On the development of a trait-based approach for studying Neotropical bats

Castillo-Figueroa, Dennis; Pérez-Torres, Jairo

doi:10.11606/1807-0205/2021.61.24

Dennis Castillo-Figueroa ²2E-mail: dennis.castillof@gmail.com (corresponding author)

Pontificia Universidad Javeriana (PUJ), Facultad de Ciencias, Departamento de Biología, Unidad de Ecología y Sistemática (UNESIS), Laboratorio de Ecología Funcional. Bogotá, Colombia.

https://orcid.org/0000-0002-4584-0762

Jairo Pérez-Torres ³3E-mail: jaiperez@javeriana.edu.co

Pontificia Universidad Javeriana (PUJ), Facultad de Ciencias, Departamento de Biología, Unidad de Ecología y Sistemática (UNESIS), Laboratorio de Ecología Funcional. Bogotá, Colombia.

https://orcid.org/0000-0001-7121-6210

²E-mail: dennis.castillof@gmail.com (corresponding author)

³E-mail: jaiperez@javeriana.edu.co

Edited by: Luís Fábio Silveira

AUTHORS’ CONTRUBUTIONS

D.C.-F.: conceived the idea, contributed to the theoretical and conceptual framework, wrote the paper, prepared figures and tables, reviewed drafts of the paper. J.P.-T.: wrote the paper, contributed to the theoretical and conceptual framework, reviewed drafts of the paper. The authors declare no conflict of interests.

