Plasma acrolein level in rheumatoid arthritis increases independently of the disease characteristics.

OBJECTIVE: This study aimed to clarify whether plasma acrolein level actually increases in rheumatoid arthritis (RA) patients, and to elucidate whether any relationship exists between the levels and the RA background variables. METHODS: Plasma levels of protein-conjugated acrolein (PC-Acro) in 84 patients (RA group) and 298 normal individuals (Control group) were measured by enzyme-linked immunosorbent assay procedures. The data were statistically analyzed with Wilcoxon rank-sum test, multiple logistic regression analyses and Spearman's rank correlation coefficient. RESULTS: The RA group showed significantly higher PC-Acro levels than the Control group (median [interquartile range]: 80.5 [63.2-105.2] and 65.9 [58.9-78.1] nmol/ml, respectively). Of background factors giving influence to PC-Acro level in the combination of the two groups, 'diagnosis of RA positive' indicated strong correlation to high PC-Acro level (odds ratio: 2.96; 95% confidence interval: 1.54-5.71). These increases of PC-Acro in the RA patients did not correlate to their disease duration and/or inflammatory variables: PC-Acro level could elevate even in early RA patients showing negative inflammatory findings. CONCLUSION: Plasma levels of PC-Acro increased with RA, but the levels did not correlate with RA background variables. This report provides the basis for further studies of early diagnosis of RA as well as its pathogenesis.

Modification of secondary head-forming activity of microinjected Ƨ-catenin mRNA by co-injected spermine and spermidine in Xenopus early embryos.

Polyamines are essential for cell growth and differentiation. In Xenopus early embryos, per embryo level of spermine is extremely low as compared with that of spermidine. To disclose the possible function of polyamines in Xenopus early embryos, we tested the effect of co-injection of spermine and spermidine on the functioning of exogenously microinjected in vitro-synthesized, Ƨ-catenin mRNA which is known to induce a secondary head after being microinjected into a ventral vegetal blastomere in 8-celled Xenopus embryos. Microinjection of Ƨ-catenin mRNA in fact induced a secondary axis with a secondary head, and co-injection of spermine or spermidine suppresses induction of the secondary head and secondary axis without drastic effects like induction of immediate cell death or execution of apoptosis at blastula stage. The inhibitory effects were dosage dependent, and at lower doses the inhibition was mainly on secondary head formation rather than on secondary axis formation. We performed similar experiments using GFP mRNA and confirmed that expression of GFP mRNA was also suppressed by co-injection of spermine. We mixed Ƨ-catenin mRNA with different amounts of spermine and performed electrophoresis on agarose gels, with a finding that the prior mixing greatly suppressed mRNA migration. These results suggest that an excess amount of spermine as well as spermidine exerts inhibitory effects on mRNA translation, and that the inhibition may be due to direct binding of polyamines to mRNA and a reduction of negative charges on mRNA molecules that might also induce the formation of cross link-like networks among mRNAs.

Effects of S-adenosylmethionine decarboxylase, polyamines, amino acids, and weak bases (amines and ammonia) on development and ribosomal RNA synthesis in Xenopus embryos.

We have been studying control mechanisms of gene expression in early embryogenesis in a South African clawed toad Xenopus laevis, especially during the period of midblastula transition (MBT), or the transition from the phase of active cell division (cleavage stage) to the phase of extensive morphogenesis (post-blastular stages). We first found that ribosomal RNA synthesis is initiated shortly after MBT in Xenopus embryos and those weak bases, such as amines and ammonium ion, selectively inhibit the initiation and subsequent activation of rRNA synthesis. We then found that rapidly labeled heterogeneous mRNA-like RNA is synthesized in embryos at pre-MBT stage. We then performed cloning and expression studies of several genes, such as those for activin receptors, follistatin and aldolases, and then reached the studies of S-adenosylmethionine decarboxylase (SAMDC), a key enzyme in polyamine metabolism. Here, we cloned a Xenopus SAMDC cDNA and performed experiments to overexpress the in vitro-synthesized SAMDC mRNA in Xenopus early embryos, and found that the maternally preset program of apoptosis occurs in cleavage stage embryos, which is executed when embryos reach the stage of MBT. In the present article, we first summarize results on SAMDC and the maternal program of apoptosis, and then describe our studies on small-molecular-weight substances like polyamines, amino acids, and amines in Xenopus embryos. Finally, we summarize our studies on weak bases, especially on ammonium ion, as the specific inhibitor of ribosomal RNA synthesis in Xenopus embryonic cells.

