A role for adherons in neural retina cell adhesion

Embryonic chick neural retina cells release glycoprotein complexes, termed adherons, into their culture medium. When absorbed onto the surface of petri dishes, neural retina adherons increase the initial rate of neural retina cell adhesion; they also stimulate the rate of cell-cell aggregation. Adheron-stimulated adhesion is tissue specific, and the spontaneous aggregation of neural retina cells is inhibited by monovalent Fab' fragments prepared from an antiserum against neural retina adherons. Therefore cell surface antigenic determinants shared with adherons are involved in normal cell-cell adhesions. The particles from the heterogeneous neural retina population contain many proteins and several glycosaminoglycans. The adherons migrate as a symmetrical 12S peak on sucrose gradients and are predominantly 15-nm spheres when examined by electron microscopy. Finally, the specific activity of neural retina adherons increases from embryonic days 7 through 12 and then declines. These results suggest that glycoprotein particles may be involved in some of the adhesive interactions between neural retina cells and between the cells and their environment.     

人胎视网膜神经肽Y免疫反应神经元的发育

本文用免疫细胞化学ＡＢＣ法,研究１５—３８周龄人胎视网膜神经肽Ｙ免疫反应（ＮｅｕｒｏｐｅｐｔｉｄｅＹｉｍｍｕｎｏｒｅｃｔｉｖｅ,ＮＰＹ－ＩＲ）神经元（以下称ＮＰＹ－ＩＲ细胞）的发育。结果表明：①胎龄１５周视网膜中央部已出现不同类型的ＮＰＹ－ＩＲ细胞：位于黄斑及其周围外核层的为ＮＰＹ－ＩＲ视锥细胞;位于内核层最内一列的为ＮＰＹ－ＩＲ无长突细胞位于节细胞层的可能为ＮＰＹ－ＩＲ移位无长突细胞或节细胞;内核层和节细胞层的ＮＰＹ－ＩＲ细胞的突起均分布在内网层的第１亚层。②胎龄２４周后,ＮＰＹ－ＩＲ视锥细胞完全消失。③随着视网膜的发育,内核层和节细胞层的ＮＰＹ－ＩＲ细胞数量增多,突起增粗增长,胞体分布由中央部扩展到周边部,其中内核层ＮＰＹ－ＩＲ细胞的密度呈现从中央部向周边部逐渐降低的分布方式,节细胞层ＮＰＹ－ＩＲ细胞则多数集中分布在视网膜的边缘和黄斑之间,形成较高密度的环状区。     

Role of N-cadherin cell adhesion molecules in the histogenesis of neural retina

We investigated the role of N-cadherin cell adhesion molecules in the histogenesis of the chicken neural retina. In the undifferentiated retina of early embryos, N-cadherin is almost evenly distributed. With differentiation, N-cadherin was gradually localized in particular cell layers. In the 8.5 to 10.5 day embryos, N-cadherin was most abundant in the optic nerve fiber layer, the plexiform layers and the outer limiting membrane. Thereafter, this molecule gradually diminished from most parts of the retina, except in the outer limiting membrane. When incubated with Fab fragments of a polyclonal antibody to N-cadherin, retinas of early embryos tended to dissociate and could not be maintained as a tissue mass. Retinas from older embryos were not dissociated by the Fab, but their morphogenesis was severely affected. We conclude that N-cadherin is essential for maintaining the overall structure of the undifferentiated retina, but during development, its role becomes restricted to maintaining more specific regions of the tissue. We also suggest that there might be additional, unidentified cadherin-like molecules in the retina.     

Adaptation of a deep-sea cephalopod to the photic environment. Evidence for three visual pigments

