Morphological coupling in development: lessons from prokaryotes.

At certain junctures in development, gene transcription is coupled to the completion of landmark morphological events. We refer to this dependence on morphogenesis for gene expression as "morphological coupling." Three examples of morphological coupling in prokaryotes are reviewed in which the activation of a transcription factor is tied to the assembly of a critically important structure in development.

A family of membrane-embedded metalloproteases involved in regulated proteolysis of membrane-associated transcription factors.

We present evidence that the sporulation protein SpoIVFB of Bacillus subtilis is a member of a newly recognized family of metalloproteases that have catalytic centers adjacent to or within the membrane. SpoIVFB is required for converting the membrane-associated precursor protein, pro-sigma(K), to the mature and active transcription factor sigma(K) by proteolytic removal of an N-terminal extension of 20 amino acids. SpoIVFB and other family members share the conserved sequence HEXXH, a hallmark of metalloproteases, as well as a second conserved motif NPDG, which is unique to the family. Both motifs, which are expected to form the catalytic center of the protease, overlap hydrophobic segments that are predicted to be separate transmembrane domains. The only other characterized member of this family of membrane-embedded metalloproteases is the mammalian Site-2 protease (S2P), which is required for the intramembrane cleavage of the eukaryotic transcription factor sterol regulatory element binding protein (SREBP). We report that amino acid substitutions in the two conserved motifs of SpoIVFB impair pro-sigma(K) processing and sigma(K)-directed gene expression during sporulation. These results and those from a similar analysis of S2P support the interpretation that both proteins are founding members of a family of metalloproteases involved in the activation of membrane-associated transcription factors. Thus, the pathways that govern the activation of the prokaryotic transcription factor pro-sigma(K) and the mammalian transcription factor SREBP not only are analogous but also use processing enzymes with strikingly homologous features.

Functioning of the Drosophila integral U1/U2 protein Snf independent of U1 and U2 small nuclear ribonucleoprotein particles is revealed by snf(+) gene dose effects.

Snf, encoded by sans fille, is the Drosophila homolog of mammalian U1A and U2B" and is an integral component of U1 and U2 small nuclear ribonucleoprotein particles (snRNPs). Surprisingly, changes in the level of this housekeeping protein can specifically affect autoregulatory activity of the RNA-binding protein Sex-lethal (Sxl) in an action that we infer must be physically separate from Snf's functioning within snRNPs. Sxl is a master switch gene that controls its own pre-mRNA splicing as well as splicing for subordinate switch genes that regulate sex determination and dosage compensation. Exploiting an unusual new set of mutant Sxl alleles in an in vivo assay, we show that Snf is rate-limiting for Sxl autoregulation when Sxl levels are low. In such situations, increasing either maternal or zygotic snf(+) dose enhances the positive autoregulatory activity of Sxl for Sxl somatic pre-mRNA splicing without affecting Sxl activities toward its other RNA targets. In contrast, increasing the dose of genes encoding either the integral U1 snRNP protein U1-70k, or the integral U2 snRNP protein SF3a(60), has no effect. Increased snf(+) enhances Sxl autoregulation even when U1-70k and SF3a(60) are reduced by mutation to levels that, in the case of SF3a(60), demonstrably interfere with Sxl autoregulation. The observation that increased snf(+) does not suppress other phenotypes associated with mutations that reduce U1-70k or SF3a(60) is additional evidence that snf(+) dose effects are not caused by increased snRNP levels. Mammalian U1A protein, like Snf, has a snRNP-independent function.

RNA binding activity of heterodimeric splicing factor U2AF: at least one RS domain is required for high-affinity binding.

