STUDY AREA

I visited patches of Guadua bamboo at forested research sites along the Manu (Terborgh et al. 1984, Gentry 1990, Robinson and Terborgh 1997), Amigos (Pitman 2006), and Tahuamanu (Alverson et al. 2000) rivers of southeastern Peru (Fig. 1). Bamboo patches consisted of G. sarcocarpa and/or G. weberbaueri, which I did not usually distinguish. My study took place at the Centra de Investigación y Capacitación Río Los Amigos (CICRA), managed by the Asociación para la Conservación de la Cuenca Amazónica (ACCA) and located between the Río Madre de Dios and Río Amigos, at the CM1 ranger station at the mouth of the Río Amigos, and at a bush camp on the Río Amiguillos. I worked at Los Amigos 27–30 July 2002, 11 June—3 August 2003, 16 February—21 April 2004, 1–23 June 2004, 20 July—15 September 2004, and 1 October—10 November 2004. More information concerning the research stations, climate, habitats, and natural history of Los Amigos can be found at the ACCA's website ( http://www.amazonconservation.org) and in Pitman (2006).

FIGURE 1.

Map of study areas in lowland southeastern Peru. Areas above 500 m elevation are shaded gray, and research sites are referenced as closed circles. Numbered sites are Oceania (1; 11° 23′ S, 69° 32′ W), Cocha Cashu Biological Station (2; 11° 85′ S, 71° 32′ W), Playa Bonita (3; 11° 50′ 19′ S, 71° 23′ 07′ W), La Vieja bush camp along the Río Amiguillos (4; 12° 26′ S, 70° 16′ W), CICRA (5; 12° 34′ S, 70° 05′ W), and CM1 (6; 12° 34′ S, 70° 04′ W), which ranged in elevation from 270 to 350 m above sea level.

Inside Manu National Park along the Río Manu, I worked from 26 June to 19 July 2004 at Estación Biológica Cocha Cashu and at Playa Bonita, located approximately 6 km north of Cocha Cashu. Habitats included mature floodplain forests and Guadua bamboo patches, described in more detail by Terborgh et al. (1990), Silman et al. (2003), and Patterson et al. (2006).

Between 8 and 18 October 2004, I visited a large patch of G. weberbaueri bordered by mature terra firme forest and cleared pasture along the north bank of the Río Tahuamanu at Oceania, Departamento Madre de Dios, Peru, 6 km west of Iberia, roughly 130 km north of Puerto Maldonado on the road to Iñapari, a frontier town on the border with Acre, Brazil. This site is further described by Tobias et al. (2007).

FIELD METHODS

I surveyed the bird communities of 13 bamboo patches or patch clusters ranging in size from less than 0.5 ha to 48.3 ha (mean = 11.1 ha, SD = 13.7) at Los Amigos, Manu National Park, and along the Río Tahuamanu (Fig. 1). I did point counts and spot-mapping along transects and supplemented these observations with mist-net captures. Patch clusters consisted of multiple imperfectly distinct bamboo patches close enough (<100 m) together that I suspected specialists would treat them as a single patch, and therefore I analyzed them as a single patch. Sampling within the 13 patches totaled 140.4 hr over 77 days. Alone, I sampled along transects marked every 25 m, between dawn and no later than 10:00 (and usually ending before 09:00). I recorded all birds seen or heard while walking and while stationary during 8-min point counts spaced no farther than ∼150 m apart along transects. In 11 of these same bamboo patches, I also captured 134 species of birds in mist nets (1096 captures in 36 953.5 net-m hr over 53 days). I also estimated the areas of these 13 bamboo patches by using a geographic information system in ArcMap 9.1 (ESRI 2005). Patch area, and net capture, and census effort for each patch are summarized in Table 1. I believe this search effort was more than sufficient to detect almost all bamboo specialists in these patches, as I also spent much additional time recording other kinds of data or camped in these patches without detecting species undetected during censuses or mist netting.

From these surveys, I created a presence—absence matrix to summarize use of each patch by bamboo specialists (Table 2). On the basis of a literature review and surveys of other adjacent habitats, I categorized Guadua bamboo specialists according to their degree of habitat specialization, with “obligate” specialists restricted to bamboo throughout their ranges, “near-obligate” specialists only occasionally found outside bamboo, and “facultative” or “potentially facultative” specialists having at least a local habitat preference for bamboo (Kratter 1997, Lebbin 2007).

