Introduction
Most bats rely on the emission of echolocation calls for survival. In aerial insectivorous species, individuals must be capable of producing high-frequency sounds and process spatial information from the echoes produced in order to catch insects successfully during their early flights (Moss et al. 1997). Thus, sounds emitted during the first days after birth may be the precursors of echolocation behavior in adult bats (Moss et al. 1997; Zhang et al. 2005). In most cases, there is a correlation between postnatal development and the type of calls emitted by young bats (Brown and Grinnell 1980). In general, young bats emit long-duration, high-intensity and low-frequency pulses, relative to the sounds emitted by adults (Brown and Grinnell 1980; Rubsamen 1987; Monroy et al. 1995; Zhang et al. 2005; Liu et al. 2007). This differentiation of pulses between bats of different age might make it easier for juveniles to recognize adult individuals and follow them to suitable foraging grounds (Kazial et al. 2001).
Works describing the development of vocalizations during postnatal growth, which include species of families Vespertilionidae (Moss et al. 1997; Zhang et al. 2005), Hipposideridae (Habersetzer and Marimuthu1986), Rhinolophidae (Rubsamen 1987; Liu et al. 2007), Noctilionidae (Brown et al. 1983), Mormoopidae (Veter et al. 2003) and Phyllostomidae (Carter et al. 2013) show a general pattern in the development of echolocation, consisting of a steady increase in frequencies and a reduction of the temporal patterns of pulses. In Mexico, there is virtually no research work addressing the relationship between postnatal growth and the development of echolocation. In this sense, the maternity colony of M. velifer that congregates each year at El Salitre cave, Morelos, offers an opportunity to describe in quantitative terms the pulses of echolocation calls produced by Myotis velifer (J. A. Allen, 1890), a species widely studied in United States but not in Mexico, during postnatal growth.
Methods
The study was conducted during June and July, 2016, in El Salitre cave, located in the municipality of Tlaltizapán, Morelos, Mexico (18° 45’ 00.3’’ N, 99° 11’ 23.3’’ W). Individuals (juvenile and adult bats) were captured with a hand net in the maternity colony that is established each year inside the cave, and were subsequently placed inside cotton cloth bags. After capture, the forearm length (FL) of each individual was measured with a CD-8’’CS digital caliper (Mitutoyo Corporation, Japan); additionally, each individual was sexed and sorted into one of 5 age categories (see Results), according to the ossification of phalanges, morphological traits and ability to fly.
A flight simulation experiment was conducted outside of the cave, consisting in rising each individual bat up to a height of two meters, and then dropping it in front of a full-spectrum Echo Meter 3+ ultrasound detector (Wildlife Acoustics, Inc, USA.) set up to record at a sample rate 256 kHz/16-bit resolution and a 1x time expansion (real time). The detector was placed at two meters from the drop point with an inclination of 40º to ensure the capture and recording of echolocation pulses emitted by each bat released. To avoid potential injuries to individuals who were unable to fly, a soft surface was placed on the landing area. This technique has been used in previous studies to record vocalizations of juvenile bats with no reports of apparent harm (e.g. Moss et al. 1997). At the end of the sound recordings, juveniles that were unable to fly were returned to the nursery colony by placing them in the same site of capture, while those able to fly entered the cave by themselves.
The recordings were analyzed using the software BatSound Pro 3.30 (Pettersson Elektronik, AB, Sweden). From the acoustic files, high-quality echolocation sequences were selected (those with an energy of at least 20 dB, as measured within the power spectrum) and with more than 10 pulses. By means of an expanded-time spectrogram (10x), a 16-bit resolution, a sample rate of 22,050 kHz, and using a Hanning-type window with 1024 Fourier transformations (FFT) and 95% overlap (Rizo-Aguilar et al. 2015), six quantitative characteristics of pulses were measured according to the diagram and description of Rivera-Parra and Burneo (2013): initial frequency, mid-pulse frequency, final frequency, bandwidth, duration, and interval. A sequence involving between 10 and 20 pulses was measured from each individual bat to record variations in each bat evaluated. Statistical analyses were conducted using the average values of each characteristic measured.
