Judith A. Lengyel

A Drosophila Neurexin Is Required for Septate Junction and Blood-Nerve Barrier Formation and Function

Septate and tight junctions are thought to seal neighboring cells together and to function as barriers between epithelial cells. We have characterized a novel member of the neurexin family, Neurexin IV (NRX), which is localized to septate junctions (SJs) of epithelial and glial cells. NRX is a transmembrane protein with a cytoplasmic domain homologous to glycophorin C, a protein required for anchoring protein 4.1 in the red blood cell. Absence of NRX results in mislocalization of Coracle, a Drosophila protein 4.1 homolog, at SJs and causes dorsal closure defects similar to those observed in coracle mutants. nrx mutant embryos are paralyzed, and electrophysiological studies indicate that the lack of NRX in glial-glial SJs causes a breakdown of the blood-brain barrier. Electron microscopy demonstrates that nrx mutants lack the ladder-like intercellular septa characteristic of pleated SJs (pSJs). These studies identify NRX as the first transmembrane protein of SJ and demonstrate a requirement for NRX in the formation of septate-junction septa and intercellular barriers.

Rates of synthesis of major classes of RNA in Drosophila embryos

Abstract We have been successful in labeling to high specific activity (3 × 105 dpm/μg) the RNA synthesized by large numbers of Drosophila embryos. Embryos of various developmental stages were rendered permeable with octane and labeled with [3H]uridine for 1 hr. At each stage the total dpm incorporated into RNA and the specific activity of the UTP pool were measured and used to calculate the absolute rate of RNA synthesis per embryo. This rate increases during embryonic development, from 1 pmole UTP/hr at 2 hr after oviposition to 6 pmoles UTP/hr at 15 hr. The rates of synthesis of nuclear and cytoplasmic poly(A)− and poly(A)+ RNAs were determined by analyzing the fractionated RNAs from each stage by sucrose gradient sedimentation. There is a significant activation of nuclear RNA synthesis at the blastoderm stage (approximately 2 hr after oviposition). After blastoderm, the rates of synthesis of nuclear and cytoplasmic poly(A)− and poly(A)+ RNA per embryo increase continuously; the rate of synthesis of each of these classes per nucleus, however, remains fairly constant. After making corrections for turnover during the labeling period, we find that the rates of synthesis of the major classes of RNA per nucleus at the gastrula stage are: cytoplasmic poly(A)+ RNA, 0.06 fg/nucleus-min; hnRNA, 0.86 fg/nucleus-min; and ribosomal RNA, 0.46 fg/nucleus-min. These rates are compared to rates of RNA synthesis in sea urchin embryos.

Drosophila Rheb GTPase is required for cell cycle progression and cell growth.

Precise body and organ sizes in the adult animal are ensured by a range of signaling pathways. In a screen to identify genes affecting hindgut morphogenesis in Drosophila, we identified a P-element insertion in dRheb, a novel, highly conserved member of the Ras superfamily of G-proteins. Overexpression of dRheb in the developing fly (using the GAL4:UAS system) causes dramatic overgrowth of multiple tissues: in the wing, this is due to an increase in cell size; in cultured cells, dRheb overexpression results in accumulation of cells in S phase and an increase in cell size. Using a loss-of-function mutation we show that dRheb is required in the whole organism for viability (growth) and for the growth of individual cells. Inhibition of dRheb activity in cultured cells results in their arrest in G1 and a reduction in size. These data demonstrate that dRheb is required for both cell growth (increase in mass) and cell cycle progression; one explanation for this dual role would be that dRheb promotes cell cycle progression by affecting cell growth. Consistent with this interpretation, we find that flies with reduced dRheb activity are hypersensitive to rapamycin, an inhibitor of the growth regulator TOR. In cultured cells, the effect of overexpressing dRheb was blocked by the addition of rapamycin. These results imply that dRheb is involved in TOR signaling.

