DOI: 10.13102/sociobiology.v65i4.3339Sociobiology 65(4): 706-713 (October, 2018) Special Issue Open access journal: http://periodicos.uefs.br/ojs/index.php/sociobiology ISSN: 0361-6525 The Cavity-Nesting Bee Guild (Apoidea) in a Neotropical Sandy Coastal Plain Introduction Bee populations are dependent of key resources related to their feeding, mating and nesting (Westrich, 1996). The Brazilian “restingas” (herbaceous-shrub and arboreal vegetation covering the sandy coastal plain) are under intense degradation, which has produced accentuated changes in the landscape and habitat loss (Rocha et al., 2007). The loss of local biodiversity, primarily by fragmentation and habitat loss can reduce the availability of nesting sites and food resources, and threaten bee communities and pollination services (Viana et al., 2012). Abstract Some solitary bees establish their nests in preexisting cavities. Such nesting behavior facilitates the investigation of their life history, as well as the monitoring of their populations in natural, semi-natural and cropped habitats. This study aimed to evaluate the acceptance of artificial substrates by cavity-nesting bees in a heterogeneous landscape. We investigated the percentage of occupation of the different trap-nests, the monthly fluctuations in the nesting activity, offspring sex ratio, mortality and parasitism, in two phytophysiognomies: herbaceous-shrub restinga (site 1) and arboreal restinga (site 2). We used as trap-nests, bamboo canes, large and small straws of cardboard inserted into solid wooden blocks. Five bee species established 193 nests, from which 386 adults emerged. Centris tarsata Smith was the most abundant species. Large straws were significantly more occupied than small straws (χ² = 19.951; df = 1; p < 0.0001). Offspring mortality rate for unknown reasons was significant different between sites, 11% (site 1) and 20% (site 2) (χ² = 4.203; df = 1; p = 0.04). The cavity-nesting bee guild had similar composition in both phytophysiognomies, there was a similar rate of occupation of trap-nests in both sites, as well as dominance of C. tarsata nests. Offspring mortality and parasites attack rates seem to be the more distinctive aspects between the herbaceous- shrub and arboreal restinga sampled. Our study indicated that remnant fragments of coastal native habitats may be important nesting sites for the maintenance of bee populations, some of which have been indicated as candidates for management as pollinators of cultivated plants in Brazil. Sociobiology An international journal on social insects P Oliveira-Rebouças1,4, CML Aguiar2,4, VS Ferreira5, GS Sodré3,4, CAL Carvalho3,4, M Gimenes2 Article History Edited by Solange Augusto, UFU, Brazil Received 09 May 2018 Initial acceptance 17 June 2018 Final acceptance 21 August 2018 Publication date 11 October 2018 Keywords Centris, Euglossa, trap-nests, Tetrapedia, nesting biology. Corresponding author Patricia Luiza de Oliveira Rebouças Departamento de Tecnologia e Ciências Sociais Universidade do Estado da Bahia Rua Edgar Chastinet, s/nº, São Geraldo CEP 48905-680, Juazeiro-BA, Brasil. E-Mail: preboucas@uneb.br Several bee species nest in natural and artificial preexisting cavities (Roubik, 1989). The trap-nests sampling technique was designed by Krombein (1967) in order to obtain nests of these bees. Since then, it has been used to answer questions related to breeding and nesting biology (Garofalo et al., 2012). It also has allowed a management of bee pollinators in agricultural and natural landscapes, resulting in the increasing of the agricultural production (Bosch & Kemp, 2000; Magalhães & Freitas, 2013; Yamamoto et al., 2014). Some studies have investigated the nesting biology of solitary bee species inhabiting the Atlantic coastal plain (Viana et al., 2001; Aguiar & Martins, 2002; Camarotti-de-Lima 1 - Universidade do Estado da Bahia, Juazeiro, Bahia, Brazil 2 - Universidade Estadual de Feira de Santana, Feira de Santana, Bahia, Brazil 3 - Universidade Federal do Recôncavo da Bahia, Cruz das Almas, Bahia, Brazil 4 - PPG- Ciências Agrárias, Universidade Federal do Recôncavo da Bahia, Cruz das Almas, Bahia, Brazil 5 - Universidade Federal do Vale do São Francisco, Petrolina, Pernambuco, Brazil RESEARCh ARTICLE - BEES Sociobiology 65(4): 706-713 (October, 2018) Special Issue 707 & Martins, 2005; Bernardino & Gaglianone, 2008; Martins et al., 2014). Some of these cavity-nesting bee species, such as Centris and Xylocopa spp. are involved in pollination of crops and wild plants (Gottsberger et al., 1988; Buchmann, 2004; Gaglianone et al., 2010; Yamamoto et al., 2012; Oliveira et al., 2013). This study aimed to evaluate the acceptance of artificial substrates (trap-nests) for nest by cavity-nesting bees in a heterogeneous landscape covered by different phytophysiognomies of ”restingas”. We investigated the percentage of occupation of the different trap-nests, the monthly fluctuations in the nesting activity of these species, as well as the sex ratio of the offspring and the incidence of mortality and parasitism of the brood cells. Material and methods Study area This study was carried out in a private reserve (RPPN- DSA, Reserva Particular do Patrimônio Natural Dunas de Santo Antônio; 12°27’S; 37°56’W), in Mata de São João, state of Bahia, Northeast of Brazil. According to the classification of Köppen, the local climate is Tropical (Af), hot and humid without dry seasons. The average temperature is between 21°C and 31 °C, and annual rainfall varies from 1,600 to 2,000 mm. The rainiest period occurs from April to June (SEI, 1999). The phytophysiognomies of this restinga are similar to those described by Cogliatti-Carvalho et al. (2001), the herbaceous-shrub vegetation of the restingas are characterized by bare sand corridors, allowing a higher incidence of sunlight, while in the arboreal restinga, there is a greater density of woody vegetation, less sunlight incidence, increased availability of litter on the ground and high humidity. The study site is covered by an herbaceous-shrub vegetation in which Humiria balsamifera, Waltheria cinerescens, Chamaecrista ramosa, Chrysobalanus icaco, and Cuphea brachiata were plants often found, and by arboreal vegetation, a kind of restinga forest, in which Bowdichia virgilioides, Stryphnodendron pulcherrimum, Andira nitida and Anacardium occidentale are common plant species and can exceed 12 m in height (Queiroz, 2007). These plant species are the most important food resources for wild bees in sandy coastal plain of Bahia, Brazil (Viana & Kleinert, 2006). Sampling The sampling was carried out in two sites 2.5 km distant from each other: one in the herbaceous-shrub vegetation (site 1), and other in arboreal vegetation (site 2). Although the sampling points are located in different phytophysiognomies, they are not far from each other enough to suggest that these bee populations are distinct. The trap-nests were kept in steel shelves covered with a plastic tarpaulin. We used as trap-nests straws made of black cardboard inserted into solid wooden blocks, as well as bamboo canes following Camillo et al. (1995), and Aguiar and Garofalo (2004). Six blocks of wood perforated by holes were placed at each site. Three blocks contained 60 holes each, in which black cardboard straws measuring 58 x 6 mm (SS = small cardboard straws) were inserted. Three other blocks contained 56 holes each, in which trap-nests of 105 x 8 mm (LS = large cardboard straws) were placed. In addition, 18 hollow bamboo canes were arranged in groups containing six bamboo canes of variable lengths (90 to 220 mm) and diameters (8 to 16 mm). The trap-nests were inspected once a month, from November 2006 to November 2007. The trap-nests used by bees were collected and replaced by new ones. Each nest was maintained in a glass tube at room temperature, and they were opened after the emergence of the imagos. The number of brood cells, the presence of dead individuals and their stage of