普氏蹄蝠下丘谐波主频神经元的时程选择性

为探讨下丘(Inferior colliculus,IC)回声定位信号主频范围内的神经元的时程选择性,在自由声场刺激条件下,我们在4 只普氏蹄蝠的IC 采用不同时程的声刺激,研究了神经元的时程选择性。通过在体细胞外记录,共获得56 个声敏感下丘神经元,其记录深度、最佳频率和最小阈值的范围分别为1547 - 3967 (2878. 9 ±629.1)μm,20 -68 (49.0 ± 11. 1)kHz 和36.5 -95. 5 (59. 8 ±13. 0)dB SPL。根据所记录到的下丘神经元对不同时程的声刺激的反应,即对不同时程的选择性(Duration selectivity),将其分为6 种类型:短通型(Short-pass,SP,n = 11/56)、带通型(Band-pass,BP,n = 1/56)、长通型(Long-pass,LP,n = 5 /56)、反带通型(Band-reject,BR,n = 3 /56)、多峰型(Multi-peak,MP,n =6 /56)和全通型(All-pass,AP,n =30 /56)或非时程选择型(Nonduration-selective,NDS)。通过比较普氏蹄蝠下丘谐波主频内和主频外神经元的时程选择性,我们发现处于回声定位信号主频范围内神经元(n =32)比主频外神经元(n = 24)具有更短的最佳时程和更高的时程选择性。结果提示,在普氏蹄蝠回声定位过程中谐波主频内神经元较谐波主频外神经元发挥了更为重要的作用。     

普氏蹄蝠下丘谐波内外神经元处理多普勒频移补偿信息的差异

为了探讨普氏蹄蝠下丘神经元在处理多普勒频移补偿后回声定位信号中的作用,实验采用双声刺激模式模拟蝙蝠不同飞行状态下产生多普勒频移补偿后的脉冲-回声对,即发声频率改变,回声频率维持恒定的情况下,研究下丘神经元对不同补偿值下的回声反应恢复率.结果发现:根据神经元在某一补偿值下对回声信号反应的恢复率是否超过70%,可将其分为具有选择性(S)和无选择性(NS)的两类神经元.且谐波内S神经元所占比例(68%)远超过非谐波内S神经元(39%).分析神经元的发放模式发现谐波内S神经元中相位型发放模式比例(44.3%)明显高于其他三种类型神经元.另外,虽然S和NS神经元的强度-潜伏期函数类型均以饱和型为主,但谐波内S神经元强度-潜伏期函数的最佳强度(best amplitude,BA)(95.3±14.0)dB SPL低于NS神经元的BA(104.1±10.2)d B SPL(P0.01),同时也低于非谐波内S神经元的BA(109.7±7.9)dB SPL(P0.01).以上实验结果表明,在下丘水平,神经元就已对多普勒频移补偿后回声定位信号的处理有了分工,集中在谐波内的S神经元通过提高对某一补偿值下回声信号反应的恢复率实现,对回声信息的精确编码,避免其他杂波干扰信息.同时,谐波内S神经元的发放模式和强度-潜伏期函数特点也满足其在复杂环境中精确声学成像的需求.     

六种共栖蝙蝠的回声定位信号及翼型特征的比较

本研究于2006 年5 ～ 8 月在桂林市七星公园七星岩洞进行,比较分析了共栖2 科(蹄蝠科和蝙蝠科)6 种共75 只蝙蝠的回声定位信号和翼型特征。普氏蹄蝠的回声定位叫声为短而多谐波的CF/ FM 型,主频率为61.2±0.8 kHz, 具有高翼载、低翼展比和中等翼尖指数; 大蹄蝠的回声定位叫声为单CF/ FM 型,主频率为68. 6 ±0.7 kHz,具有高翼载、低翼展比和中等翼尖指数;中蹄蝠的回声定位叫声为单CF / FM 型,主频率为85.2 ±0.5 kHz,具有中等翼载、低翼展比和中等翼尖指数;高颅鼠耳蝠的回声定位叫声为长带宽的FM 型,主频率为50.7 ±3.8 kHz,具有低翼载、中等翼展比和低翼尖指数;大足鼠耳蝠回声定位叫声为FM 型,主频率为39.9 ±3.2 kHz,具有中等翼载、低翼展比和高翼尖指数;绒山蝠回声定位叫声为短而多谐波的FM 型,主频率为49.0± 0. 4 kHz,具有高翼载、中等翼展比和低翼尖指数。经单因素方差分析表明,6 种蝙蝠之间绝大部分的形态和声音参数差异显著(One-way ANOVA,P < 0. 05)。以上结果说明,6 种同地共栖蝙蝠种属特异的回声定位叫声
和形态结构体现出了相互之间的生态位分离,从而降低了种间竞争压力,使得6 种蝙蝠能够同地共存。     