STATISTICAL ANALYSES

Nestedness is a measure of order within a set of communities (Atmar and Patterson 1993). In a perfectly nested system, no species found within a depauperate community (island or habitat patch) is absent from a more species-rich community. I used Atmar and Patterson's (1995) Nestedness Calculator to determine the degree of nestedness of these bamboo-specialist communities. The Nestedness Calculator generates a measure, referred to as the “temperature” (T), from a presence—absence matrix and compares the observed temperature to those of 5000 matrices created by randomly rearranging the original matrix. The temperature can range from zero to 100° with zero being perfectly nested and low temperatures representing ordered systems with little “heat of disorder” and high temperatures reflecting highly disordered, un-nested systems (Atmar and Patterson 1993). I used one-tailed Spearman ρ correlation tests to investigate correlations between area of the bamboo patch, nestedness rank, and species richness of bamboo specialists.

TABLE 1.

Location, name, area, and mist-net and survey effort (rounded to nearest hour) expended to sample the bird communities of 13 patches of Guadua bamboo, southeastern Peru. The numbers of bamboo specialists detected in each patch are apportioned by the number of total specialists and of obligate and near-obligate specialists (facultative specialists excluded). The final column presents the nestedness rank of each patch when only obligate and near-obligate specialists are analyzed. Patches with the bird communities most nested within the matrix have the highest nestedness rankings. Patches 2 and 4 were likely larger prior to this study, but recent clearing for agriculture had reduced the extent of patch 2, and within 2 years bamboo died off naturally in large areas adjacent to patch 4. Patch 11 bordered an airstrip and may have been larger many years prior to this study. Less search effort was required and expended in smaller patchers. In patch 12, the total sampling time includes a single ∼1-hr survey in the late afternoon (all other patches were censused during the morning only).

PATCH SIZE AND NESTEDNESS

Communities of bamboo specialists were nested and highly sensitive to patch area at the local scale. As patch size declined, specialist species dropped out of the community in a nonrandom, nested fashion. Small bamboo patches may still support a diversity of specialists, and I found 10 species of near-obligate and obligate bamboo specialists in a 0.86-ha patch (number 8) near CICRA. These included the Peruvian Recurvebill (Simoxenops ucayalae), not detected in the slightly larger patches 9 and 12.

No obligate specialists and only a single facultative specialist, the Chestnut-tailed Antbird (Myrmeciza hemimelaena), were present in the smallest bamboo patch (patch 13, 0.15 ha), suggesting that 0.15 ha is below the minimum patch size most specialists require. The Peruvian Warbling-Antbird (Hypocnemis peruviana peruviana), also detected in this tiny bamboo patch, is closely related to the bamboo specialist Yellow-bellied Warbling-Antbird (Hypocnemis subflava collinsi). The Peruvian Warbling-Antbird was likely using dense forest along a stream nearby as well as the bamboo patch, potentially offering a glimpse of the transition that presumably occurs when forest species colonize bamboo patches in the early stages of the process of specialization for bamboo habitat.

PATCH SIZE, OCCURRENCE OF SPECIALISTS, AND POPULATION ESTIMATES

I found bamboo specialists in small patches, indicating that they may occur at higher densities and have larger populations than previously estimated. My results indicate that occurrence of specialists may differ from that assumed in prior studies. Of 19 specialists (Table 3) compared, I detected 14 (74%) in patches smaller than territory sizes estimated by Kratter (1997) and Lloyd (2004). This likely indicates that these species' territories can be smaller than previously estimated on the basis of a small sample of bamboo patches; however the influence of a history of shrinking patch size or species incorporating adjacent forest into their territory can not be completely ruled out. Four of the 14 species (29%) were facultative specialists, possibly defending territories larger than the smallest bamboo patch within which they were detected. The remaining ten species were obligate and near-obligate specialists, less likely to use adjacent forest habitats. I detected all nine of these obligate and near-obligate specialists in at least two patches smaller than their previously estimated territory sizes. I found the Striated Antbird (Drymophila devillei) in three smaller patches, the Rufous-headed Woodpecker (Celeus spectabilis) and Peruvian Recurvebill in four smaller patches, the Flammulated Pygmy-Tyrant (Hemitriccus flammulatus) in five smaller patches, and the Brown-rumped Foliage-Gleaner (Automolus melanopezus) and Dusky-tailed Flatbill (Ramphotrigon fuscicauda) in six smaller patches. Although it is possible that these species incorporated both forest and bamboo into their territories or that these bamboo patches were larger prior to this study, it seems just as or more likely that they can use territories smaller than previous thought. Small bamboo patches are often undetected in remotely sensed images. Individual birds inhabiting small bamboo patches or a combination of small bamboo patches and bits of adjacent forest will not be counted in population estimates, and actual sizes of populations of these specialists may be underestimated.

