Primary optic projections in the rabbit. Study using the horseradish peroxidase anterograde labeling technic

The primary visual pathways, in particular those to the lateral geniculate body, of 11 albino and 7 pigmented rabbits, were studied using the method of anterograde labelling with horseradish peroxidase following injection of the tracer into the vitreous body of one eye. A heavy projection to the contralateral dorsal lateral geniculate nucleus was seen in all animals. In both albino and pigmented animals a region devoid of label was present in the medial part of the alpha sector of the nucleus. This region corresponded to a compact, oval or wedge-shaped field of terminal label in the ipsilateral nucleus, which was much heavier in pigmented than in albino rabbits. In the ventral lateral geniculate nucleus, contralateral retinal input was almost entirely confined to the caudal half of the lateral sector of the nucleus, where two laminae of dense terminal label, separated by a less densely labelled area, were oriented parallel to one another and to the optic tract. This bilaminar distribution of retinal afferents to the ventral lateral geniculate nucleus has not been described in previous studies. The ipsilateral projection was to the dorsal part of the lateral sector and was most prominent in pigmented animals. The "intergeniculate leaflet" received a prominent contralateral input in all animals, and a clear ipsilateral input in pigmented animals, which overlapped with the contralateral input. Projections to other primary visual centres (pretectal nuclei, superior colliculus, nuclei of the accessory optic tract) are also described.     

Survival of xenogeneic grafts of embryonic pigment and carapace rudiments in embryos of Chelydra serpentina

In a study of survival of embryonic grafts in turtles, Chelydra was used as host and Chrysemys and Amyda as donors. Somites and overlying ectoderm with or without adjacent neural tube were transplanted. The operations were unilateral and orthotopic. The involved the anterior portion of the carapace. In other experiments, bilateral neural crest and dorsal neural tube were transplanted orthotopically. In experiments with Chrysemys as donor, pigment cells formed conspicuous red areas ventrally when neural crest was included in the graft. This pigment faded gradually but persisted for three or four years. When somites and adjacent ectoderm of Chrysemys carapace were transplanted, the graft area was lightly pigmented at hatching. This pigmentation increased subsequently. The Chrysemys grafts were either accepted or partially rejected. In cases of apparent complete acceptance, the graft region took on characteristics of the host. When Amyda served as donor of carapace rudiments, the graft area retained characteristics of the donor. At hatching, dark spots on a yellow background were present and scutes were absent. A few months after hatching, the graft area became necrotic. Subsequently, scutes with host characteristics or skin covered the graft area.     

The structures of dorsal and ventral regions of a dragonfly retina

Summary The apposition eyes of the corduliid dragonfly Hemicordulia tau are each divided by pigment colour, facet size and facet arrangement into three regions: dorsal, ventral, and a posterior larval strip. Each ommatidium has two primary pigment cells, twenty-five secondary pigment cells, and eight receptor cells, all surrounded by tracheae which probably prevent light passing between ommatidia, and reduce the weight of the eye. Electron microscopy reveals that the receptor cells are of two types: small vestigial cells making virtually no contribution to the rhabdom, and full-size typical cells. The ventral ommatidia have a distal typical cell (oriented either horizontally or vertically), four medial typical cells, two proximal typical cells and one full-length vestigial cell. The dorsal ommatidia have only four full-length typical cells, and one distal and three vestigial full-length cells. The cross-section of dorsal rhabdoms is small and circular distally, but expands to a large three-pointed star medially and proximally. The tiered receptor arrangement in the ventral ommatidia is typical of other Odonata but the dorsal structure has not been fully described in other species. Specialised dorsal eye regions are typical of insects that detect others against the sky.     

Methadone accumulation in ocular tissue.

For up to 6 days after administration of tritiated methadone the eyes of albino (Sprague Dawley) and pigmented (Long Evans) rats and frogs (Rana pipens) were assayed for methadone and metabolites in various eye substructures. The pigmented structures of the eye were found to contain the highest concentration of radioactivity at all time periods tested. At 6 days after administration of a single dose the pigmented epithelium of the rat retina showed a 100 times greater concentration of radioactivity than the blood. At 6 hours after dosage the pigmented eyes showed a 40 times greater concentration than the albino eyes suggesting that methadone does have a strong affinity for the pigmented structures of the eye.     