菲菊头蝠回声定位信号特征及下丘神经元频率调谐

研究了菲菊头蝠自由飞行状态下的回声定位信号和下丘神经元的声反应特性。菲菊头蝠在自由飞行时发射的CF/FM型回声定位叫声含2-3个谐波,主频为105.3±1.7kHz,时程为39.5±9.6ms,脉冲间隔为73.9±16.0ms。在所记录到的159个下丘神经元中,E型(Echolocation)神经元为32.7%(52/159),其中CF1型(Constantfrequency)占11.3%(18/159),FM1型(Frequencymodulated)占20.1%(32/159),FM2型占1.3%(2/159);NE型(Nonecholocation)神经元的比例为67.3%(107/159)。这些神经元的最佳频率(Bestfrequency,BF)与记录深度之间存在线性关系(r=0.9471,P<0.01)。E型神经元的深度范围为349-1855(1027.5±351.6)μm,阈值范围为6-74(43.1±14.5)dBSPL,潜伏期范围为10.0-26.0(14.6±3.8)ms。NE型神经元的分别为93.0-1745.0(733.3±290.3)μm、2-70(36.5±23.8)dBSPL、5.0-23.0(13.5±3.7)ms。记录到的53个IC神经元的调谐曲线(Frequencytuningcurve,FTC)均为开放型,51个为单峰型,2个为双峰型。单峰型神经元中大部分为狭窄型(Q10dB>5),占70.6%(36/51),E型神经元全部为狭窄型,Q10dB为10.4±7.1(5.5-31.6),其中CF1型为18.3±11.2(5.5-31.6),FM1型为8.7±4.7(5.5-24.3),FM2型为6.9±0.3(6.7-7.1);NE型神经元既有宽阔型也有狭窄型,Q10dB为6.6±5.1(1.6-25.6)。两个双峰型FTC主、副峰分别偏向高、低频区,高频边对应的是E型神经元。     

两种同域分布蹄蝠在开阔度不同的环境中回声定位声波的可塑性

在广西桂林研究了同域分布的大蹄蝠(Hipposideros armiger)和中蹄蝠(H.larvatus)在不同开阔度环境中回声定位声波信号的变化。用超声波仪录制自由悬挂和分别释放于人工"大棚"和"小棚"内飞行的蝙蝠的回声定位声波,使用超声分析软件分析声脉冲时程、主频率及声脉冲间隔,通过重复测量方差分析比较不同状态下的声波参数。结果表明:中蹄蝠声波的主频在悬挂状态下最高,小棚内飞行时次之,大棚内飞行最低;两种蹄蝠声波的脉冲时程和脉冲间隔在悬挂状态下最长,大棚内飞行次之,小棚内飞行最低。总之,这两种蹄蝠的回声定位声波能够随所处状态的变化而变化,可根据生境的复杂度调节声讯号,具有明显的声波可塑性。     

