Efficient trans-splicing of a yeast mitochondrial RNA group II intron implicates a strong 5' exon-intron interaction.

The reaction mechanism for self-splicing introns requires the existence of a 5' exon binding site on the intron. Experimental evidence is now presented consistent with the existence of such a binding site by demonstrating efficient and accurate trans-self-splicing of a yeast mitochondrial group II intron. Partial and complete trans-splicing reactions take place in the absence of branch formation, part of the usual pathway of nuclear splicing and group II self-splicing. In addition to indicating the existence of a 5' exon binding site on the intron, the results have mechanistic implications for group II self-splicing and perhaps for nuclear splicing as well.

Cell biology. TAPping into mRNA export.

There seem to be numerous pathways for exporting mRNAs from the nucleus to the cytoplasm. But working out which set of export adaptors and receptors transport individual mRNAs has been very difficult. In a Perspective, Moore and Rosbash discuss a new strategy using cell-penetrating peptide inhibitors for unraveling the routes of mRNA export in living cells (Gallouzi and Steitz).

Phase shifting of the circadian clock by induction of the Drosophila period protein.

Virtually all organisms manifest circadian (24-hour) rhythms, governed by an ill-defined endogenous pacemaker or clock. Several lines of evidence suggest that the Drosophila melanogaster period gene product PER is a clock component. If PER were central to the time-keeping mechanism, a transient increase in its concentration would cause a stable shift in the phase of the clock. Therefore, transgenic flies bearing a heat-inducible copy of PER were subjected to temperature pulses. This treatment caused long-lasting phase shifts in the locomotor activity circadian rhythm, a result that supports the contention that PER is a bona fide clock component.

PER protein interactions and temperature compensation of a circadian clock in Drosophila.

The periods of circadian clocks are relatively temperature-insensitive. Indeed, the perL mutation in the Drosophila melanogaster period gene, a central component of the clock, affects temperature compensation as well as period length. The per protein (PER) contains a dimerization domain (PAS) within which the perL mutation is located. Amino acid substitutions at the perL position rendered PER dimerization temperature-sensitive. In addition, another region of PER interacted with PAS, and the perL mutation enhanced this putative intramolecular interaction, which may compete with PAS-PAS intermolecular interactions. Therefore, temperature compensation of circadian period in Drosophila may be due in part to temperature-independent PER activity, which is based on competition between inter- and intramolecular interactions with similar temperature coefficients.

Molecular transfer of a species-specific behavior from Drosophila simulans to Drosophila melanogaster.

Drosophila males modulate the interpulse intervals produced during their courtship songs. These song cycles, which are altered by mutations in the clock gene period, exhibit a species-specific variation that facilitates mating. We have used chimeric period gene constructs from Drosophila melanogaster and Drosophila simulans in germline transformation experiments to map the genetic control of their song rhythm difference to a small segment of the amino acid encoding information within this gene.

Who's on first? The U1 snRNP-5' splice site interaction and splicing.

U1 small nuclear ribonucleoprotein (snRNP) is important for pre-mRNA splicing both in yeast (Saccharomyces cerevisiae) and mammalian systems. The RNA component of U1 snRNP, U1 snRNA, interacts by base pairing with pre-mRNA 5' splice sites. This article examines recent evidence suggesting that U1 snRNP is important for an early step in spliceosome assembly rather than a late step that contributes to the specificity of 5' splice-site cleavage.

Members of a family of Drosophila putative odorant-binding proteins are expressed in different subsets of olfactory hairs.

A polymerase chain reaction-based method was used to generate a Drosophila melanogaster antennal cDNA library from which head cDNAs were subtracted. We identified five cDNAs that code for antennal proteins containing six cysteines in a conserved pattern shared with known moth antennal proteins, including pheromone-binding proteins. Another cDNA codes for a protein related to vertebrate brain proteins that bind hydrophobic ligands. In all, we describe seven antennal proteins which contain potential signal peptides, suggesting that, like pheromone-binding proteins, they may be secreted in the lumen of olfactory hairs. The expression patterns of these putative odorant-binding proteins define at least four different subsets of olfactory hairs and suggest that the Drosophila olfactory apparatus is functionally segregated.