TABLE 3.

Density and size of territories of Guadua bamboo specialists from Kratter (1997) and Lloyd (2004) and the size of the smallest patch in which specialists were detected in this study. Territory size was estimated by dividing 100 ha by the number of territories or density of birds per 100 ha, under the assumption the entire area was saturated or included in a territory.

Other factors may influence the presence of bamboo specialists within a patch, such as proximity to rivers that may serve as dispersal routes for certain species. I encountered the Manu Antbird (Cercomacra manu) in only three of the 13 patches I surveyed, all of which were within a few hundred meters of rivers. The Manu Antbird is also closely related to the Jet Antbird (C. nigricans), Rio Branco Antbird (C. carbonaria), Mato Grosso Antbird (C. melanaria), and Bananal Antbird (C. ferdinandi), of which the latter three are also closely associated with riparian habitats (Zimmer and Isler 2003). If the Manu Antbird requires proximity to rivers for dispersal or other reasons, then it may be absent from vast areas of bamboo far from large streams in terra firme, resulting in an overestimate of its population based on the extent of bamboo.

Specialists may also be absent from suitable habitat because of interspecific competition. In no patch I sampled did I find more than two of the three specialist tody-tyrants or more than one of the three Synallaxis spinetails. Interspecific competition among these ecologically similar tody-tyrants may prevent all three tody-tyrants, the Long-crested Pygmy-Tyrant (Lophotriccus eulophot.es), Flammulated Pygmy-Tyrant, and White-cheeked Tody-Flycatcher (Poecilotriccus albifacies), or even two of three spinetails, the Ruddy Spinetail (S. rutilons), Chestnut-throated Spinetail (S. cherriei), and Cabanis's Spinetail (S. cabanisi) from co-occurring in a single patch. Therefore, the White-cheeked Tody-Flycatcher may be absent from much suitable habitat (e.g., terra firme bamboo patches) because of the presence of the Flammulated Pygmy-Tyrant and Long-crested Pygmy-Tyrant. Additional sampling of the specialist bird community of bamboo patches deep within terra firme would help clarify these patterns of these species' co-occurrence and would clarify whether the Manu Antbird is as scarce away from rivers as my study suggests.

My data come from areas of relatively intact and unfragmented forests so may not be applicable to isolated bamboo patches in landscapes heavily altered by people. Regional development proposals, such as the paved “Trans-Oceanica” highway, likely will increase human settlement, habitat destruction, and regrowth of bamboo within human-altered landscapes (Nepstad et al. 2001, Conover 2003). Conditions under which specialists are present or absent in bamboo patches regenerating from human disturbances may be a worthy study for future researchers. I have seen many specialists, such as the Chestnut-capped Puffbird (Bucco macrodactylus), Cabanis's Spinetail, Bamboo Antshrike (Cymbilaimus sanctaemariae), and Yellow Tyrannulet (Capsiempis flaveola) during brief visits to patches of bamboo growing in clearings along the Manu Road that are contiguous with areas of natural bamboo and forest, and I have seen the Long-crested Pygmy-Tyrant on territories at the edge of treefall gaps and forest edges created by loggers at Los Amigos and along the road to Iberia. Bamboo that invades roadsides and pastures, however, may not support specialists if the quantity or quality of the surrounding habitats is difficult for specialists to disperse through, and I have not encountered any bamboo specialists during short visits to such isolated bamboo patches along roads near Puerto Maldonado. Therefore, I am doubtful that regrowth of bamboo in isolated, human-disturbed areas will increase the habitat available for bamboo specialists of conservation concern until data suggesting otherwise become available.