弱噪声对小鼠下丘神经元频率调谐的影响

为探讨弱噪声对小鼠 (MusmusculusKm)中脑下丘 (inferiorcolliculus ,IC)神经元声信号提取的影响 ,采用单位胞外记录方法 ,研究了加入弱白噪声 (强度相当于纯音阈强度下 5dB)前后神经元频率调谐曲线的变化。实验共记录到 10 4个下丘神经元 ,测量了 32个神经元的频率调谐曲线。结果显示 :①弱噪声条件下神经元的频率调谐曲线表现出 3种类型 ,即锐化 (34 4 % ,11/ 32 )、拓宽 (18 8% ,6 / 32 )和不受影响 (4 6 9% ,15 / 32 ) ,其中锐化呈现有意义的变化 ;②频率调谐受弱噪声锐化的神经元 ,其Q10 、Q3 0 平均分别增大 (34 4 2±17 0 4 ) % (P =0 0 2 6 ,n =11)和 (4 6 34± 2 2 88) % (P =0 0 0 9,n =7) ,且Q3 0 变化率大于Q10 ;③弱噪声对调谐曲线的高、低频边锐化度不一 ,神经元低频边的反转斜率基本不变 [由 0 16± 0 0 8变为 0 16± 0 0 7kHz/dB (P =0 94 7,n =7) ],而高频边明显下降 [由 0 5 2± 0 2 5下降为 0 2 6± 0 13kHz/dB ,平均减小 (4 3 81±2 4 0 6 ) % ,(P =0 0 4 6 ,n =7) ]。上述结果表明 ,弱噪声可锐化小鼠IC神经元频率调谐 ,并强化神经元的声信号高频分析能力     

幼小蝙蝠下丘神经元的听反应特性

实验在出生6—8天的8只幼龄鲁氏菊头蝠(Rhinolophus rouxi)上进行。使用玻璃微电极记录中脑下丘听神经元对超声信号的反应。共观察了162个听单位,它们对超声反应的最佳频率分布范围为25.8—60.9千赫,多数集中在43.0—47.0千赫。反应的潜伏期在6.0—38.0毫秒,平均为15.4±5.2毫秒。反应的最低阈值在25—84dB,平均为69.8±10.3dB.这些神经元对超声刺激的调谐曲线都较宽阔,故Q10-dB值都较小。当微电极由下丘表面垂直下插时,所记录到的神经元的最佳频率与记录深度之间不存在相关关系,即没有音调筑构现象。听神经元的这些特性与同种成年动物构成显著差异。     

普氏蹄蝠(Hipposideros pratti)回声定位声波、形态及捕食策略

研究了普氏蹄蝠(Hipposideros pratti)不同状态(飞行、悬挂)下的回声定位声波特征、形态特征和生态特征(捕食策略、捕食地和食物类型).结果表明,普氏蹄蝠的回声定位声波为CFFM型,在不同状态下,主频率有一定的差异,飞行状态的主频率略低于悬挂状态,表明普氏蹄蝠是利用多谱勒补偿效应来适应飞行速度引起的主频率变化,以进行准确的定位和有效的捕食;同时飞行状态下声脉冲时间、声脉冲间隔时间及FM带宽略低于悬挂状态,而声脉冲重复率和能率环略高于悬挂状态,表明普氏蹄蝠在不同状态下利用不同特征的声波进行捕食.由回声定位声波推断和野外观察可知,普氏蹄蝠可能在树冠周围以盘旋方式(在昆虫高峰期)或以捕蝇器式(在昆虫高峰期之后)捕食中等偏大的振翅昆虫(如甲虫).     

五种蝙蝠形态与回声定位叫声的性别差异

为研究角菊头蝠(Rhinolophus cornutus)、三叶蹄蝠(Aselliscus uheeleri)、大蹄蝠(Hipposideros armiger)、大鼠耳蝠(Myotis myotis)和大足鼠耳蝠(M．riketti)的形态和回声定位叫声的性别差异性,明确同种蝙蝠雌雄个体对食物、栖息地等资源利用的细微差异,我们利用超声波探测仪、Batsound分析软件及SPSS11．0统计软件对5种95只蝙蝠进行了录音、声波分析和统计分析。5种蝙蝠形态性别差异性不显著,角菊头蝠、三叶蹄蝠、大蹄蝠和大足鼠耳蝠叫声频率性别差异性显著,大鼠耳蝠叫声频率性别差异性不显著。角菊头蝠雌性叫声的基频、分音、主频率高于雄性,声脉冲时间、间隔时间大于雄性,调频(FM)带宽小于雄性;三叶蹄蝠、大蹄蝠叫声的基频、主频率雄性高于雌性,调频带宽雌性小于雄性;大足鼠耳蝠叫声的主频率雄性高于雌性,FM带宽雌性大于雄性[动物学报49(6)：742～747,2003]。     