development, as well as the presence of other insects in the brood cells were recorded. Data analysis The χ² test was used to compare trap-nest occupation in each site and the occupied trap-nests of each size (Zar, 2011). The χ² Test goodness of fit tests was used to compare the following aspects between the two sites: length of trap- nest and the frequency of occupation of the trap-nest (is the percentage the ratio between the total number of nests founded by the total number of nests available large and small card nests plus cane bamboo in each site), in order to check the extent to which the observed sex ratio deviated from the expected frequency (1M:1F), and to analyze differences in progeny sex ratio among nests of different size and nests from different sites . Heterogeneity χ² test was used to analyze the rates of immature mortality and parasitism (Zar, 2011). The Mann-Whitney test was used to monthly assess whether there were preferably in the two types of trap-nest offered, and also to check the difference on the development time between males and females emerged in the nest (Zar, 2011). Spearman correlation (rS) analyses were performed to assess monthly temperature and precipitation effects on the monthly frequency of new nests, being considered significant p <0.05 by the Student’s t-test (Zar, 2011). Sörensen index (Cs) was used to evaluate the degree of similarity in the species composition of the cavity-nesting guild in both sites (Magurran, 2011). The analyzes were performed using R software (R Development Core Team, 2016). Results Trap-nests occupation, species richness and abundance Five bee species nested in the trap-nests (Table 1). Although the phytophysiognomies are different in the two sampling points, there was no significant difference in the total number of nests between these sites (χ² = 0.375; df = 1; p = 0.54). A similar species composition of the cavity- nesting bee guild was found in the two sites (Cs = 0.88). Only Tetrapedia diversipes Klug occurred exclusively in the site 2. P Oliveira-Rebouças, CML Aguiar, VS Ferreira, GS Sodré, CAL Carvalho, M Gimenes – Cavity-Nesting Bee Guild in Restinga708 The occupation rates of the trap-nests were also similar, 25% (site 1) and 28% (site 2). Centris tarsata Smith established the highest number of nests in both sites, 18% of the all nests in the site 1 and 20% in the site 2 (Table 1). Regarding to the occupation of the straws of different dimensions, the total occupation rate (the two sites together) was 36% to the large straws (122 nests established), and 11% to the small straws (39 nests). There was a statistically significant difference in the occupation rates of these straws of different dimensions (χ² = 19.951; df = 1; p < 0.001). Centris analis Fabricius, C. tarsata, and T. diversipes used both types of cardboard straws, while Centris trigonoides Lepeletier used only the large straws. C. tarsata established significantly more nests in large straws than in small ones (χ² = 82.6; df = 1; p < 0.001), while C. analis established a higher number of nests in small straws (χ² = 12.772; df = 1; p < 0.001). There was no significant difference in the occupation of large and small straws by T. diversipes (χ² = 3.469; df = 1; p > 0.05) (Table 1). Regarding to the occupation of bamboo canes, 89% of those that were made available to the bees were occupied. C. tarsata used mainly those from 10 to 13 mm diameter, while Euglossa cordata Linnaeus, occupied only those with 18 mm in diameter. Bee species Site 1 Site 2 Total LS SS BC Total LS SS BC N I N I N I N I N I N I N I N I Centris analis 15 26 5 5 10 21 - - 15 15 - - 15 15 - - Centris tarsata 64 178 51 106 - - 13 72 73 113 53 60 4 - 16 53 Centris trigonoides 10 23 10 23 - - - - 1 2 1 2 - - - - Tetrapedia diversipes - - - - - - - - 12 19 2 4 10 15 - - Euglossa cordata 2 1 - - - - 2 1 1 9 - - - - 1 9 Total 91 228 66 134 10 21 15 73 102 158 56 66 29 30 17 62 Table 1. Number of nests provisioned (N) and number of imagos emerged (I) in