软体动物维甲酸X受体研究进展

维甲酸X受体(retinoid X receptor,RXR)作为配体依赖的转录因子,是核受体超家族重要的一员.脊椎动物RXR与配体及其辅调节因子相互作用,调控基因的协调表达,在胚胎发育、细胞分化、新陈代谢等许多生理过程中起着重要作用.软体动物RXR的研究因其与腹足类性畸变的关系越来越受到关注.本文综述了目前获得的软体动物RXR基因的结构,比较了软体动物RXR基因各功能结构域与人类和其他动物RXR的相似性.以RXR编码区的氨基酸序列为基础,构建了系统进化树,发现软体动物RXR与脊索动物而不是其他无脊椎动物的RXR聚成一支.软体动物和甲壳动物不同RXR亚型的氨基酸序列比较发现,两类动物可能存在不同的剪切酶或剪切位点.此外论文还针对软体动物RXR的配体、二聚体伙伴以及生理功能等方面的研究进行了综述.     

Involvement of glycan chains in the antigenicity of Rapana thomasiana hemocyanin

Functional unit (FU) RtH2-e from Rapana thomasiana hemocyanin (Hc) was degraded into small fragments with chymotrypsin. The glycopeptides were separated from the non-glycosylated peptides by chromatography on Concanavalin-A-Sepharose and characterized by mass spectrometry. The glycan part of the glycopeptides (all with common peptide stretch of 14 amino acids) consists of the classical trimannosyl-N,N-diacetylchitobiose core for N-glycosylation, predominantly extended with a unique tetrasaccharide that is branched on fucose. In inhibition ELISA experiments, the glycopeptides interfered in the complex formation between FU RtH2-e and rabbit antibodies against Rapana Hc (about 30% of inhibition). The inhibition also was retained after treatment of the glycopeptides with pronase in order to completely destroy the peptide part. The inhibitory effect of the non-glycosylated peptides, on the other hand, was very low. This study thus demonstrates that the glycans attached to FU RtH2-e contribute to the antigenicity of Rapana Hc.     

Variability of shell repair in the Manila clam Ruditapes philippinarum affected by the Brown Ring Disease: a microstructural and biochemical study

For more than two decades, the Manila clam Ruditapes philippinarum has been regularly affected by Brown Ring Disease (BRD), an epizootic event caused by the bacterium Vibrio tapetis and characterized by the development of a brown deposit on the inner face of valves. Although BRD infection is often lethal, some clams recover by mineralizing a new repair shell layer, which covers the brown deposit and fully isolates it from living tissues. In order to understand this specific shell repair process, the microstructures of repaired zones were compared to those of shells unaffected by BRD. In addition, the organic matrix associated with unaffected shells and to repair patches were extracted and compared by biochemical and immunological techniques. Our results show that the repaired zones exhibit microstructures that resemble the so-called homogeneous microstructure of the internal layer, with some marked differences, like the development of crossed-acicular crystals, which form chevron-like patterns. In the three tested batches of repaired layers, the matrices exhibit certain heterogeneity, i.e., they are partially to widely different from the ones of shells unaffected by BRD, as illustrated by SDS-PAGE and by serological comparisons. Our results strongly suggest a modification of the secretory regime of calcifying mantle cells during the shell repair process. Polyclonal antibodies, which were developed against specific protein fractions of the shell, represent relevant tools for localizing by immunohistology the cells responsible for the repair.     

Gene structure of two-domain arginine kinases from Anthopleura japonicus and Pseudocardium sachalinensis

Unusual two-domain arginine kinases (AKs) arose independently at least two times during molecular evolution of phosphagen kinases: AKs from the primitive sea anemone Anthopleura japonicus and from the clam Pseudocardium sachalinensis. To elucidate its unusual evolution, the structures of Anthopleura and Pseudocardium AK genes have been determined. The Anthopleura gene consisted of 4 exons and 3 introns: two domains are linked by a bridge intron, and each domain contains one intron in different positions. On the other hand, the Pseudocardium gene consisted of 10 exons and 9 introns: two domains are also linked by a bridge intron, and domains 1 and 2 contains 3 and 5 introns, respectively, of which 3 introns are located in exactly same positions. Since the two domains of Pseudocardium AK are estimated to have diverged about 290 million years ago, the 3 introns have been conserved at least for this long. Comparison of intron positions in Anthopleura, Pseudocardium and C. elegans AK genes indicates that there is no intron conserved through the three AK lineages, in sharp contrast to relatively conservative intron positions in creatine kinase (CK) gene family.     

