Phylogeography and diversification of Oriental weaverbirds (<i>Ploceus</i> spp.): A gradual increase of eurytopy

Abdul Razaq; Giovanni Forcina; Urban Olsson; Qian Tang; Robert Tizard; Naing Lin; Nila Pwint; Aleem Ahmed Khan

doi:10.1016/j.avrs.2023.100120

Avian Research > 2023 > 14(1): 100120. > DOI: 10.1016/j.avrs.2023.100120

Abdul Razaq, Giovanni Forcina, Urban Olsson, Qian Tang, Robert Tizard, Naing Lin, Nila Pwint, Aleem Ahmed Khan. 2023: Phylogeography and diversification of Oriental weaverbirds (Ploceus spp.): A gradual increase of eurytopy. Avian Research, 14(1): 100120. DOI: 10.1016/j.avrs.2023.100120

Citation:

PDF (2312 KB)

Phylogeography and diversification of Oriental weaverbirds (Ploceus spp.): A gradual increase of eurytopy

Abdul Razaq^{a, 1},
Giovanni Forcina^{b, c, d, ,},
Urban Olsson^{e, f},
Qian Tang^g,
Robert Tizard^{h, i},
Naing Lin^{h, i},
Nila Pwintⁱ,
Aleem Ahmed Khan^a, ,

a.
Institute of Pure & Applied Biology, Zoology Division, Bahauddin Zakariya University, Multan, Pakistan
b.
Universidad de Alcalá (UAH), Global Change Ecology and Evolution Research Group (GloCEE), Departamento de Ciencias de La Vida, 28805, Alcalá de Henares, Spain
c.
CIBIO, Centro de Investigação em Biodiversidade e Recursos Genéticos, InBIO Laboratório Associado, Universidade do Porto, Campus de Vairão, 4485-661, Vairão, Portugal
d.
BIOPOLIS Program in Genomics, Biodiversity and Land Planning, CIBIO, Campus de Vairão, 4485-661, Vairão, Portugal
e.
Department of Biology and Environmental Science, University of Gothenburg, Box 463, SE-405 30, Gothenburg, Sweden
f.
Gothenburg Global Biodiversity Centre, Box 461, SE-405 30, Gothenburg, Sweden
g.
Department of Biological Sciences, National University of Singapore, 16 Science Drive 4, Republic of Singapore
h.
Wildlife Conservation Society, Global Conservation Program, Bronx, NY, USA
i.
Nature and Wildlife Conservation Division, Ministry of Natural Resources and Environmental Conservation, Naypyidaw, Myanmar

Funds:

the Ministry of Universities of the Spanish Government (María Zambrano/Next Generation EU) and the Portuguese Foundation for Science and Technology FCT, PTDC/BAA-AGR/28866/2017

More Information

Corresponding author:
Universidad de Alcalá (UAH), Global Change Ecology and Evolution Research Group (GloCEE), Departamento de Ciencias de La Vida, 28805, Alcalá de Henares, Spain. E-mail address: giovanni.forcina@uah.es (G. Forcina)

Institute of Pure & Applied Biology, Zoology Division, Bahauddin Zakariya University, Multan, Pakistan. E-mail address: aleembzu25@yahoo.com.au (A.A. Khan)
¹ Deceased. Sadly, our friend and colleague Abdul Razaq passed away just as the final version of the manuscript had been prepared, the last remaining requirement for earning his Ph.D. We dedicate it to his memory.
Received Date: 01 Jan 2023
Rev Recd Date: 25 Jun 2023
Accepted Date: 25 Jun 2023
Available Online: 10 Jan 2024
Publish Date: 16 Jul 2023

Graphical Abstract

Abstract

Abstract

Weaverbirds are a speciose group of colorful passerines inhabiting the Old World Tropics. Nevertheless, the Oriental weaverbirds (Ploceus spp.), widespread across southern Asia, are much less diverse and restricted to a few ecological niches compared to their African counterpart. To investigate their phylogeography, we retrieved 101 samples of Baya Weaver (P. philippinus), Streaked Weaver (P. manyar), Black-Throated Weaver (P. benghalensis) and Asian Golden Weaver (P. hypoxanthus) along with GenBank sequences of Finn's Weaver (P. megarhynchus). We reconstructed the first molecular phylogeny based on a dataset consisting of both mitochondrial and nuclear genes, dating the most recent common ancestor of Oriental Ploceus to ~11 mya. Subsequent speciation appears to have been a combination of divergence within the Indian subcontinent and dispersal across a barrier situated between the Indian subcontinent and the Indochinese region, which provided habitats with a varying degree of isolations and ultimately promoted divergences in allopatry. Two descendants of the earliest nodes, P. megarhynchus and P. hypoxanthus, are both rare and local, often found near large river systems, which perhaps reflects niche conservatism and a lack of adaptive potential. The three smaller species are all widespread, common and less habitat specific. The most recent divergence, between western and eastern P. philippinus populations, is supported by both phylogenetic and morphological evidence, pointing toward limited gene flow between them. However, a zone of intergradation may exist in Myanmar and Brahmaputra flood plains, thus preventing a recommendation for species level recognition without further study.
- Avian phylogenetics,
- Indian subcontinent,
- Indochinese region,
- Multilocus analyses,
- Ploceidae

FullText(HTML)