restinga vegetation, Bahia, Brazil. Site 1: herbaceous-shrub vegetation, site 2: arboreal vegetation. LS = large cardboard straws, SS = small cardboard straws, BC = bamboo canes. Fig 1. Number of nests established by bees in trap-nests, maximum and minimum temperature, and monthly pluviosity, in Mata de São João, state of Bahia, Brazil, from November 2006 to November 2007. Fig 2. Number of nests established by bee species in restinga vegetation. Temporal distribution of nesting activity Nesting activity in this restinga occurred mainly from December to June, with an abundance peak of nests in December (Fig 1). The total number of nests established per month, was influenced by the nesting activity of C. tarsata, which established the highest number of nests. The temporal distribution of its nesting activity was more restricted (six months) than that of other species, such as C. analis, which had the longest nesting period (nine months) (Fig 2). There was a significant positive correlation between minimum monthly temperature and the total number of nests built (rS = 0.71; p < 0.05), for the nests built by C. tarsata (rS = 0.62; p < 0.05) and C. trigonoides (rS = 0.64; p < 0.05), but not for the other species. There was no correlation between monthly rainfall and the total number of nests (rS = 0.03; p < 0.05). Sociobiology 65(4): 706-713 (October, 2018) Special Issue 709 Brood cells provisioned, emergence of imagos and sex ratio C. tarsata provisioned the highest number of brood cells, both in cardboard straws (n = 263 brood cell) and bamboo canes (n = 130) (Table 2). The average number of brood cells per nest was 2.39 in cardboard nests, and 4.48 in bamboo canes. The number of brood cells varied in all types of trap-nests, with a maximum of 11 brood cells per nest in bamboo straws and seven in cardboards tubes. The most frequent number of brood cells per nest was one (21% of nests), three (22%) in cardboard tubes, and five (23%) and ten (17%) in bamboo straws. The brood cells were arranged linearly in the nests established in cardboard straws, while they tended to be oblique in bamboo canes. Most C. analis nests (52%) had three brood cells, while in C. trigonoides nests four brood cells were more frequent (44%) and three brood cells were common in T. diversipes nests (38%). The interval between the collection of the nests and the emergence of imagos was quite variable. Most C. trigonoides and T. diversipes immatures had a development time longer than 121 days (Table 3). Only C. tarsata had a significant difference on the development time between males (maximum of 50 days) and females (maximum of 54 days) (U = 10.734; p < 0.05). From the 554 brood cells provisioned by bees, 386 imagos emerged (Table 2), so the emergence success was 70% in this habitat. In the nests built in bamboo canes, the emergence success was higher than 90% of the brood cells provisioned in the nests of C. tarsata and E. cordata. In the nests built by these bees in cardboard tubes, this percentage ranged between 50 and 66% (Table 2). The sex ratio of C. tarsata offspring was significantly different from 1:1 (χ² = 18.91; p < 0.0001) in cardboard straws (4M: 1F). But the sex ratio of the offspring produced in bamboo canes did not differ significantly from 1:1 (Table 2). Bee species ♂ ♀ SR χ² EB BC C/N (n) (n) (n) (n) C. tarsata (cardboard straws) 143 35 4.1M:1F 18.910* 166 263 2.39 C. tarsata (bamboo canes) 63 66 1.0M:1F 0.004 125 130 4.48 C. analis 32 20 1.6M:1F 0.974 41 81 2.08 C. trigonoides 16 11 1.4M:1F 0.168 25 36 3.45 T. diversipes 16 3 5.3M:1F 3.606 19 33 2.75 E. cordata 5 6 1.0M:1F 10 11 1.10 Total 275 141 386 554 * p < 0.05 Table 2. Number (n) of males and females of cavity-nesting bees produced in trap-nests (including imagos found dead inside brood cells), offspring sex ratio (SR), Chi-square test for SR (χ²), number of imagos emerged (EB), number of brood cells (BC), and number of brood cells per bee nest (C/N). Mortality Emergences of natural enemies (Anthrax sp., Mesocheira bicolor Fabricius, Leucospis sp.) were recorded in 45 brood cells from these bee nests (Table 4). Bee offspring mortality rate for unknown reasons was 11% (site 1) and 20% (site 2) (Table 4). There was a significant difference between the sampling sites (χ² = 4.203; df = 1; p < 0.05). The mortality rate in C. tarsata offspring was lower in the nests established in bamboo canes (4%) than in cardboard straws (19%) (Table 4). The incidence of brood cell parasitism was higher at the arboreal vegetation (site 2 = 13%), than in the herbaceous- shrubby vegetation (site 1 = 5%), significantly different (χ² = 4.629; df = 1; p < 0.05). C. tarsata had low rates of parasitism in cardboard straws and in bamboo canes, as well as in both sites (Table 4). T. diversipes had high percentage of brood cells attacked by natural enemies (Table 4). Bee species Time intervals (in days) 01 -3 0 31 -6 0 61 -9 0 91 -1 20 12 1- 15 0 15 1- 18 0 18 1- 21 0 21 1- 24 0 24 1- 27 1 >2 71 n C. tarsata 150 142 - - - - - - - - 291 C. analis 22 4 15 - - - - - - - 41 C. trigonoides 1 3 - - - 1 2 12 5 24 T. diversipes 1 3 - - 2 4 3 3 - - 16 E. cordata 1 7 - - - - - - - 1 9 Table 3. Number of imagos of cavity-nesting bees emerged from trap-nests per time intervals between the collection of the nests and the emergence. P Oliveira-Rebouças, CML Aguiar, VS Ferreira, GS Sodré, CAL Carvalho, M Gimenes – Cavity-Nesting Bee Guild in Restinga710 Discussion The cavity-nest bee guild in the RPPN-DSA had few species, as well as in other coastal habitats in the Northest of Brazil, as sand dunes (Viana et al., 2001), coastal savanna (coastal “tabuleiros”), and coastal rainforest (Aguiar & Martins, 2002). Differences in species richness in cavity- nesting guilds may be related to differences in the species composition of each bee assemblage, as they can also be influenced by sampling, since there are different probabilities of nesting females finding the trap-nests and accepting them as substrates of nesting. Flower-visiting data from RPPN-DSA have indicated that there are at least ten other cavity-nesting bee species in this area. The abundance of several of these cavity-nesting bees in flowers was low, suggesting that their populations are small (P. Oliveira-Rebouças, unpublished data). The absence of Xylocopa species using the trap-nests was surprising, since they are usual components of the cavity- nesting bees guild in the Brazilian coastal plain (Viana et al., 2001; Aguiar & Martins, 2002; Viana & Alves-dos- Santos, 2002; Silva et al., 2015). Five Xylocopa species were collected visiting flowers in the RPPN-DSA, and two of them (Xylocopa cearensis Ducke and Xylocopa subcyanea Pérez) were very abundant in this bee assemblage (P. Oliveira- Rebouças, unpublished data). However, they did not use the trap-nests available, although there were adequate for their nesting (bamboo canes up to 220 mm in diameter). The percentage of trap-nests occupied was moderate, both in site 1 (25%) and site 2 (28%). These trap-nests occupation rates were higher than those recorded in other coastal habitats in Northeast Brazil. Viana et al. (2001) reported that solitary bees used only 14% of the trap-nests available in a fragment of tropical sand dunes, and Aguiar and Martins (2002) recorded that bees occupied 7% of the trap-nests in a coastal savanna (tabuleiros vegetation). On the other hand, these authors recorded occupancy of 25% of trap-nests in a coastal rainforest. The trap-nests occupation rates by nesting bees can be influenced by several factors, such as the local availability of natural substrates for nesting (Frankie et al., 1988; Viana et al., 2001; Silva & Viana, 2002), the diversity of the trap-nests available (Vandenberg, 1995), the degree of exposure to the sun (Frankie et al., 1988), and the local availability of trophic resources (Gathmann et al., 1994). These factors appear to have not interfered in the trap- nest occupation rates between sites in the RPPN-DSA, since