Isolation and characterization of Xenopus laevis homologs of the mouse inv gene and functional analysis of the conserved calmodulin binding sites.

The homozygous inv (inversion of embryonic turning) mouse mutant shows situs inversus and polycystic kidney disease, both of which result from the lack of the inv gene. Previously, we suggested that inv may be important for the left-right axis formation, not only in mice but also in Xenopus, and that calmodulin regulates this inv protein function. Here, we isolated and characterized two Xenopus laevis homologs (Xinv-1 and Xinv-2) of the mouse inv gene, and performed functional analysis of the conserved IQ motifs that interact with calmodulin. Xinv-1 expresses early in development in the same manner as mouse inv does. Unexpectedly, a full-length Xenopus inv mRNA did not randomize cardiac orientation when injected into Xenopus embryos, which is different from mouse inv mRNA. Contrary to mouse inv mRNA, Xenopus inv mRNA with mutated IQ randomized cardiac orientation. The present study indicates that calmodulin binding sites (IQ motifs) are crucial in controlling the biological activity of both mouse and Xenopus inv proteins. Although mouse and Xenopus inv genes have a quite similar structure, the interaction with calmodulin and IQ motifs of Xenopus inv and mouse inv proteins may regulate their function in different ways.

A developmental biological study of aldolase gene expression in Xenopus laevis.

We cloned cDNAs for Xenopus aldolases A, B and C. These three aldolase genes are localized on different chromosomes as a single copy gene. In the adult, the aldolase A gene is expressed extensively in muscle tissues, whereas the aldolase B gene is expressed strongly in kidney, liver, stomach and intestine, while the aldolase C gene is expressed in brain, heart and ovary. In oocytes aldolase A and C mRNAs, but not aldolase B mRNA, are extensively transcribed. Thus, aldolase A and C mRNAs, but not B mRNA, occur abundantly in eggs as maternal mRNAs, and strong expression of aldolase B mRNA is seen only after the late neurula stage. We conclude that aldolase A and C mRNAs are major aldolase mRNAs in early stages of Xenopus embryogenesis which proceeds utilizing yolk as the only energy source. aldolase B mRNA, on the other hand, is expressed only later in development in tissues which are required for dietary fructose metabolism. We also isolated the Xenopus aldolase C genomic gene (ca. 12 kb) and found that its promoter (ca. 2 kb) contains regions necessary for tissue-specific expression and also a GC rich region which is essential for basal transcriptional activity.

Overexpression of S-adenosylmethionine decarboxylase (SAMDC) in Xenopus embryos activates maternal program of apoptosis as a "fail-safe" mechanism of early embryogenesis.

In Xenopus, injection of S-adenosylmethionine decarboxylase (SAMDC) mRNA into fertilized eggs or 2-cell stage embryos induces massive cell dissociation and embryo-lysis at the early gastrula stage due to activation of the maternal program of apoptosis. We injected SAMDC mRNA into only one of the animal side blastomeres of embryos at different stages of cleavage, and examined the timing of the onset of the apoptotic reaction. In the injection at 4- and 8-cell stages, a considerable number of embryos developed into tadpoles and in the injection at 16- and 32-cell stages, all the embryos became tadpoles, although tadpoles obtained were sometimes abnormal. However, using GFP as a lineage tracer, we found that descendant cells of the blastomere injected with SAMDC mRNA at 8- to 32-cell stages are confined within the blastocoel at the early gastrula stage and undergo apoptotic cell death within the blastocoel, in spite of the continued development of the injected embryos. These results indicate that cells overexpressed with SAMDC undergo apoptotic cell death consistently at the early gastrula stage, irrespective of the timing of the mRNA injection. We assume that apoptosis is executed in Xenopus early gastrulae as a "fail-safe" mechanism to eliminate physiologically-severely damaged cells to save the rest of the embryo.

Gene Expression from Endogenou and Exogenously-introduced DNAs in Early Embryogenesis of Xenopus laevis: (Xenopus embryogenesis/nuclear RNA synthesis/midblastula transition/CAT gene injection/actin-CAT fusion gene).

