电刺激家鸽中脑诱导运动的初步研究

用电刺激方法研究浅麻醉状态下家鸽中脑的不同区域诱发的行为反应,认识家鸽中脑运动相关脑区的空间编码规律。在中脑的半环隆枕(TOS)、丘间核等核团区域诱导出扇动翅膀、呼吸加快、羽毛倒伏等运动行为。     

凹耳蛙的两性异形

测量和比较采自黄山的凹耳蛙成体标本(雌雄各20个),统计结果表明成年雌雄蛙的体长、头宽、吻长、鼻间距、眼间距、眼径、鼓膜宽、前臂及指长、前臂宽等两性形态学指标存在显著性差异。对与体长显著相关的形态特征,以体长为协变量的协方差分析表明凹耳蛙雌雄两性在头宽、眼间距、眼径、鼓膜宽存在显著差异。凹耳蛙两性异形比达到0.418,雌性平均体长对雄性平均体长的比达到1.716。头宽、眼间距、眼径、鼓膜宽等局部形态特征与体长的线性回归分析表明,雌性斜率大于雄性斜率,说明雌性凹耳蛙上述局部特征随体长的生长速率明显大于雄性。雌性体长的繁殖力选择能够很好地解释凹耳蛙的两性异形。     

凹耳臭蛙胚胎发育及其分类学意义(英文)

通过人工受精的方法获得的凹耳臭蛙(Odorrana tormota)的早期胚胎及胚后幼体的发育过程,根据胚胎发育过程中的形态及生理特征变化规律进行分期。把凹耳臭蛙的发育过程分成两个阶段:1)早期胚胎发育阶段,即从蛙卵受精到鳃盖完成期,在18～23℃水温下,凹耳臭蛙早期胚胎发育阶段历时324h;2)蝌蚪发育阶段,即从鳃盖完成期结束到尾部被完全吸收,本阶段在20～24℃水温条件下历时1207h。凹耳臭蛙蝌蚪未发现腹吸盘特征,从形态特征上支持了分子系统分类学将之从湍蛙属划出的观点。实验中发现,多数胚胎在8细胞期为纬裂,16细胞期为经裂,同时有小部分胚胎(1.5%)在8细胞期为经裂,16细胞期为纬裂。该文进一步讨论了影响卵裂率、孵化率、发育速度,以及生态适应的因素。     

雄性凹耳蛙不同合唱期鸣声特征的变化

声音通讯在凹耳蛙(Odorrana tormota)的繁殖过程中起到关键作用,雄性凹耳蛙个体处于不同性选择压力下会采取不同的发声策略,然而相关研究仍缺乏。本实验采用个体标记法,基于2021年3-5月的野外实验,对雄性凹耳蛙个体(n=12)处于合唱高潮期和低潮期鸣声中的非线性发声现象(nonlinear vocal phenomena,以下简称NLP)总含量及其各组分(混音、半谐波、频率跳跃)含量、鸣声时长以及鸣叫频次之间的差异进行Wilcoxon符号秩检验。结果显示,雄蛙处于合唱高潮期和低潮期鸣声中的部分NLP组分(混音、半谐波)含量以及鸣声时长均没有显著性差异,合唱低潮期的NLP总含量、部分NLP组分(频率跳跃频次)显著大于高潮期,合唱高潮期的发声率显著大于低潮期。实验结果表明,雄性凹耳蛙不同合唱期会采取不同的发声策略,即性选择压力较小的低潮期通过提高鸣声中的NLP含量、扩大声音传播距离、增大声音的不可预测性来更好吸引雌性;高潮期性选择压力大时,雄蛙通过提高鸣叫频次使得个体鸣声更加突出,从而提高抱对成功率。     