Evidence that the TIM light response is relevant to light-induced phase shifts in Drosophila melanogaster.

Light is a major environmental signal for the entrainment of circadian rhythms. In Drosophila melanogaster, recent experiments suggest that photic information is transduced to the clock through the timeless gene product, TIM. We provide genetic and spectral evidence supporting the relevance of TIM light responses to clock resetting. A missense mutant TIM, TIM-SL, exhibits greater sensitivity to light in both TIM protein disappearance and locomotor activity phase shifting assays. We show that the wavelength dependence of light-induced decreases in TIM levels and that of light-mediated phase shifting are virtually identical. Analysis of dose response of TIM disappearance in a variety of mutant genotypes suggests cell-autonomous light responses that are largely independent of the canonical visual transduction pathway.

Temporally regulated nuclear entry of the Drosophila period protein contributes to the circadian clock.

The Drosophila period protein (PER) is a predominantly nuclear protein and a likely component of a circadian clock. PER is required for daily oscillations in the transcription of its own gene and thus participates in a circadian feedback loop. In this study, key pacemaker neurons of the Drosophila brain were examined to determine whether the subcellular distribution of PER changes with the time of day. Indeed, PER was found to accumulate in the cytoplasm for several hours before entering the nucleus during a narrow time window. Three long-period mutations (perL) cause a delay in the timing of nuclear translocation and a further delay at elevated temperature. The data indicate that regulation of PER nuclear entry is critical for circadian oscillations by providing a necessary temporal delay between PER synthesis and its effect on transcription.

Antibodies to the period gene product of Drosophila reveal diverse tissue distribution and rhythmic changes in the visual system.

Polyclonal antibodies were prepared against the period gene product, which influences biological rhythms in D. melanogaster, by using small synthetic peptides from the per sequence as immunogens. The peptide that elicited the best antibody reagent was a small domain near the site of the pers (short period) mutation. Specific immunohistochemical staining was detected in a variety of tissue types: the embryonic CNS; a few cell bodies in the central brain of pupae; these and other cells in the central brain of adults, as well as imaginal cells in the eyes, optic lobes, and the gut. The intensity of per-specific staining in the visual system was found to oscillate, defining a free-running circadian rhythm with a peak in the middle of the night.

An antibody to the Drosophila period protein recognizes circadian pacemaker neurons in Aplysia and Bulla.

The molecular mechanisms of the pacemakers underlying circadian rhythms are not well understood. One molecule that presumably functions in the circadian clock of Drosophila is the product of the period (per) gene, which dramatically affects biological rhythms when mutated. An antibody specific for the per protein labels putative circadian pacemaker neurons and fibers in eyes of two marine gastropods, Aplysia and Bulla. As was found for the Drosophila per protein, there is a daily rhythm in the levels of the per-like antigen in Aplysia eyes. Thus, certain molecular features of the per protein, as well as aspects of the temporal regulation of its expression, may be conserved in circadian pacemakers of widely divergent species.

A promoterless period gene mediates behavioral rhythmicity and cyclical per expression in a restricted subset of the Drosophila nervous system.

Transgenic flies carrying a 7.2 kb piece of DNA from the period (per) gene were analyzed for the presence of circadian locomotor activity rhythms and fluctuations of per-encoded mRNA and protein. The 5' end of this genomic fragment is within the first intron, which precedes the coding region. This promotorless fragment could rescue circadian behavioral rhythms and mediate spatial expression of PER in a subset of wild-type per cells within the CNS and PNS. In one behaviorally rhythmic line, PER protein was found in only "per lateral neurons." In the rhythmic transgenics, per mRNA and protein levels undergo circadian cycling, as previously described for wild type. Cycling of PER in brain cells of flies carrying the same 7.2 kb piece of per DNA under the control of a heat shock promoter corroborated the hypothesis that per's molecular cyclings and behavioral rhythmicity are causally related.