In Xenopus laevis embryogenesis, gene expression from endogenous and exogenously-introduced DNAs is reported to start only after 12 rounds of cleavage, at the stage called midblastula transition (MBT). In isotopic labeling experiments, however, we found that the synthesis of heterogeneous mRNA-like RNA occurs from the early cleavage stage, and that gene expression from zygotic genomes occurs sequentially in three characteristically different phases: the pre-MBT phase, in which heterogeneous mRNA-like RNA and small amounts of small-molecular-weight RNAs are synthesized; the MBT phase, in which there is a large increase in 4S RNA synthesis, and the post-MBT phase, in which rRNA is also synthesized. Moreover in our studies on the expression of exogenously introduced DNA, we found that circular forms of bacterial chloramphenicol acetyltransferase (CAT) genes connected to viral promoters were expressed from the early cleavage stage, whereas circular forms of genes connected to Xenopus cardiac α-actin promoter were expressed only after the embryos reached the neurula stage, when the endogenous α-actin gene started to be expressed. We, therefore, conclude that in Xenopus embryogenesis, DNA-dependent RNA polymerases II, III and I are activated in this order, and that the promoter, not changes associated with the MBT, probably determine the timing of gene expression.

Expression of Embryo-Specific Epidermal XK81 Keratin Gene in Dissociated Cells of Xenopus laevis Animal Caps Co-cultured with Mesoderm-Inducing Vegetal Cells: (Xenopus embryonic cells/dissociated animal cap/keratin gene expression/α-actin mRNA/mesodermal induction).

Dissociated cells of whole embryos or their animal halves were cultured until the time when sibling embryos reached the neurula stage, and expression of genes for embryo-specific epidermal XK81 keratin, muscle-specific α-actin and histone H4 was studied by Northern blot analysis. In the experiments with dissociated midblastula cells, the expression of keratin gene, but not two other genes, was found to be inhibited in animal cap cells when these cells were cultured with vegetal cells. However, in the experiments with midgastrula cells, such inhibition was not observed even when animal cap cells were co-cultured with vegetal cells. Therefore, keratin gene expression in animal cap cells is sensitive at the midblastula stage, but resistant at the midgastrula stage, to the inhibitory activity by vegetal cells. To determine when such transition occurs, we prepared animal cap cells from embryos at different stages and co-cultured them with vegetal cells from midblastulae. Results obtained showed that the transition takes place at the late blastula stage (stage 9). These results suggest that the transcriptional system for the embryo-specific epidermal XK81 keratin gene is stabilized in animal cap cells prior to gastrulation, so that it is expressed autonomously, without being inhibited by contact with vegetal cells.

Half-Life of Histone H4 mRNA in Xenopus laevis Embryonic Cells at Different Stages: (histone H4 mRNA/Northern blotting/Xenopus embryonic cells/ half-life/actinomycin D).

By Northern blotting methods we have recently found that the relative amount of histone H4 mRNA per Xenopus embryo is constant during cleavage, doubles during the gastrula stage, then decreases at the neurula stage to the level slightly lower than that of the cleavage-embryo. At each developmental stage, the level of mRNA will depend on three parameters: amount of maternal mRNA remaining, rate of the synthesis of the mRNA and rate of the decay of the mRNA. In the present experiment, we compared rates of the decay of H4 mRNA in Xenopus embryonic cells at different stages by pulse-chase experiments with actinomycin D as an inhibitor of transcription. Under the conditions used, the half-life of H4 mRNA was estimated to be 90, 80, and 100 min, for the late blastula, late gastrula and neurula stages, respectively. The decay of H4 mRNA with a half-life of 90 min at the late blastula stage predicts exhaustion of most of maternal H4 mRNA by the early gastruia stage. The slightly longer half-life of H4 mRNA in neurula than in late gastrula cells suggests that H4 mRNA is more stable in neurula cells than in late gastrula cells, and therefore, the large decrease in the level of H4 mRNA observed at the neurula stage does not depend on the increase in the turnover-rate of H4 mRNA. Probably, neurula cells synthesize less H4 mRNA than late gastrula cells but utilize it for longer time.