鸣禽控制发声核团和脑干听觉核团及神经通路…

采用辣根过氧化物酶顺、逆行标记方法对鸣禽鸟蜡嘴雀控制发声的神经核团、脑干听觉核团及神经通路,从外周至中枢逐级进行了追踪研究。结果表明：１．控制发声的神经核团及通路,前脑古纹状体腹内侧粗核是大脑控制发声的重要核团之一,它发出枕中脑后束经端脑前联合呈双侧支配延脑中间核,中间核又发出舌下神经经气管鸣管分支支配鸣肌,中间核同时也接受中脑背内侧核的支配;２．脑干听觉中枢及通路,中脑背外侧核是脑干较高级听觉中     

鸣禽控制发声核团和脑干听觉核团及神经通路的综合研究

采用辣根过氧化物酶顺、逆行标记方法对鸣禽鸟蜡嘴雀控制发声的神经核团、脑干听觉核团及神经通路,从外周至中枢逐级进行了追踪研究。结果表明：１．控制发声的神经核团及通路,前脑古纹状体腹内侧粗核是大脑控制发声的重要核团之一,它发出枕中脑后束经端脑前联合呈双侧支配延脑中间核,中间核又发出舌下神经经气管鸣管分支支配鸣肌,中间核同时也接受中脑背内侧核的支配,２．脑干听觉中枢及通路,中脑背外侧核是脑干较高级听觉中枢、初级中枢耳蜗核由角核和前庭外侧核组成,ＮＡ发出以对侧为主的纤维经外侧丘系可直接传入中脑背外侧核形成脑干听觉直接通路。     

非线性鸣声对雄性凹耳蛙应答的影响

为了解非线性鸣声对凹耳蛙(Odorrana tormota)应答音的影响以及非线性鸣声是否能够增强鸣声的不可预测性,本研究通过回放非线性鸣声和线性鸣声来刺激陌生雄性凹耳蛙,并记录应答次数及统计分析应答音相关参数。结果表明,回放非线性鸣声时会引起陌生蛙(n=22)更多次数的应答,但两种刺激引起的首次应答时间没有显著差异。对应答音相关参数分析表明,线性鸣声引起的应答音在总时长上比非线性鸣声引起的应答音更长且具有显著差异,而其他声音参数(包括平均基频、最大基频、最小基频、主频)均没有显著差异。推测当陌生雄蛙听到同类鸣叫时,出于保护领地和资源的本能反应,陌生蛙都会第一时间作出反应,因此在两类声音的应答反应时间上并没有区别。而在应答次数上,非线性鸣声引起了凹耳蛙更多次数的应答,可能是由于鸣声中的非线性现象使得声音更加复杂,包含更多信息,容易提高声音接收者对这类声音的关注度。本研究结果表明,凹耳蛙鸣声中包含的非线性现象能够增强其声音的不可预测性,引起陌生蛙产生更多的应答次数。     

基于12S rRNA基因序列探讨凹耳蛙(无尾目,蛙科)的分类地位

为探讨凹耳蛙Rana tormotus的分类地位,测定了凹耳蛙线粒体12S rRNA基因序列,并从GenBank中下载了蛙科33种蛙的同源序列进行分析,用BI法、NJ法和MP法构建分子系统树.结果表明:3种树拓扑结构基本一致,都显示凹耳蛙与长吻胡湍蛙Huia nasica亲缘关系最近,凹耳蛙与长吻胡湍蛙相聚后再与臭蛙Odorrana组成单系群,而与湍蛙Amolops亲缘关系较远.据此,支持将该蛙从湍蛙属划出,并建议归入臭蛙属.     

1例雄性朱鹮脑内脑啡肽的免疫组织化学分布

用免疫组织化学方法研究脑啡肽(ENK)在极危物种朱(Nipponia nippon)脑内的分布,结合计算机图像分析仪检测免疫阳性细胞和末梢的灰度值。ENK阳性细胞、纤维和终末分布如下:发声核团有原纹状体中间区腹部、丘脑背内侧核外侧部、中脑丘间核、中脑背内侧核、延髓舌下神经核。听觉中枢有丘脑卵圆核壳区、中脑背外侧核壳区、脑桥外侧丘系腹核、上橄榄核、耳蜗核等。内分泌核团有视前区前核、旧纹状体增加部、下丘脑外侧核、下丘脑腹内侧核等。结果表明,朱脑内ENK可能对发声、听觉和下丘脑内分泌的生理活动有一定的调制作用。     