菊头幅出生后下丘听神经元反应特性的演化

实验在出生后1周到6周的幼年和成年鲁氏菊头蝠(Rhinolophusrouxi)上进行。结果发现,出生第1周的动物下丘听神经元对超声刺激反应的最佳频率低,潜伏期长,阈值高。它们的平均值分别为:31.24±14.08千赫,16.56±3.83毫秒和74.24±6.22dB。同时,调谐曲线宽阔,Q10-dB值小,其均值为2.34±0.96。随着周令增长,上述特性逐渐改变。到第6周时,最佳频率的均值发展到70.16±19.16千赫,最佳频率分布峰值也移至75—85千赫的高频段,反应潜伏期均值降至8.12±1.86毫秒,阈值均值降至32.82±26.36dB,已出现相当多具有非常陡削调谐曲线的神精元,Q10-dB值在20以上者占到80％,有的高达100以上,已接近成年动物。     

Temporally patterned sound pulse trains affect intensity and frequency sensitivity of inferior collicular neurons of the big brown bat, Eptesicus fuscus

This study examined the effect of temporally patterned pulse trains on intensity and frequency sensitivity of inferior collicular neurons of the big brown bat, Eptesicus fuscus. Intensity sensitivity of inferior collicular neurons was expressed by the dynamic range and slope of rate-intensity functions. Inferior collicular neurons with non-monotonic rate-intensity functions have smaller dynamic ranges and larger slopes than neurons with monotonic or saturated rate-intensity functions. Intensity sensitivity of all inferior collicular neurons improved by increasing the number of non-monotonic rate-intensity functions when the pulse repetition rate of pulse trains increased from 10 to 30 pulses per second. Intensity sensitivity of 43% inferior collicular neurons further improved when the pulse repetition rate of pulse trains increased still from 30 to 90 pulses per second. Frequency sensitivity of inferior collicular neurons was expressed by the Q10, Q20, and Q30 values of threshold frequency tuning curves and bandwidths of isointensity frequency tuning curves. Threshold frequency tuning curves of all inferior collicular neurons were V-shape and mirror-images of their counterpart isointensity frequency tuning curves. The Q10, Q20, and Q30 values of threshold frequency tuning curves of all inferior collicular neurons progressively increased and bandwidths of isointensity frequency tuning curves decreased with increasing pulse repetition rate in temporally patterned pulse trains. Biological relevance of these findings to bat echolocation is discussed.     

在不同状态和生境复杂度中大蹄蝠回声定位叫声的可塑性

蝙蝠回声定位声波的可塑性对其适应不同状态、生境以及捕食和社会交流具有重要的作用。为进一步研究大蹄蝠的回声定位声波在不同状态和生境下的可塑性,通过室内行为实验,对大蹄蝠在4 种不同状态(室内飞行、静息、布袋内和手持)和4 种不同生境复杂度(室外、室内0 棵树、室内1 棵树、室内5 棵树)条件下飞行的回声定位声波特征进行研究。结果表明:大蹄蝠的回声定位声波为CF - FM 型,通常连续发出2 - 4 个脉冲组成一个脉冲组。对比大蹄蝠在4 种不同状态下的回声定位叫声发现,主频按静息、布袋内、手持、飞行的顺序依次降低,后端FM 频宽则按手持、布袋内、飞行和静息的顺序依次变短;而脉冲间隔和脉冲时程则均按静 息、飞行、布袋内、手持的顺序依次增加。对比大蹄蝠在4 种不同生境复杂度中飞行的回声定位叫声发现,主频按室外、室内0 棵树、室内1 棵树、室内5 棵树依次提高,而脉冲时程及脉冲间隔则依次缩短;室外放飞条件下的后端FM 频宽比室内飞行的短。研究结果说明,大蹄蝠在不同状态、不同生境复杂度条件下的回声定位叫声具有明显的可塑性和生境适应性。     

