Dissonant Representations of Visual Space in Prefrontal Cortex during Eye Movements

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Genetic mosaic analysis of the equatorial-less mutation in Drosophila mezunogaster

eql (equatorial-less) is a recessive lethal mutation on the second chromosome of Drosophila melanogasfer. J. Campos-Ortega found that eql clones in somatic mosaic flies have reduced numbers of photoreceptor cells, and he suggested that only the R1, R6, and R7 photoreceptor cells were missing in this mutant. These photoreceptor cells help to define the inverted orientation of ommatidial facets along the equatorial midline of the fly eye, hence the mutation was named “equatorial-less”. We have conducted a detailed analysis of the eql mutation, by serial section reconstruction of eql clones marked with bw or w^? in somatic mosaic flies. We found that all photoreceptor cell types (Rl–R8) could be deleted by the eql mutation, and in rare cases the number of photoreceptor cells was increased. The apparent lack of photoreceptor cell type specificity was confirmed by our analysis of genetically mosaic facets, which indicated that no single photoreceptor cell, or subset of photoreceptor cells, was uniquely required to express eql Rather, eql appears to function in all photoreceptor cells, and possibly in all eye precursor cells. The distribution of photoreceptor cell numbers in w eql facets was consistent with the hypothesis that each photoreceptor cell was deleted independently of the others. The eql gene is located on the right arm of chromosome 2 at map location 2 ? 104.5 ± 0.7 and lies between the polytene chromosome bands 59D8 and 60A7. © 1995 Wiley-Liss, Inc.     

An evaluation of vertebrate seed dispersal syndromes in four species of black nightshade (Solanum sect. Solanum)

We examined the ecological relevance of bird versus mammal dispersal syndromes in four species of Solanum, S. americanum Type A, S. americanum Type B, S. ptychanthum, and S. sarrachoides. These plants were selected because their morphological characteristics, such as fruit color, mass, and persistence, resembled those typically associated with classically-defined bird and mammal dispersal syndromes. We monitored persistence of tagged fruits, compared physical and chemical chaacteristics, performed fruit preference trials with northern bobwhite quail (Colinus virginianus), deer mice (Peromyscus maniculatus), and American robins (Turdus migratorius), and assessed differences in use of olfactory cues by foraging deer mice. We predicted that principal components analysis of physical and chemical characteristics would place fruits of these species along a clear gradient from bird to mammal dispersal syndromes (S. americanum Type A, S. americanum Type B, S. ptychanthum, and S. sarrachoides). However, physical and chemical characteristics did not consistently follow the gradient. Also, contrary to expectations, both birds and mammals demonstrated a preference for S. americanum Types A and B, both bird fruits. Deer mice and bobwhite quail showed much less discrimination among fruit types than did American robins. While the relatively strong odor of the green-fruited S. sarrachoides suggested a mammalian attractant, deer mice discovered the relatively odorless S. americanum Type A significantly more quickly. We conclude that in Solanum, suites of morphological characteristics resembling bird and mammal dispersal syndromes are not good predictors of fruit choice by birds and mammals. We note, however, that this conclusion is based on a sample of three animal species. Alternative explanations for fruit character suites should be considered. For example, the adaptive significance for an association of green coloration of ripe fruit with impersistence (dropping when ripe), as in S. sarrachoides and some S. ptychanthum, may relate more to photosynthesis and carbon balance in detached fruits than to disperser attraction.     

The visual ecology of pupillary action in superposition eyes

The two most common mechanisms of pupillary screening-pigment migration in arthropod superposition eyes are the cone and longitudinal pigment migration mechanisms. The dynamics of each were investigated by optical modelling and by determining experimentally the relationship between eye glow brightness and screening pigment position within the eyes of two representative insect species: the noctuid moth Agrotis infusa and the dung beetle Copris elphenor. During dark adaptation, in both mechanisms, the screening pigment is contracted distally to expose the proximal half of each crystalline cone. During light adaptation the pigment migrates proximally and reduces light flux in the retina. In the longitudinal mechanism, pigment migrates into the clear zone of the eye. In the cone mechanism, pigment never enters the clear zone and is instead restricted to the proximal half of each crystalline cone: a migrating sleeve of pigment creates a small aperture at the end of the crystalline cone, the area of which depends on the degree of light adaptation. According to the model, the cone mechanism provides a limited range of light attenuation (ca. 0.6 log units) for which both good spatial resolution and accuracy of control are maintained, and within this range attenuation is controlled very finely. Beyond this range, whilst attenuation is still possible, diffraction at the pigment aperture and increasing coarseness of control worsen visual performance significantly. In contrast, the longitudinal mechanism provides a much larger useful range of light attenuation (up to several log units) and maintains reasonable fineness of attenuation control over the entire range (although not as fine as the cone mechanism). The experimental results support the model. An extensive survey of arthropods with superposition eyes reveals that the cone mechanism is almost exclusively possessed by those animals experiencing a narrow range of light intensities, and the longitudinal mechanism by those experiencing a wide range.Dedicated to Professor Rolf Elofsson on the occasion of his retirement from the Chair of Zoology in Lund     

Induction of reproductive diapause via perception of photoperiod through the compound eyes in the adult blow fly, Protophormia terraenovae