黄雀发声核团与部分听觉中枢内P物质的分布和性双态比较

用免疫组织化学方法研究P物质在雌雄黄雀发声控制核团和听觉中枢内的分布,结合计算机图像分析仪检测SP免疫阳性细胞和末梢的灰度值,并作雌雄比较。结果如下:1.在发声学习中枢嗅叶X区有大量的SP阳性神经末梢和一些神经细胞。2.在发声控制核团前脑高级发声中枢(HVc)、古纹状体栎核、发声学习中枢新纹状体巨细胞核和丘脑背内侧核外侧部内有许多的SP免疫阳性细胞。3.在发声控制中枢中脑背内侧核和延髓舌下神经核气管呜管部、听觉中枢丘脑卵圆核的壳区、中脑背外侧核壳区及中脑丘间核等有密集的SP免疫阳性神经末梢和纤维分布;雄性发声中枢内SP的分布比雌性丰富,两者有显著的差异。结果表明:SP的分布在雌雄发声中枢之间存在显著的性双态;SP广泛分布于黄雀发声控制核团和部分听觉中枢内,提示SP可能在发声控制及听觉中枢内具有重要的生理功能。     

Auditory sexual difference in the large odorous frog Odorrana graminea

Acoustic communication is an important behavior in frog courtship. Male and female frogs of most species, except the concave-eared torrent frog Odorrana tormota, have largely similar audiograms. The large odorous frogs (Odorrana graminea) are sympatric with O. tormota, but have no ear canals. The difference in hearing between two sexes of the frog is unknown. We recorded auditory evoked near-field potentials and single-unit responses from the auditory midbrain (the torus semicircularis) to determine auditory frequency sensitivity and threshold. The results show that males have the upper frequency limit at 24 kHz and females have the upper limit at 16 kHz. The more sensitive frequency range is 3–15 kHz for males and 1–8 kHz for females. Males have the minimum threshold at 11 kHz (58 dB SPL), higher about 5 dB than that at 3 kHz for females. The best excitatory frequencies of single units are mostly between 3 and 5 kHz in females and at 7–8 kHz in males. The underlying mechanism of auditory sexual differences is discussed.     

Auditory response characteristics of the piebald odorous frog and their implications

The piebald odorous frog (Odorrana schmackeri), the large odorous frog (Odorrana livida) and the concave-eared torrent frog (Amolops tormotus) are sympatric species living near the same torrent streams in the vicinity of Mt. Huangshan, China. A recent study demonstrated that A. tormotus can use sound signals involving ultrasonic components for communication in a noisy environment, and another sympatric species, O. livida, can also perceive ultrasonic sound. Here we report data on the hearing range of O. schmackeri by studying auditory evoked potentials and single-unit data from the torus semicircularis. This frog exhibits its two most sensitive peaks at 2 kHz and 3.5–4.0 kHz with thresholds <42 dB SPL, with an upper frequency limit of hearing at 8.5 kHz with threshold of 87 dB SPL. The upper limit is much lower than those of O. livida and A. tormotus, at 22 and 34 kHz, respectively. It suggests that sympatric species may respond differently to similar environmental selection pressures sculpting auditory communication systems.     

