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Ghysen, Alain; Dambly‐Chaudière, Christine
doi: 10.1002/bies.950150502pmid: 8343140
Different types of sense organs are present on the larva of Drosophila. Several genes that specify the type of sense organ that will form at a particular position have been recently identified. Here we review the functional and molecular analyses of these genes, and summarize the evidence which supports a role in the choice of which type of organ will be formed. Most or all of these genes are required for the appropriate specification of adult as well as larval sense organs, suggesting that the larval and adult systems share many gene requirements. Interestingly, the specifying genes identified so far in the peripheral nervous system are also expressed in subsets of cells in the central nervous system, where they might have similar roles.
Von Ahsen, Uwe; Schroeder, Renée
doi: 10.1002/bies.950150503pmid: 8343141
RNA can catalyse chemical reactions through its ability to fold into complex three‐dimensional structures and to specifically bind small molecules and divalent metal ions. The 2′‐hydroxyl groups of the ribose moieties contribute to this exceptional reactivity of RNA, compared to DNA. RNA is not only able to catalyse phosphate ester transfer reactions in ribonucleic acids, but can also show aminoacyl esterase activity, and is probably able to promote peptide bond formation. Bearing its potential for functioning both as a genome and as a gene product, RNA is suitable for in vitro evolution experiments enabling the selection of molecules with new properties. The growing repertoire of RNA catalysed reactions will establish RNA as a primordial molecule in the evolution of life.
doi: 10.1002/bies.950150504pmid: 8393666
Retinoids play an important role in development and differentiation(1,2). Their effect is mediated through nuclear receptors, RAR (α, β and γ) and RXR (α, β and γ), Abbreviations. RAR: retinoic acid receptor; RXR: retinoid X receptor; T3:thyroid hormone receptor; VD3R: vitamin D3 receptor; PPAR: peroxisome proliferator activated receptor; EcR ecdycsone receptor; USP, ultraspiracle; NGFI‐B: also referred to as nur77a; ELP: embryonal long terminal repeat‐binding protein; FTZ‐F1: positive regulator of the fushi tarazu gene in blastodermstage embryos of Drosophila melanogaster; GR: glucocorticoid receptor; ER: estrogen receptor; RARE, retinoic acid response element; PR: progesterone receptor; DR+x: direct repeat with a spacing of x nucleotides; DBD: DNA‐binding domain; CRABP I and II: cellular retinoic acid binding protein type I and II, respectively; MoMLV: Moloney Murine Leukemia Virus; TBP: TATA‐binding protein; TAF: TBP associated factor. which are members of a distinct subclass (hereafter referred to as type II) of the nuclear receptor superfamily that includes the thyroid hormone receptor (T3R), the vitamin D3 receptor (VD3R) and the peroxisome proliferator activated receptor (PPAR). Type II receptors transactivate through binding sites composed of closely related half‐sites (consensus sequence AGG/T TCA) arranged as direct repeats and, with the possible exception of RXR, do not bind to their cognate binding sites as homodimers but require RXR for high affinity binding. RXR thus provides a link between biologically distinct ligand induced pathways and is a potential target for cross‐regulation. In addition, RAR can utilize alternative routes to enhance transcription initiation mediated through transcriptional co‐activators which are expressed in a cell‐type specific manner.
doi: 10.1002/bies.950150505pmid: 8343142
Regulated secretory proteins are stored within specialized vesicles known as secretory granules. It is not known how proteins are sorted into these organelles. Regulated proteins may possess targeting signals which interact with specific sorting receptors in the lumen of the trans‐Golgi network (TGN) prior to their aggregation to form the characteristic dense‐core of the granule. Alternatively, sorting may occur as the result of specific aggregation of regulated proteins in the TGN. Aggregates may be directed to secretory granules by interaction of a targeting signal on the surface with a sorting receptor. Novel targeting signals which confer on regulated proteins a tendency to aggregate under certain conditions, and in so doing cause them to be incorporated into secretory granules, have been implicated. Specific targeting signals may also play a role in directing membrane proteins to secretory granules.
Clark, Janet A.; Amara, Susan G.
doi: 10.1002/bies.950150506pmid: 8102052
Many biologically active compounds including neurotransmitters, metabolic precursors, and certain drugs are accumulated intracellularly by transporters that are coupled to the transmembrane Na+ gradient. Amino acid neurotransmitter transporters play a key role in the regulation of extracellular amino acid concentrations and termination of neurotransmission in the CNS Abbreviations: CNS, central nervous system; GABA, γ‐aminobutyric acid; cDNA, complementary deoxyribonucleic acid; mRNA, messenger ribonucleic acid; NMDA, N‐methyl‐D‐aspartate; PKC, protein kinase C; PMA, phorbol 12‐myristate 13‐acetate; DAG, diacyl glycerol; R59022, DAG kinase inhibitor; AA, arachidonic acid; ACHC, cis‐3‐aminocyclohexanecarboxylic acid; GAT‐A, ACHC‐sensitive GABA transporter; GAT‐B, β‐alanine‐sensitive GABA transporter; GLY‐1 and GLYT‐1, glycine transporters; PROT‐1, proline transporter; BGT‐1, betaine transporter. . Transporters for the major amino acid neurotransmitters glutamate, GABA, and glycine are found in both neurons and glial cells. Recent work has resulted in the identification of cDNAs encoding several amino acid neurotransmitter transport proteins, all of which belong to the Na+‐and Cl−‐dependent transporter gene family. The diversity of this family suggests a degree of transporter heterogeneity that is greater than that indicated by biochemical and pharmacological studies.
Elledge, Stephen J.; Zhou, Zheng; Allen, James B.; Navas, Tony A.
doi: 10.1002/bies.950150507pmid: 8343143
Ribonucleotide reductase (RNR) catalyzes the rate limiting step in the production of deoxyribonucleotides needed for DNA synthesis. In addition to the well documented allosteric regulation, the synthesis of the enzyme is also tightly regulated at the level of transcription. mRNAs for both subunits are cell cycle regulated and inducible by DNA damage in all organisms examined, including E. coli, S. cerevisiae and H. sapiens. This DNA damage regulation is thought to provide a metabolic state that facilitates DNA replicational repair processes. S. cerevisiae also encodes a second large subunit gene, RNR3, that is expressed only in the presence of DNA damage. Genetic analysis of the DNA damage response in S. cerevisiae has shown that RNR expression is under both positive and negative control. Among mutants constitutive for RNR expression are the general transcriptional repression genes, SSN6 and TUP1. Mutations in POL1 and POL3 also activate RNR expression, indicating that the DNA damage sensory network may respond directly to blocks in DNA synthesis. A protein kinase, Dun1, has been identified that controls inducibility of RNR1, RNR2 and RNR3 in response to DNA damage and replication blocks. This result suggests that the RNR genes in S. cerevisiae form a regulon that is coordinately regulated by protein phosphorylation in response to DNA damage.
doi: 10.1002/bies.950150508pmid: 8102053
The blood‐brain barrier (BBB) is a complex structure formed by vascular endothelial cells, which serve to stabilize the homeostasic processes that are essential for neural functioning. The barrier relies on tight junctions between neighboring endothelial cells and a highly restricted passage of blood‐borne components through the endothelial lining. Selective transport mechanisms guarantee the essential import and export of metabolites through the BBB into and out of the neural microenvironment. The dual functions of barrier and carrier depend on distinct proteins, some of which have been characterized in detail.
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