Background

Most signals are thought to be reliable based on the underlying logic that receivers only respond to signals that are sufficiently reliable (Maynard and Harper 2003; Searcy and Nowicki 2005). If a signal is always unreliable, the receivers would ignore that signal. Thus, the signaling systems would not exist at all. When the signaler's and receiver's interests are opposed (e.g., in male-male competition for resources), there are two main explanations for the reliability of signals. First, some signals are reliable because those signals are forced to be honest due to physiological or anatomical constraints on signal production (Maynard and Parker 1976). For example, the dominant frequencies of calls used in male-male conflict in some frogs belongs in this category; the frequency is determined by the size of the vocal apparatus, which is determined by body size, and the dominant frequency is thus constrained to reflect reliable information about body size (Martin 1971, 1972). A performance constraint on the trilled vocalizations in Emberizidae is an additional example: maximal values of frequency bandwidth and trill rates are limited by motor constraint (Podos 1996, 1997). The second explanation for signal reliability is based on costs. Costs that stem from signaling can prevent deceit if the signaler's fitness is decreased due to cheating (Grafen 1990). Birds often use vocal signals in territorial disputes, and the vocal signal used here might be associated with escalated contests (Searcy and Beecher 2009). If a weak individual cannot bear an escalated contest, reliable vocal signals could guarantee the cost of a conceivable escalated contest (Vehrencamp 2000; Molles and Vehrencamp 2001).

Although signals are often honest, unreliable signaling can exist in signaling systems (Maynard and Harper 2003; Searcy and Nowicki 2005). Unreliable signaling can be defined by departures from the typical correlation between the signal and an attribute of the signaler (Hauser 1996). For example, If signal a is typically correlated with action A, unreliable signaling occurs when an individual signals a but does not perform A (i.e., over-signaling) or does not signal a but does perform A (i.e., under-signaling). Depending on the value of the contested resource and the expected cost of an escalated contest for the signaler, models predict that unreliable signaling can be a useful strategy for some individuals or in some context (Szamado 2000; Szalai and Szamado 2009). For example, although song type matching (i.e., singing to the rival with the same song that the rival has just sung) has long be seen as an aggressive signal in song sparrows during male-male conflict (Stoddard et al. 1992), this signal can reflect the signaler's expectation of an escalated contest in the initial of territory conflict but fail to predict direct attack (Searcy et al. 2006; Akcay et al. 2013). Because the reliability of a signal is context dependent, testing the signal in different contexts might aid the understanding of both the function of the signal and the evolution of the signaling system.

Soft song is characterized by markedly lower amplitudes than normal song (here termed broadcast song) and has long been observed in many birds (Dabelsteen et al. 1998; Morton 2000). Recent studies have confirmed that soft song is an aggressive signal; soft song can predict aggressive escalation in both passerine (Searcy et al. 2006; Ballentine et al. 2008; Hof and Hazlett 2010; Akcay et al. 2011) and non-passerine birds (Rek and Osiejuk 2011). Additionally, playback experiments with mounted specimens have shown that soft song is a reliable aggressive signal in male-male conflict (Searcy and Beecher 2009; van Staaden et al. 2011; Searcy et al. 2014). In a previous study, we found that the relationship between soft song production and subsequent attack is significant in the Brownish-flanked Bush Warbler Cettia fortipes (Xia et al. 2013b). Here, we examined the correlation between soft song production and subsequent attack in different male-male conflict contexts in this species.

The brownish-flanked bush warbler is a small, furtive passerine found throughout Southeast Asia. During the breeding season, the males sing clear, high-pitched broadcast songs from dense undergrowth (del Hoyo et al. 2006; Kennerley and Pearson 2010). The males have a small repertoire of broadcast songs (typically two or three songs) and always sing the broadcast song types in alternating patterns (e.g., a-b-a-b; Xia et al. 2013a). Compared to broadcast song, soft song in this species is characterized by lower amplitude, a significantly lower minimum frequency, more notes, a longer duration, and a higher note rate (Xia et al. 2013b). Thus, soft song is easily distinguished from broadcast song in the field. Based on our observations, broadcast song is always used in spontaneous singing and after expelling an intruder, while soft song is used during encounters between rival males. In a previous playback study (Xia et al. 2013b), we used mounted specimens positioned within the territory of subject males and conducted playback trails of broadcast songs and found that six of 25 territorial owners attacked the mounted specimen, and all attacking subjects generated soft songs immediately prior to the attacks. However, the context of the playback experiment of Xia et al. (2013b) is uncommon in the field because in contrast to broadcast song, soft song was always produced by the intruder when in close contact with the territory owner. The first aim of this study was to investigate whether soft song and subsequent attack are correlated in the territorial owner when the intruder produces soft song. The context of this study is more similar to that of the field when the territory owner closely encounters the intruder. Thus, this context can provide additional information about the function of soft song for birds.

The second aim of this study was to investigate the cost of soft song in the Brownish-flanked Bush Warbler. For signals with no obvious physiological or anatomical constraints, cost should be the most probable explanation for the stability of the signaling system (Vehrencamp 2000; Molles and Vehrencamp 2001). A previous study showed that soft song can induce male brownish-flanked bush warbler to spend significantly more time near the loudspeaker (Xia et al. 2013b). We hypothesized that closeness is a cost to the signaler in the experiment detailed by Xia et al. (2013b) based on the underlying logic that increasing closeness increases the possibility of attack. However, this underlying logic has not been verified in this species. In the present study, we show direct evidence of cost to the soft song signaler; i.e., soft songs induced more attacks.