四种细胞因子在中华蟾蜍脑中的分布

采用免疫组织化学SABC法,研究白介素-1α、干扰素-γ、神经生长因子-β和肿瘤坏死因子-α在成体中华蟾蜍脑中的表达和分布特点。结果发现,白介素-1α阳性细胞数量很多,分布于脑的各个区域。白介素-1α多在细胞的胞体中,而原始海马锥体细胞,中脑的背前侧被盖核和腹后侧被盖核中的细胞可见阳性的突起。干扰素-γ阳性细胞数量较多,分布在端脑的原始海马和隔区,丘脑腹外侧核,下丘脑的视前区、视交叉上核和腹侧漏斗核,中脑被盖的背前侧被盖核、腹前侧被盖核、背后侧被盖核和腹后侧被盖核中,小脑的Purkinje细胞层和延髓的网状核,其中原始海马,背前侧被盖核和背后侧被盖核,视交叉上核,Purkinje细胞层和网状核中的细胞中可见阳性突起。神经生长因子-β阳性细胞数量较少,主要存在于下丘脑的视前区和视交叉上核,中脑被盖的腹前侧被盖核,小脑的Purkinje细胞层和延髓的网状核中,其中视前区、Purkinje细胞层和网状核中细胞可见阳性突起。肿瘤坏死因子-α阳性细胞数量最少,分布范围仅限于中脑被盖背前侧区和延髓的网状核及中缝核,但细胞具有阳性突起。因此,白介素-1α和干扰素-γ在成体动物脑中分布较为广泛,可能是神经细胞生命活动所必需的;而神经生长因子-β和肿瘤坏死因子-α在成体动物脑中分布范围狭窄,其作用可能仅限于脑中的某些特殊区域。     

Localization of three types of arginine vasotocin receptors in the brain and pituitary of the newt Cynops pyrrhogaster

The distribution of three types of arginine vasotocin (AVT) receptors in the brain and pituitary of the newt Cynops pyrrhogaster, namely, the V1a-, V2-, and V3/V1b-type receptors, was studied by means of in situ hybridization and immunohistochemistry. mRNA signals and immunoreactive cells for the V1a-type receptor were observed in the telencephalon (mitral layer of the olfactory bulb, dorsal and medial pallium, lateral and medial amygdala, bed nucleus of the decussation of the fasciculus telencephali, bed nucleus of the stria terminalis), diencephalon (anterior preoptic area, magnocellular preoptic nucleus, suprachiasmatic nucleus, ventral thalamus, dorsal and ventral hypothalamic nucleus), mesencephalon (tegmentum, interpeduncular nucleus), and medulla oblongata (median reticular formation, nucleus motorius tegmenti). Cells expressing the V2-type receptor were found in the telencephalon (medial pallium, lateral and medial amygdala, bed nucleus of the decussation of the fasciculus telencephali), and mesencephalon (tegmentum trigemini and facialis). In the paraphysis (possibly the main site of cerebrospinal fluid production), only V2-type receptor mRNA signal and immunoreactivity were detected. V3/V1b-type receptor mRNA was expressed in the diencephalon (dorsal hypothalamic nucleus, nucleus tuberculi posterioris), mesencephalon (tegmentum, interpeduncular nucleus), and medulla oblongata (raphe nucleus), whereas V3/V1b-type-receptor-like immunoreactivity was scarcely detectable in the entire brain. The V3/V1b-type receptor was predominantly expressed in the anterior pituitary. V3/V1b-type receptor and proopiomelanocortin mRNAs were co-localized in the distal lobe of the pituitary. This is the first report of the distribution of three types of AVT receptor in the brain and pituitary of non-mammalian vertebrates.     

Ultrasound-evoked immediate early gene expression in the brainstem of the Chinese torrent frog, <Emphasis Type="Italic">Odorrana tormota</Emphasis>

The concave-eared torrent frog, Odorrana tormota, has evolved the extraordinary ability to communicate ultrasonically (i.e., using frequencies > 20 kHz), and electrophysiological experiments have demonstrated that neurons in the frog’s midbrain (torus semicircularis) respond to frequencies up to 34 kHz. However, at this time, it is unclear which region(s) of the torus and what other brainstem nuclei are involved in the detection of ultrasound. To gain insight into the anatomical substrate of ultrasound detection, we mapped expression of the activity-dependent gene, egr-1, in the brain in response to a full-spectrum mating call, a filtered, ultrasound-only call, and no sound. We found that the ultrasound-only call elicited egr-1 expression in the superior olivary and principal nucleus of the torus semicircularis. In sampled areas of the principal nucleus, the ultrasound-only call tended to evoke higher egr-1 expression than the full-spectrum call and, in the center of the nucleus, induced significantly higher egr-1 levels than the no-sound control. In the superior olivary nucleus, the full-spectrum and ultrasound-only calls evoked similar levels of expression that were significantly greater than the control, and egr-1 induction in the laminar nucleus showed no evidence of acoustic modulation. These data suggest that the sampled areas of the principal nucleus are among the regions sensitive to ultrasound in this species.     