there was no difference in the occupation of the trap-nests in herbaceous-shrub and arboreal phytophysiognomies. The abundance of bee nests established in each site (91 and 102 nests) in the restinga RPPN-DSA was higher than those found in sand dunes (n = 62) (Viana et al., 2001), in coastal rainforest (n = 19), in coastal savanna vegetation (n = 47), and in a mosaic of these two latter habitats (n = 69) (Aguiar & Martins, 2002). Differences in the number of bee nests may be related to the number of sampled sites in each area, to the sampling effort, as well as to the local dominance of some species that can establish many nests. In the RPPN-DSA, the high number of nests in both phytophysiognomies was due to the high nesting success of C. tarsata in these habitats. This high dominance of C. tarsata on artificial nesting substrates has been recorded in other habitats in Northeast Brazil, as coastal sand dunes (Viana et al., 2001), coastal savanna (Aguiar & Martins, 2002), dry forest (“Caatinga”) and semideciduous forest (Aguiar & Garófalo, 2004). These findings support the hypothesis raised by Aguiar and Garofalo (2004) about the high ability of C. tarsata populations to occupy open environments, with high temperatures and high insolation. Probably, this factor contributed to the large number of nests founded by C. tarsata females in RPPN-DSA, because much of the this area is covered by an herbaceous-shrub vegetation, which allows high incidence of sunlight. These solitary bees used different types and sizes of trap-nests in unequal proportions. In large straws there were higher number of nests, and they attracted more bee species than small straws, as was also observed in other habitats (Aguiar & Garofalo, 2004; Pina & Aguiar, 2011). C. tarsata showed more affinity for large cardboard straws, while C. analis used mainly small cardboard straws, similar to that observed in coastal savanna, where 54% of the C. tarsata nests were built in large straws and 88% of C. analis nests were in small straws (Aguiar & Martins, 2002). Table 4. Mortality percentage in bee brood cells due to unknown causes or parasitism. Site 1: herbaceous-shrub vegetation, site 2: arboreal vegetation. NBC: total number of brood cells attacked by natural enemies (parasites). Bee species Unknown causes (%) Parasitism (%) Natural enemies NBC (N) site 1 site 2 Total site 1 site 2 Total C. tarsata (bamboo canes) 1.4 7.0 3.9 2.7 12.3 6.9 Anthrax sp. Mesocheira bicolor 1 8 C. tarsata (cardboard straws) 10.1 29.6 19.4 4.3 8.8 6.5 Anthrax sp. Mesocheira bicolor Leucospis sp. 7 7 3 C. analis 20.5 37.8 28.4 6.8 10.8 8.6 Leucospis sp. 7 C. trigonoides 29.4 - 27.8 5.9 - 5.6 Leucospis sp. 2 T. diversipes - 18.2 18.2 - 21.2 21.2 Leucospis sp. Anthrax sp. 6 1 E. cordata 50.0 - 9.1 - 33.3 33.3 Anthrax sp. 3 Sociobiology 65(4): 706-713 (October, 2018) Special Issue 711 We registered high amount of trap-nests occupied by solitary bees (especially C. tarsata) in the hottest months (summer) in the RPPN-DSA, with a peak of abundance in December, when rainfall was low. In other studies, variations were observed between seasons and years. In coastal savanna, the highest number of nests was registered in summer (November), a rainy and hot season (Aguiar & Martins 2002). According to Viana et al. (2001), in coastal sand dunes of Northeastern Brazil, the dominant species, C. tarsata, had abundance peak of nests in December (in summer, the dry season) in the first year, while a higher number of nests was found in the rainy months (autumn) in the second year. The fluctuations in the frequency of nesting can be related to intrinsic factors of the cavity-nesting species or to environmental factors, such as weather patterns, or the dynamic of floral resources availability (Frankie et al., 1988). The number of brood cells built per nest was variable in all species, as reported in other habitats, for C. tarsata (Aguiar & Garófalo, 2004; Buschini & Wolff, 2006) and C. analis (Jesus & Garófalo, 2000). Large