Changing rates of histone mRNA synthesis and turnover in Drosophila embryos

The rates of synthesis and turnover of histone mRNA in Drosophila embryos were determined by hybridization of in vivo and in vitro labeled embryonic RNA to Drosophila histone DNA of the recombinant plasmid cDm500. There is a large store of maternal histone mRNA, equivalent to at least 7 X 10(7) copies of each of the five classes of histone mRNA per embryo. Embryonic synthesis of histone mRNA begins at 90 min after oviposition, making the histone genes among the first to be transcribed by embryonic nuclei. Embryonic histone mRNA accumulates rapidly during the blastoderm and gastrula stages. The peak in the rate of histone mRNA synthesis per embryo coincides with the peak in the rate of DNA synthesis per embryo, which occurs at 6 hr after oviposition. After 6 hr, as the rate of DNA synthesis per embryo decreases, the rate of histone mRNA synthesis and the total mass of histone mRNA per embryo both drop sharply. The rate of histone mRNA synthesis per gene falls more than 60 fold in the first 13 hr after oviposition, from 1.3 -2.5 copies per gene-min at 2 hr to 0.02-0.03 copies per gene-min at 13 hr. From measurements of the mass of histone mRNA per embryo and of the rate of accumulation of newly synthesized histone mRNA at a number of stages of early embryogenesis we determined that the cytoplasmic half-life of histone mRNA decreases approximately 7 fold during early Drosophila development, from 2.3 hr at blastoderm to 20 min by the end of gastrulation. Thus the level of expression of histone genes in Drosophila development is controlled not only by the size of the maternal mRNA pool and changes in the rate of histone mRNA synthesis, but also by changes in the rate of histone mRNA turnover.

The zygotic mutant tailless affects the anterior and posterior ectodermal regions of the Drosophila embryo

The recessive zygotic lethal mutation tailless maps to region 100A5,6-B1,2 at the tip of the right arm of chromosome 3, and results in shortened pharyngeal ridges in the head skeleton of the mature embryo and the elimination of the eighth abdominal segment and telson. Although they have a normal body length, tailless embryos have a smaller number of abdominal segments, some of which are larger than normal. The mutant phenotype is seen as early as 8 hr postfertilization, when tailless embryos are observed to have fewer tracheal pits than wildtype. At 9 hr, tailless embryos appear to be missing segments A8, A9, and A10 and have an abnormal clypeolabrum, optic lobes, and procephalic lobe. Segments A4, A5, A6, and A7 appear larger in tailless embryos than wildtype at this stage. The tailless mutation, although affecting anterior and posterior ectodermal structures in the mature embryo, does not affect the formation of pole cells, the posterior midgut, or the proctodeum, which arise from the most posterior region of the embryo. The mutation does result, however, in the failure of Malpighian tubule formation. Consistent with its effect on ectodermal segments, tailless leads to a reduction in the number of segmented, paired ganglia in the ventral nerve cord as well as to an abrupt alteration in the posterior region of the tracheal system. The role the tailless gene may play in the formation of the most anterior and posterior regions of the embryos ectodermal body plan is discussed.

Changing rates of DNA and RNA synthesis in Drosophila embryos

Abstract Rates of DNA and RNA synthesis during Drosophila embryogenesis were measured by labeling octane-treated embryos with [ 14 C]thymidine and [ 3 H]uridine. Radioactivity incorporated per hour was converted to rates of synthesis using measurements of the pool-specific activity during the labeling periods. The rate of DNA synthesis during early embryogenesis increases to a maximum at 6 hr after oviposition and then decreases sharply. Measured rates of DNA synthesis were used to calculate that the total amount of DNA per embryo doubles every 18 min at blastoderm, every 70–80 min during gastrulation, and less than once every 7 hr at later stages. The rate of RNA accumulation per embryo increases continuously during the first 14 hr of embryogenesis. The rate of nuclear RNA synthesis per diploid amount of DNA, however, decreases fivefold between blastoderm and primary organogenesis. The cytoplasmic poly(A) + RNA synthesized by blastoderm embryos associates rapidly with polysomes. The relatively high rate of synthesis of polysomal poly(A) + RNA per nucleus at blastoderm allows the small number of nuclei present at blastoderm to make a significant quantitative contribution to the informational RNA active in the early embryo. At the end of blastoderm, approximately 14% of the mRNA being translated in the embryo has been synthesized after fertilization.