Dpp and Hh signaling in the Drosophila embryonic eye field.

We have analyzed the function of the Decapentaplegic (Dpp) and Hedgehog (Hh) signaling pathways in partitioning the dorsal head neurectoderm of the Drosophila embryo. This region, referred to as the anterior brain/eye anlage, gives rise to both the visual system and the protocerebrum. The anlage splits up into three main domains: the head midline ectoderm, protocerebral neurectoderm and visual primordium. Similar to their vertebrate counterparts, Hh and Dpp play an important role in the partitioning of the anterior brain/eye anlage. Dpp is secreted in the dorsal midline of the head. Lowering Dpp levels (in dpp heterozygotes or hypomorphic alleles) results in a 'cyclops' phenotype, where mid-dorsal head epidermis is transformed into dorsolateral structures, i.e. eye/optic lobe tissue, which causes a continuous visual primordium across the dorsal midline. Absence of Dpp results in the transformation of both dorsomedial and dorsolateral structures into brain neuroblasts. Regulatory genes that are required for eye/optic lobe fate, including sine oculis (so) and eyes absent (eya), are turned on in their respective domains by Dpp. The gene zerknuellt (zen), which is expressed in response to peak levels of Dpp in the dorsal midline, secondarily represses so and eya in the dorsomedial domain. Hh and its receptor/inhibitor, Patched (Ptc), are expressed in a transverse stripe along the posterior boundary of the eye field. As reported previously, Hh triggers the expression of determinants for larval eye (atonal) and adult eye (eyeless) in those cells of the eye field that are close to the Hh source. Eya and So, which are induced by Dpp, are epistatic to the Hh signal. Loss of Ptc, as well as overexpression of Hh, results in the ectopic induction of larval eye tissue in the dorsal midline (cyclopia). We discuss the similarities between vertebrate systems and Drosophila with regard to the fate map of the anterior brain/eye anlage, and its partitioning by Dpp and Hh signaling.     

The construction of the insect compound eye: the involvement of cell displacement and cell surface properties in the positioning of cells

The highly patterned arrangement of cells in the Ephestia compound eye arises in an orderly spatiotemporal sequence from a small population of cells organized into ommatidial precursors (“differentiation center”). The presumptive retina cells in the posterior region of this zone differentiate in an anterior to posterior order before differentiation proceeds in an anterior direction from the zone. The bidirectional growth of the compound eye from the differentiation center cannot be ascribed solely to an inductively transmitted “wave of differentiation”; the spreading of an epithelial sheet of cells bordering the center is, at least in part, involved in this process. This latter statement is based on the observation that when genetically marked tissues are transferred from the eye regions of donor pupae to the corresponding sites of host pupae, the grafts are displaced along the antero-posterior head axis, either in an anterior direction or a posterior direction depending upon their original positions relative to the differentiation center. The tissues derived from pupal grafts transposed or reoriented along this same axis often experience striking configurational changes and axial displacements. Findings of this nature support the hypothesis that cells of the prospective adult eye possess position-specific differences in cell adhesiveness.     

Is the Schwabe Organ a Retained Larval Eye? Anatomical and Behavioural Studies of a Novel Sense Organ in Adult Leptochiton asellus (Mollusca,Polyplacophora) Indicate Links to Larval Photoreceptors

The discovery of a sensory organ, the Schwabe organ, was recently reported as a unifying feature of chitons in the order Lepidopleurida. It is a patch of pigmented tissue located on the roof of the pallial cavity, beneath the velum on either side of the mouth. The epithelium is densely innervated and contains two types of potential sensory cells. As the function of the Schwabe organ remains unknown, we have taken a cross-disciplinary approach, using anatomical, histological and behavioural techniques to understand it. In general, the pigmentation that characterises this sensory structure gradually fades after death; however, one particular concentrated pigment dot persists. This dot is positionally homologous to the larval eye in chiton trochophores, found in the same neuroanatomical location, and furthermore the metamorphic migration of the larval eye is ventral in species known to possess Schwabe organs. Here we report the presence of a discrete subsurface epithelial structure in the region of the Schwabe organ in Leptochiton asellus that histologically resembles the chiton larval eye. Behavioural experiments demonstrate that Leptochiton asellus with intact Schwabe organs actively avoid an upwelling light source, while Leptochiton asellus with surgically ablated Schwabe organs and a control species lacking the organ (members of the other extant order, Chitonida) do not (Kruskal-Wallis, H = 24.82, df = 3, p < 0.0001). We propose that the Schwabe organ represents the adult expression of the chiton larval eye, being retained and elaborated in adult lepidopleurans.     