Pleural-buccal interneurons in the pteropod mollusc Clione limacina

Paired, Phe-Met-Arg-Phe-NH₂-ergic pleural-to-buccal projecting neurons of the pleural ganglia were suggested to be responsible for feeding arrest associated with defensive withdrawal in freshwater and terrestrial pulmonate molluscs. In the present study, the pleural-to-buccal projecting cells were, for the first time, identified in a representative opisthobranch, the carnivorous marine pteropod Clione limacina. Two symmetric neurons of its pleural ganglia were found to be similar to the pulmonate pleural-to-buccal projecting neurons in the number of neurons, positions of their cell bodies in the central nervous system, a unique, indirect route of their axon, electrotonic coupling of the left and right cells, and expression of Phe-Met-Arg-Phe-NH₂-like immunoreactivity and inhibitory action on neurons participating in the motor program for feeding. In their turn, pleural-to-buccal projecting neurons receive excitatory inputs from the protractor interneurons involved in the feeding rhythm generation. Also, it was demonstrated that the pleural-to-buccal projecting cells activity positively correlates with spontaneous and induced acceleration of the locomotor rhythm. Accordingly, stimulation of the cerebral command neuron for locomotion, cell CPA1, excited pleural-to-buccal projecting neurons. We conclude that the neuronal network underlying feeding behavior in both pulmonate and opisthobranch molluscs is similarly linked to defensive behavior by pleural Phe-Met-Arg-Phe-NH₂-ergic neurons, thus indicating evolutionary conservation of these pleural-buccal projections. Accepted: 22 June 1999     

In situ Raman spectroscopic studies of the teeth of the chiton Acanthopleura hirtosa

 In situ Raman spectroscopy, in combination with energy dispersive spectroscopy, has been used for the first time to determine the identities and locations, at the micron level, of mineral phases present in single chiton teeth that have been extensively mineralized. At the later stages of development the major lateral teeth of the chiton Acanthopleura hirtosa show characteristic spectroscopic evidence for the presence of lepidocrocite (γ-FeOOH), magnetite (Fe₃O₄), and an apatitic calcium phosphate. Goethite (α-FeOOH) and ferrihydrite (5 Fe₂O₃·9 H₂O), which have been detected previously in teeth at the early stages of mineralization, were not detected in this mature tooth. The spatial distribution of these phases was determined, providing evidence for the presence of a discrete layer of lepidocrocite between the magnetite and apatite regions, illustrating the complexity of the biomineralization process. The technique of laser Raman microscopy is shown to be ideal for the examination of small biomineralized structures in situ, such as chiton teeth. Received: 6 July 1998 / Accepted: 19 August 1998     

Cerebral neurons underlying prey capture movements in the pteropod mollusc,Clione limacina

The pteropod mollusc Clione limacina is a highly specialized carnivore which feeds on shelled pteropods and uses, for their capture, three pairs of oral appendages, called buccal cones. Contact with the prey induces rapid eversion of buccal cones, which then become tentacle-like and grasp the shell of the prey. In the previous paper, a large group of electrically coupled, normally silent cells (A motoneurons) has been described in the cerebral ganglia of Clione. Activation of A neurons induces opening of oral skin folds and extrusion of the buccal cones. The present study continues the analysis of the electrical properties of A motoneurons.Brief intracellular stimulation of an A neuron can produce prolonged firing (afterdischarge), lasting up to 40 s, in the entire population of A neurons. Afterdischarge activity is based on an afterdepolarization evoked by an initial strong burst of A neuron spikes. The data suggest that this afterdepolarization represents excitatory synaptic input from unidentified neurons which in turn receive excitatory inputs from A neurons, thus organizing positive feedback. The main functional role of this positive feedback is the spread and synchronization of spike activity among all A neurons in the population. In addition, it serves to transform a brief excitatory input to A neurons into their prolonged and stable firing, which is required during certain phases of feeding behavior in Clione.