Localized JAK/STAT signaling is required for oriented cell rearrangement in a tubular epithelium

Rearrangement of cells constrained within an epithelium is a key process that contributes to tubular morphogenesis. We show that activation in a gradient of the highly conserved JAK/STAT pathway is essential for orienting the cell rearrangement that drives elongation of a genetically tractable model. Using loss-of-function and gain-of-function experiments, we show that the components of the pathway from ligand to the activated transcriptional regulator STAT are required for cell rearrangement in the Drosophila embryonic hindgut. The difference in effect between localized expression of ligand (Unpaired) and dominant active JAK (Hopscotch) demonstrates that the ligand plays a cell non-autonomous role in hindgut cell rearrangement. Taken together with the appearance of STAT92E in a gradient in the hindgut epithelium, these results support a model in which an anteroposterior gradient of ligand results in a gradient of activated STAT. These results provide the first example in which JAK/STAT signaling plays a required role in orienting cell rearrangement that elongates an epithelium.

Ecdysteroid-regulated heat-shock gene expression during Drosophila melanogaster development

Peaks in hsp 26, 28, and 83 RNA levels are correlated with peaks in ecdysteroid titers during mid-embryogenesis, pupariation, and mid-pupation, and with a peak in the level of RNA from the 74EF ecdysone puff at pupariation. Inhibition of the ecdysteroid peak at pupariation by temperature shift of the conditionally ecdysteroid-deficient strain ecd-1 was followed by a disappearance of hsp 26 RNA and a decline in hsp 83 RNA level; subsequent addition of exogeneous 20-OH-ecdysone to the temperature-shifted strain resulted in a severalfold increase in hsp 83 RNA level, and a dramatic increase in that of hsp 26. These results are consistent with the induction of the hsp 83, 28, and 26 genes by ecdysteroid at several developmental stages.

Control of tailless expression by bicoid, dorsal and synergistically interacting terminal system regulatory elements

Three different maternal morphogen gradients regulate expression of the gap gene tailless (tll), which is required to establish the acron and telson of the Drosophila embryo. To identify elements in the tll promoter that respond to these different maternal systems, we have generated promoter-lacZ fusions and transformed them into the germline. Expression of these constructs in both wild type and mutant embryos revealed the presence of at least two separate but synergistically interacting regions that mediate tll expression by the terminal system. This functional synergism between regulatory elements may play a role in the translation of the torso (tor) morphogen gradient into the sharp boundary of tll gene activity. In addition to regions mediating activation by the terminal system, regions mediating both activation and repression by bicoid (bcd), and repression by dorsal (dl) were identified. Binding sites of bcd protein in a 0.5 kb region, revealed by DNaseI footprinting, could be crucial for the bcd-dependent activation of tll expression in the anterior stripe.

Transcription and metabolism of RNA from the Drosophila melanogaster heat shock puff site 93D

Characteristics of the major heat shock puff site 93 D and the RNA transcribed from it have been investigated by hybridization to polytene chromosome preparations and to recombinant DNA. By saturation in situ hybridization, the length of the transcribed region at 93 D is twice that of the mRNA coding region at the heat shock puff site 87 A. From the known length of the heat shock mRNA sequence at 87 A, we calculate that the minimum length of the transcribed region at 93 D is 9.6 kb (kb = kilobase, i.e., 1,000 nucleotides). — The metabolism of RNA transcribed from 93 D has been compared with that of RNA coding for the major heat shock protein hsp70 in cells incubated for one hour at 35° C. Hsp70 mRNA sequences, assayed by hybridization to a specific recombinant DNA probe and by in situ hybridization to 87 A, were found in both poly(A)+ and poly(A)− cytoplasmic RNA and were more concentrated in cytoplasmic RNA than in nuclear RNA. In contrast, sequences complementary to 93 D, assayed by in situ hybridization, were more concentrated in nuclear than in cytoplasmic RNA. This implies that sequences from 93 D exit from the nucleus at a lower rate and/or are turned over in the cytoplasm at a higher rate, than sequences from 87 A. Site 93 D is also unusual in that its transcribed region is represented in both poly (A)+ and poly (A)− nuclear RNA, even though 93 D-complementary RNA in the cytoplasm is predominantly poly (A)−. Finally, only 28–58% of the length of DNA transcribed at 93 D is represented in cytoplasmic RNA, indicating that only a portion of the sequences transcribed from 93 D are exported from the nucleus. The transcripts from two heat shock loci, 93 D and 87 A, thus appear to be metabolized in significantly different ways.