Ascending and descending efferent pathways of the midbrain reticular formation of the cat (radioautographic study)

By means of the anterograde axoplasmic transport technique for a mixture of labelled aminoacids (3H-leucine and 3H-proline), ascending and descending systems of the reticular formation fibers in the cat mesencephalon have been studied. Projections from the mesencephalon reticular formation (MRF) ascend to the subthalamus, lateral, dorsal and periventricular hypothalamus, to the periventricular nuclei of the midline and to the intralaminar nuclei of the thalamus. The descending pathways project to the grey substance surrounding the aqueduct of cerebrum, locus coeruleus, parabrachial region and reticular formation of the pons and medulla oblongata. The projections to the reticular nucleus of the thalamus, ventral nucleus of the external geniculate body and superior colliculi arise from the dorsal half of the MRF, and projections to the striatum, lateral reticular nucleus of the medulla oblongata--from its ventral half. Most of the structures are reciprocally connected with the MRF.     

Changes in Electroencephalogram Approximate Entropy Reflect Auditory Processing and Functional Complexity in Frogs

Brain systems engage in what are generally considered to be among the most complex forms of information processing. In the present study, we investigated the functional complexity of anuran auditory processing using the approximate entropy(Ap En) protocol for electroencephalogram(EEG) recordings from the forebrain and midbrain while male and female music frogs(Babina daunchina) listened to acoustic stimuli whose biological significance varied. The stimuli used were synthesized white noise(reflecting a novel signal), conspecific male advertisement calls with either high or low sexual attractiveness(reflecting sexual selection) and silence(reflecting a baseline). The results showed that 1) Ap En evoked by conspecific calls exceeded Ap En evoked by synthesized white noise in the left mesencephalon indicating this structure plays a critical role in processing acoustic signals with biological significance; 2) Ap En in the mesencephalon was significantly higher than for the telencephalon, consistent with the fact that the anuran midbrain contains a large well-organized auditory nucleus(torus semicircularis) while the forebrain does not; 3) for females Ap En in the mesencephalon was significantly different than that of males, suggesting that males and females process biological stimuli related to mate choice differently.     

Evaluation of Postspike Changes in Neuronal Excitability by Comparing Ordinary and Shuffled Autocorrelation Functions

Responses of single neurons to tonal signals amplitude-modulated by repeating segments of lowfrequency noise were studied in the dorsal (cochlear) medullary nucleus and midbrain auditory center (torus semicircularis) of the grass frog Rana temporaria. An autocorrelation function of the response to a total presentation and a shuffled autocorrelation function were derived. The latter was obtained by correlating the impulse response to each segment of the modulated signal with responses to all other segments with the exception of the initial one. After the necessary normalization, the function differed from the initial autocorrelation only in lacking postspike changes in excitability. A delay dependence of the ratio of the two functions directly demonstrated the time course of the postspike change in excitability of the studied cell. The majority of second-order neurons, which are in the dorsal nucleus of the medulla oblongata, were characterized only by brief intervals of absolute and relative refractoriness. However, cells with excitability that was markedly facilitated immediately after the refractory period were observed even in this nucleus. Neurons with a complex pattern of postspike changes in excitability were detected in the torus semicircularis. In these cells, a comparatively long postspike decrease in excitability was usually interrupted by intervals in which the neuron sensitivity was significantly higher than normal. The results demonstrate that spike generation has a marked effect on subsequent activity in brainstem auditory units. The effects may play an important role in the formation of the temporal pattern of neuronal responses to auditory signals.