Methods

Study area and species

During May 2013 we conducted experiments on a population of brownish-flanked bush warblers in the Dongzhai National Nature Reserve in the Henan province of southern China (31.9°N, 114.3°E). The males in this population have been monitored, color-banded and recorded as a part of a long-term study since 2007. Brownish-flanked bush warblers defend territories from March to July. Most of the territories are characterized by dense bushes that are dominated by Camellia sinensis tea plants; thus, the territory boundaries are typically well defined by the habitat.

Song stimuli

The songs used in the playback experiments were recorded using a TASCAM HD-P2 portable digital recorder (Tascam Co., Japan) and a Sennheiser MKH416P48 external directional microphone (Sennheiser Co., Germany) at a sampling rate of 44.1 kHz and a sample size of 16 bits. For the playback trials, we randomly selected five broadcast songs that were recorded from five different males during the 2011 breeding season and five soft songs that were randomly selected from five different males recorded during the 2012 breeding season. We used Goldwave 5.25 (GoldWave Inc., Canada) to adjust the broadcast song rate to one song every 10 s, which is similar to the song rate of this species. For the soft songs, we repeated the recordings to achieve a total time of 3 min because the majority of the soft song recordings were shorter than 3 min. Using a CEL-240 sound level meter (Casella Co., USA), the speaker volume for the playback trials of the broadcast and soft songs were adjusted to 80 dB and 60 dB, respectively, at a distance of 1 m above the speaker. This amplitude approximates the natural amplitude of song in the field as evaluated by ear by observers. In total, we used ten unique 3-min playback stimuli that included five broadcast songs and five soft songs. Similar playback stimuli have been used in a previous playback study of the species (see Xia et al. 2013b).

Playback procedure

We used mounted specimens of four male brownish-flanked bush warblers obtained with permission from the Museum of Beijing Normal University, and we randomly selected one for each subject male. Prior to each playback trial, we located each subject male by its spontaneous singing behavior. We positioned a single mounted specimen on the ground concealed under bushes within the territory of each subject male at approximately 10 m from the singing spot. The specimens were always placed away from the territorial boundary to decrease the effects on neighbors. Playback was conducted using uncompressed.wav files stored on a TeclastX18Mp3 player (Teclast Co., Shenzhen, China) connected to a Senway loudspeaker (Senway Amplifier Co., Shenzhen, China). The loudspeaker was placed next to the mounted specimen and concealed with grass or dead leaves.

There were 51 subject males used in this study. Each subject male was exposed to one playback trial. The type of playback (either broadcast or soft song playback) was determined by a coin toss for the first subject and was then alternated between broadcast song and soft song for the subsequent subject males. The specific broadcast or soft song playback stimuli were randomly selected for each subject male. Most of the males in this population have been color-banded, which allowed us to ensure that the playback stimuli were not recorded from the subject male or its immediate neighbors. Two observers, positioned approximately 10 m away from the mounted specimen, recorded the behavioral responses of the subject males. We stopped playback if the subject male began to physically attack the mounted specimen. Otherwise, the experiment continued for the 3 min duration. If a subject male did not appear within 3 m during the 3 min playback, we abandoned the trial because we could not be sure that the subject male had seen the mounted specimen. If the 3 m criterion was met, we recorded the attack latency, which was defined as the time from which the male first appeared within 3 m of the mounted specimen to attack (defined as any physical contact with the mount specimens). Due to difficulties in observing some behaviors (e.g., wing quivering) in the dense vegetation of the birds' habitat, we only recorded whether soft song was produced for each subject male. Because most attack latencies were < 10 s in our previous study (Xia et al. 2013b), we were only concerned with signals that occurred within 10 s prior to the attack. For those subjects that did not attack, we focused on the signals in the last 10 s within 3 m of the mounted specimens during 3 min playback. We obtained data from 51 subjects that included 26 subjects in the broadcast songs playback group and 25 subjects in the soft songs playback group.

Data analysis

We used Fisher's exact test to compare the numbers of attacks by the subject males between the broadcast song playback group and the soft song playback group. After we removed the data for the subject males that did not attack the mount specimen, a t test was used to compare the attack latency between the broadcast song playback group and soft song playback group. To test the relationship between soft song and subsequent attack, we used Fisher's exact tests for the broadcast song playback group and the soft song playback group, respectively.

All data are expressed as the mean ± the SE, and differences were considered significant at P < 0.05. The data were analyzed using SPSS v.20 (IBM Co., New York, NY, USA). Permission for this study was granted by the National Bird-banding Center of China (license number H20110042) and the Dongzai National Nature Reserve (license number 2011002).

Results

The relationship between soft song and subsequent attack was significant in the broadcast song playback group (Fisher exact test, P = 0.046) but not in the soft song playback group (Fisher exact test, P = 0.202; Table 1). Both under-signaling and over-signaling subject males were observed. In broadcast song playback group, 15.4% subject males attacked without producing soft song (under-signaling) and 11.5% subject males produced soft song but did not attack (over-signaling); in soft song playback group, 28.0% subject males attacked without producing soft song (under-signaling) and 8.0% subject males produced soft song but did not attack (over-signaling) (Table 1).

