Analysis of the origin and development of hatching gland cells by transplantation of the embryonic shield in the fish, Oryzias latipes

Hatching gland cells of the medaka, Oryzias latipes, have been observed to differentiate from the anterior end of the hypoblast, which seems to first involute at the onset of gastrulation. These results suggest that the hatching gland cells of medaka originate from the embryonic shield, the putative organizer of this fish. The present study investigated whether hatching gland cells really originate from the embryonic shield in the medaka. Transplantation experiments with embryonic shield and in situ hybridization detection of hatching enzyme gene expression as a sign of terminal differentiation of the gland cells were carried out. The analysis was performed according to the following processes. First, identification and functional characterization of the embryonic shield region were made by determining the expression of medaka goosecoid gene and its organizer activity. Second, it was confirmed that the embryonic shield had an organizer activity, inducing a secondary embryo, and that the developmental patterns of hatching gland cells in primary and secondary embryos were identical. Finally, the hatching gland cells as identified by hatching enzyme gene expression were found to coincide with the dye-labeled progeny cells of the transplanted embryonic shield. In conclusion, it was determined that hatching gland cells were derived from the embryonic shield that functioned as the organizer in medaka.     

Linking gene regulation to cell behaviors in the posterior growth zone of sequentially segmenting arthropods

Virtually all arthropods all arthropods add their body segments sequentially, one by one in an anterior to posterior progression. That process requires not only segment specification but typically growth and elongation. Here we review the functions of some of the key genes that regulate segmentation: Wnt, caudal, Notch pathway, and pair-rule genes, and discuss what can be inferred about their evolution. We focus on how these regulatory factors are integrated with growth and elongation and discuss the importance and challenges of baseline measures of growth and elongation. We emphasize a perspective that integrates the genetic regulation of segment patterning with the cellular mechanisms of growth and elongation.     

The chemical nature of the factor responsible for embryonic induction: An historical overview

The discovery by Hans Spemann of the “organizer” tissue and its ability to induce the formation of the amphibian embryo’s neural tube inspired leading embryologists to attempt to elucidate embryonic induction’s underlying mechanisms. Since then several studies have described several developmental model system to better understand the role of specific signaling molecules, the interplay of different signals and tissue interactions in regulating tissue induction and patterning events. Different groups of workers set out to subject embryonic amphibian tissues and inductive adult organs to various extraction methods in the hope that the active agents could be isolated and chemically identified. In addition, a large number of well characterized chemical compounds were tested.     

Development of silver stained structures during spermatogenesis in different genera of Formicidae

Development of silver stained structures during the spermatogenesis of Tapinoma nigerrlum, Pheidole pallidula, Tetramorium caespitum, Tetramorium semilaeve, Lasius niger and Plagiolepis schmitzii are studied. Nucleolar masses are only observed in early prophase. Obvious NORs are present in metaphase in all genera and species studied. However, there are no nucleolar Ag precipitates after metaphase. A resumption of silver stainability occurs in round spermatids. The majority of these genera present differential activity between the existing NORs. In T. nigerrimum there is primary or secondary NOR activity in all chromosomes of the complement, although there are interpopulation differences in relation to the NOR activity. In the remaining genera only certain chromosomes present NOR activity. Interpopulation genetic differences and environmental factors can cause differential activity of secondary NORs as observed in Tapinoma nigerrimum.     

Numerical variation of nucleolar organizer regions after silver staining in domestic and wild Suidae (Mammalia)

Selective silver staining was used to investigate the cellular distribution of numbers of nucleolar organizer regions (NORs) in domestic pigs (Sus scrofa) of eight different breeds, the European wild boar (S. scrofa scrofa), Indonesian wild boar (S. scrofa vittatus), Javan warty pig (S. verrucosus), Sulawesi warty pig (S. celebensis), and pigmy hog (S. salvanius). In the domestic pig as well as in the wild (sub)species of Sus, actively transcribing ribosomal RNA genes were found to be present in the secondary constrictions of chromosome pairs 10 and 8. Chromosomes 10 were consistently Ag-positive. Chromosomes 8 less frequently showed Ag-NORs, resulting in different mean numbers of Ag-NORs per individual animal. Mean Ag-NOR numbers per breed or (sub)species were generally higher in the wild representatives of Sus than in the domestic breeds. The highest mean numbers of Ag-NORs were observed in the Meishan breed and in S. celebensis and S. salvanius. The Meishan breed appears to be conservative in Ag-NOR staining pattern, being more comparable to the Asian wild Suidae than to the European breeds.     

尼罗罗非鱼染色体的C带、Ag带和减数分裂联会复合体的研究

以Sumner法和界面铺张——硝酸银技术,对尼罗罗非鱼(Tilapia nilotica)染色体C带、Ag染带及减数分裂前期精母细胞联会复合体(SC)进行了显微和亚显微结构观察。 尼罗罗非鱼的2n=44,核型可分为三个组:第一组为4对亚中着丝粒染色体;第二组为17对亚端着丝粒染色体;第三组为具1对端着丝粒的特大染色体。 结构异染色质主要分布于着丝粒附近,其中Nos.6、8、15亚中着丝粒染色体短臂全部深染。带有银染核仁组织者(Ag-NORs)染色体的数目为2—6条,NORs均位于6、8、15亚中着丝粒染色体短臂。 银染色可清楚地显示尼罗罗非鱼的联会复合体(SC)结构和减数分裂行为。SC组型与有丝分裂染色体的组型有较好的一致性。     

Isolation and characterization of Chinese hamster ribosomal DNA clones

We have examined the ribosomal RNA (rRNA) genes of the Chinese hamster ovary (CHO) cell line. A partial EcoRI library of genomic CHO DNA was prepared using lambda Charon-4A. We isolated two recombinants containing the region transcribed as 45S pre-rRNA and 13 kb of external spacer flanking 5' and 3' to the transcribed region. These sequences show restriction site homology with the vast majority of the genomic sequences complementary to rRNA. In addition to this form of rDNA, Southern blot analysis of EcoRI-cut CHO genomic DNA reveals numerous minor fragments ranging from 2 to 19 kb which are complementary to 18S rRNA. We isolated one clone which contains the 18S rRNA gene and sequences 5' which appear to contain length heterogeneity within the non-transcribed spacer region. We have nine additional cloned EcoRI fragments in which the homology with 18S rRNA is limited to a 0.9-kb EcoRI-HindIII fragment. This EcoRI-HindIII fragment is present in each of the cloned EcoRI fragments, and is flanked on both sides by apparently nonribosomal sequences which bear little restriction site homology with each other or the major cloned rDNA repeat.