Covering and surgical removal of the compound eyes were performed to localize photoreceptors for photoperiodic responses in the blow fly Protophormia terraenovae (Diptera, Calliphoridae). Adult females showed a long-day photoperiodic response to control reproductive diapause. When the compound eyes were bilaterally covered with silver paint, diapause incidence increased under diapause-preventing conditions, i.e., a long-day photoperiod and constant light, as though flies were kept under constant darkness. Neither silver painting on a medial region of the head capsule nor control painting in which both compound eyes were painted in a clear solvent caused significant effects on diapause incidence. Unilateral painting of the compound eye caused an increment of diapause incidence under constant light but no effects under a long-day photoperiod. When the compound eyes were bilaterally removed, all the flies developed their ovaries both under a long-day and a short-day photoperiod. Unilateral removal of the compound eye also caused ovarian development under a short-day photoperiod, whereas removal of one antennal lobe or all ocelli caused no effects on diapause incidence. Since P. terraenovae completely lost responsiveness to photoperiod after blinding of the compound eyes, it is likely that this fly perceives photoperiod through its compound eyes. Accepted: 18 February 1997     

视觉刺激对猴初级视皮层神经元眼球位置效应的影响

用细胞外记录的方法,研究了视觉刺激对清醒猴初级视皮层神经元眼球位置效应的影响,当猴注视电视屏幕上２５个不同位置的小光点时,屏蔽上分别给予两种不同形式的视觉刺激：注视点周围的闪光圆环和感受野内的移动光条。这两种刺激都能增强初级视皮层神经元的眼球位置相关活动,并相应地使受眼球位置调制的神经元的比例明显增加。     

栖境不同的两种跳甲复眼结构比较

栖息于荫暗隐蔽处的蛇莓跳甲(Altica fragariae)和向阳开阔地的萎陵跳甲(A.Ampelophaga)的复眼外部形态及小眼微细结构有如下相同特征：两复眼均比较小,呈“八”字型排列在头部近背方的两侧;每个小眼含有一个双凸面的角膜锥体、4个森氏细胞和7个小网膜细胞;2个主色素细胞及11-12个附色素细胞围绕在小眼的外缘;小网膜细胞和色素细胞内均有丰富色素颗粒,当光照强度发生变化时,小网膜细胞内的色素颗粒发生位移;在视杆中段横切面上,视杆由7个微绒毛呈平行排列的矩形视小杆组成,其中的6个视小杆互相连成一个近似六边形的框架,将另一个视小杆围在中央。两种跳甲复眼结构的主要差异有：蛇莓跳甲每个复眼大约仅有150个小眼,而萎陵跳甲约有2印个;复眼曲率半径前者只有后者的一半;视杆中段横切面上,视杆占整个小网膜面积的比率两虫分别为37%和25%,蛇莓跳甲高于萎陵跳甲。对以上形态结构特征可能具有的功能意义进行了初步讨论。     

The early stages of ommatidial development in the flour beetle Tribolium castaneum (Coleoptera; Tenebrionidae)

 Using electron microscopy, the first stages of ommatidial development in the flour beetle Tribolium castaneum were analysed in relation to the cellular architecture of the adult compound eye and were compared to the corresponding patterning process in the fruit fly Drosophila melanogaster. The ommatidia of the slightly horse-shoe shaped beetle compound eye contain six peripheral and two central retinula cells. The rhabdomere of the posteriorly located central photoreceptor cell is restricted to the distal half of the rhabdom whilst that of the anterior one is restricted to its proximal half. The development of the compound eye takes place in an external eye imaginal disc. Most stages of ommatidial development, as known from Drosophila, i.e. arc-like cell groups, five-cell clusters, immature eight-cell clusters and symmetrical eight-cell clusters, are very precisely conserved between the two species. Two major differences exist: 1. In Tribolium, the cone cell precursor cells synchronously join to the immature eight-cell cluster. As a consequence, the symmetrical eight-cell cluster immediately transforms into a four-cone-cell cluster. 2. The maturing ommatidia do not undergo rotation in Tribolium. Overall, no morphological indiation for an equator in the adult Tribolium compound eye could be found. Considering the strong evolutionary conservation of early ommatidial development, homology of photoreceptor cells of distantly related insects is proposed to be inferred from their ontogenetic origin. Received: 6 November 1995 / Accepted: 9 April 1996     

The morphology of mouthparts,wings and genitalia of Paleozoic insect families Protohymenidae and Scytohymenidae reveals new details and supposed function

Megasecoptera is an extinct group of insects with specialized rostrum-like mouthparts, which is a synapomorphy shared with all members of the Late Paleozoic Palaeodictyopterida, and markedly slender wings that are unable to flex backwards. Here we describe the close up morphology of Protohymenidae and Scytohymenidae and uncover new aspects of the endoskeleton (tentorium) of the head, structure of the mouthparts with discernible proximal part of stylets controlled by muscles, surface of compound eyes that consist of a hexagonal pattern of large facets, structure and microstructures on the wings and reconstruct male and female external genitalia using ESEM and light stereomicroscopy. Furthermore, we describe Protohymen novokshonovi sp. n. based on an exceptionally well preserved fossil from the early Permian at Tshekarda in Russia, which shows crucial details, and the earliest species of Protohymenidae, Carbohymen testai gen. et sp. n. from a late Carboniferous siderite nodule at Mazon Creek in Illinois, USA. Our comparative study confirmed a set of structural and microstructural details on their wings, such as the composite anterior wing margin, development of an apical cell and the previously unknown external genitalia. Based on the results and comparison of homologous structures known primarily for extant relatives, such as mayflies and dragonflies, we outline for the first time the function of the mouthparts, in particular, the stylets, structure of the tentorium, vision provided by large hexagonal ommatidia and male copulatory structures bearing curved claspers for holding a female during copulation and penial lobes with seminal grooves.