The cercal receptor system of the praying mantid,Archimantis brunneriana Sauss.

Summary The cerci of the praying mantid, Archimantis brunneriana Sauss., are paired segmented sensory organs located at the tip of the abdomen. Basally the cercal segments are slightly flattened dorso-ventrally and are fused to such a degree that it is difficult to distinguish them. Distally the segments become progressively more flattened laterally and their boundaries become more obvious.Two types of sensilla are present on the cerci, trichoid sensilla and filiform sensilla. Trichoid hairs are longest on the medial side of the cerci and toward the cercal base. On the proximal cercal segments they are grouped toward the middle of each segment while they are more uniformly distributed on the distal segments. Filiform sensilla are found at the distal end of each segment except the last and are most abundant on the middle segments of the cercus. Both the number of cercal segments and the number of sensilla are variable. Trichoid hairs are highly variable in appearance from short and stout to long and thin. They arise from a raised base, have a fluted shaft, and some have a pore at the tip. They are innervated by from one to five dendrites, one of which is always considerably larger than the others. Some of the dendrites continue out into the shaft of the hair.Filiform hairs have fluted shafts and are mounted in a flexible membrane within a cuticular ring in a depression. They are innervated by a single large sensory neuron, the dendrite of which passes across a flattened area on the inner wall of the lumen of the hair. The dendritic sheath forms the lining of the ecdysial canal and is therefore firmly attached to the hair. The dendrite is attached to the sheath by desmosomes distally and is penetrated by projections of the sheath more proximally. A fibrous cap surrounds the dendrite and may hold it in place relative to the hair.The cercal receptor system of Archimantis is compared to those of cockroaches and crickets.     

Sensing the effect of body load in legs: responses of tibial campaniform sensilla to forces applied to the thorax in freely standing cockroaches

Sense organs in the legs that detect body weight are an important component in the regulation of posture and locomotion. We tested the abilities of tibial campaniform sensilla, receptors that can monitor forces in the cockroach leg, to encode variations in body load in freely standing animals. Small magnets were attached to the thorax and currents were applied to a coil below the substrate. Sensory and motor activities were monitored neurographically. The tibial sensilla could show vigorous discharges to changing forces when animals stood upon their legs and actively supported the body weight. Firing of individual afferents depended upon the orientation of the receptors cuticular cap: proximal sensilla (oriented perpendicular to the leg axis) discharged to force increases while distal receptors (parallel to the leg) fired to decreasing forces. Proximal sensillum discharges were prolonged and could encode the level of load when increases were sustained. Firing of the trochanteral extensor motoneuron was also strongly modulated by changing load. In some postures, sensillum discharges paralleled changes in motor frequency consistent with a known interjoint reflex. These findings demonstrate that tibial campaniform sensilla can monitor the effects of body weight upon the legs and may aid in generating support of body load.     

Possible coevolution of male and female genital form and function in a calopterygid damselfly

In this paper some evolutionary changes of genitalia in the damselfly Calopteryx haemorrhoidalis are investigated by determining their current and past function. Calopteryx haemorrhoidalis males stimulate females by aedeagal frictioning on a set of vaginal sensilla. The aedeagus is considerably variable and positively correlates with volumes of ejected sperm from the spermatheca. Interestingly, females show a significantly reduced sensillum number compared with other family members. Here I explore whether there existed directional selection for aedeagal width at its evolutionary onset; and whether the sensillum reduction evolved to make sperm ejection less effective. Using C. haemorrhoidalis aedeagi in females whose species retained the ancestral conditions (no stimulatory ability and large sensillum numbers), Hetaerina cruentata and C. xanthostoma, my results corroborated these assumptions: variation in aedeagal width inversely correlated with sperm ejection rate while sperm ejection was higher in species with high sensillum numbers. A suggested coevolutionary interpretation of these results in C. haemorrhoidalis is that aedeagal width was favoured which was followed by a sensillum reduction.     

Encoding of forces by cockroach tibial campaniform sensilla: implications in dynamic control of posture and locomotion

Forces exerted by a leg in support and propulsion can vary considerably when animals stand upon or traverse irregular terrains. We characterized the responses of the cockroach tibial campaniform sensilla, mechanoreceptors which encode force via strains produced in the exoskeleton, by applying forces to the leg at controlled magnitudes and rates. We also examined how sensory responses are altered in the presence of different levels of static load. All receptors exhibit phasico-tonic discharges that reflect the level and rate of force application. Our studies show that: (1) tonic discharges of sensilla can signal the level of force, but accurate encoding of static loads may be affected by substantial receptor adaptation and hysteresis; (2) the absolute tonic sensitivities of receptors decrease when incremental forces are applied at different initial load levels; (3) phasic discharges of sensilla accurately encode the rate of force application; and (4) sensitivities to changing rates of force are strictly preserved in the presence of static loads. These findings imply that discharges of the sensilla are particularly tuned to the rate of change of force at all levels of leg loading. This information could be utilized to adapt posture and walking to varying terrains and unexpected perturbations. Accepted: 8 January 2000     

Cuticular sensory receptors on the antenna and maxillary palp of a fly larva, Nephrotoma suturalis (Diptera: Tipulidae)

Abstract. The apex of the larval antenna of the crane fly Nephrotoma suturalis has 6 cuticular sensilla that stained intensely black with silver nitrate, which indicates their porosity. The large sensory cone is innervated by 14 neurons and the 3 small, smooth surfaced, conical pegs have 4 neurons each. The small and large cylindrical sensilla with their smooth walls and pleated apices are innervated by 4 and 6 nerve cells, respectively. The 15 sensilla on the apex of the maxillary palp are all stained by silver nitrate. These sensilla are of five types: 7 type A sensilla with a smooth surface, a distinct apical pore, and 3 or 4 neurons; 2 type B sensilla with a smooth surface, many pores, and 5 neurons; 1 type C sensillum with a grooved surface, a large apical pore, smaller pores in the grooves, and 6 neurons; 3 type D sensilla with a smooth surface, a grooved apex that is elongated into a projection, and 4 neurons; 2 type E sensilla with many pores covering the surface, leaf-like appearance, and 4 neurons. The number and types of sensilla are similar to those in other nematocerous larvae, but in the many different forms of sensilla and the structure of the sensory cone, these tipulid larvae differ greatly from other larvae of lower Diptera.     

