P23085100018003) and RMk-12 (P23085100210003). The authors would like to thank Dato’ Indera Mohd Ridza Bin Awang, Director General of Forestry Department of Peninsular Malaysia (JPSM) and Director of Selangor State Forestry Department for the permit given to assess the sites within the permanent Forest Reserve of Bukit Kutu FR, Gading FR and Bukit Tarek (E) FR under Permit No: US/ 11/2018; and we would like to thank Dato’ Abdul Kadir Abu Hashim, Director General of Department of Wildlife and National Park (DWNP) Peninsular Malaysia for the wildlife research permit (JPHLTN.600-6/1/4 JLD 2(110)(P9.2/01/2023)). Special mentions also go to Wendy Yong Sze Yee for generating the study site map and Dr. Lillian Chua, Director of Forest Biodiversity Division of Forest Research Institute Malaysia (FRIM), for her kind guidance and advice. The authors acknowledge NRECC and FRIM for providing the necessary funding, facilities and assistance. Lastly, the authors thank Enago (www.enago.com) for their English language review and editing services. Understorey bird assemblages in selected environmentally sensitive areas ... 25 Author contributions KM and SMA conceived the original idea and contributed to the design of the research. KM and NAAM gathered the data, performed the analysis and wrote the first draft of the manuscript. KM aided in the interpretation of the results and provided critical feedback to the manuscript. KM, NAAM and SMA discussed and agreed to the final draft of the manuscript. Conflicts of interest There are no conflicts of interest amongst the authors. References ° Amit B, Tuen AA, Haron K, Harun MH (2014) Diversity of bird species in the oil palm plantation on peat. Oil Palm Bulletin 69: 21-26. ° Bakri A, Yusof E, Zakaria M, Roslan M (2016) The diversity of diurnal bird’s species in Sungai Chongkak Recreational Forest, Selangor. Sustaining economic climates through agriculture, forestry and plantation. 2nd Kuala Lumpur International Agriculture, Forestry and Plantation, Hotel Putra, Kuala Lumpur, Malaysia, February 20 — 21, 2016. ° Barlow J, Peres CA, Henriques LM, Stouffer PC, Wunderle JM (2006) The responses of understorey birds to forest fragmentation, logging and wildfires: An Amazonian synthesis. Biological Conservation 128 (2): 182-192. https://doi.org/10.1016/j.biocon. 2005.09.028 ° Barlow J, Peres C (2016) Avifauna responses to single and recurrent wildfires in Amazonian Forests. Figshare https://doi.org/10.6084/m9.figshare.c.3293120.v1 ° Bing DY, Rajpar MN, Zakaria M (2013) Avian richness and habitat characteristics in primary and logged hill dipterocarp tropical rainforest of peninsular Malaysia. Malayan Nature Journal 64 (4): 300-316. ° Biun A, Buang M (2014) Diversity and abundance of bird ommunities in Tasek Bera Ramsar site, Pahang, Malaysia. Journal of Wildlife and Park 27: 25-34. ° Blake J, Loiselle B (2001) Bird assemblages in second-growth and old-growth forests, Costa Rica: perspectives from mist nets and point ounts. The Auk 118 (2): 304-326. https://doi.org/10.1093/auk/118.2.304 ° Buzas MA, Hayek L-C (2005) On richness and evenness within and between communities. Paleobiology 31 (2): 199-220. https://doi.org/10.1666/0094-8373(2005) 031[0199:ORAEWA]2.0.CO;2 ° Chao A, Gotelli N, Hsieh TC, Sander E, Ma KH, Colwell R, Ellison A (2014) Rarefaction and extrapolation with Hill numbers: a framework for sampling and estimation in species diversity studies. Ecological Monographs 84 (1): 45-67. httos://doi.org/10.1890/13- 0133.1 ° Clarke K, Warwick R (2001) A further biodiversity index applicable to species lists: variation in taxonomic distinctness. Marine Ecology Progress Series 216: 265-278. https://doi.org/10.3354/meps216265 26 Munian K et al Clements JF, Schulenberg TS, Iliff MJ, Billerman SM, Fredericks TA, Gerbracht JA, Lepage D, Sullivan BL, Wood CL (2021) The eBird/Clements checklist of Birds of the World: v2021. 