The changes in the variables of echolocation pulses were related to postnatal growth of offspring using forearm length as an indicator of age (Rajan and Marimuthu 1999; Sharifi 2004). The relationship between the changes in the pulse parameters measured and the increase in forearm size was described through a simple linear regression analysis for each variable using the program Statistica (Statsoft 2001 7); outlier data were previously eliminated through a exploratory data analysis. In order to meet the normality assumption, data were transformed to natural logarithms.
Results
A total of 136 individuals were captured (75 females and 61 males). Of these, 21 had no hair and had not opened the eyes yet ( = 23.35 mm, class 1); 35 showed signs of hair and teeth growth, and during the recording experiment these individuals fluttered before and during the fall (LA = 28.99 mm, class 2); 43 had well-defined teeth and pelage, but were unable to fly (LA = 37.63 mm, class 3); 26 showed non-ossified phalanx epiphyses but were able to fly (LA = 64.95 mm, class 4 or subadults); and 11 were considered as adults ( = 44.81 mm, class 5).
The echolocation pulses of M. velifer during postnatal growth are short-lasting and of modulated frequency (Figure 1). In case of class-1 juvenile bats, the initial frequency was relatively low ( = 56.86 kHz) compared with the one used by class-5 individuals = 83.73 kHz). Similarly, the bandwidth changed over time, with a steady increase in the range of frequencies used from class 1 ( = 24.33 kHz) to class 5 ( = 50.52 kHz). By contrast, the duration of pulses was reduced drastically from class 1 to class 2, shifting from 11.58 to 4.71 ms. From class 2, the duration of pulses showed a slight variation. The mean range shifted from 152.11 ms for class-1 to 93.64 ms for class-5 bats.
The statistical analyses (Table 1) showed a significant positive relationship (P < 0.001) between forearm length and initial frequency, mid-pulse frequency, and bandwidth, indicating that these variables increased as juvenile bats grew. In addition, there was a significant negative relationship (P < 0.001) between forearm length and the duration and interval of pulses, indicating that the time parameters of pulses decreased as juvenile bats grew. However, in the case of the final pulse frequency there was no correlation (P = 0.879) with forearm length of juvenile bats; hence, this variable remained virtually unchanged throughout the early growth stages to adulthood.
Discussion
Our results show that the postnatal development of echolocation in M. velifer follows a pattern that resembles the one described for other bat species, consisting in a steady rise in frequencies and a shortening in the temporal patterns of pulses as juvenile bats grow (Brown and Grinnell 1980; Brown et al. 1983; Habersetzer and Marimuthu 1986; Rubsamen 1987; Moss et al. 1997; Liu et al. 2007).
The youngest (class 1) bats emitted sounds of relatively low frequencies and long duration, compared to pulses emitted by adults (initial frequency, 44.5-91.6 kHz). These calls may be the precursors of echolocation sounds used by adults, that is, there is likely a gradual learning process in the use and modulation of the high frequencies (Moss et al. 1997; Zhang et al. 2005). The adjustment of increasing frequencies could also be due to the maturation of the larynx. For instance, it is known that in vespertilionid bats, the frequency and duration of calls are controlled by the contraction and relaxation of the cricothyroid muscles surrounding the larynx and controlling the strain of the vocal cords (Gould 1975; Moss et al. 1997).
These findings also revealed a steady increase in the bandwidth of echolocation pulses as juvenile bats grow. The modulated frequency and broadband pulses recorded for subadults (class 4) and adults (class 5) allow the precise location of prey and provide information related to its shape and texture (Schnitzler and Kalko 2001; Altringham 2011). In particular, the increased bandwidth may be related to the development of the echolocation system to capture insects in closed environments as bats grow and feed by themselves.
The drastic reduction in the temporal parameters of pulses throughout the postnatal development of juvenile bats can be attributed to the maturation of the organs involved in sound emission and reception (Monroy et al. 1995; Moss et al. 1997), or to the learning process to interpret the information transmitted by the echoes of calls emitted, as both pulse duration and the interval between pulses are adjusted according to the distance between the bat and its hunting target (Neuweiler, 2000).