Changes in the Level of Histone H4 mRNA in Xenopus leavies Embryogenesis.: (histone H4 mRNA/Xenopus early embryo/ Northern blotting/ S-1 protection/ paternal H4 gene expression).

In Xenopus laevis, the change in the amount of histone H4 mRNA per embryo measured by Northern blotting methods follows a unique change during early embryogenesis: It starts to increase first at the blastula stage, doubles by the gastrula stage then decreases considerably at the neurula stage, and then increases again from the tailbud stage on. The present paper establishes these developmental changes, and furthermore, provides evidence that the synthesis of H4 mRNA starts or at least increases to a detectable level at the midblastula stage as shown by S-1 protection analysis of the expression of paternal histone H4 genes in X. borealis (♀) and X. laevis (♂) hybrid embryos.

Cytological Studies of Large Nucleus-Like Structures Formed by Exogenously-Injected Linear and Circular DNAs in Fertilized Eggs of Xenopus laevis: (nucleus-like structures/DNA microinjection/Xenopus fertilized eggs/nuclear pore complex).

Relatively large amounts of linear or circular DNAs were injected into the animal or vegetal cytoplasm of fertilized eggs of Xenopus laevis and the nature of large nucleus-like structures formed by the injected DNAs was studied cytologically and electron microscopically. Results of fluorescent microscopic examination combined with immunohistochemical analysis strongly suggested that the injected DNAs were assembled into the nucleus-like structures probably after being complexed with maternal histones. The assemblage of nucleus-like structures preferentially took place in the animal most region of the egg, and the size of the nucleus-like structures formed depended on the amount of the injected DNA. The nucleus-like structures were surrounded by double membranes equipped with nuclear pore complexes, but there were at least two abnormal features in their ultrastructures. First, nucleus-like structures contained cytoplasmic particulate materials, most probably ribosomes and/or glycogen granules. Secondly, many of the nuclear pore complexes on the "nuclear envelope" appeared to be incomplete, with blebs formed from inner leaflet and protruded into the perinuclear space. Injected circular plasmid DNAs were also assembled into large nucleus-like structures in the animal most region, and appeared to be partitioned into descendant cells during the cleavage.

Elimination of heparan sulfate by heparitinases induces abnormal mesodermal and neural formation in Xenopus embryos.

The expression of heparan sulfate glycosaminoglycan (HS-GAG) was examined in Xenopus embryos during the developmental stages. Chemical analysis showed the existence of HS-GAG in the 35 S-labeled embryos. By western blot analysis using a specific anti-HS monoclonal antibody, HS-GAG related epitope was found after the neurulation on two protein bands, whose molecular weights were approximately 90 kDa and 100 kDa, respectively. Immunohistochemistry revealed that HS-GAG occurred exclusively in the animal hemisphere in early gastrulae, and then appeared predominantly on the sheath of the neural tube, the notochord and epithelium. To address whether HS-GAG chains contribute to Xenopus embryonic development, we eliminated the embryonic HS-GAG by injecting purified Flavobacterium heparitinases (HSase) into their blastocoels. Most of the injected embryos were aberrant in mesodermal and neural formation, and became acephalic. Histological examination showed that these embryos were completely devoid of the central nervous system and the mesodermal tissues. Neither heat-inactivated heparitinase nor chondroitinase showed such abnormality. The HS-GAG-eliminated embryos showed decreased expression of both muscular and neural-specific markers. These results suggest that HS-GAG plays an indispensable role in establishing the fundamental body plan during early Xenopus development.

Growth of fetal rat gastro-intestinal epithelial cells is region-specifically controlled by growth factors and substrata in primary culture.