Trait type	Complex or functional dimension	Trait	Attribute	Trait obtention	Description of the trait
Morphological	Size	Body mass	Value of the trait in grams (g)	SI, FM	Based on weight
		Total length	Value of the trait in millimeters (mm)	FM	Measurement from the tail (if any) to the head (tail + body + head). If there is no tail, the measurement encompasses the lower end of the body to the head
		Forearm length	Value of the trait in millimeters (mm)	SI, FM, BC	Measurement from the base of the elbow (tip of the olecranon process) to the distal region of the forearm where it joins the carpus
	Wings	Length of the third digit	Value of the trait in millimeters (mm)	FM, BC	In biological collections the trait is the result of the sum of the metacarpus and its three phalanges. The metacarpus is measured from the joint with the phalanx to the junction with the carpus. The phalanx is measured as the maximum distance between the joints. In the field, the trait is measured from the junction of the metacarpus with the carpus to the tip of the third phalanx
		Length of the fifth digit	Value of the trait in millimeters (mm)	FM, BC	In biological collections the trait is the result of the sum of the metacarpus and its two phalanges. The metacarpus is measured from the joint with the phalanx to the junction with the carpus. The phalanx is measured as the maximum distance between the joints. In the field, it is measured from the junction of the metacarpus with the carps to the tip of the second phalanx
		Wing loading	Value of the trait in Newtons/m²	FM, SI	Wing loading (Wl) is body mass in kg times acceleration of gravity (Mg) divided by its wing area in m² (S); *gravity acceleration = 9.8 m/s²; Wl = Mg/S (N/m²)
		Aspect ratio	Adimensional (numerical)	FM, SI	Aspect ratio (A) is the result of the wing span squared (m²) (B) divided by wing area (m²) (S); A = B²/S
		Tip shape index	Adimensional (numerical)	FM, SI	Tip shape index (I) is the tip area ratio (Ts) divided by tip length ratio (Tl) minus Ts; I = Ts/(Tl-Ts)
		Wing span	Value of the trait in millimeters (mm)	FM, SI	Measurement taken from tip to tip of the extended wings held along to the long axis of the body
	Pollex	Length of the pollex without claw	Value of the trait in millimeters (mm)	FM, BC	Measurement from the beginning of the phalanx of finger to the beginning of the claw
		Length of the pollex with claw	Value of the trait in millimeters (mm)	FM, BC	Measurement from the beginning of the phalanx of the thumb to the tip of the claw
	Hindlimbs	Length of the foot without claw	Value of the trait in millimeters (mm)	FM, BC	Measurement from the joint with the tibia to the beginning of the claws
		length of the foot with claw	Value of the trait in millimeters (mm)	FM, BC	Measurement from the tibia joint to the tip of the claw
		Length of the tibia	Value of the trait in millimeters (mm)	FM, BC	Measurement from the joint with the femur to the joint with the foot
		Length of calcaneus	Value of the trait in millimeters (mm)	FM, BC	Measure from the base of the calcaneus to the tip of it
	Head	Length of the ear	Value of the trait in millimeters (mm)	FM	Measure from the base of the ear to its most apical region
		Length of tragus	Value of the trait in millimeters (mm)	FM	Measure from the base to the tip of the structure
		Length of nose leaf	Value of the trait in millimeters (mm)	FM, BC	Measurement from the base of the nasal horseshoe to the tip of the lancet
		Inner nostril width ratio	Adimensional (numerical)	FM, BC	Ratio of the cranial width to the inner nostril width
	Tail	Tail length	Value of the trait in millimeters (mm)	FM	Measurement from the insertion of the tail in the body to its distal end
		Uropatagium area	Value of the trait in area (m²)	FM	Measurement of the surface area of the intrafemoral membrane
Life history	Reproductive	Litters per year	Mean number of litters during a year	FM, SI	Number of litters produced per year
		Litter size	Mean number of pups per litter	FM, SI	Number of pups produced per litter
		Gestation duration	Mean days in pregnancy	FM, SI	Length of the pregnancy expressed in days
		Lactation duration	Mean days in lactation	FM, SI	Length of the lactation expressed in days
		Reproductive status	For females the frequencies or population averages of each stage: Proestrus. Estrus. Metestrus. Anestrus. For males the frequencies or population averages of: Scrotted males Non-scrotted males	FM	Reproductive stage that involves hormonal concentration (progesterone and estradiol peaks) and physiological changes in females (corpus luteum and ovarian follicle). Vaginal smears can reveal superficial nucleated cells (proestrus), superficial non-nucleated cells parabasal (estrus), intermediate cells (metestrus) and parabasal cells (anestrus) in bat females. Females can be considered reproductive when they presented a dominance in proestrus, estrus, and metestrus. By contrast, non-reproductive females are when the dominant stage is anestrus. This can be measured individually and can also be expressed in frequencies or population averages of each stage. For males, reproductive status can be determined by examining testes (scrotted or not), thus obtaining frequencies or population averages of each condition.