Table 1. Number of subject males to 3 min of playback of broadcast or soft songs

Responses		Playback broadcast songs	Playback soft songs
Attack on specimen	Produced soft songs	6	11
Attack on specimen	No soft song	4	7
No attack	Produced soft songs	3	2
No attack	No soft song	13	5

| Show Table

DownLoad: CSV

The soft song playback group evoked significantly more attacks than did the broadcast song playback group (Fisher exact test, P = 0.025; Table 1), and the attack latency was significantly shorter in the soft song playback group (23.2 ± 7.9 s) than in the broadcast song playback group (59.9 ± 16.7 s; t test, t₂₆ = 2.252, P = 0.033; Figure 1).

Figure 1. Attack latency (mean ± SE) of the subject males in the playback experiment.

Attack latency was defined as the time between the first appearance of the subject male within 3 m of the mounted specimens and the time of physical contact with the mount specimen. The attack latency was significantly shorter in soft songs playback group than in the broadcast song playback group (t test, t₂₆ = 2.252, P = 0.033).

DownLoad: Full-Size Img PowerPoint

Discussion

Reliability of soft song

Although the signal must be sufficiently reliable to maintain a stable signaling system, there is room for cheating as a strategy for some individuals or in some context (Szamado 2000; Szalai and Szamado 2009). In this study, we found that the correlation of the subject males' soft songs and subsequent attacks was significant in the broadcast song playback group but not in the soft song playback group. The reliability of an aggressive signal requires a correlation between the signal and an escalation toward physical fighting on the part of the signaler (Hauser 1996; Searcy and Nowicki 2005). Our data show that there was less reliability in the soft song playback group.

Can the subject males benefit from the unreliable signaling? There were two males in the broadcast song playback group and three males in the soft song playback group that produced soft song but did not attack the intruder (i.e., the mounted specimen). The potential benefit of this over-signaling is intimidation of the intruder that could cause the intruder to concede (Searcy and Nowicki 2005; Maynard and Harper 2003). Comparison of the attack rates of the soft song playback group (72.0%) and the broadcast song playback group (38.5%) indicates that soft songs from the intruder (mounted specimen) did not cause more territory owners to concede. However, we should note the asymmetry between the intruder and the territory owner (Maynard and Price 1973). Territory is always more valuable for the territory owner, thus it is not easy for the territory owner to be intimidated by the soft song of an intruder. Whether over-signaling benefits the territory owner remains an open question because the intruder (mounted specimen) could not retreat in our experiment. There were four males in the broadcast song playback group and seven males in soft song playback group that did attack the intruder (mounted specimen) but did not produce soft song. We believe that the potential benefit acquired by these under-signaling subject males was gaining the initiative in fighting. Based on this hypothesis, we infer that under-signaling might occur more often when a fight is inevitable. Our data support this inference; more under-signaling subject males were observed in the soft song playback group (28.0%) than in the broadcast song playback group (15.4%). In the future, we will demonstrate that initiating attack is beneficial in fights, and we will then fully understand the benefit acquired by the under-signaling subject males.

Limited reliability for soft song is also found in other species, i.e. attack was not correctly predicted in about one third of the Song Sparrow Melospiza melodia males (Akcay et al. 2013). Similarly, under-signaling is more common than over-signaling (Searcy et al. 2006; Akcay et al. 2013). As how responses to intrusion may rely on attributes of responding animals themselves (Moseley et al. 2013), high quality individuals may adopt under-signaling strategy without bothering to waste time in signaling (Searcy et al. 2013). To test this hypothesis, fighting ability or/and aggressive intentions will be compared between under-signaling males and other males in future work.

The cost of soft song

Cost is crucial for the maintenance of aggressive signaling systems (Vehrencamp 2000; Molles and Vehrencamp 2001). If there is no cost for aggressive signaling, it is advantageous for individuals produce the maximal levels such signals during conflicts. If all individuals signal maximally, it will be difficult for the receivers to judge the signaler's aggressive intentions based on the information contained in that signal. Thus, the receivers would ignore the signal, and the signaling system could not exist.

Among several potential cost concern soft song (summarized in Akcay et al. 2011; Akcay and Beecher 2012), receiver-retaliation cost get most support (Ballentine et al. 2008; Hof and Hazlett 2010; Anderson et al. 2012; Templeton et al. 2012). Receiver-retaliation cost posits that soft song increases the likelihood of the receiver retaliating aggressively. In a previous study, we found that soft song induces subject males to spend more time near the sound source (i.e., loudspeaker; Xia et al. 2013b) and inferred that being closer might indicate an increased possibility of attack. Recent studies have found that some behaviors that were previously thought to reflect attack intent are not actually correlated with attack (Ballentine et al. 2008; Hof and Hazlett 2010; Searcy et al. 2006). Thus, it is insufficient to assume that the closeness of the receiver is a cost of to the soft song signaler (Hof and Hazlett 2010; Hof and Podos 2013). The present study showed that when soft song was played back, more subject males conducted attacks of the mounted specimen with shorter attack latencies. The greater number of subject males attacking on mounted specimen indicates greater harm due to fighting to the signaler, and the shorter attack latency indicates that the signaler had less time for retreat. Both these factors provide direct evidence regarding receiver-retaliation cost of soft song; i.e., signalers that produce soft song put themselves at risk for fighting.