‘Compromise’ in Echolocation Calls between Different Colonies of the Intermediate Leaf-Nosed Bat (Hipposideros larvatus)

Each animal population has its own acoustic signature which facilitates identification, communication and reproduction. The sonar signals of bats can convey social information, such as species identity and contextual information. The goal of this study was to determine whether bats adjust their echolocation call structures to mutually recognize and communicate when they encounter the bats from different colonies. We used the intermediate leaf-nosed bats (Hipposideros larvatus) as a case study to investigate the variations of echolocation calls when bats from one colony were introduced singly into the home cage of a new colony or two bats from different colonies were cohabitated together for one month. Our experiments showed that the single bat individual altered its peak frequency of echolocation calls to approach the call of new colony members and two bats from different colonies adjusted their call frequencies toward each other to a similar frequency after being chronically cohabitated. These results indicate that the ‘compromise’ in echolocation calls might be used to ensure effective mutual communication among bats.     

Prestin Shows Divergent Evolution Between Constant Frequency Echolocating Bats

The gene Prestin encodes a motor protein that is thought to confer the high-frequency sensitivity and selectivity that characterizes the mammalian auditory system. Recent research shows that the Prestin gene has undergone a burst of positive selection on the ancestral branch of the Old World horseshoe and leaf-nosed bats (Rhinolophidae and Hipposideridae, respectively), and also on the branch leading to echolocating cetaceans. Moreover, these two groups share a large number of convergent amino acid sequence replacements. Horseshoe and leaf-nosed bats exhibit narrowband echolocation, in which the emitted calls are based on the second harmonic of a predominantly constant frequency (CF) component, the frequency of which is also over-represented in the cochlea. This highly specialized form of echolocation has also evolved independently in the neotropical Parnell's mustached bat (Pteronotus parnellii). To test whether the convergent evolution of CF echolocation between lineages has arisen from common changes in the Prestin gene, we sequenced the Prestin coding region (~2,212?bp, >99% coverage) in P. parnellii and several related species that use broadband echolocation calls. Our reconstructed Prestin gene tree and amino acid tree showed that P. parnellii did not group together with Old World horseshoe and leaf-nosed bats, but rather clustered within its true sister species. Comparisons of sequences confirmed that P. parnellii shared most amino acid changes with its congeners, and we found no evidence of positive selection in the branch leading to the genus of Pteronotus. Our result suggests that the adaptive changes seen in Prestin in horseshoe and leaf-nosed bats are not necessary for CF echolocation in P. parnellii.     

偏离最佳频率的声信号对几内亚长翼蝠下丘神经元的前掩蔽

为探讨偏离神经元最佳频率(best frequency,BF)的声刺激对下丘神经元的前掩蔽效应,实验选用5只听力正常的几内亚长翼蝠(Miniopterus magnater),记录它们的下丘神经元对偏离BF的掩蔽声和探测声(BF)的反应.结果发现,当掩蔽声向高或低频方向偏离神经元的BF时,掩蔽效应逐渐降低.根据计算出的...     

The effect of sound intensity on duration-tuning characteristics of bat inferior collicular neurons

Previous studies have shown that inferior collicular neurons of the big brown bat, Eptesicus fuscus, serve as short-, band-, long- and all-pass filters for sound durations. Neurons with band-, short- and long-pass filtering characteristics discharged maximally to a specific sound duration or a range of sound durations. In contrast, neurons with all-pass filtering characteristics do not have duration selectivity. To determine if duration-tuning characteristics of collicular neurons were tolerant to changes in sound intensity, we examined the duration-tuning characteristics of collicular neurons using a wide range of sound intensities. Duration-tuning characteristics examined included the type, bandwidth and slope of duration-tuning curves. Sound intensity delivered within 20 dB of minimum threshold did not affect duration-tuning characteristics of all collicular neurons studied. Sound intensities at still higher levels did not affect the tuning characteristics of two-thirds of collicular neurons but decreased the duration selectivity and changed the duration-tuning curves of the remaining one-third of neurons from one type to another. However, these two groups of duration-tuning collicular neurons were not separately organized inside the inferior colliculus. The biological relevance of these findings to bat echolocation is discussed.     

