Developmental Regulations Research Articles

Characterization of the P25 silk gene and associated insertion elements in Galleria mellonella

Insect silk genes attract attention by their precise territorial and developmental regulations and extremely high expression rates. Our present investigations demonstrated that the P25 silk gene of Galleria mellonella is down-regulated by ecdysteroid hormones. The gene was identified within 5217 nucleotides (nt) of two genomic clones. In contrast to other silk genes, Galleria P25 lacks the canonical TATA box. Transcription is initiated wihin a region of three nucleotides that lie at the end of a capsite initiator sequence ACAGT and about 90 nt downstream from a CAAT box. A stretch of 32 nt with a core sequence CTTTT was detected in the 5′ region of Galleria P25 as well as in the presumptive regulatory regions of all other silk genes that are expressed in the posterior silk gland. However, consensus sequences reported for the regulatory regions of Bombyx silk genes are not obvious in Galleria P25. The coding sequence of this gene includes 654 nt, is interrupted by 4 introns, and ends in position +3369; a potential polyadenylation signal starts at +4382. The gene contains 3 copies of a short interspersed nuclear element (SINE), which are located in the upstream region (−833 to −579) and in the first (+542 to +840) and second (+2259 to +2556) introns. The repeat, which was named Gm1, occurs in some other Galleria genes and exhibits homology to Bm1 SINE of the silkworm and to a similar element of a spider. Another insertion of at least 150 nt and with loosely defined borders is present in the 3′ untranslated region ( UTR) of Galleria P25. It includes a box (+3453 to +3552) of 99 nt that is tentatively called Lep1 because it was disclosed also in some other Lepidoptera. Lep1 seems to represent the core region of insertion elements that occur in the genoms of lepidopteran insects in various species specific and region specific modifications.

Dynamic changes in expression of glutamate transporter mRNAs in developing brain.

Developmental changes in gene expression for three glutamate transporter subtypes in the mouse brain were analysed by in situ hybridization. During embryonic stages, GluT-1 and GLT-1 mRNAs were expressed at high levels in the ventricular zone, whereas EAAC1 mRNA was not detected in the zone. In the mantle zone, transcription levels of three transporter mRNAs were low during embryonic stages, and these levels, especially those of the GluT-1 and GLT-1 mRNAs, displayed remarkable increases postnatally to reach maximal levels at 14 days of age. These dynamic developmental regulations suggest that the glutamate transporter not only regulates the excitatory synaptic transmission at mature stages, but might also be intimately involved in the brain development.

Developmental and Differential Regulations in Gene Expression of Xenopus Pleiotropic Factors-α and -β

Using conserved nucleotide sequences in mammalian osteoblast specific factor-1 (OSF-1) coding regions, we isolated two kinds of cDNA clones from the Xenopus brain library. The encoded proteins, named Xenopus pleiotrophic factors (X-PTFs)-α and -β, were 65 and 87% homologous to human midkine and OSF-1, respectively. In the adult frog, X- ptf-α was expressed in the ovary, brain, eye, bone, heart and lung, whereas X- ptf-β was expressed in the brain, eye and bone. By in situ hybridization of the tailbud embryo, X- ptf-α mRNA was detected rather broadly in the head/tail regions including the central nervous system (CNS), whereas X- ptf-β mRNA was restricted to the CNS, particularly in the hind-brain. During embryogenesis, X- ptf-α mRNA was detected in the one-cell stage embryo, whereas only zygotic expression was observed in X- ptf-β. X- ptf-β mRNAs contained ∼79 bp tandem repeats in the 3′-untranslated region, complementary to those found in retinoic acid cellular receptor mRNA and in the sense strand of short interspersed repeat transcripts in X. laevis.

Characterization of the 5' and promoter regions of the gene encoding the mouse neuronal cell adhesion molecule F3.

F3 is a 135 kDa neuronal cell surface adhesive glycoprotein belonging to the immunoglobulin supergene family (IgSF) which mediates heterophilic contact formation among neural cells and is involved in the control of neurite growth. F3 expression is regulated, during critical developmental periods, on neuronal subpopulations thus suggesting that control of F3 gene expression could be of morphogenetic relevance. To shed light on the mechanism involved in the control of F3 gene expression we isolated clones covering about 50 kilobases of the F3 gene which also included the promoter region. The study of F3 gene exon/intron organization revealed that, like other neural IgSF molecules, each of the first two F3 C2 domains is encoded by two exons while the N-terminus, the signal peptide and the 5' untranslated region are each encoded by distinct exons. A single transcription start site was identified, surrounded by a short 114 bp sequence able to direct reporter gene expression in both F3-expressing and -non-expressing cells. In addition, a cell type-specific enhancer, only active in F3-expressing cells, was found immediately upstream to it. Structural analysis of the promoter region revealed consensus sequences for binding transcription factors involved in cell type-specific and/or developmental regulations. Most of them are homeobox containing transcription factors thus suggesting that regulation of F3 gene expression could be part of a large developmental program.