Besides receiver-retaliation cost (Anderson et al. 2012; Templeton et al. 2012; Searcy et al. 2014), there is cost from potential intruder in the song sparrow: as soft songs are low in amplitude, a potential intruder might fail to hear a male who uses soft song in conflict and thus be more likely to intrude on the soft song signaler's territory (Searcy and Nowicki 2006). As increasing evidence indicates that territorial conflicts can be eavesdropped on by other potential rivals (Akcay et al. 2010; Sprau et al. 2012), future work should test whether brownish-flanked bush warbler soft song signalers experience a greater number of intrusions.

Conclusions

In this work, we showed the receiver-dependent costs entailed by the soft song of the Brownish-flanked Bush Warbler; i.e., the signaler that produces soft song suffer more and quicker attacks from the receiver. We observed both over-signaling and under-signaling male Brownish-flanked Bush Warblers. In simulated intrusion that coupled playback of soft song with a mount specimen, a greater number of territory owner directly attacked without producing soft song (under-signaling). We suggest that such under-signaling males might benefit from taking the initiative in fights.

Competing interests

The authors declare that they have no competing interests.

Acknowledgements

This study was supported by National Natural Science Foundation of China (No.31172098) and the China Postdoctoral Science Foundation (No.2014 M550026). We would like to thank Jiayu LIU for her help on field work.

Authors' contributions

YYZ and CWX conceived and designed the experiments. CWX, DPW, BYL performed the experiments. CWX analyzed the data. YYZ, CWX, HL wrote or revise the manuscript. All authors read and approved the final manuscript.

References (79)

References

Ali, S., Ripley, S.D., 1983. The Handbook of the Birds of India and Pakistan. Compact edition. Oxford University Press, Bombay.

Bandelt, H.J., Forster, P., Röhl, A., 1999. Median-joining networks for inferring intraspecific phylogenies. Mol. Biol. Evol. 16, 37–48. .

Barley, A.J., Datta-Roy, A., Karanth, K.P., Brown, R.M., 2014. Sun skink diversification across the Indian–Southeast Asian biogeographical interface. J. Biogeogr. 42, 292–304. .

Bird, J.P., Martin, R., Akçakaya, H.R., Gilroy, J., Burfield, I.J., Garnett, S.T., et al., 2020. Generation lengths of the world's birds and their implications for extinction risk. Conserv. Biol. 34, 1252–1261. .

Bouckaert, R., Heled, J., Kühnert, D., Vaughan, T., Wu, C.H., Xie, D., et al., 2014. BEAST 2: a software platform for Bayesian evolutionary analysis. PLoS Comput. Biol. 10, e1003537. .

Brown, C.R., Covas, R., Anderson, M.D., Brown, M.B., 2003. Multistate estimates of survival and movement in relation to colony size in the sociable weaver. Behav. Ecol. 14, 463–471. .

Cerling, T.E., Harris, J.M., MacFadden, B.J., Leakey, M.G., Quadek, J., Eisenmann, V., et al., 1997. Global vegetation change through the Miocene/Pliocene boundary. Nature 389, 153–159. .

Chapin, J.P., 1917. The classification of the weaver-birds. Bull. Am. Mus. Nat. Hist. 37, 243–280.

Chingangbam, D.S., Laishram, J.M., Suzuki, H., 2015. Molecular phylogenetic characterization of common murine rodents from Manipur, Northeast India. Genes Genet. Syst. 90, 21–30. .

Copeland, P., 1997. The when and where of the growth of the Himalaya and the Tibetan plateau. In: Ruddiman, W.F. (Ed.), Tectonic Uplift and Climate Change. Plenum press, New York, London, pp. 19–40. .

Covas, R., Brown, C.R., Anderson, M.D., Brown, M.B., 2002. Stabilizing selection on body mass in the sociable weaver Philetairus socius. Proc. R. Soc. B 269, 1905–1909. .

Covas, R., Brown, C.R., Anderson, M.D., Brown, M.B., 2004a. Juvenile and adult survival in the sociable weaver (Philetairus socius), a southern-temperate colonial cooperative breeder in Africa. Auk 121, 1199–1207.

Covas, R., Doutrelant, C., du Plessis, M.A., 2004b. Experimental evidence of a link between breeding conditions and the decision to breed or to help in a colonial cooperative bird. Proc. R. Soc. A B 271, 827–832.

Covas, R., du Plessis, M.A., 2005. The effect of helpers on artiﬁcially increased brood size in sociable weavers (Philetairus socius). Behav. Ecol. Sociobiol. 57, 631–636. .

Covas, R., Dalecky, A., Caizergues, A., Doutrelant, C., 2006. Kin associations and direct vs. indirect ﬁtness beneﬁts in colonial cooperatively breeding sociable weavers Philetairus socius. Behav. Ecol. Sociobiol. 60, 323–331. .

Crook, J.H., 1963. The Asian weaver birds: problems of co-existence and evolution with particular reference to behavior. J. Bombay Nat. Hist. Soc. 60, 1–48.