The mammalian gastro-intestinal tract can be divided into three parts: esophagus and forestomach, glandular stomach, and intestine. We have previously reported primary culture systems for duodenal and glandular stomach epithelial cells in which the cells express tissue-specific marker proteins. However, the effects of growth factors and substrata on cell growth have not been fully investigated. In this study a primary culture system was established for forestomach epithelial cells and the mechanism by which the growth of gastro-intestinal epithelial cells is controlled in primary culture was examined. Forestomach, glandular stomach and duodenal epithelial cells proliferated rapidly in culture, increasing their numbers about 30-, 20-and 10-fold, respectively, in the first 5 days. Scanning electron microscopy showed that these three types of epithelial cells exhibited region-specific morphologies in culture. Results on the effects of growth factors and substrata on the proliferation of the epithelial cells revealed that the culture conditions required to induce maximal epithelial growth differed. Forestomach and glandular stomach epithelial cells required similar combinations of growth factors to proliferate, and these were quite different from those required for duodenal epithelial cells. Glandular stomach and duodenal epithelial cells could proliferate in a serum-free condition while forestomach epithelial cells could not. Thus, glandular stomach epithelial cells exhibited intermediate characteristics between forestomach and duodenal epithelial cells regarding their growth factor requirement. Glandular stomach and duodenal epithelial cells could not proliferate on plastic without collagen substrata while forestomach epithelial cells could. Duodenal epithelial cells proliferated faster on collagen gels than on collagen films, and forestomach epithelial cells faster on collagen films than on collagen gels. Glandular stomach epithelial cells proliferated similarly on both substrata. Thus again, glandular stomach epithelial cells exhibited intermediate characteristics between forestomach and duodenal epithelial cells regarding their substratum dependency. We conclude that the growth of gastro-intestinal epithelial cells is affected by both growth factors and substrata, and that glandular stomach epithelial cells exhibit intermediate characteristics between forestomach and duodenal epithelial cells in responding to these factors. These results suggest that a head-to-tail gradient exists in the gastro-intestinal tract which controls the epithelial response to growth factors and substrata.

Frizzled-10, up-regulated in primary colorectal cancer, is a positive regulator of the WNT - beta-catenin - TCF signaling pathway.

WNT signaling pathway is implicated in embryogenesis as well as in carcinogenesis. We have previously cloned and characterized Frizzled-1 (FZD1), FZD2, FZD3, FZD4, FZD5, FZD6, FZD7, FZD8, and FZD10, encoding seven-transmembrane-type WNT receptors. Here, expression of FZD10 mRNA in various types of human cancer and effects of FZD10 mRNA microinjection into Xenopus early embryos were investigated. Northern blot analyses revealed relatively high-level expression of 4.0-kb FZD10 mRNA in cervical cancer cell lines HeLa S3, SKG-I, SKG-IIIa, and in a glioblastoma cell line A-172. Matched tumor/normal expression array analysis revealed significant up-regulation of FZD10 mRNA in 2 cases of primary colon cancer. Function of FZD10 was next investigated by using Xenopus axis duplication assay, in which positive regulators of the WNT - beta-catenin - TCF signaling pathway induce axis duplication. Injection of wild-type FZD10 mRNA into the ventral marginal zone of 4-cell-stage Xenopus embryos induced partial axis duplication in 40% of embryos. Ventral injection of Thr579Ala FZD10 mRNA or Val581Leu FZD10 mRNA with mutations in the C-terminal Ser/Thr-X-Val motif also induced partial axis duplication in about 40% of embryos. Furthermore, ventral injection of FZD10 mRNA significantly augmented the potential of co-injected Xenopus wnt-8 (Xwnt-8) mRNA to induce complete axis duplication. These results suggest that up-regulation of FZD10 mRNA in several types of human cells might lead to carcinogenesis through activation of the beta-catenin - TCF signaling pathway synergistically with some class of WNTs.

Gene expression in Pre-MBT embryos and activation of maternally-inherited program of apoptosis to be executed at around MBT as a fail-safe mechanism in Xenopus early embryogenesis.