三种蚤生殖系统的细微结构:雄性外生殖器的发育

本文研究了缓慢细蚤Leptopsylla segnis(Schonherr),不等单蚤Monopsyllus anisus(Rothschild)和猫栉首蚤指名亚种Ctenocephalides felis felis(Bouche)雄性外生殖器的结构,观察了从幼虫、前蛹、蛹至成虫各发育时期的雄性外生殖器的内部结构变化.对有争议的雄蚤上抱器的起源,雄蚤生殖孔的位置,雄性外生殖器芽内陷的腹节以及射精管横切面的细胞数目和阳茎背、腹杆的结构等问题进行了详细的观察和探讨.     

广西高原鳅属鱼类一穴居新种记述

2003年1月,在广西壮族自治区天峨县红水河水系地下河采集到一批盲鱼标本。经鉴定,为高原鳅属Triplophysa一未经发表的新种。新种天峨高原鳅Triplophysa tianeensis sp．nov．与个旧盲高原鳅T．gejiuensis、石林盲高原鳅T．shilinensis、阿庐高原鳅T．aluensis和南丹高原鳅T．nandanensis相似;本新种腹鳍末端不达肛门,尾鳍分枝鳍条16,可进一步与个旧盲高原鳅和石林盲高原鳅(腹鳍末端达到肛门,尾鳍分枝鳍条14-15)相区别;本新种背鳍起点位于体之中点、腹鳍起点之后,肛门紧靠臀鳍起点,可进一步与阿庐高原鳅(背鳍起点靠近吻端、位于腹鳍起点之前,肛门距臀鳍起点仍有一段距离)相区别。本新种与同分布于红水河水系的南丹高原鳅Triplophysa nandanensis Lan et al.较为相似;但二者区别明显：新种背鳍分枝鳍条7、胸鳍分枝鳍条9、腹鳍分枝鳍条6、背鳍外缘平截、背鳍起点位于腹鳍起点之后,后者背鳍分枝鳍条8、胸鳍分枝鳍条10～11、腹鳍分枝鳍条7、背鳍外缘凹入、背鳍起点位于腹鳍起点之前;此外,新种的穴居特征更为显著：眼极度退化、头长为眼径16．8—32．8(25．0)倍、部分个体无色素斑且各鳍无斑点,而南丹高原鳅眼小、头长为眼径4．7～9．0(7．5)倍、体和头背侧密布云状斑且各鳍均具点状斑。     

A horseradish peroxidase study on the mammillothalamic tract in the rat

The mammillary projections to the anterior thalamic nuclei were investigated in the rat, using the horseradish peroxidase (HRP) method. Pars centralis of the medial mammillary nucleus projects to the medial portion of the ateromedial nucleus (AM). Pars medialis (Mm) of the medial mammillary nucleus sends fibers to the ipsilateral AM and sparsely to the medial portion of the contralateral side. The ventral and dorsal portions of Mm project to the anterior and posterior portions of AM, respectively. The pars latralis (Ml) and pars posterior (Mp) of the medial mammillary nucleus send fibers predominantly to the ipsilateral anteroventral nucleus and sparsely to the contralateral side. A slight difference between Ml and Mp projections was observed. The lateral mammillary nucleus projects bilaterally to the anterodorsal nucleus.     

