Obg is a ribosome-associated GTPase essential for bacterial viability and is conserved in most organisms, from bacteria to eukaryotes. Obg is also expressed in plants, which predicts an important role for this molecule in plant viability; however, the functions of the plant Obg homologs have not been reported. Here, we first identified Arabidopsis AtObgC as a plant chloroplast-targeting Obg and elucidated its molecular biological and physiological properties. AtObgC encodes a plant-specific Obg GTPase that contains an N-terminal region for chloroplast targeting and has intrinsic GTP hydrolysis activity. A targeting assay using a few AtObgC N-terminal truncation mutants revealed that AtObgC localizes to chloroplasts and its transit peptide consists of more than 50 amino acid residues. Interestingly, GFP-fused full-length AtObgC exhibited a punctate staining pattern in chloroplasts of Arabidopsis protoplasts, which suggests a dimerization or multimerization of AtObgC. Moreover, its Obg fold was indispensable for the generation of the punctate staining pattern, and thus, was supposed to be important for such oligomerization of AtObgC by mediating the protein-protein interaction. In addition, the T-DNA insertion AtObgC null mutant exhibited an embryonic lethal phenotype that disturbed the early stage of embryogenesis. Altogether, our results provide a significant implication that AtObgC as a chloroplast targeting GTPase plays an important role at the early embryogenesis by exerting its function in chloroplast protein synthesis.
Background
Teleost paired fins are composed of two endoskeletal domains, proximal and distal radials, and an exoskeletal domain, the fin ray. The zebrafish pectoral fin displays elaborately patterned radials along the anteroposterior (AP) axis. Radials are considered homologous to tetrapod limb skeletons, and their patterning mechanisms in embryonic development are similar to those of limb development. Nevertheless, the pattern along the AP axis in fin rays has not been well described in the zebrafish pectoral fin, although several recent reports have revealed that fin ray development shares some cellular and genetic properties with fin/limb endoskeleton development. Thus, fin ray morphogenesis may involve developmental mechanisms for AP patterning in the fin/limb endoskeleton, and may have a specific pattern along the AP axis.
Results
We conducted detailed morphological observations on fin rays and their connection to distal radials by comparing intra- and inter-strain zebrafish specimens. Although the number of fin rays varied, pectoral fin rays could be categorized into three domains along the AP axis, according to the connection between the fin rays and distal radials; additionally, the number of fin rays varied in the posterior part of the three domains. This result was confirmed by observation of the morphogenesis process of fin rays and distal radials, which showed altered localization of distal radials in the middle domain. We also evaluated the expression pattern of lhx genes, which have AP patterning activity in limb development, in fin rays and during distal radial development and found these genes to be expressed during morphogenesis in both fin rays and distal radials.
Conclusion
The fin ray and its connection to the endoskeleton are patterned along the AP axis, and the pattern along the AP axis in the fin ray and the radial connection is constructed by the developmental mechanism related to AP patterning in the limb/fin bud. Our results indicate the possibility that the developmental mechanisms of fin rays and their connection are comparable to those of the distal element of the limb skeleton.
After a dose of 10 micrograms of 6-aminonicotinamide (6-AN) was administered to day-4- chick embryo in ovo, micromelia was obviously observed in the hind limbs of 7-day chick embryos. We examined the teratogenic mechanism of 6-AN by using the normal or micromelial hind limbs (buds) from day 5 to day 7, with special attention to the biosynthesis of glycosaminoglycan (GAG) and proteoglycan as an index of limb chondrogenesis. The present study provides evidence for abnormalities in the levels of GAG or proteoglycan biosynthesis in the micromelial hind limbs (buds). 1) Both [35S]sulfate and [3H]glucosamine incorporation into GAG per 10 limbs or mg DNA of the micromelia were inhibited, suggesting a decrease of GAG synthesis. 2) The micromelial limbs synthesized low-sulfated chondroitin sulfate (chondroitin) as judged by the 35S/3H ratio, the proportion of unsulfated disaccharide (delta Di-0S), and the result of cellulose acetate electrophoresis, although there were no significant differences in the approximate molecular size of 35S-chondroitin sulfates synthesized between the normal and micromelial limbs. 3) PAPS-synthesizing activity in the micromelial limbs was markedly inhibited, and this may result in the production of low-sulfated proteoglycan. 4) The transition from mesenchymal- to cartilage-specific proteoglycan synthesis did not appear in the micromelial limbs as judged by the sedimentation profiles. 5) 6-AN caused marked reductions in the oxygen consumption and ATP level of the micromelial limbs, thereby causing the defect in PAPS formation. We suggest that these 6-AN-induced sequential molecular defects (the reduction of respiratory activity, ATP and PAPS level, and concomitant interference with GAG and proteoglycan biosynthesis) in the limbs (buds) during the critical period of limb morphogenesis must be major factors resulting in the cartilage growth retardation or disorder, i.e., micromelia.
Genetic and molecular analysis of the restoration of fertility (Rf) genes for Ogura male-sterility from a Japanese wild radish (Raphanus sativus var. hortensis f. raphanistroides Makino)Abstract Ogura male-sterile cytoplasm is one of the most extensively studied cytoplasms in Brassicaceae.
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