		Sexual maturity age	Mean number of years	FM, SI	Age at first reproductive event (adult)
		Mating systems	Monogamic; Polygyny; Polyandry; Promiscuty	FM, SI	All the potential combinations between bats to find mate and copulate during reproductive season
	Physiological	Digestive capactiy	Food intake response	LE	Bat capacity to obtain nutrients when consumption item differ in nutrient quality. Food intake response is defined as the relationship (following power function) between volumetric food intake and nutrient concentration
		Gut size	Mean surface area (cm²)	BC	Gut area of the total gut
		Gut retention time of seeds	Mean number of time (minutes)	LE	Time that the seeds are retained inside the gut of the bat until is expelled by feces
		Type of lingual papillae	Gustative, including vallate and fungiform, or mechanical comprising basal, postero-median, scalelike, filiform, foliate, conical, and horny	BC	Shape of the papillae in tongue
		Metabolic rate	Mean energetic expenditure (kcal/day)	FM, LE	Energy unit per time required by an individual to maintain its basal physiological functions
		Body temperature	Mean and ranks of body temperature (ºC)	FM, LE	Individual capacity to survive at a specific temperature, either hot or cold temperatures
	Behavioral	Migration	Resident; Migratory	FM, SI	Species movement according its life history
		Sociality	Solitary; Society; Group; Colony; Aggregation	FM, SI	Clustering of individuals
		Foraging strategy	Gleaning foragers; Aerial foragers; Trawling foragers	SI	Behavioral strategy that is used to obtain food
		Activity pattern	Number of recording events per time hour	FM	Activity period of bat species within nocturnal time. Commonly spanned from 18:00h to 6:00h
	Trophic niche	Feeding guild	Necterivore; Frugivore; Carnívore; Omnívore; Sanguinivore; Insectívore; Piscívore	SI	Based on the food item that is consumed mainly for a large part of bat life
		Diet specialization	Value of the niche breadth index selected (e.g., Levin, Morisita, etc.) ranging from low values (specialist) to high values (generalist)	FM	Based on the percentage of the contribution of each food item to the total diet the species. Levin index as well as Morisita index can estimate dietary specialization
		Bite force	Maximum bite force (Newtons)	FM, BC, SI	Is the result of the interplay between the teeth, the masticatory muscles, the mandible, the maxillae, and temporomandibular joints. Bite force can be measured in vivo with an isometric Kistler force transducer or can be estimated with assessments of muscular and bony morphology from skulls using algorithms
	Spatial niche	Foraging hábitat	Background space; Uncluttered space; Highly cluttered space	SI	It is the space where the bat is found most of the time, especially when searching for food. Resource availability and conditions limit foraging habitat
		Vertical stratification	Capture rate (individuals per mist-net hour) in each strata: Understory; Canopy	FM	Based on the proportion of bat capture rate in ground (shrubs) and canopy nets (treetops). Bats can also use both strata (no preference)
		Home range	Mean surface area traveled during a period of time (km²)	FM, SI	Area of available habitat over which an individual does its daily activities. There are several ways to estimate home range such as minimum convex polygon, minimum area probabilities, areas of kernel, etc.
		Type of roost	Animal burrow or hole; Termite ant/nest; Cavity in fallen tree; Cavity in standing tree; Exposed on standing tree; Foliage, leaf tent; Foliage, unmodified foliage; Rocks, crevices, or caves; Under fallen tree; Undercut earth bank	FM, SI	Diurnal roosts used by bats
	Echolocation	Duration	Time (ms)	FM, SI	Time span of the call emitted by the bat
		Interval	Time (ms)	FM, SI	Time between one call to another emitted by the bat
		Frequency	Pitch of a sound (Khz)	FM, SI	Number of pressure waves of the call emitted by the bat that pass by a reference point per unit time. This can include the start of the call (initial frequency), the end of the call (final frequency) and the maximum amplitude of the call (maximum frequency)
		Intensity	Strength of the tone signal (db)	FM, SI	Height of the sound pressure wave emitted by the bat
		Harmonics	Number or harmonics (if any)	FM, SI	Wave that is a multiple of the fundamental frequency emitted by the bat