S-adenosylmethionine decarboxylase (SAMDC) is an enzyme which converts S-adenosylmethione (SAM), a methyl donor, to decarboxylated SAM (dcSAM), an aminopropyl donor for polyamine biosynthesis. In our studies on gene expression control in Xenopus early embryogenesis, we cloned the mRNA for Xenopus SAMDC, and overexpressed the enzyme by microinjecting its mRNA into Xenopus fertilized eggs. In the mRNA-injected embryos, the level of SAMDC was enormously increased, the SAM was exhausted, and protein synthesis was greatly inhibited, but cellular polyamine content did not change appreciably. SAMDC-overexpressed embryos cleaved and developed normally up to the early blastula stage, but at the midblastula stage, or the stage of midblastula transition (MBT), all the embryos were dissociated into cells, and destroyed due to execution of apoptosis. During cleavage SAMDC-overexpressed embryos transcribed caspase-8 gene, and this was followed by activation of caspase-9. When we overexpressed p53 mRNA in fertilized eggs, similar apoptosis took place at MBT, but in this case, transcription of caspase-8 did not occur, however activation of caspase-9 took place. Apoptosis induced by SAMDC-overexpression was completely suppressed by Bcl-2, whereas apoptosis induced by p53 overexpression or treatments with other toxic agents was only partially rescued. When we injected SAMDC mRNA into only one blastomere of 8- to 32-celled embryos, descendant cells of the mRNA-injected blastomere were segregated into the blastocoel and underwent apoptosis within the blastocoel, although such embryos continued to develop and became tadpoles with various extents of anomaly, reflecting the developmental fate of the eliminated cells. Thus, embryonic cells appear to check themselves at MBT and if physiologically severely-damaged cells occur, they are eliminated from the embryo by activation and execution of the maternally-inherited program of apoptosis. We assume that the apoptosis executed at MBT is a "fail-safe" mechanism of early development to save the embryo from accidental damages that take place during cleavage.

Cleavage and survival of Xenopus embryos exposed to 8 T static magnetic fields in a rotating clinostat.

In this study, we examined cleavage and survival of fertilized Xenopus embryos exposed to 8 T static magnetic fields (SMFs). We investigated fertilized Xenopus embryos exposed to magnetic field either in static chamber or in a rotating culture system. Our results showed that the exposure to the strong magnetic field of 8 T changed the third cleavage furrow from the usual horizontal one to a perpendicular one; however, when the direction of gravity was randomized by exposing embryos to magnetic field in a rotating culture system, the third cleavage furrow were formed horizontally, a finding which suggests that the observed distortion of the third cleavage furrow in magnetism-exposed embryos was accomplished by altering gravity effects which were elicited by diamagnetic force due to high gradient magnetic field. Our results also showed that the exposure to the strong magnetic field did not damage survival. These results demonstrate that SMF and altering gravity cause distortion of the third cleavage furrow and show that effects of exposing cleavage embryos to magnetic field were transient and did not affect the post-cleavage development. We also showed that strong magnetic field is not hazardous to the cleavage and blastula-gastrula transition of developing embryonic cells.

Occurrence of pre-MBT synthesis of caspase-8 mRNA and activation of caspase-8 prior to execution of SAMDC (S-adenosylmethionine decarboxylase)-induced, but not p53-induced, apoptosis in Xenopus late blastulae.

Overexpression of S-adenosylmethionine decarboxylase (SAMDC) in Xenopus fertilized eggs activates caspase-9 and executes maternal program of apoptosis shortly after midblastula transition (MBT). We find that overexpression of caspase-8 and p53, like that of SAMDC, induces apoptosis in Xenopus late blastulae. The apoptosis induced by p53 was abolished by injection of mRNA for xdm-2, a negative regulator of p53, and by injection of a peptide inhibitor or a dominant-negative type mutant of caspase-9, but not caspase-8. The apoptosis induced by SAMDC was not abolished by injection of xdm-2 mRNA, but was abolished by injection of a peptide inhibitor or a dominant-negative type mutant mRNA of both caspase-9 and caspase-8. Unlike caspase-9 mRNA, caspase-8 mRNA did not occur as a maternal mRNA rather induced to be expressed during cleavage stage (pre-MBT stage) by overexpression of SAMDC but not p53. Furthermore, while activities to process procaspase-8 and procaspase-9 appeared in SAMDC-overexpressed apoptotic embryos, the activity to process procaspase-8 did not appear in p53-overexpressed apoptotic embryos. We conclude there are at least two pathways in the execution of the maternal program of apoptosis in Xenopus embryos; one being through do novo expression of caspase-8 gene during cleavage stage, and the other without involvement of caspase-8.

Expression of circular and linearized bacterial chloramphenicol acetyltransferase genes with or without viral promoters after injection into fertilized eggs, unfertilized eggs and oocytes ofXenopus laevis.