Watasenia scintillans, a bioluminescent deep-sea squid, has a specially developed eye with a large open pupil and three visual pigments. Photoreceptor cells (outer segment: 476 micron; inner segment: 99 micron) were long in the small area of the ventral retina receiving downwelling light, whereas they were short (outer segment: 207 micron; inner segment: 44 micron) in the other regions of the retina. The short photoreceptor cells contained the visual pigment with retinal (lambda max approximately 484 nm), probably for the purpose of adapting to their environmental light. The outer segment of the long photoreceptor cells consisted of two strata, a pinkish proximal area and a yellow distal area. The visual pigment with 3-dehydroretinal (lambda max approximately 500 nm) was located in the pinkish proximal area, giving high sensitivity at longer wavelengths. A newly found pigment (lambda max approximately 471 nm) was in the yellow distal area. The small area of the ventral retina containing two visual pigments is thought to have a high and broad spectral sensitivity, which is useful for distinguishing the bioluminescence of squids of the same species in their environmental downwelling light. These findings were obtained by partial bleaching of the extracted pigment from various areas of the retina and by high-performance liquid chromatographic analysis of the chromophore, complemented by microscopic observations.     

西双版纳片断山地雨林蚁科昆虫群落研究

西双版纳是中国具有热带雨林的３个地区之一。采用样地调查法对西双版纳自然保护区山地雨林和３块山地雨林片断的蚂蚁群落作了比较研究。目的是揭示保护区与各片断间距离对蚂各落的影响。在４种样地中共计采集蚂蚁６亚科３５属７４种。与保护区距离不等的片断各有自己的特有种（１０－１１种）,各片断的特圾种少于自然保护区（１５种）。随着片断与自然保护区的距离增加,片断与保护区共有物种数减少（从５种、３种至２种）;最重要     

Isolation of a cell-surface receptor for chick neural retina adherons

Embryonic chick neural retina cells release glycoprotein complexes, termed adherons, into their culture medium. When absorbed onto the surface of petri dishes, neural retina adherons increase the initial rate of neural retina cell adhesion. In solution they increase the rate of cell-cell aggregation. Cell-cell and adheron-cell adhesions of cultured retina cells are selectively inhibited by heparan-sulfate glycosaminoglycan, but not by chondroitin sulfate or hyaluronic acid, suggesting that a heparan-sulfate proteoglycan may be involved in the adhesion process. We isolated a heparan-sulfate proteoglycan from the growth-conditioned medium of neural retina cells, and prepared an antiserum against it. Monovalent Fab' fragments of these antibodies completely inhibited cell-adheron adhesion, and partially blocked spontaneous cell-cell aggregation. An antigenically and structurally similar heparan-sulfate proteoglycan was isolated from the cell surface. This proteoglycan bound directly to adherons, and when absorbed to plastic, stimulated cell-substratum adhesion. These data suggest that a heparan-sulfate proteoglycan on the surface of chick neural retina cells acted as a receptor for adhesion-mediating glycoprotein complexes (adherons).     

Molecular cloning and characterization of rhodopsin in a teleost (Plecoglossus altivelis,Osmeridae)

Amplified fragments encoding exon-4 of opsin cDNAs were cloned from the retina of landlocked ayu (Plecoglossus altivelis), and sequenced. On the basis of the sequence homology to previously characterized fish visual pigments, one clone was identified as rod opsin (AYU-Rh), and two clones as green (AYU-G1, -G2), one as red (AYU-R) and two as ultraviolet (AYU-UV1, -UV2) cone opsins. The 335-amino acid sequence deduced from the full-length cDNA of AYU-Rh included residues highly conserved in vertebrate rhodopsins and showed the greatest degree (88%) of similarity with salmon rhodopsin. Southern blotting analysis indicated that ayu possess two rhodopsin genes, one encoding visual rhodopsin (AYU-Rh) and the other non-visual extra-ocular rhodopsin (AYU-ExoRh). RT-PCR experiments revealed that AYU-Rh was expressed in the retina and AYU-ExoRh in the pineal gland. In situ hybridization experiments showed that the mRNA of AYU-Rh was localized only in rod cells not in cone cells. Lake and river type landlocked ayu having different amounts of retinal and 3-hydroxyretinal in their retinas expressed a rhodopsin (AYU-Rh) of identical amino acid sequence.     