Morphological Trait	Life history trait	Location	Application	Reference
Body size, forearm length, greatest length of skull, condylobasal length, length of maxillary toothrow, breadth across upper molars, width across post-orbital constriction, breadth of braincase, wing loading, aspect ratio	Diet, foraging location, foraging strategy	Manu Biosphere Reserve, Perú	Response to elevational gradient	*Cisneros et al.,* 2014**Cisneros, L.M.; Burgio, K.R.; Dreiss, L.M.; Klingbeil, B.T.; Patterson, B.D.; Presley, S.J. & Willig, M.R. 2014. Multiple dimensions of bat biodiversity along an extensive tropical elevational gradient. Journal of Animal Ecology, 83(5): 1124-1136.
Body size, forearm length, greatest length of skull, condylobasal length, length of maxillary toothrow, breadth across upper molars, width across post-orbital constriction, Breadth of braincase, Wing loading, aspect ratio	Diet, foraging location, foraging strategy, roost type	Caribbean lowlands in northeastern Costa Rica	Response to human-modified landscapes	*Cisneros et al.,* 2016**Cisneros, L.M.; Fagan, M.E. & Willig, M.R. 2016. Environmental and spatial drivers of taxonomic, functional, and phylogenetic characteristics of bat communities in human-modified landscapes. PeerJ, 4: e2551. http://doi.org/10.7717/peerj.2551 http://doi.org/10.7717/peerj.2551...
Body size, forearm length, greatest length of skull, condylobasal length, length of maxillary toothrow, breadth across upper molars, width across post-orbital constriction, breadth of braincase, wing loading, aspect ratio	Diet, foraging location, foraging strategy, roost type	Caribbean lowlands of northeastern Costa Rica	Response to human-modified landscapes	*Cisneros et al.,* 2015**Cisneros, L.M.; Fagan, M.E. & Willig, M.R. 2015. Effects of human-modified landscapes on taxonomic, functional and phylogenetic dimensions of bat biodiversity. Diversity and Distributions, 21(5): 523-533.
Body mass, wing aspect ratio, wing loading	Trophic level, dietary specialization, vertical stratification, mobility	Manaus, Central Amazon, Brazil	Response to habitat fragmentation	*Farneda et al.,* 2015**Farneda, F.Z.; Rocha, R.; López-Baucells, A.; Groenenberg, M.; Silva, I.; Palmeirim, J.M.; Bobrowiec, P. & Meyer, C.F.J. 2015. Trait-related responses to habitat fragmentation in Amazonian bats. Journal of Applied Ecology , 52(5): 1381-1391.
Body mass, forearm length, wing morphology	Echolocation, Vertical stratification	Manaus, Central Amazon, Brazil	Response to habitat fragmentation	*Núñez et al.,* 2019**Núñez, S.F.; López-Baucells, A.; Rocha, R.; Farneda, F.Z.; Bobrowiec, P.E.D.; Palmeirim, J.M. & Meyer, C.F.J. 2019. Echolocation and Stratum Preference: Key Trait Correlates of Vulnerability of Insectivorous Bats to Tropical Forest Fragmentation. Frontiers Ecology and Evolution, 7: 373. http://doi.org/10.3389/fevo.2019.00373 http://doi.org/10.3389/fevo.2019.00373...
Body mass	Trophic level, diet, habitat breath	Colombia, México, Bolivia, Brazil, Costa Rica, Guatemala, Nicaragua, Perú	Human-modified landscapes	*Farneda et al.,* 2019**Farneda, F.Z.; Meyer, C.F.J. & Grelle, C.E.V. 2019. Effects of land-use change on functional and taxonomic diversity of Neotropical bats. Biotropica, 52(1): 120-128.
Body mass, wing loading	Trophic level, dietary specialization, vertical stratification	Manaus, Central Amazon, Brazil	Response to habitat fragmentation	*Farneda et al.,* 2018**Farneda, F.Z.; Rocha, R.; López-Baucells, A.; Sampaio, E.M.; Palmeirim, J.M.; Bobrowiec, P.E.D.; Grelle, C.E.V. & Meyer, C.F.J. 2018. Functional recovery of Amazonian bat assemblages following secondary forest succession. Biological Conservation, 218: 192-199.
Forearm length, aspect ratio, wing load and body mass	foraging guild, main feeding habits, main trophic level	Tocantins State, Central Brazil	Response to human-modified landscapes	*Pereira et al.,* 2018**Pereira, M.; Fonseca, C. & Aguiar, L.M.S. 2018. Loss of multiple dimensions of bat diversity under land-use intensification in the Brazilian Cerrado. Hystrix, 29(1): 25-32.
Body mass, wing aspect ratio, relative wing loading	Trophic level, vertical foraging area	Los Chimalapas, México	Habitat fragmentation	*García-García et al.,* 2014**García-García, J.L.; Santos-Moreno, A. & Kraker-Castañeda, C. 2014. Ecological traits of Phyllostomid bats associated with sensitivity to tropical forest fragmentation in Los Chimalapas, México. Tropical Conservation Science, 7(3): 457-474.