The pre-mRNA splicing factor U2AF (U2 small nuclear ribonucleoprotein particle [snRNP] auxiliary factor) plays a critical role in 3' splice site selection. U2AF binds site specifically to the intron pyrimidine tract between the branchpoint and the 3' splice site and targets U2 snRNP to the branch site at an early step in spliceosome assembly. Human U2AF is a heterodimer composed of large (hU2AF65) and small (hU2AF35) subunits. hU2AF65 contains an arginine-serine-rich (RS) domain and three RNA recognition motifs (RRMs). hU2AF35 has a degenerate RRM and a carboxyl-terminal RS domain. Genetic studies have recently shown that the RS domains on the Drosophila U2AF subunit homologs are each inessential and might have redundant functions in vivo. The site-specific pyrimidine tract binding activity of the U2AF heterodimer has previously been assigned to hU2AF65. While the requirement for the three RRMs on hU2AF65 is firmly established, a role for the large-subunit RS domain in RNA binding remains unresolved. We have analyzed the RNA binding activity of the U2AF heterodimer in vitro. When the Drosophila small-subunit homolog (dU2AF38) was complexed with the large-subunit (dU2AF50) pyrimidine tract, RNA binding activity increased 20-fold over that of free dU2AF50. We detected a similar increase in RNA binding activity when we compared the human U2AF heterodimer and hU2AF65. Surprisingly, the RS domain on dU2AF38 was necessary for the increased binding activity of the dU2AF heterodimer. In addition, removal of the RS domain from the Drosophila large-subunit monomer (dU2AF50DeltaRS) severely impaired its binding activity. However, if the dU2AF38 RS domain was supplied in a complex with dU2AF50DeltaRS, high-affinity binding was restored. These results suggest that the presence of one RS domain of U2AF, on either the large or small subunit, promotes high-affinity pyrimidine tract RNA binding activity, consistent with redundant roles for the U2AF RS domains in vivo.

Molecular genetic analysis of the heterodimeric splicing factor U2AF: the RS domain on either the large or small Drosophila subunit is dispensable in vivo.

The pre-mRNA splicing factor U2AF (U2 snRNP auxiliary factor) has an essential role in 3' splice site selection. U2AF binds the intron pyrimidine tract between the branchpoint and the 3' splice site and recruits U2 snRNP to the branch site at an early step in spliceosome assembly. Human U2AF is a heterodimer composed of large (hU2AF65) and small (hU2AF35) subunits. Both subunits contain a domain enriched in arginine-serine dipeptide repeats termed an RS domain. The two U2AF RS domains have been assigned essential and independent roles in spliceosome assembly in vitro-the hU2AF65 RS domain is required to target U2 snRNP to the branch site and the hU2AF35 RS domain is necessary for protein-protein interactions with constitutive and alternative splicing factors. We have investigated the functional requirements for the RS domains on the Drosophila U2AF homolog in vivo. In sharp contrast to its essential role in U2 snRNP recruitment in vitro, the RS domain on the Drosophila large subunit homolog (dU2AF50) was completely dispensable in vivo. Prompted by this unexpected result, we analyzed the RS domain on the Drosophila small subunit homolog (dU2AF38). Despite its requirement for enhancer-dependent splicing activity in vitro, the dU2AF38 RS domain was also inessential in vivo. Finally, we have tested whether the Drosophila U2AF heterodimer requires any RS domain. Flies mutant for both the small and large subunits could not be rescued by dU2AF50deltaRS and dU2AF38deltaRS transgenes. Therefore, in contrast to the separate roles assigned to the U2AF RS domains in vitro, our genetic data suggest that they may have redundant functions in vivo.

Interaction between subunits of heterodimeric splicing factor U2AF is essential in vivo.