Effects of fragments and landscape characteristics on the orchid bee richness (Apidae: Euglossini) in an urban matrix,southwestern Amazonia

Orchid bees are important pollinators in tropical forests. Although studies have already detected effects of habitat loss and forest fragmentation on bee assemblages, little is known about orchid bees in urban forest fragments. The aim of this study was to analyse the influence of forest fragments (size and edge index) and landscape features (forest cover area and built-up area around the forest fragments, connectivity and spatial distance from the urban center) on the abundance, richness and composition of orchid bees. Male bees were attracted by odoriferous baits and collected in ten forest fragments of different sizes. In total, we collected 3166 male bees belonging to 4 genera and 38 species. The increase of the built-up area and the reduction of the forest cover area around the forest fragments decreased the abundance and richness of bees. We recorded a smaller number of bees in areas closer to the urban center. We failed to find a significant relationship between abundance/richness of bees and forest fragment area, edge index, and connectivity. We observed that the faunistic dissimilarity was positively correlated with the geographic distance between forest fragments. The forest fragments that presented greater landscape dissimilarity also presented greater faunistic dissimilarity. Our results suggest that the matrix structure around the forest fragments is an important factor that influences the Euglossini bee assemblages inside these forest fragments. Based on our results, we believed that the conservation of fragments with a larger forest cover area and smaller built-up areas around them contribute to the maintenance of the diversity of orchid bees and their pollination services.     

Sodium Iodate Selectively Injuries the Posterior Pole of the Retina in a Dose-Dependent Manner: Morphological and Electrophysiological Study

Sequential morphological and functional features of retinal damage in mice exposed to different doses (40 vs. 20 mg/kg) of sodium iodate (NaIO₃) were analyzed. Retinal morphology, apoptosis (TUNEL assay), and function (electroretinography; ERG) were examined at several time points after NaIO₃ administration. The higher dose of NaIO₃ caused progressive degeneration of the whole retinal area and total suppression of scotopic and photopic ERG. In contrast, the lower dose induced much less severe degeneration in peripheral part of retina along with a moderate decline of b- and a-wave amplitudes in ERG, corroborating the presence of regions within retina that retain their function. The peak of photoreceptor apoptosis was found on the 3rd day, but the lower dose induced more intense reaction within the central retina than in its peripheral region. In conclusion, these results indicate that peripheral area of the retina reveals better resistance to NaIO₃ injury than its central part.     

Rhythmic activities of isolated and clustered pacemaker neurons and photoreceptors of Aplysia retina in culture

Each eye of Aplysia contains a circadian clock that produces a robust rhythm of optic nerve impulse activity. To isolate the pacemaker neurons and photoreceptors of the eye and determine their participation in the circadian clock and its generation of rhythmic autoactivity, the retina was dissociated and its cells were placed in primary cell culture. The isolated neurons and photoreceptors survived and vigorously extended neurites tipped with growth cones. Many of the photoreceptors previously described from histological sections of the intact retina were identified in culture, including the large R-type photoreceptor, which gave robust photoresponses, and the smaller tufted, whorled, and flared photoreceptors. The pacemaker neurons responsible for the rhythmic impulse activity generated by the eye were identified by their distinctive monopolar morphology and recordings were made of their activity. Isolated pacemaker neurons produced spontaneous action potentials in darkness, and pacemaker neurons attached to fragments of retina or in an isolated cluster interacted to produce robust spontaneous activity. This study establishes that isolated retinal pacemaker neurons retain their innate autoactivity and ability to produce action potentials in culture and that clusters of coupled pacemaker neurons are capable of generating robust autoactivity comparable to pacemaker neuron rhythmic activity recorded in the intact retina, which was previously shown to correspond to 1:1 with the optic nerve compound action potential activity. © 1996 John Wiley & Sons, Inc.     

Physicochemical studies on tryptic digestion of bovine fibrinogen.

The high molecular weight fragments observed during tryptic digestion of bovine fibrinogen and the variation of their relative proportion with time has been studied. Separation of the different molecular species was carried out by gel filtration and the molecular weights of the isolated fragments were determined by sedimentation equilibrium and from their electrophoretic mobilities in sodium dodecylsulfate-polyacrylamide gels. The fibrinogen is degraded by trypsin into distinct fragments, with molecular weights of 270 000, 170 000, 90 000 and 50 000 accompanied by a series of smaller fragments whose properties were not investigated. The relative proportion of the components was estimated from area measurements on scans of the stained gels obtained after electrophoresis in the presence of sodium dodecylsulfate. The relative concentration and the molecular weight of each component established its molar concentration in each of the digestion mixtures obtained after varying incubation times (1-60 min). These data were used for a kinetic analysis of the process. The kinetic model derived on the basis of the trinodular model of fibrinogen (see Appendix) gave a very good representation of all the experimental results.     