1. URL: https:/Awww.birds.cornell.edu/clementschecklist/download/ Colwell RK, Chao A, Gotelli NJ, Lin S-Y, Mao CX, Chazdon RL, Longino JT (2012) Models and estimators linking individual-based and sample-based rarefaction, extrapolation and comparison of assemblages. Journal of Plant Ecology 5 (1): 3-21. https://doi.org/10.1093/jpe/rtr044 Corlett R (2017) Frugivory and seed dispersal by vertebrates in tropical and subtropical Asia: An update. Global Ecology and Conservation 11: 1-22. httos://doi.org/10.1016/ j.gecco.2017.04.007 Davies RG, Orme CDL, Storch D, Olson VA, Thomas GH, Ross SG, Ding T, Rasmussen PC, Bennett PM, Owens IPF, Blackburn TM, Gaston KJ (2007) Topography, energy and the global distribution of bird species richness. Proceedings Biological Sciences 274 (1614): 1189-97. https://doi.org/10.1098/rspb.2006.0061 Dearborn D, Kark S (2010) Motivations for conserving urban biodiversity. Conservation Biology 24 (2): 432-440. https://doi.org/10.1111/j.1523-1739.2009.01328.x Derlindati E, Caziani S (2005) Using canopy and understory mist nets and point counts to study bird assemblages in Chaco forests. The Wilson Bulletin 117 (1): 92-99. https:// doi.org/10.1676/03-063 Diaz |, Armesto J, Reid S, Sieving K, Willson M (2005) Linking forest structure and composition: avian diversity in successional forests of Chiloé Island, Chile. Biological Conservation 123 (1): 91-101. https://doi.org/10.1016/j.biocon.2004.10.011. Ferger S, Schleuning M, Hemp A, Howell K, BOhning-Gaese K (2014) Food resources and vegetation structure mediate climatic effects on species richness of birds. Global Ecology and Biogeography 23 (5): 541-549. https://doi.org/10.1111/geb.12151 Festus IA (2014) Key issues on landscape planning in the context of environmental sustainability. European Scientific Journal 10 (2). https://doi.org/10.19044/esj.2014. v10n2p%25p Gomes LL, Oostra V, Nijman V, Cleef A, Kappelle M (2008) Tolerance of frugivorous birds to habitat disturbance in a tropical cloud forest. Biological Conservation 141 (3): 860-871. https://doi.org/10.1016/j.biocon.2008.01.007 Gotelli N, Colwell R (2001) Quantifying biodiversity: procedures and pitfalls in the measurement and comparison of species richness. Ecology Letters 4 (4): 379-391. https://doi.org/10.1046/j.1461-0248.2001.00230.x Gram WK, Faaborg J (1997) The distribution of neotropical migrant birds wintering in the El Cielo Biosphere Reserve, Tamaulipas, Mexico. The Condor 99 (3): 658-67. https://doi.org/10.2307/1370478 Herrera-Silveira J, Morales-Ojeda S (2009) Evaluation of the health status of a coastal ecosystem in southeast Mexico: Assessment of water quality, phytoplankton and submerged aquatic vegetation. Marine Pollution Bulletin 59: 72-86. https://doi.org/ 10.1016/j.marpolbul.2008.11.017 Herzog S, Kessler M, Cahill T (2002) Estimating species richness of tropical bird communities from rapid assessment data. The Auk 119 (3): 749-769. https://doi.org/ 10.1093/auk/119.3.749 Hsieh TC, Ma KH, Chao A (2020) iNEXT: interpolation and extrapolation for species diversity. URL: http://chao.stat.nthu.edu.tw/wordpress/software_download/ Understorey bird assemblages in selected environmentally sensitive areas ... 27 Husin MZ, Rajpar MN (2015) Effects of logging and recovery process on avian richness and diversity in hill dipterocarp tropical rainforest-Malaysia. Journal of Environmental Biology 36 Spec No: 121-7. Ignatieva M, Stewart G, Meurk C (2010) Planning and design of ecological networks in urban areas. Landscape and Ecological Engineering 7 (1): 17-25. htips://doi.org/ 10.1007/s11355-010-0143-y IUCN (2022) The IUCN Red List of Threatened Species. Version 2022-2. https:// www.iucnredlist.org. Accessed on: 2022-8-15. Jabatan Alam Sekitar (1993) Buku panduan kawasan sensitif alam sekitar. Jabatan Alam Sekitar, Kementerian Sains, Teknologi dan Alam Sekitar, Kuala Lumpur. [In Malay]. [ISBN 978-9-83-9795066] Jabatan Perancangan Bandar dan Desa (1998) Kawasan sensitif alam sekitar [Environmentally sensitive areas]. Bengkel KSAS JPBD-Semenanjung Malaysia, Kuala Lumpur, 22-23 April 1998. Jabatan Perancangan Bandar dan Desa (2017) Garis panduan perancangan pemuliharaan dan pembangunan Kawasan Sensitif Alam Sekitar. 