Circular and linearized plasmids containing bacterial chloramphenicol acetyltransferase (CAT) genes connected or not connected to viral promoters were injected into fertilized eggs, unfertilized eggs and oocyte nuclei ofXenopus laevis, and CAT enzyme expression was studied under different conditions. Circular DNAs injected into fertilized eggs did not change their molecular form greatly, but CAT enzyme activity was expressed by the blastula or gastrula stage depending on the strength of the enhancer contained within the promoter. Linearized plasmid DNAs injected into fertilized eggs were concatemerized and replicated extensively by the blastula stage, and were expressed also actively irrespective of whether DNAs contained the promoter or not. The CAT enzyme activity was roughly comparable to the level of CAT mRNA in injected embryos. Similar results were obtained for both circular and linearized DNAs in unfertilized eggs, although the level of CAT enzyme expressed here was quite low. In oocyte nuclei, by contrast, only circular DNAs were expressed, and the expression was independent of whether or not the DNAs contained the promoter. The large concatemers formed in embryos comigrated with host DNA, but the majority of them disappeared later, at the tadpole stage, suggesting the extrachromosomal nature of these DNAs. The pronounced decrease in the amount of comigrating DNAs was accompanied by the disappearance of both CAT mRNA and enzyme activity. Therefore, we conclude that active CAT enzyme expression induced by injection of linearized DNAs in embryos and early stage larvae is due mainly to transcription from the transiently existing extra-chromosomal concatermers rather than from long-lasting, probably genome-integrated DNAs.

Mobilization of newly synthesized RNAs into polysomes inXenopus laevis embryos.

The mobilization of newly synthesized 18S and 28S rRNAs, 4S RNA and poly(A)+ RNA into polysomes was studied in isolated cells ofXenopus laevis embryos between cleavage and neurula stages. Throughout these stages, 4S RNA and poly(A)+ RNA were mobilized immediately following their appearance in the cytoplasm. 18S rRNA however, stayed in the ribosomal subunit fraction for about 30 min until the 28S rRNA appeared, when the two rRNAs were mobilized together at an equimolar ratio. This mobilization, at a 1:1 molar ratio, appeared to be realized at initiation monome formation. Thus, the efficiency of the mobilization of two newly synthesized rRNAs, shortly after their arrival at the cytoplasm, differed considerably but difference disappeared once steady state was reached.The contribution of newly synthesized 18S and 28S rRNAs to polysomes remains small throughout early development. around 3% of newly synthesized 4S RNA is polysomal which is the same distribution observed for unlabeled 4S RNA. Less than 10% of the newly synthesized cytoplasmic poly(A)+ RNA was mobilized into polysomes during cleavage, but in later stages the proportion increased to around 20%-25%. These results show that newly synthesized RNAs are utilized for protein synthesis at characteristic rates soon after they are synthesized during early embryonic development. On the basis of the data presented here and elsewhere we discuss quantitative aspects of the utilization of newly synthesized and maternal RNAs during early embryogenesis.

Isolation of Xenopus HGF gene promoter and its functional analysis in embryos and animal caps.

Previously, we isolated Xenopus HGF (hepatocyte growth factor) cDNA and showed in Xenopus embryos that expression of this gene starts at the late gastrula stage mainly in the ventral mesoderm, and furthermore that the expression is induced in animal cap by activin A and bFGF (basic fibroblast growth factor). Here we have cloned the Xenopus HGF gene, covering a 14 kb 5'-upstream region and a 0.2 kb 5'-coding region. Within about 0.5 kb of the 5'-flanking region, the Xenopus HGF gene contained a TATA-like element AATGAAA, one putative NF-1 binding site, two NF-IL-6 binding motif sequences, one putative TGF-ß-dependent inhibitory element (TIE) and one AP-1 binding site. A recombinant circular plasmid consisting of a 1.7 kb HGF promoter region and the bacterial chloramphenicol acetyltransferase (CAT) gene was first expressed at the late gastrula stage in the ventral mesoderm, as was the endogenous HGF gene. The expression of the fusion gene was induced in animal cap cells by activin A and bFGF although induction by the latter was not so strong. Using a series of 5'-deletion constructs introduced into animal caps, silencer elements, which seem to be essential for the gene's regionally correct expression, and the element responsible for induction by activin were found. The results show that the HGF gene promoter isolated here contains elements which may endow the gene with the regulative function for its temporally and spatially regulated expression, although the element necessary for induction by bFGF seems to be missing.