In vitro biosynthesis, core glycosylation and membrane integration of opsin

A membrane-integrated , core-glycosylated form of bovine opsin was synthesized in vitro when bovine retina mRNA was translated in a wheat germ cell-free system supplemented with dog pancreas microsomal vesicles; glycosylation and integration of opsin into membranes were coupled to translation. Proteolysis with themolysin was used to probe the orientation of opsin within the dog pancreas microsomal membrane, and to compare it with that of opsin in rod cell disk membranes isolated from bovine retina. Intact microsomal or disk vesicles were required for production of discrete, membrane-associated thermolysin fragments of opsin; no discrete opsin fragments were detected when membranes were incubated with thermolysin in the presence of the nonionic detergent, Triton X-100. The major opsin fragments produced by themosylin treatment of intact microsomal vesicles resembled those from disk vesicles in their size, oligosaccharide content, and order of appearance. In each case, the first cleavage of opsin took place at the COOH-terminus, generating a glycosylated fragment, O’, which was only slightly smaller than intact opsin. Both the microsomal and disk membrane forms of O’ were next cleaved internally; glycosylated fragments of similar sizes in both cases were detected which were derived from the NH(2)-terminal portion of O’. Several smaller NH(2)-terminal fragments of opsin were detected only in thermolysin-treated microsomal membranes, and not in disk membranes. The data suggest that the topology of opsin integrated into dog pancreas microsomal vesicles is similar to that in rod cell disk vesicles, although not identical. In each case, the glycosylated NH(2)-terminal region of opsin is located within the lumen of the vesicle, while discrete COOH-terminal and internal segments of opsin apparently emerge at the outer, cytoplasmic face of the membrane. Thus, opsin in the heterologous microsomal membrane, like its counterpart in the native disk membrane, may cross the bilayer at least three times. The internal domain of the polypeptide that emerges at the outer membrane surface is apparently more highly exposed in the case of opsin in microsomal membranes, evidenced by the additional internal thermolysin cleavage sites detected.     

Recognition of position-specific properties of tectal cell membranes by retinal axons in vitro

In order to test the preference of growing axons for membrane-associated positional specificity a new in vitro assay was developed. In this assay, membrane fragments of two different sources are arranged as a carpet of very narrow alternating strips. Axons growing on such striped carpets are simultaneously confronted with the two substrates at the stripe borders. If there is a preference of axons for one or the other substrate they become oriented by the stripes and grow within the lanes of the preferred substrate. Such preferential growth could, in principle, be due to affinity to attractive factors on the preferred stripes or avoidance of repulsive factors on the alternate stripes. This assay system was used to investigate growth of chick retinal axons on tectal membranes. Tissue strips cut from various areas of the retina were explanted and the extending axons were confronted with stripes of cell membranes from various areas within the optic tectum. Tectal cell membranes prove to be an excellent substrate for the growth of retinal axons. Nasal and temporal axons can grow well on membranes of both posterior and anterior tectal cells. If, however, temporal axons are given a choice and encounter the border between anterior and posterior membranes they show a marked preference for growth on membranes of the anterior tectum, their natural target area. Nasal axons do not show a preference in this assay system. The transition from nasal to temporal properties within the retina is abrupt. In contrast, the transition from anterior to posterior properties of the tectal cell membranes occurs as a smooth gradient. Significantly, the positional differences of tectal membrane properties are only seen during the period of development of the retinotectal projection and are independent of tectal innervation by retinal axons. These anterior-posterior differences disappear by embryonic day 14.     