The strength and periodicity of D. melanogaster circadian rhythms are differentially affected by alterations in period gene expression.

The per gene of D. melanogaster influences or participates in the generation of biological rhythms. Previous experiments have identified the head as the location from which per exerts its effect on circadian rhythms. To localize further this region and to examine the effects of altered levels and altered spatial expression patterns of the per gene on circadian rhythms of locomotor activity, we have characterized transformed lines containing per gene constructs missing substantial cis-acting regulatory information. The data suggest that wild-type levels of per gene expression are necessary in only a small fraction of the nervous system for near wild-type periods, whereas a larger fraction of per-expressing cells in the brain contributes to the strength of the circadian rhythms.

Drosophila CRY is a deep brain circadian photoreceptor.

cry (cryptochrome) is an important clock gene, and recent data indicate that it encodes a critical circadian photoreceptor in Drosophila. A mutant allele, cry(b), inhibits circadian photoresponses. Restricting CRY expression to specific fly tissues shows that CRY expression is needed in a cell-autonomous fashion for oscillators present in different locations. CRY overexpression in brain pacemaker cells increases behavioral photosensitivity, and this restricted CRY expression also rescues all circadian defects of cry(b) behavior. As wild-type pacemaker neurons express CRY, the results indicate that they make a striking contribution to all aspects of behavioral circadian rhythms and are directly light responsive. These brain neurons therefore contain an identified deep brain photoreceptor, as well as the other circadian elements: a central pace-maker and a behavioral output system.

The timSL mutant of the Drosophila rhythm gene timeless manifests allele-specific interactions with period gene mutants.

To identify new components of the Drosophila circadian clock, we screened chemically mutagenized flies for suppressors or enhancers of the long periods characteristic of the period (per) mutant allele perL. We isolated a novel mutant that maps to the rhythm gene timeless (tim). This novel allele, timSL, alters the temporal pattern of perL protein nuclear localization and restores temperature compensation to perL flies. timSL more generally manifests specific interactions with different per alleles. The identification of this first period-altering tim allele provides further evidence that TIM is a major component of the clock, and the allele-specific interactions with PER provide evidence that the PER/TIM heterodimer is a unit of circadian function. Although timSL fails to restore PER-L/TIM temperature insensitivity in yeast, it alters the TIM phosphorylation pattern during the late night. The effects on phosphorylation suggest that timSL functions as a partial bypass suppressor of perL and provide evidence that the TIM phosphorylation program contributes to the circadian timekeeping mechanism.

Molecular control of circadian rhythms.

Circadian rhythms are virtually ubiquitous in eukaryotes and have been shown to exist even in some prokaryotes. The generally accepted view is that these rhythms are generated by an endogenous clock. Recent progress, especially in the Drosophila, Neurospora and mouse systems, has revealed new clock components and mechanisms. These include the mouse clock gene, the Drosophila timeless gene, and the role of light in Neurospora.

mRNA nuclear export.

The export of mRNA from the nucleus to the cytoplasm is an essential step in the expression of genetic information in eukaryotes. It is an energy-dependent process and involves transport across the nuclear pores. It requires both cis-acting ribonucleoprotein particle signals and specific trans-acting factors. Although much remains to be learned, recent information has begun to define this pathway at both the cellular and biochemical levels and indicates that it is used as a key regulatory step by several viruses.

The DECD box putative ATPase Sub2p is an early mRNA export factor.