The heterodimeric pre-mRNA splicing factor, U2AF (U2 snRNP auxiliary factor), plays a critical role in 3' splice site selection. Although the U2AF subunits associate in a tight complex, biochemical experiments designed to address the requirement for both subunits in splicing have yielded conflicting results. We have taken a genetic approach to assess the requirement for the Drosophila U2AF heterodimer in vivo. We developed a novel Escherichia coli copurification assay to map the domain on the Drosophila U2AF large subunit (dU2AF50) that interacts with the Drosophila small subunit (dU2AF38). A 28-amino-acid fragment on dU2AF50 that is both necessary and sufficient for interaction with dU2AF38 was identified. Using the copurification assay, we scanned this 28-amino-acid interaction domain for mutations that abrogate heterodimer formation. A collection of these dU2AF50 point mutants was then tested in vivo for genetic complementation of a recessive lethal dU2AF50 allele. A mutation that completely abolished interaction with dU2AF38 was incapable of complementation, whereas dU2AF50 mutations that did not effect heterodimer formation rescued the recessive lethal dU2AF50 allele. Analysis of heterodimer formation in embryo extracts derived from these interaction mutant lines revealed a perfect correlation between the efficiency of subunit association and the ability to complement the dU2AF50 recessive lethal allele. These data indicate that Drosophila U2AF heterodimer formation is essential for viability in vivo, consistent with a requirement for both subunits in splicing in vitro.

Chemical shift mapping of the RNA-binding interface of the multiple-RBD protein sex-lethal.

The Drosophila protein Sex-lethal (Sxl) contains two RNP consensus-type RNA-binding domains (RBDs) separated by a short linker sequence. Both domains are essential for high-affinity binding to the single-stranded polypyrimidine tract (PPT) within the regulated 3' splice site of the transformer (tra) pre-mRNA. In this paper, the effect of RNA binding to a protein fragment containing both RBDs from Sxl (Sxl-RBD1 + 2) has been characterized by heteronuclear NMR. Nearly complete (85-90%) backbone resonance assignments have been obtained for unbound and RNA-bound states of Sxl-RBD1 + 2. A comparison of amide 1H and 15N chemical shifts between free and bound states has highlighted residues which respond to RNA binding. The beta-sheets in both RBDs (RBD1 and RBD2) form an RNA interaction surface, as has been observed in other RBDs. A significant number of residues display different behavior when comparing RBD1 and RBD2. This argues for a model in which RBD1 and RBD2 of Sxl have different or nonanalogous points of interaction with the tra PPT. R142 (in RBD2) exhibits the largest chemical shift change upon RNA binding. The role of R142 in RNA binding was tested by measuring the Kd of a mutant of Sxl-RBD1 + 2 in which R142 was replaced by alanine. This mutant lost the ability to bind RNA, showing a correlation with the chemical shift difference data. The RNA-binding affinities of two other mutants, F146A and T138I, were also shown to correlate with the NMR observations.

Mutations in the hrp48 gene, which encodes a Drosophila heterogeneous nuclear ribonucleoprotein particle protein, cause lethality and developmental defects and affect P-element third-intron splicing in vivo.

The Drosophila melanogaster hnRNP protein, hrp48, is an abundant heterogeneous nuclear RNA-associated protein. Previous biochemical studies have implicated hrp48 as a component of a ribonucleoprotein complex involved in the regulation of the tissue-specific alternative splicing of the P-element third intron (IVS3). We have taken a genetic approach to analyzing the role of hrp48. Mutations in the hrp48 gene were identified and characterized. hrp48 is an essential gene. Hypomorphic mutations which reduce the level of hrp48 protein display developmental defects, including reduced numbers of ommatidia in the eye and morphological bristle abnormalities. Using a P-element third-intron reporter transgene, we found that reduced levels of hrp48 partially relieve IVS3 splicing inhibition in somatic cells. This is the first direct evidence that hrp48 plays a functional role in IVS3 splicing inhibition.

Mutations in the small subunit of the Drosophila U2AF splicing factor cause lethality and developmental defects.