Body weight, forearm, wing loading, aspect ratio	Diet	Hidalgo, México	Response to human-modified landscapes	*García-Morales et al.,* 2016**García-Morales, R.; Moreno, C.E.; Badano, E.I.; Zuria, I.; Galindo-Gonzalez, J.; Rojas-Martínez, A.E. & Ávila-Gómez, E.S. 2016. Deforestation Impacts on Bat Functional Diversity in Tropical Landscapes. Plos One , 11(12): e0166765. http://doi.org/10.1371/journal.pone.0166765 http://doi.org/10.1371/journal.pone.0166...
Body mass, aspect ratio, wing load	Type of food	the Serra da Mantiqueira massif, Minas Gerais and São Paulo, Brazil	Response to elevational gradient	*Mancini et al.,* 2019**Mancini, M.C.S.; Laurindo, R.S.; Hintze, F. Mello, R.M. & Gregorin, R. 2019. Different bat guilds have distinct functional responses to elevation. Acta Oecologica , 96: 35-42.
Weight (body mass), size (forearm), wing morphology (aspect ratio and wing loading)	Dietary specialization	North of the state of Paraná, Brazil	Response to human-modified landscapes	*Pereira et al.,* 2019**Pereira, A.D.; de Lima, I.P. & dos Reis, N.R. 2019. Changes in Bat Diversity in Agrosystems in the Atlantic Rain Forest, Brazil. Mastozoología Neotropical, 26(1): 155-166.
Weight, aspect ratio	Feeding guild, type of shelter used	Minas Gerais and Bahia, Brazil	Response to elevational gradient	*Rodrigues Coelho et al.,* 2018**Rodrigues Coelho, E.; Paglia, A.P.; Viana-Junior, A.B.; Falcão, L.A.D. & Ferreira, G.B. 2018. Species Richness, Abundance and Functional Diversity of a Bat Community along an Elevational Gradient in the Espinhaço Mountain Range, Southeastern Brazil. Acta Chiropterologica , 20(1): 129-138.
Length of third digit, length of fifth digit, forearm length	Size, foraging strategy, foraging habitat, diet	Córdoba, Colombia	Response to human-modified landscapes	Castillo-Figueroa & Pérez-Torres, 2018Castillo-Figueroa, D.; Stukenholtz, E.; Stevens, R.D. & Pérez-Torres, J. 2018. Cases of induced alloparental care in Seba’s short-tailed fruit bat. Neotropical Biology and Conservation, 13(4): 347-349.
Body mass, wingspan, aspect ratio, wing loading	Trophic guild	Villavicencio, Colombia	Response to human-modified landscapes	*Ramírez-Mejía et al.,* 2020**Ramírez-Mejía, A.F.; Urbina-Cardona, J.N. & Sánchez, F. 2020. Functional diversity of phyllostomid bats in an urban-rural landscape: A scale-dependent analysis. Biotropica, 52(6): 1-15. http://doi.org/10.1111/btp.12816 http://doi.org/10.1111/btp.12816...
Body mass, aspect ratio, greatest length, braincase and zygomatic breadth	Degree of frugivory	México, Perú, Brazil, Guatemala	Relation to seed dispersal networks	*Laurindo et al.,* 2020**Laurindo, R.S.; Vizentin-Bugoni, J.; Tavares, D.C.; Mancini, M.C.S.; Mello, R.M. & Gregorin, R. 2020. Drivers of bat roles in Neotropical seed dispersal networks: abundance is more important than functional traits. Oecologia, 193: 189-198.
Aspect ratio, wing loading, forearm length, body mass, breadth across molars, breadth of braincase, condylobasal length, greatest length of skull, maxillary toothrow, postorbital constriction	Diet, foraging location, foraging strategy	Sarapiquí, Costa Rica	Response to human-modified landscapes	*Presley et al.,* 2017**Presley, S.J.; Cisneros, L.M.; Higgins, C.L.; Klingbeil, B.T.; Scheiner, S.M. & Willig, M.R. 2017. Phylogenetic and functional underdispersion in Neotropical phyllostomid bat. Biotropica, 50(1): 135-145.
Weight, forearm lenght, wing loading, aspect ratio, wing tip index, length of the spear, breadth of the spear, length of the horseshoe, breadth of the horseshoe	Trophic guild	Chamela-Cuixmala Biosphere Reserve (CCBR), México	Response to regenerating forests and seasonality	*Martínez-Ferreira et al.,* 2020**Martínez-Ferreira, S.R.; Alvarez-Añorve, M.Y.; Bravo-Monzón, A.E.; Montiel-González, C.; Flores-Puerto, J.I.; Morales-Díaz, S.P.; Chiappa-Carrara, X.; Oyama, K. & Avila-Cabadilla, L.D. 2020. Taxonomic and Functional Diversity and Composition of Bats in a Regenerating Neotropical Dry Forest. Diversity, 12: 332. http://doi.org/10.3390/d12090332 http://doi.org/10.3390/d12090332...
Body mass, wing loading, relative wing loading, aspecto ratio	Diet, peak frequency, bandwidth, call duration, roost duration	Las Cruces Biological Station, Costa Rica	Response to human-modified landscapes	*Frank et al.,* 2017**Frank, H.K.; Frishkoff, L.O.; Mendenhall, C.D.; Daily, G.C. & Hadly, E.A. 2017. Phylogeny, traits, and biodiversity of a Neotropical bat assemblage: Close relatives show similar responses to local deforestation. American Naturalist , 190(2): 200-212.

[1] ²E-mail: dennis.castillof@gmail.com (corresponding author)

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On the development of a trait-based approach for studying Neotropical bats

Abstract