Tissue specific effects of ommochrome pathway mutations in Drosophila melanogaster

The tissue-specific effects of 17 mutations affecting the synthesis of brown eye pigment (xanthommatin) have been investigated by combining them with chocolate and red cells, two mutations causing ectopic pigmentation of the Malpighian tubules and larval fat body (which normally only synthesize pigment precursors). The majority of mutations block the pigmentation of four organs; the normally pigmented eyes and ocelli, and ectopically pigmented tubules and fat body. They represent genes that would appear to be required for the normal operation of the pathway per se and are likely to encode structural proteins. Mutations at 5 loci affect pigmentation of a subset of organs: cd and po affect only the eyes and ocelli; kar affects the eyes, ocelli and fat body; car causes excretion of pigment from tubules; and z affects pigmentation of the eyes alone. Of these loci, only z has been shown to encode a regulatory protein and the role of the remaining four gene products is not clear. Two mutations affecting the red eye pigments (drosopterins), bw and mal, do not substantially perturb brown pigment synthesis in any of the four organs.     

The importance of larval eyes in the polychaete Capitella teleta: effects of larval eye deletion on formation of the adult eye

In many marine invertebrates with biphasic life cycles, juvenile/adult traits begin to develop before metamorphosis. For structures that are present at multiple developmental stages, but have distinct larval and adult forms, it is unclear whether larval and adult structures have shared or distinct developmental origins. In this study, we examine the relationship between the larval and adult eyes in the polychaete Capitella teleta. In addition, we describe a novel marker for larval and juvenile photoreceptor cells. Infrared laser deletion of individual micromeres in early embryos suggests that the same micromeres at the eight‐cell stage that are specified to generate the larval eyes also form the adult eyes. Direct deletion of the larval eye, including the pigment cell and the corresponding photoreceptor cell, resulted in a lack of shading pigment cells in juveniles and adults, demonstrating that this structure does not regenerate. However, a sensory photoreceptor cell was present in juveniles following direct larval eye deletions, indicating that larval and adult photoreceptors are separate cells. We propose that the formation of the adult eye in juveniles of C. teleta requires the presence of the pigment cell of the larval eye, but the adult photoreceptor is either recruited from adjacent neural tissue or arises de novo after metamorphosis. These results are different from the development and spatial orientation of larval and adult eyes found in other polychaetes, in which two scenarios have been proposed: larval eyes persist and function as adult eyes; or, distinct pigmented adult eyes begin developing separately from larval eyes prior to metamorphosis.     

Experimental studies on a mutant gene (e) preventing the differentiation of eye and normal hypothalamus primordia in the axolotl

The phenotype of axolotls (Ambystoma mexicanum) homozygous for the mutant gene e (“eyeless”) is different from normal in that (1) no optic vesicles develop in $\text{e}\text{e}$ embryos, (2) $\text{e}\text{e}$ larvae from posthatching onward are darker than normal white larvae, and (3) fully grown $\text{e}\text{e}$ animals are sterile.Experiments reported here show that eyelessness in $\text{e}\text{e}$ embryos results from a direct effect of the gene on presumptive forebrain ectoderm; not on the mesoderm that induces the ectoderm to form eyes. Homotopic grafts of normal presumptive ectoderm on $\text{e}\text{e}$ blastula hosts differentiated complete eyes, but reciprocally grafted embryos were always eyeless. Similarly, grafts of either $\text{e}\text{e}$ or normal presumptive prechordal mesoderm into normal hosts gave normal eyes, but in the mutant hosts no eyes developed. Thus the e gene affects only the ectodermal component of the inductive system for eye formation.Genetically eyeless (pigmented) cells, when interspersed prior to gastrulation among genetically eyed (albino) cells in the eye preprimordium, are induced to form clones of pigmented retinal epithelium in the albino host eye.The sterility of $\text{e}\text{e}$ larvae appears also to be due to a direct effect of the e gene on the ectodermal (neural plate) primordium of the hypothalamus. Grafts of normal cells which included the hypothalamic, but not the optic or anterior pituitary primordia, always restored fertility to $\text{e}\text{e}$ recipients.The mutant pigmentation phenotype was demonstrated to be a consequence of eyelessness and, therefore, an indirect effect of the gene. The pigment pattern of normal embryos from which both optic vesicles were removed resembles that of the mutants. In addition, implantation of a single full-sized, functional eye was able to restore the normal pigmentation, but not fertility, to $\text{e}\text{e}$ recipients.     