Sugar sensing in higher plants.

Sugar repression of photosynthetic genes is likely a central control mechanism mediating energy homeostasis in a wide range of algae and higher plants. It overrides light activation and is coupled to developmental and environmental regulations. How sugar signals are sensed and transduced to the nucleus remains unclear. To elucidate sugar-sensing mechanisms, we monitored the effects of a variety of sugars, glucose analogs, and metabolic intermediates on photosynthetic fusion genes in a sensitive and versatile maize protoplast transient expression system. The results show that sugars that are the substrates of hexokinase (HK) cause repression at a low concentration (1 to 10 mM), indicating a low degree of specificity and the irrelevance of osmotic change. Studies with various glucose analogs suggest that glucose transport across the plasma membrane is necessary but not sufficient to trigger repression, whereas subsequent phosphorylation by HK may be required. The effectiveness of 2-deoxyglucose, a nonmetabolizable glucose analog, and the ineffectiveness of various metabolic intermediates in eliciting repression eliminate the involvement of glycolysis and other metabolic pathways. Replenishing intracellular phosphate and ATP diminished by hexoses does not overcome repression. Because mannoheptulose, a specific HK inhibitor, blocks the severe repression triggered by 2-deoxyglucose and yet the phosphorylated products per se do not act as repression signals, we propose that HK may have dual functions and may act as a key sensor and signal transmitter of sugar repression in higher plants.

Creutzfeld-Jakob Disease and Other Transmissible Spongiform Encephalopathies

<h3>ABSTRACT</h3> In a majority of ants, a newly mated queen independently founds a colony and claustrally raises her first brood without foraging outside the nest. During claustral independent colony foundation (ICF) in several ants, the esophagus of the founding queen expands and develops into a thoracic crop, which is then filled with a liquid substrate for larval feeding. It has been suggested that these substrates are converted from her body reserves (e.g., histolyzed flight muscles) or redistributed from a gastral crop. Here, we examined thoracic crop development in <i>Lasius japonicus</i> during claustral ICF. The foundresses claustrally fed their larvae from week 2 to 5 after ICF onset, and the first worker emerged at week 6. The development proceeded as follows: in week 0, foundress dorsal esophagus wall was pleated and thickened. Then, from week 2 to 5, the esophagus expanded dorsally toward where flight muscles had been present, following flight muscle histolysis. Gastral crop expansion followed esophagus expansion. Thus, thoracic crop formation may be spatiotemporally coordinated with flight muscle histolysis in <i>Lasius japonicus</i> queens, and similar developmental regulations might be common in other claustral ICF ants.

Developmental tissue expression and phylogenetic conservation of stathmin, a phosphoprotein associated with cell regulations.

Stathmin is a 19-kDa phosphoprotein presumably involved in regulations of cell proliferation, differentiation, and functions as an intracellular relay for extracellular signals activating diverse second messenger pathways. Antisera prepared against the whole protein or against two peptides (residues 15-27 and 134-149) recognized the two isoforms (alpha and beta) of stathmin in their different phosphorylated states on immunoblots. Also, the possible existence of a family of stathmin-related proteins is suggested by the detection with some sera of proteins of 17, 21, and 60 kDa in brain. Stathmin and its diverse molecular forms were detected in all mouse tissues tested, in varying concentrations. Depending on the tissue, it is 2-100 times more abundant in the neonate than in the adult. It is most abundant in brain at both developmental stages, the protein levels being paralleled by the expression of the corresponding mRNA as detected with a specific cDNA probe. Antibodies directed against the rat protein also reacted with stathmin-like proteins in the brain of other mammals, birds, reptiles, amphibians, and some fish species, and the various isoforms could be recognized on immunoblots. In conclusion, our results suggest that stathmin is most likely involved in two distinct types of regulations: 1) "developmental" regulations, related to cell proliferation, differentiation, and maturation, and 2) "functional" regulations mostly at the adult stage, and typically in the nervous system. In addition, stathmin is also phylogenetically well conserved at least in vertebrates. Together, these observations support the proposed ubiquitous nature and general importance of stathmin in biological regulations.