Crowe, T.M., 1978. The evolution of guinea-fowl (Galliformes, Phasianidae, Numidinae) taxonomy, phylogeny, speciation and biogeography. Ann. S. Afr. Mus. 76, 43–136.

Darriba, D., Taboada, G.L., Doallo, R., Posada, D., 2012. jModelTest: more models, new heuristics and parallel computing. Nat. Methods 9, 772. .

Deignan, H.G., 1956. New races of birds from Laem Thong. Proc. Biol. Soc. Wash. 69, 211.

de Silva, T.N., Peterson, A.T., Bates, J.M., Fernando, S.W., Girard, M.G., 2017. Phylogenetic relationships of weaverbirds (Aves: Ploceidae): A first robust phylogeny based on mitochondrial and nuclear markers. Mol. Phylogenet. Evol. 109, 21–32. .

de Silva, T.N., Peterson, A.T., Perktas, U., 2019. An extensive molecular phylogeny of weaverbirds (Aves: Ploceidae) unveils broad nonmonophyly of traditional genera and new relationships. Auk 136, ukz041. .

del Hoyo, J., Collar, N.J., 2016. HBW and BirdLife International Illustrated Checklist of the Birds of the World. vol. 2. Passerines. In: Lynx Edicions, Barcelona.

del Hoyo, J., Elliott, A., Christie, D., 2010. Handbook of the Birds of the World. vol. 15. Weaverbirds to New World Warblers. In: Lynx Edicions, Barcelona. .

Dickinson, E., Christidis, L., 2014. The Howard and Moore Complete Checklist of the Birds of the World. Aves Press, East Sussex.

Drummond, A.J., Suchard, M.A., Xie, D., Rambaut, A., 2012. Bayesian phylogenetics with BEAUti and the BEAST 1.7. Mol. Biol. Evol. 29, 1969–1973. .

Favre, A., Päckert, M., Pauls, S.U., Jähnig, S.C., Uhl, D., Michalak, I., et al., 2015. The role of the uplift of the Qinghai-Tibetan Plateau for the evolution of Tibetan biotas. Biol. Rev. 90, 236–253. .

Forcina, G., Panayides, P., Guerrini, M., Nardi, F., Gupta, B.K., Mori, E., et al., 2012. Molecular evolution of the Asian francolins (Francolinus, Galliformes): A modern reappraisal of a classic study in speciation. Mol. Phylogenet. Evol. 65, 523–534. .

Forcina, G., Guerrini, M., Khaliq, I., Khan, A.A., Barbanera, F., 2018. Human-modified biogeographic patterns and conservation in game birds: The dilemma of the black francolin (Francolinus francolinus, Phasianidae) in Pakistan. PLoS One 13, e0205059. .

France-Lanord, C., Derry, L.A., 1994. δ13C of organic carbon in the Bengal fan: source, evolution, and transport of C3 and C4 plant carbon to marine sediments. Geochem. Cosmochim. Acta 58, 4809–4814. .

Fry, C.H., Keith, S., 2004. Sparrows to Buntings. In: The Birds of Africa, vol. 7. Christopher Helm, London. .

Fu, Y.X., 1997. Statistical tests of neutrality of mutations against population growth, hitchhiking and background selection. Genetics 147, 915–925. .

Gill, F., Donsker, D., Rasmussen, P., 2021. IOC World Bird List. (v11.2).

Govin, G., Najman, Y., Copley, A., Millar, I., van der Beek, P., Huyghe, P., et al., 2018. Timing and mechanism of the rise of the Shillong Plateau in the Himalayan foreland. Geology 46, 279–282. .

Harpending, H.C., 1994. Signature of ancient population growth in a low-resolution mitochondrial DNA mismatch distribution. Hum. Biol. 66, 591–600.

Hartert, E., 1902. On birds from Pahang, eastern Malay Peninsula. Novit. Zool. 9, 537–580.

Jacobs, B.F., Kingston, J.D., Jacobs, L.L., 1999. The origin of grass-dominated ecosystems. Ann. Mo. Bot. Gard. 86, 590–643. .

Karanth, K.P., 2003. Evolution of disjunct distributions among wet-zone species of the indian subcontinent: testing various hypothesis using a phylogenetic approach. Curr. Sci. 85, 1276–1283.

Kershaw, P., van der Kaars, S., Moss, P., Opdyke, B., Guichard, F., Rule, S., et al., 2006. Environmental change and the arrival of people in the Australian region. Before Farming 1, 1–24. .

Kumar, S., Stecher, G., Tamura, K., 2016. MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets. Mol. Biol. Evol. 33, 1870–1874. .

Lavé, J., Avouac, J.P., 2001. Fluvial incision and tectonic uplift across the Himalayas of Central Nepal. J. Geophys. Res. 106, 26561–26591. .

Leigh, J.W., Bryant, D., 2015. popart: full-feature software for haplotype network construction. Methods Ecol. Evol. 6, 1110–1116. .

Librado, P., Rozas, J., 2009. DnaSP v5: a software for comprehensive analysis of DNA polymorphism data. Bioinformatics 25, 1451–1452. .

Licht, A., Boura, A., Franceschi, D.D., Utescher, T., Sein, C., Jaeger, J., 2014a. Late middle eocene fossil wood of Myanmar: implications for the landscape and the climate of the eocene bengal bay. Rev. Palaeobot. Palynol. 216, 44–54. .