Transdifferentiation of eye tissues in anuran amphibians: Analysis of the transdifferentiation capacity of the iris of Xenopus laevis larvae

Abstract. Lensectomized Xenopus laevis larvae are capable of regenerating a lens from the cells of the outer cornea. Unlike the outer cornea, the iris of larval Xenopus exhibits a high degree of phenotypic stability, even when it has been damaged to various degrees in order to stimulate its latent transdifferentiative competence. However, when isolated from its surrounding tissues and implanted in an appropriate site, the dorsal iris of larval Xenopus is capable of following a differentiative pathway different to that normally followed in situ. Our results show that, when such an implant is placed in the vitreous chamber of a lensectomized eye, the pigmented epithelial cells of the iris transdifferentiate into neural retina regardless of whether the iris stroma is present or not. Unlike the vitreous chamber, the environment of the anterior chamber of a lensectomized eye does not promote the transdifferentiative process of the iris. We suggest the existence of eye factors that promote retina-forming transformation of the iris and that are distributed in a gradient in lensectomized eyes.     

Development of the compound eyes of dragonflies (Odonata). III. Adult compound eyes

The distribution of ommatidial diameters and interommatidial angles, as determined by measuring the angles between the optic axes of adjacent ommatidia, are mapped across the surface of the compound eyes of a variety of species selected for different adult behaviors, developmental histories, and taxonomic positions. The size of the visual fields, prey capture foveas, foveas composed of large dorsal ommatidia, and other specializations in the numbers of ommatidia that view various directions in the visual field are discussed in relation to adult behavior. Advanced species have less resemblance between their larval and adult eyes than primitive species. In contrast to their larvae, adults increase the monocular resolution of each eye at the expense of binocular vision. Most species have foveas which view in approximately the anterior direction, instead of in a region of binocular overlap, and many species have foveal bands which view along the horizon. Some advanced perching species, which approach their prey and other odonates from below, have an additional vertical foveal band that views along a vertical plane from the anterior direction to a more dorsal direction. The most unusual foveal band is seen in active flying species. The large dorsal ommatidia of the migratory Anax junius, which cover approximately one third of the eye surface, view a narrow region of the visual field that extends along a plane from the most lateral direction of one eye to a dorsal direction, and continues without interruption to the most lateral direction of the other eye.     

L-Dopa and the Albino Riddle: Content of L-Dopa in the Developing Retina of Pigmented and Albino Mice

Background

The absence or deficiency of melanin as in albinos, has detrimental effects on retinal development that include aberrant axonal projections from eye to brain and impaired vision. In pigmented retinal pigment epithelium (RPE), dihydroxyphenalanine (L-Dopa), an intermediate in the synthetic path for melanin, has been hypothesized to regulate the tempo of neurogenesis. The time course of expression of retinal L-Dopa, whether it is harbored exclusively in the RPE, the extent of deficiency in albinos compared to isogenic controls, and whether L-Dopa can be restored if exogenously delivered to the albino have been unknown.

Methodology/Principal Findings

L-Dopa and catecholamines including dopamine extracted from retinas of pigmented (C57BL/6J) and congenic albino (C57BL/6J-tyr^c2j) mice, were measured throughout development beginning at E10.5 and at maturity. L-Dopa, but not dopamine nor any other catecholamine, appears in pigmented retina as soon as tyrosinase is expressed in RPE at E10.5. In pigmented retina, L-Dopa content increases throughout pre- and postnatal development until the end of the first postnatal month after which it declines sharply. This time course reflects the onset and completion of retinal development. L-Dopa is absent from embryonic albino retina and is greatly reduced in postnatal albino retina compared to pigmented retina. Dopamine is undetectable in both albino and pigmented retinas until after the postnatal expression of the neuronal enzyme tyrosine hydroxylase. If provided to pregnant albino mothers, L-Dopa accumulates in the RPE of the fetuses.

Conclusions

L-Dopa in pigmented RPE is most abundant during development after which content declines. This L-Dopa is not converted to dopamine. L-Dopa is absent or at low levels in albino retina and can be restored to the RPE by administration in utero. These findings further implicate L-Dopa as a factor in the RPE that could influence development, and demonstrate that administration of L-Dopa could be a means to rescue developmental abnormalities characteristic of albinos.     

Does anterior (non-polarizing region) tissue signal in the developing chick limb?