1, 1. Kementerian Perumahan dan Kerajaan Tempatan, 23 pp. [In Malay]. [ISBN 978-967-5456-55-8] Jeyarajasingam A, Pearson A (2012) A field guide to the birds of Peninsular Malaysia and Singapore. 2. Oxford University Press [ISBN 978-0-19-963942-7] Johns AG (1996) Bird population persistence in Sabahan logging concessions. Biological Conservation 75 (1): 3-10. https://doi.org/10.1016/0006-3207(95)00044-5 Johnson E, Stouffer PC, Vargas C (2011) Diversity, biomass, and trophic structure of a central amazonian rainforest bird community. Revista Brasileira de Ornitologia 19 (1): 1-1. Khan FAAA, Bujang MF, Kassim MA, Yap SY, Ketol B, Marni W, Sait |, Laman CJ, Aimran AAA, Mawek Z, Tajudin AAMA, Ali H, Abdullah MT (2008) Biodiversity assesment in a Sarawak lowland dipterocarp rainforest of Niah National Park. Journal of Tropical Biology and Conservation 4. Lambert FR (1997) The consequences of selective logging for Bornean lowland forest birds. Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences 335 (1275): 443-457. https://doi.org/10.1098/rstb.1992.0036 Lim LB, Majid RA, Norsham Y (1999) Studies on the mammal fauna of Bukit Kutu Wildlife Reserve, Hulu Selangor. Journal of Wildlife and Park 17: 1-16. Lim LB, Yong D, Tharmalingam M, Shin CK, Lim CC (2009) Vertebrate species diversity in Broga and Sungai Lallang Forest Reserve, Hulu Langat, Selangor, Peninsular Malaysia. Journal Science and Technology of Tropics 5: 87-99. MAFF (1989) Environmentally sensitive areas. Ministry of Agriculture, Fisheries and Food,London. First Annual Report as required Under Section 18(8) of the Agriculture Act 198. Mansor MS, Sah SAM (2012) The influence of habitat structure on bird species composition in lowland Malaysian rain forests. Tropical Life Sciences Research 23 (1): 1-14. Mohd-Taib FS, Ishak SN, Mansor MS, Md-Nor S (2018) Impacts of inundation on bird assemblages in forests in and around a hydrodam in Terengganu, Malaysia. Sains Malaysiana 47 (8): 1645-1656. https://doi.org/10.17576/jsm-2018-4708-03 28 Munian K et al Moradi HV, Zakaria M, Mohd A, Yusof E (2008) Insectivorous birds and environmental factors across an edge-interior gradient in tropical rainforest of Malaysia. International Journal of Zoological Research 5 (1): 27-41. https://doi.org/10.3923/ijzr.2009.27.41 Morante-Filho JC, Arroyo-Rodriguez V, Pessoa MdS, Cazetta E, Faria D (2018) Direct and cascading effects of landscape structure on tropical forest and non-forest frugivorous birds. Ecological Applications: a Publication of the Ecological Society of America 28 (8): 2024-2032. https://doi.org/10.1002/eap.1791 Nason A (1992) Discovering birds: An introduction to the birds of Nigeria. Pisces Publications [ISBN 978-1-87-435700-1] Nor Hashim E, Ramli R (2013) Comparative study of understorey birds diversity inhabiting lowland rainforest virgin jungle reserve and regenerated forest. The Scientific WorldJournal 2013: 676507. https://doi.org/10.1155/2013/676507 Oksanen J, Blanchet FG, Friendly M, Kindt R, Legendre P, McGlinn D, Minchin P, O’Hara RB, Simpson G, Solymos P, Stevens MHH, Szoecs E, Wagner H (2019) Vegan: community ecology package. URL: hitp://CRAN.R-project.org/package=vegan Peh KH, Jong Jd, Sodhi N, Lim SH, Yap CM (2005) Lowland rainforest avifauna and human disturbance: persistence of primary forest birds in selectively logged forests and mixed-rural habitats of southern Peninsular Malaysia. Biological Conservation 123 (4): 489-505. https://doi.org/10.1016/j.biocon.2005.01.010 Ponpituk Y, Siri S, Safoowong M, Suksavate W, Marod D, Duengkae P (2020) Temporal