Licht, A., van Cappelle, M., Abels, H.A., Ladant, J-B., Trabucho-Alexandre, J., France-Lanord, C., et al., 2014b. Asian monsoons in a late Eocene greenhouse world. Nature 513, 501–506. .

Louys, J., Meijaard, E., 2010. Palaeoecology of Southeast Asian megafauna-bearing sites from the Pleistocene and a review of environmental changes in the region. J. Biogeogr. 37, 1432–1449. .

Meher-Homji, V.M., 1983. On the Indo-Malaysian & Indo-African elements in India. Feddes Repert. 94, 407–424.

Molnar, P., 2005. Mio-pliocene growth of the Tibetan Plateau and evolution of East Asian climate. Palaeontol. Electron. 8, 2.

Molnar, P., England, P., Martinod, J., 1993. Mantle dynamics, uplift of the Tibetan Plateu, and the Indian monsoon. Rev. Geophys. 31, 357–396. .

Moreau, R.E., 1960. Conspectus and classification of the Ploceine weaver-birds. Ibis 102, 443–471.

Morgan, M.E., Kingston, J.D., Marino, B.D., 1994. Carbon isotopic evidence for the emergence of C4 plants in the Neogene from Pakistan and Kenya. Nature 367, 162–165. .

Morley, R.J., 2012. A review of the Cenozoic paleoclimate history of Southeast Asia. In: Gower, D.J., Johnson, K.G., Richardson, J.E., Rosen, B.R., Rüber, L., Williams, S. (Eds.), Biotic Evolution and Environmental Change in Southeast Asia. Cambridge University Press, Cambridge, pp. 79–114.

Nei, M., 1978. Estimation of average heterozygosity and genetic distance from a small number of individuals. Genetics 89, 583–590. .

Nie, J., Zhang, R., Necula, C., Heslop, D., Liu, Q., Gong, L., et al., 2014. Late Miocene–early Pleistocene paleoclimate history of the Chinese Loess Plateau revealed by remanence unmixing. Geophys. Res. Lett. 41, 2163–2168. .

Olsson, U., Alström, P., 2020. A comprehensive phylogeny and taxonomic evaluation of the waxbills (Aves: Estrildidae). Mol. Phylogenet. Evol. 146, 106757. .

Päckert, M., Martens, J., Sun, Y.H., Strutzenberger, P., 2016. The phylogenetic relationships of Przevalski's Finch Urocynchramus pylzowi, the most ancient Tibetan endemic passerine known to date. Ibis 158, 530–540. .

Price, T.D., Hooper, D.M., Buchanan, C.D., Johansson, U.S., Tietze, D.T., Alström, P., et al., 2014. Niche filling slows the diversification of Himalayan songbirds. Nature 509, 222–225. .

Quade, J., Cater, J.M.L., Ojha, T.P., Adam, J., Harrison, T.M., 1995. Late Miocene environmental change in Nepal and the northern Indian subcontinent: Stable isotopic evidence from paleosols. Geol. Soc. Am. Bull. 107, 1381–1397. .

Quade, J., Cereling, T.E., Bowman, J.R., 1989. Development of Oriental Monsoon revealed by marked ecological shift during the latest Miocene in northern Pakistan. Nature 342, 163–166. .

Rambaut, A., 2016. FigTree. Version 1.4.3. .

Rambaut, A., Drummond, A.J., 2013. Tracer. Version 1.6.0. .

Rambaut, A., Drummond, A.J., 2016. TreeAnnotator. Version 1.8.4. .

Ramos-Onsins, S., Rozas, J., 2002. Statistical properties of new neutrality tests against population growth. Mol. Biol. Evol. 19, 2092–2100. .

Rasmussen, P.C., Anderton, J.C., 2012. Birds of South Asia: The Ripley Guide. Vols. 1 and 2, second ed. National Museum of Natural History–Smithsonian Institution, Michigan State University and Lynx Edicions, Washington, D.C., Michigan and Barcelona.

Roberts, T.J., 1992. The Birds of Pakistan. vol. Ⅱ, Passerines. In: first ed. Oxford University Press, Karachi, p. 617.

Robson, C., 2000. A Field Guide to the Birds of Thailand and South-East Asia. Asia Books, Bangkok.

Rogers, A.R., Harpending, H., 1992. Population growth makes waves in the distribution of pairwise genetic differences. Mol. Biol. Evol. 9, 552–569. .

Rozas, J., Ferrer-Mata, A., Sanchez-DelBarrio, J.C., Guirao-Rico, S., Librado, P., Ramos-Onsins, S.E., et al., 2017. DnaSP v6: DNA sequence polymorphism analysis of large datasets. Mol. Biol. Evol. 34, 3299–3302. .

Schenekar, T., Weiss, S., 2011. High rate of calculation errors in mismatch distribution analysis results in numerous false inferences of biological importance. Heredity 107, 511–512. .

Sinclair, I., Ryan, P., Christy, P., Hockey, P., 2010. Birds of Africa, South of the Sahara. Princeton University Press, Princeton.

Spottiswoode, C.N., 2009. Fine-scale life-history variation in sociable weavers in relation to colony size. J. Anim. Ecol. 78, 504–512. .