Tissue-specific neuro-glia interactions determine neurite differentiation in ganglion cells

Guided formation and extension of axons versus dendrites is considered crucial for structuring the nervous system. In the chick visual system, retinal ganglion cells (RGCs) extend their axons into the tectum opticum, but not into glial somata containing retina layers. We addressed the question whether the different glia of retina and tectum opticum differentially affect axon growth. Glial cells were purified from retina and tectum opticum by complement-mediated cytolysis of non-glial cells. RGCs were purified by enzymatic delayering from flat mounted retina. RGCs were seeded onto retinal versus tectal glia monolayers. Subsequent neuritic differentiation was analysed by immunofluorescence microscopy and scanning electron microscopy. Qualitative and quantitative evaluation revealed that retinal glia somata inhibited axons. Time-lapse video recording indicated that axonal inhibition was based on the collapse of lamellipodia- and filopodia-rich growth cones of axons. In contrast to retinal glia, tectal glia supported axonal extension. Notably, retinal glia were not inhibitory for neurons in general, because in control experiments axon extension of dorsal root ganglia was not hampered. Therefore, the axon inhibition by retinal glia was neuron type-specific. In summary, the data demonstrate that homotopic (retinal) glia somata inhibit axonal outgrowth of RGCs, whereas heterotopic (tectal) glia of the synaptic target area support RGC axon extension. The data underscore the pivotal role of glia in structuring the developing nervous system.     

正常有色素家兔眼的视网膜功能研究

目的通过分析正常有色素家兔的mfERG的特征,了解其视网膜的功能特性。方法对9只兔18眼正常有色素家兔同时检测mfERG,并与正常成人的18只眼的检测结果对照分析。结果正常有色素家兔mfERG的P1波振幅密度三维地形图特点,可见黄斑区高峰,但较人黄斑区高峰为低,其他部分呈颞侧高鼻侧低的斜坡状,象限野mfERG颞侧半可见P1波振幅密度、P1波振幅、N1波振幅比鼻侧增高;也高于正常成人眼的颞侧值。五个环形野mfERG,P1波振幅密度,第1环最大,由1环到5环依次递减,P1和N1波振幅以4环和5环最大;与人相比环1的P1波振幅密度和振幅降低,环4和环5增高。结论兔眼颞侧视网膜功能高于鼻侧。兔眼视网膜存在类人黄斑区,但其黄斑中心视功能不如人眼,中心外视功能高于人眼。     

Pigmented epithelium to retinal transdifferentiation and Pax6 expression in larval Xenopus laevis

This study examines the retinal transdifferentiation (TD) of retinal pigmented epithelium (RPE) fragments dissected from Xenopus laevis larvae and implanted into the vitreous chamber of non-lentectomized host eyes. In these experimental conditions, most RPE implants transformed into polarized vesicles in which the side adjacent to the lens maintained the RPE phenotype, while the side adjacent to the host retina transformed into a laminar retina with the photoreceptor layer facing the cavity of the vesicle and with the ganglionar cell layer facing the host retina. The formation of a new retina with a laminar organization is the result of depigmentation, proliferation and differentiation of progenitor cells under the influence of inductive factors from the host retina. The phases of the TD process were followed using BrdU labelling as a marker of the proliferation phase and using a monoclonal antibody (mAbHP1) as a definitive indicator of retina formation. Pigmented RPE cells do not express Pax6. In the early phase of RPE to retinal TD, all depigmented and proliferating progenitor cells expressed Pax6. Changes in the Pax6 expression pattern became apparent in the early phase of differentiation, when Pax6 expression decreased in the presumptive outer nuclear layer (ONL) of the new-forming retina. Finally, during the late differentiation phase, the ONL, which contains photoreceptors, no longer expressed Pax6, Pax6 expression being confined to the ganglion cell layer and the inner nuclear layer. These results indicate that Pax6 may have different roles during the different phases of RPE to retinal TD, acting as an early retinal determinant and later directing progenitor cell fate.     

Fully differentiated Xenopus eye fragments regenerate to form pattern-duplicated visuo-tectal projections

In order to determine if differentiated Xenopus retina is capable of undergoing regeneration and duplicative pattern formation, we devised a new surgical technique for removal of the temporal two-thirds of the retina. In a series of progressively older larval eyes starting with late tailbud stage embryos (stage 38) and extending to limb-bud stage tadpoles (stage 48), nasal one-third-sized eye fragments successfully regenerated to form nearly normal sized eyes over 75% of the time. Histological preparations showed that early wound healing involved the formation of a neuroepithelium at the ventro-temporal region of the fragment. The pigmented retinal epithelium and associated retinal tissue appeared to be involved in this process. Animals from each stage were reared through metamorphosis and electrophysiologic techniques were employed to determine visuo-tectal projections. Seventy percent of stage 38 animals showed evidence of pattern-duplicated projections. Ninety percent of their responding tectal points showed duplicate innervation from two retinal regions. Older animals (stages 44 to 48) showed less duplication. Only 52% of their responding tectal points duplicated (P less than 0.001). Thus, fully differentiated Xenopus retina can undergo regeneration and duplicative pattern formation similar to that shown by embryonic retinal tissue.     