Mechanical adaptations for echolocation in the cochlea of the bat Hipposideros lankadiva

The cochlear mechanics of bats with long constant-frequency components in their echolocation calls are sharply tuned to the dominant second harmonic constant frequency. Hipposiderid bats employ a shorter constant-frequency call component whose frequency is less stable than in long-constant-frequency bats. To investigate to what degree cochlear mechanics in hipposiderid bats are already specialized for the processing of constant frequencies, we recorded distortion-product otoacoustic emissions in Hipposideros lankadiva. Iso-distortion threshold curves for the 2f1-f2 distortion-product otoacoustic emission reveal a threshold maximum close to the second harmonic constant frequency, between 65.0 and 70.0 kHz, and a second insensitivity close to the first harmonic constant frequency. The group delay of the 2f1-f2 distortion is prolonged for both frequency ranges, indicating that a specialized cochlear resonance may act to absorb the constant-frequency call components. Compared to long-constant-frequency bats, the threshold maximum at the second harmonic constant frequency is less pronounced and the optimum cochlear frequency separation is larger. Distortion-product otoacoustic emission suppression tuning curves and neuronal tuning curves recorded from neurons in the cochlear nucleus display an increase of tuning sharpness close to the second harmonic constant-frequency range which is smaller than that reported for long-constant-frequency bats. Our data suggest that the cochlea of hipposiderid bats represents an intermediate state between that of non-specialized bats and long-constant-frequency bats.     

Different Auditory Feedback Control for Echolocation and Communication in Horseshoe Bats

Auditory feedback from the animal''s own voice is essential during bat echolocation: to optimize signal detection, bats continuously adjust various call parameters in response to changing echo signals. Auditory feedback seems also necessary for controlling many bat communication calls, although it remains unclear how auditory feedback control differs in echolocation and communication. We tackled this question by analyzing echolocation and communication in greater horseshoe bats, whose echolocation pulses are dominated by a constant frequency component that matches the frequency range they hear best. To maintain echoes within this “auditory fovea”, horseshoe bats constantly adjust their echolocation call frequency depending on the frequency of the returning echo signal. This Doppler-shift compensation (DSC) behavior represents one of the most precise forms of sensory-motor feedback known. We examined the variability of echolocation pulses emitted at rest (resting frequencies, RFs) and one type of communication signal which resembles an echolocation pulse but is much shorter (short constant frequency communication calls, SCFs) and produced only during social interactions. We found that while RFs varied from day to day, corroborating earlier studies in other constant frequency bats, SCF-frequencies remained unchanged. In addition, RFs overlapped for some bats whereas SCF-frequencies were always distinctly different. This indicates that auditory feedback during echolocation changed with varying RFs but remained constant or may have been absent during emission of SCF calls for communication. This fundamentally different feedback mechanism for echolocation and communication may have enabled these bats to use SCF calls for individual recognition whereas they adjusted RF calls to accommodate the daily shifts of their auditory fovea.     

菲菊头蝠回声定位声波频率的性二态有利于性别识别

许多动物的叫声频率呈现性二态现象。蝙蝠夜间活动,主要利用声音信号导航空间、追踪猎物、传递交流信息。本研究选择成体菲菊头蝠作为研究对象,检验回声定位声波频率性二态是否有利于性别识别。研究发现,菲菊头蝠回声定位声波频率参数具有显著性别差异。播放白噪音、雄性回声定位声波及雌性回声定位声波期间,实验个体的反应叫声数量依次递减。播放白噪音、雌性回声定位声波及雄性回声定位声波后,实验个体的反应叫声数量依次递增。白噪音诱导反应叫声强度高于回声定位声波诱导反应叫声强度。研究结果表明,菲菊头蝠回声定位声波的频率参数编码发声者性别信息,有利于种群内部的性别识别。本研究暗示,回声定位声波可能在蝙蝠配偶选择中扮演一定作用。