Sundevall, C.J., 1836. Ornithologiskt system. K. - Sven. Vetenskapsakademiens Handl. 1835, 43–130 (In Swedish).

Suraprasit, K., Chaimanee, Y., Bocherens, H., Chavasseau, O., Jaeger, J.-J., 2014. Systematics and phylogeny of middle Miocene Cervidae (Mammalia) from Mae Moh Basin (Thailand) and a paleoenvironmental estimate using enamel isotropy of sympatric herbivore species. J. Vertebr. Paleontol. 34, 179–194. .

Swofford, D.L., 2002. PAUP: Phylogenetic Analysis Using Parsimony (And Other Methods) Version 4. Sinauer Associates, Sunderland, Massachusetts.

Tajima, F., 1989. Statistical method for testing the neutral mutation hypothesis by DNA polymorphism. Genetics 123, 585–595.

Ticehurst, C., 1932. Ploceus infortunatus burmanicus. Bull. Br. Ornithol. Club 52, 104–105.

Valdiya, K.S., 1998. Dynamic Himalaya. Universities Press, Hyderabad.

Warren, B.H., Bermingham, E., Bourgeois, Y., Estep, L.K., Prys-Jones, R.P., Strasberg, D., et al., 2012. Hybridization and barriers to gene flow in an island bird radiation. Evolution 66, 1490–1505. .

Weir, J.T., Schluter, D., 2008. Calibrating the avian molecular clock. Mol. Ecol. 17, 2321–2328. .

Yu, Y., Harris, A.J., Blair, C., He, X., 2015. RASP (Reconstruct Ancestral State in Phylogenies): A tool for historical biogeography. Mol. Phylogenet. Evol. 87, 46–49. .

Cited By

Figures(5) / Tables(1)

Get Citation

PDF

XML

Article Metrics

Article views (8) PDF downloads (3)

	Monika Homolková, Petr Musil, Diego Pavón-Jordán, Dorota Gajdošová, Zuzana Musilová, Šárka Neužilová, Jan Zouhar. 2024: Changes in the adult sex ratio of six duck species breeding populations over two decades. Avian Research, 15(1): 100187. DOI: 10.1016/j.avrs.2024.100187
	Yuqi Zou, Yiting Jiang, Zitan Song, Xiaobin Fang, Changqing Ding. 2024: The Crested Ibises expanding to plain areas exhibit a higher tolerance of human proximity. Avian Research, 15(1): 100165. DOI: 10.1016/j.avrs.2024.100165
	Mengzhen Wang, Wenwen Chen, Chunlin Li, Jinming Zhao. 2022: Definition of spatial positions within foraging Greater White-fronted Geese flocks from an individual's perspective: Cost-benefit dynamics change with the distance to flock edge. Avian Research, 13(1): 100056. DOI: 10.1016/j.avrs.2022.100056
	Dimitar Demerdzhiev, Dobromir Dobrev, Georgi Popgeorgiev, Stoycho Stoychev. 2022: Landscape alteration affects the demography of an endangered avian predator by reducing the habitat quality. Avian Research, 13(1): 100030. DOI: 10.1016/j.avrs.2022.100030
	Yiwen Chen, Yat-tung Yu, Fanjuan Meng, Xueqin Deng, Lei Cao, Anthony David Fox. 2021: Migration routes, population status and important sites used by the globally threatened Black-faced Spoonbill (Platalea minor): a synthesis of surveys and tracking studies. Avian Research, 12(1): 74. DOI: 10.1186/s40657-021-00307-z
	Ru Jia, Tian Ma, Fengjiang Zhang, Guogang Zhang, Dongping Liu, Jun Lu. 2019: Population dynamics and habitat use of the Black-necked Crane (Grus nigricollis) in the Yarlung Tsangpo River basin, Tibet, China. Avian Research, 10(1): 32. DOI: 10.1186/s40657-019-0170-9
	Chuanwu Chen, Marcel Holyoak, Yanping Wang, Xingfeng Si, Ping Ding. 2019: Spatiotemporal distribution of seasonal bird assemblages on land-bridge islands: linking dynamic and static views of metacommunities. Avian Research, 10(1): 25. DOI: 10.1186/s40657-019-0164-7
	Saâd Hanane. 2016: Effects of location, orchard type, laying period and nest position on the reproductive performance of Turtle Doves (Streptopelia turtur) on intensively cultivated farmland. Avian Research, 7(1): 4. DOI: 10.1186/s40657-016-0039-0
	Yuxiang LI, Changzhan SONG, Yucheng YANG, Xiaojing LI, Fengli LI, Jie HUANG, Xiuli HUANG. 2012: Monitoring population dynamics of the migratory Red-crowned Crane (Grus japonensis) at Shuangtaihekou National Nature Reserve, northeastern China, from 1991 to 2012. Avian Research, 3(3): 225-229. DOI: 10.5122/cbirds.2012.0029
	Fawen QIAN, Hongxing JIANG, guohai YU, Youzhong YU, Jun YANG, Siliang PANG, Renzu PIAO. 2012: Survey of breeding populations of the Red-Crowned Crane (Grus japonensis) in the Songnen Plain, northeastern China. Avian Research, 3(3): 217-224. DOI: 10.5122/cbirds.2012.0028

Phylogeography and diversification of Oriental weaverbirds (Ploceus spp.): A gradual increase of eurytopy