Nuclear mRNA metabolism relies on the interplay between transcription, processing, and nuclear export. RNA polymerase II transcripts experience major rearrangements within the nucleus, which include alterations in the structure of the mRNA precursors as well as the addition and perhaps even removal of proteins prior to transport across the nuclear membrane. Such mRNP-remodeling steps are thought to require the activity of RNA helicases/ATPases. One such protein, the DECD box RNA-dependent ATPase Sub2p/UAP56, is involved in both early and late steps of spliceosome assembly. Here, we report a more general function of Saccharomyces cerevisiae Sub2p in mRNA nuclear export. We observe a rapid and dramatic nuclear accumulation of poly(A)(+) RNA in strains carrying mutant alleles of sub2. Strikingly, an intronless transcript, HSP104, also accumulates in nuclei, suggesting that Sub2p function is not restricted to splicing events. The HSP104 transcripts are localized in a single nuclear focus that is suggested to be at or near their site of transcription. Intriguingly, Sub2p shows strong genetic and functional interactions with the RNA polymerase II-associated DNA/DNA:RNA helicase Rad3p as well as the nuclear RNA exosome component Rrp6p, which was independently implicated in the retention of mRNAs at transcription sites. Taken together, our data suggest that Sub2p functions at an early step in the mRNA export process.

The importin-beta family member Crm1p bridges the interaction between Rev and the nuclear pore complex during nuclear export.

BACKGROUND: The human immunodeficiency virus (HIV-1) uses the viral protein Rev to regulate gene expression by promoting the export of unspliced and partially spliced viral transcripts. Rev has been shown to function in a variety of organisms, including Saccharomyces cerevisiae. The export activity of Rev depends on a nuclear export signal (NES), which is believed to interact either directly or indirectly with the nuclear pore complex to carry out its export function. Crm1p is a member of the importin-beta protein family, other members of which are known to be directly involved in nuclear import. Crm1p has recently been shown to contribute to nuclear export in vertebrate systems. Here, we have studied this mechanism of nuclear to cytoplasmic transport. RESULTS: Viable mis-sense mutations in the CRM1 gene substantially reduced or eliminated the biological activity of Rev in S. cerevisiae, providing strong evidence that Crm1p also contributes to transport of Rev NES-containing proteins and ribonucleoproteins in this organism. Crm1p interacted with FG-repeat-containing nuclear pore proteins as well as Rev, and we have demonstrated that the previously described two-hybrid interaction between Rev and the yeast nuclear pore protein Rip1p is dependent on wild-type Crm1p. CONCLUSIONS: We conclude that Crm1p interacts with the Rev NES and nuclear pore proteins during delivery of cargo to the nuclear pore complex. Our findings also agree well with current experiments on Crm1p orthologs in Schizosaccharomyces pombe and in vertebrate systems.

Two genes for ribosomal protein 51 of Saccharomyces cerevisiae complement and contribute to the ribosomes.

We cloned and sequenced the second gene coding for yeast ribosomal protein 51 (RP51B). When the DNA sequence of this gene was compared with the DNA sequence of RP51A (J.L. Teem and M. Rosbash, Proc. Natl. Acad. Sci. U.S.A. 80:4403--4407, 1983), the following conclusions emerged: both genes code for a protein of 135 amino acids; both open reading frames are interrupted by a single intron which occurs directly after the initiating methionine; the open reading frames are 96% homologous and code for the same protein with the exception of the carboxy-terminal amino acid; DNA sequence homology outside of the coding region is extremely limited. The cloned genes, in combination with the one-step gene disruption techniques of Rothstein (R. J. Rothstein, Methods Enzymol. 101:202-211, 1983), were used to generate haploid strains containing mutations in the RP51A or RP51B genes or in both. Strains missing a normal RP51A gene grew poorly (180-min generation time versus 130 min for the wild type), whereas strains carrying a mutant RP51B were relatively normal. Strains carrying mutations in the two genes grew extremely poorly (6 to 9 h), which led us to conclude that RP51A and RP51B were both expressed. The results of Northern blot and primer extension experiments indicate that strains with a wild-type copy of the RP51B gene and a mutant (or deleted) RP51A gene grow slowly because of an insufficient amount of RP51 mRNA. The growth defect was completely rescued with additional copies of RP51B. The data suggest that RP51A contributes more RP51 mRNA (and more RP51 protein) than does RP51B and that intergenic dosage compensation, sufficient to rescue the growth defect of strains missing a wild-type RP51A gene, does not take place.