variation in the population of bulbuls (Family Pycnonotidae) in lower montane forest, Northern Thailand. Biodiversitas Journal of Biological Diversity 21 (8). httos://doi.org/ 10.13057/biodiv/d210829 Rajpar MN, Zakaria M (2014) Effects of habitat characteristics on waterbird distribution and richness in wetland ecosystem of Malaysia. Journal of Wildlife and Park 28: 107-122. Raman TRS (2006) Effects of habitat structure and adjacent habitats on birds in tropical rainforest fragments and shaded lantations in the Western Ghats, India. Biodiversity and Conservation 15 (4): 1577-1607. https://doi.org/10.1007/s10531-005-2352-5 Ramly FN, Ramli R (2009) Harnessing the potential of biodiversity. Simposium Biologi Malaysia, Bangi, Malaysia. 355 pp. Reid S, Diaz |, Armesto J, Willson M (2004) Importance of native bamboo for understory birds in Chilean temperate forests. The Auk 121 (2): 515-525. https://doi.org/10.1093/ auk/121.2.515 Robson C (2020) Field guide to the birds of South-East Asia. Bloomsbury Publishing, 544 pp. RStudio Team (2021) RStudio: Integrated development environment for R. RStudio, PBC, Boston. URL: http:/(www.rstudio.com Sankamethawee WV, Pierce A, Gale G, Hardesty BD (2011) Plant-frugivore interactions in an intact tropical forest in north-east Thailand. Integrative Zoology 6 (3): 195-212. https://doi.org/10.1111/).1749-4877.2011.00244.x Sekercioglu C, Ehrlich P, Daily G, Aygen D, Goehring D, Sandi R (2002) Disappearance of insectivorous birds from tropical forest fragments. Proceedings of the National Academy of Sciences 99 (1): 263-267. https://doi.org/10.1073/pnas.012616199 Shafawati F,, Md-Nor S (2009) Avian temporal diversity assessment in Pangsun, Selangor. The Journal Wildlife and Parks 26. Understorey bird assemblages in selected environmentally sensitive areas ... 29 Shafie NJ, Ahmad A, Ismail NA, David G, Abdullah MT (2018) Bird assemblages in lowland dipterocarp forests of Tasik Kenyir and Setiu, Terengganu. Journal of Sustainability Science and Management 13 (2): 43-56. Shahfiz MA, Munian K, Ruzman NHA, Zakaria NA, Fauzi NFM (2021) Introduction of biological parameters for Environmentally Sensitive Area (ESA) classification for permanent forest reserve: A case study based on small vertebrates’ ssessments in Selangor. |OP Conference Series: Earth and Environmental Science 736 (1). https:// doi.org/10.1088/1755-1315/736/1/012066 Shakya S, Sheldon F (2017) The phylogeny of the world's bulbuls (Pycnonotidae) inferred using a Supermatrix approach. Ibis 159 (3): 498-509. https://doi.org/10.1111/ibi. 12464 Sidra S, Ali Z, Chaudhry MN (2015) Avian diversity at new campus of Punjab University in relation to land use change. Pakistan Journal of Zoology 45 (4): 1069-1082. Tscharntke T, Sekercioglu C, Dietsch T, Sodhi N, Hoehn P, Tylianakis J (2008) Landscape constraints on functional diversity of birds and insects in tropical agroecosystems. Ecology 89 (4): 944-951. https://doi.org/10.1890/07-0455.1 Wang Y, Finch D (2002) Consistency of mist netting and point counts in assessing landbird species richness and relative abundance during migration. The Condor 104 (1): 59-72. https://doi.org/10.1093/condor/104.1.59 Watson W, Tully J, Moser E, Dee D, Bryant K, Schall R, Allan H (1995) Coal resources in environmentally-sensitive lands under federal management. Open-File Report https:// doi.org/10.3133/ofr95631 Zakaria M, Leong PC, Yusuf ME (2005) Comparison of species composition in three forest types: towards using bird as indicator of forest ecosystem health. Journal of Biological Science 5 (6): 734-737. https://doi.org/10.3923/jbs.2005. 734.737 Zakaria M, Rajpar MN, Moradi HV, Rosli Z (2013) Comparison of understorey bird species in relation to edge-interior gradient in an isolated tropical rainforest of Malaysia. Environment, Development and Sustainability 16 (2): 375-392. https://doi.org/10.1007/ $10668-013-9482-9