An autoradiographic time study during regeneration in fully differentiated Xenopus eyes.

Nasal one-third sized fragments were created from fully differentiated larval Xenopus eyes (stage 47). At various times post-surgery, animals were injected with tritiated thymidine. All animals were fixed 1 day post-injection. Animals injected 1 day post-surgery showed limited healing and thymidine labeling in the retina. In animals injected 1 week post-surgery, heavy thymidine label was localized in the ventrotemporal retina in a "thickened" neuroepithelium internal to the extending pigmented retinal epithelium. In contrast, the dorsal retina showed no apparent extra labeling, but rather resembled normal ciliary margin. In animals injected 1 month post-surgery, the eye fragment regained normal size and retinal layering, and the label was restricted to the ciliary margin. Regenerative growth associated with healing appeared to have been completed by this time. This extra cell division that occurs during the 1st month post-surgery may underlie novel axonal targeting properties shown by nasal one-third sized fragments. For example, these findings are consistent with the idea that pattern duplication of the visuotectal projection in nasal one-third sized eye fragments occurs via intercalary cell division during healing and regeneration.     

Relation between the rate of cell movement under agarose and the positioning of cells in heterotypic aggregates

Single-cell suspensions prepared from 9-day-old chick tissues (skeletal muscle, liver, and neural retina) were used to investigate a possible relationship between intrinsic mobilities of different cell types and their positioning behavior in mixed (heterotypic) cellular aggregates. The relative mobilities of the three cell types, determined by comparing their ability to migrate under an agarose layer, was muscle greater than liver greater than neural retina. The gyratory shaker method was employed to produce heterotypic aggregates from mixed suspensions of muscle, liver, and neural retina cells and the tissue-specific positioning of cells after 24 h in culture was determined from histological and autoradiograph sections. The hierarchy for "inside" positioning of segregated cells was muscle greater than liver greater than neural retina cells, correlating with the rate of movement of these cells in the migration assay. The implication of the results is that relative speed of movement may determine the positioning of cells in heterotypic aggregates.     

Low oxygen consumption in the inner retina of the visual streak of the rabbit

The oxygen requirements of different retinal layers are of interest in understanding the vulnerability of the retina to hypoxic damage in retinal diseases with an ischemic component. Here, we report the first measurements of retinal oxygen consumption in the visual streak of the rabbit retina, the region with the highest density of retinal neurons, and compare it with that in the less-specialized region of the retina underlying the vascularized portion of the rabbit retina. Oxygen-sensitive microelectrodes were used to measure oxygen tension as a function of retinal depth in anesthetized animals. Measurements were performed in the region of the retina containing overlying retinal vessels and in the center of the visual streak. Established mathematical analyses of the intraretinal oxygen distribution were used to quantify the rate of oxygen consumption in the inner and outer retina and the relative oxygen contributions from the choroidal and vitreal sides. Outer retinal oxygen consumption was higher in the visual streak than in the vascularized area (means +/- SE, 284 +/- 20 vs. 210 +/- 23 nl O2.min(-1) x cm(-2), P = 0.026, n = 10). However, inner retinal oxygen consumption in the visual streak was significantly lower than in the vascular area (57 +/- 4.3 vs. 146 +/- 12 nl O2 x min(-1) x cm(-2), P < 0.001). We conclude that despite the higher processing requirements of the inner retina in the visual streak, it has a significantly lower oxygen consumption rate than the inner retina underlying the retinal vasculature. This suggests that the oxygen uptake of the inner retina is regulated to a large degree by the available oxygen supply rather than the processing requirements of the inner retina alone.