The morphogenetic properties of embryonic chick limb bud tissue from anterior positions and from the posterior (polarizing) region are compared. Quail grafts, which possess the distinctive nucleolar cell marker, and γ-irradiation are used. Supernumerary limb structures induced by anterior tissue wedge grafts are found to be nearly exclusively graft, donor tissue derived. This contrasts with the duplicate limb structures formed in response to posterior (polarizing region) tissue grafts in which host cells predominate. Distinction between anterior and posterior tissue properties was also demonstrated using doses of radiation (～ 12 Gy = 1200 rad) which inhibit cell proliferation, but have negligible effects on avian polarizing activity. These doses, however, are found to completely abolish morphogenetic activity by chick or quail anterior tissue grafts. The results of anterior (nonpolarizing) region tissue grafts are best interpreted as graft self-differentiation under the influence of a posterior signalling region, whose properties in the limb bud are demonstrably unique.     

Nerve growth factor-induced stimulation of dorsal root ganglion/spinal cord co-grafts in oculo: enhanced survival and growth of CGRP-immunoreactive sensory neurons

Intraocular co-grafts of rat fetal spinal cord and dorsal root ganglia were used to examine the enhanced survival, growth, and differentiation of sensory neurons by nerve growth factor. E14 lumbar spinal segments were implanted into the anterior eye chamber of capsaicin-pretreated rats. Two weeks later, an E14 dorsal root ganglion was implanted beside the spinal cord graft. Nerve growth factor or vehicle was injected weekly for 4 weeks into the anterior eye chamber. Co-grafts were examined weekly and, at 6 weeks, processed for calcitonin gene-related peptide (CGRP) immunofluorescence. No differences in overall size were determined for the grafts. Co-grafts treated with nerve growth factor contained many more CGRP neurons (19.4 cells/20 microm) that were significantly larger (mean 764 microm2) than neurons from control co-grafts (8.6 cells/20 microm; mean 373 microm2). In co-grafts treated with nerve growth factor, CGRP-immunoreactive fibers were extensive in the dorsal root ganglion, adjacent iris, and spinal cord compared to control co-grafts. A few CGRP-positive motoneurons were observed in the spinal cord, but no differences in number or size of motoneurons were found. The current report demonstrates that spinal cord and dorsal root ganglia can be co-grafted in oculo for long periods of time. Many dorsal root ganglion neurons survive and send peripheral processes into the iris and central processes into the spinal cord under the influence of exogenous nerve growth factor. The intraocular graft paradigm can be of use to further examine the role of neurotrophic factors in regulating or modulating dorsal root ganglion and spinal cord neurons.     

Compatible limb patterning mechanisms in urodeles and anurans

We have experimentally tested the similarity of limb pattern-forming mechanisms in urodeles and anurans. To determine whether the mechanisms of limb outgrowth are equivalent, we compared the results of two kinds of reciprocal limb bud grafts between Xenopus and axolotls: contralateral grafts to confront anterior and posterior positions of graft and host, and ipsilateral grafts to align equivalent circumferential positions. Axolotl limb buds grafted to Xenopus hosts are immunologically rejected at a relatively early stage. Prior to rejection, however, experimental (but not control) grafts form supernumerary digits. Xenopus limb buds grafted to axolotl hosts are not rejected within the time frame of the experiment and therefore can be used to test the ability of frog cells to elicit responses from axolotl tissue that are similar to those that are elicited by axolotl tissue itself. When Xenopus buds were grafted to axolotl limb stumps so as to align circumferential positions, the majority of limbs did not form any supernumerary digits. However, in experimental grafts, where anterior and posterior of host and graft were misaligned, supernumerary digits formed at positional discontinuities. These results suggest that Xenopus/axolotl cell interactions result in responses that are similar to axolotl/axolotl cell interactions. Furthermore, axolotl and Xenopus cells can cooperate to build recognizable skeletal elements, despite large differences in cell size and growth rate between the two species. We infer from these results that urodeles and anurans share the same limb pattern-forming mechanisms, including compatible positional signals that allow appropriate localized cellular interactions between the two species. Our results suggest an approach for understanding homology of the tetrapod limb based on experimental cellular interactions.