variations in the number of brood cells were also found in different types of trap-nests (cardboard straws and bamboo canes) in the studied area. The number of brood cells built per nest, as well as the brood cells arrangement in nests, depend upon the size of the cavity. On the other hand, behavioral decisions of the female bees regarding time spent in the same cavity to produce offspring affect the number of brood cells produced by nest, since the more time invested in the same nest the more brood cells are expected to be produced. Alternatively, distributing the reproductive effort in several nests should also have some effect on variability in the number of cells per nest (Jesus & Garofalo, 2000). The total sex ratio of C. tarsata offspring was biased to males, mainly in cardboard straws (4M:1F), but not in bamboo canes (1M:1F). Bias to males have been recorded in some populations of C. tarsata (Aguiar & Martins 2002; Aguiar & Garófalo, 2004; Buschini & Wolff, 2006). However, in other populations, the sex ratio of the offspring was 1:1 (Silva et al., 2001; Aguiar & Garófalo, 2004). Several factors can affect the offspring sex ratio of cavity-nesting bees, as the length (Alonso et al., 2012; Gruber et al., 2011; Stephen & Osgood, 1965) and diameter of the cavities (Rust 1998), the abundance of food resources in the environment, the foraging efficiency of nesting females (Torchio & Tepedino, 1980), and conditions of the mother (Seidelmann et al., 2010). The mortality rate by unknown reasons varied among the species. C. tarsata offspring had low mortality in bamboo canes (< 4%), and higher in cardboard straws (19%). These values were lower than those in other habitats, as reported by Aguiar and Garófalo (2004), who recorded 41% in dry forest and 42% in a semideciduous forest in Brazil. Buschini and Wolff (2006) found high rates of offspring mortality (58% to 70%) by unknown reasons in swamp habitat and grasslands in southern Brazil. The mortality rate in C. analis offspring (35%) was moderate similar to that observed in agricultural areas in Brazil (24-25%) (Aguiar & Pina, 2012). Higher mortality rates were found in an urban area in southeastern Brazil, 63% (Jesus & Garófalo, 2000) and 42% (Couto & Camillo, 2007). Offspring mortality may be related to failures in development, environmental factors, such as temperature (Jesus & Garófalo, 2000; Gazola & Garófalo, 2009), changes in air humidity conditions (Buschini & Wolff, 2006), or even to the handling of the nests (Aguiar & Pina, 2012). Although the phytophysiognomies sampled in the RPPN-DSA were different, the cavity-nesting bee guild had a similar composition in the studied sites, there was a similar rate of occupation of trap-nests in both sites, as well as dominance of C. tarsata nests. Mortality rates due to unknown causes and by parasite attack on the offspring of some cavity-nesting bee species seem to be the most distinctive aspect between herbaceous-shrub restinga and arboreal restinga phytophysiognomies sampled. Another relevant aspect was the lack of records on both sites of some cavity-nesting species, collected in flowers, but did not use the available artificial nesting substrates, indicating that the trap-nest sampling method alone is not enough to adequately sample the species richness of the cavity-nesting bee guild. Finally, our study indicated that remnant fragments of coastal native habitats may be refuges for the maintenance of bee populations, some of which, such as C. tarsata and C. analis, have been indicated as candidates for management as pollinators of cultivated plants in Brazil. Acknowledgments This study was financed in part by the “Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil” (CAPES) - Finance Code 001. We thank “Conselho Nacional de Desenvolvimento Científico e Tecnológico” (CNPq) for granting a scholarship to CALC (number 305885/2017-0). References Aguiar, C.M.L. & Garófalo, C.A. (2004). 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