Structural and functional classification of antennal sensilla of the cockroach,Leucophaea maderae

Summary Antennal sensilla of Leucophaea maderae were investigated electrophysiologically, labeled and then examined with the scanning or transmission electron microscope. The sensilla can be classified into morphological types according to their external shape and the structure of their hair wall. Sensilla showing similar reaction spectra of their cells can be cathegorized into physiological groups. The morphological classification corresponds to the physiological grouping: one morphological type of sensillum comprises one or several groups of physiologically similar sensilla. In many of these groups constant combinations of physiologically different cells occur. The possible functional significance of the relationships found between the structural features of the sensilla and the physiological properties of their sensory cells is discussed.Supported by the Deutsche Forschungsgemeinschaft (Scha 292/1)     

桔小实蝇本地寄生蜂长尾全裂茧蜂成虫

应用扫描电镜（SEM）对桔小实蝇本地寄生蜂长尾全裂茧蜂 Diachasmimorpha longicaudata (Ashmead) 成虫的触角感器进行观察。结果表明：长尾全裂茧蜂成虫触角由柄节、梗节和鞭节组成,鞭节共 49-52小节。在触角上共有 8种感器,分别为 Bhm鬃毛、毛形感器、刺形感器、锥形感器、板形感器、腔锥形感器、钟形感器、嗅孔。毛型感器是主要感器,数量多且分布广,其次为板形感器。除了腔锥形感器 Ⅱ外,雌雄蜂没有明显的二型现象。     

小菜蛾成虫喙管感器的超微结构及其神经元中枢投射

【目的】明确小菜蛾Plutella xylostella成虫喙管感器的形态结构及感器神经元的投射。【方法】利用扫描电子显微镜观察小菜蛾成虫喙管结构和感器,利用神经回填技术和激光共聚焦显微镜观察喙管感器神经元在脑部的投射。【结果】小菜蛾成虫喙管上存在毛形感器(两种亚型)、腔锥形感器、锥形感器、刺形感器和栓锥形感器5种不同类型的感器。毛形感器表面光滑,分布于外颚叶外侧,可分为毛形感器Ⅰ型和Ⅱ型两种亚型,其中Ⅰ型比Ⅱ型长;锥形感器分布于喙管外表面,由一个感觉锥和一个短的圆形基座组成;腔锥形感器仅分布于食管内侧,只有一个粗短感觉锥而无基座;刺形感器由一个细长的感觉毛和一个圆形基座组成,表面无孔,分布于喙管的外表面;栓锥形感器是昆虫喙管上最典型的感受器,集中分布于喙管顶端区域,感器顶部凹腔伸出一个单感觉锥。此外,喙管上的感觉和运动神经元投射到初级味觉中枢咽下神经节。【结论】本研究阐明了小菜蛾成虫喙管感器的类型、分布和形态特征及其感器神经元在脑部的投射形态,为深入了解小菜蛾喙管感器的生理和功能奠定了基础。     

黄胸蓟马触角感器的形态和分布

摘要: 【目的】本研究旨在明确黄胸蓟马Thrips hawaiiensis各个发育阶段触角感器类型、形态和分布。【方法】运用扫描电镜技术观察黄胸蓟马雌雄成虫、若虫、预蛹、蛹触角的形态结构以及触角上感器类型、形态和分布。【结果】黄胸蓟马成虫触角由柄节、梗节和鞭节3个部分组成,其中长的鞭节分为5个鞭小节(I-V)。雌成虫触角平均长度为263.70±5.78 μm,雄成虫触角平均长度为225.79±8.92 μm。触角长度随着虫龄的增长而显著增加。雌雄成虫触角上共发现Bhm氏鬃毛、钟形感器、刺形感器(I和II)、毛形感器、锥形感器(I, II和III)、腔锥形感器和腔形感器7种触角感器以及微毛和表皮齿2种表皮结构。预蛹触角呈锥形,无明显分节,可以自由活动,平均长138.81±6.29 μm。蛹触角紧贴头胸背部,圆柱形、无明显分节,不能自由活动,平均长213.07±6.30 μm。1龄和2龄若虫触角由柄节、梗节和鞭节组成,其鞭节分为4个鞭小节(I-IV),触角平均长度分别为122.48±1.72和134.58±3.75 μm。1龄若虫触角上分布有Bhm氏鬃毛、钟形感器、刺形感器(I和II)、锥形感器(I和II)、腔锥形感器、腔形感器、毛形感器和特殊结构感器共8种类型感器,表面分布表皮齿和舌状结构2种表皮结构;2龄若虫触角上分布有Bhm氏鬃毛、钟形感器、刺形感器(I和II)、毛形感器、锥形感器(I和II)、腔锥形感器、腔形感器7种类型感器以及表皮齿1种表皮结构。【结论】本研究较全面地对黄胸蓟马各个发育阶段的触角及触角感器形态和分布进行了观察和描述,并对其功能进行了推测。研究结果为进一步研究蓟马类昆虫触角感器的生理功能奠定了理论基础。