The essential eukaryotic pre-mRNA splicing factor U2AF (U2 small nuclear ribonucleoprotein auxiliary factor) is required to specify the 3' splice at an early step in spliceosome assembly. U2AF binds site-specifically to the intron polypyrimidine tract and recruits U2 small nuclear ribonucleoprotein to the branch site. Human U2AF (hU2AF) is a heterodimer composed of a large (hU2AF65) and small (hU2AF35) subunit. Although these proteins associate in a tight complex, the biochemical requirement for U2AF activity can be satisfied solely by the large subunit. The requirement for the small subunit in splicing has remained enigmatic. No biochemical activity has been found for hU2AF35 and it has been implicated in splicing only indirectly by its interaction with known splicing factors. In the absence of a biochemical assay, we have taken a genetic approach to investigate the function of the small subunit in the fruit fly Drosophila melanogaster. A cDNA clone encoding the small subunit of Drosophila U2AF (dU2AF38) has been isolated and sequenced. The dU2AF38 protein is highly homologous to hU2AF35 containing a conserved central arginine- and serine-rich (RS) domain. A recessive P-element insertion mutation affecting dU2AF38 causes a reduction in viability and fertility and morphological bristle defects. Consistent with a general role in splicing, a null allele of dU2AF38 is fully penetrant recessive lethal, like null alleles of the Drosophila U2AF large subunit.

Biochemistry and regulation of pre-mRNA splicing.

During the past year, significant advances have been made in the field of pre-mRNA splicing. It is now clear that members of the serine-arginine-rich protein family are key players in exon definition and function at multiple steps in the spliceosome cycle. Novel findings have been made concerning the role of exon sequences, which function as both constitutive and regulated enhancers of splicing, in trans-splicing and as targets for tissue-specific control of splicing patterns. By combining biochemical approaches in human and yeast extracts with genetic analysis, much has been learned about the RNA-RNA and RNA-protein interactions that are necessary to assemble the various complexes that are found along the pathway to the catalytically active spliceosome.

Interaction of the sex-lethal RNA binding domains with RNA.

Sex determination and X chromosome dosage compensation in Drosophila melanogaster are directed by the Sex-lethal (Sxl) protein. In part, Sxl functions by regulating the splicing of the transformer pre-mRNA by binding to a 3' splice site polypyrimidine tract. Polypyrimidine tracts are essential for splicing of metazoan pre-mRNAs. To unravel the mechanism of splicing regulation at polypyrimidine tracts we analyzed the interaction of Sxl with RNA. The RNA binding activity of Sxl was mapped to the two ribonucleoprotein consensus sequence domains of the protein. Quantitation of binding showed that both RNA binding domains (RBDs) were required in cis for site-specific RNA binding. Individual RBDs interacted with RNA more weakly and had lost the ability to discriminate between wild-type and mutant transformer polypyrimidine tracts. Structural elements in one of the RBDs that are likely to interact with a polypyrimidine tract were identified using nuclear magnetic resonance techniques. In addition, our data suggest that multiple imino protons of the transformer polypyrimidine tract were involved in hydrogen bonding. Interestingly, in vitro Sxl bound with equal affinity to polypyrimidine tracts of pre-mRNAs that it does not regulate in vivo. We discuss the implications of this finding for the mechanism through which Sxl may gain selectivity for particular polypyrimidine tracts in vivo.

Integration of multiple developmental signals in Bacillus subtilis through the Spo0A transcription factor.

Multiple physiological and environmental signals are needed to initiate endospore formation in Bacillus subtilis. One key event controlling sporulation is activation of the Spo0A transcription factor. Spo0A is a member of a large family of conserved regulatory proteins whose activity is controlled by phosphorylation. We have isolated deletion mutations that remove part of the conserved amino terminus of Spo0A and make the transcription factor constitutively active, indicating that the amino terminus normally functions to keep the protein in an inactive state. Expression of an activated gene product is sufficient to activate expression of several sporulation genes in the absence of signals normally needed for initiation of sporulation. Our results indicate that nutritional, cell density, and cell-cycle signals are integrated through the phosphorylation pathway that controls activation of Spo0A.

3'-UTR-dependent deadenylation by the yeast poly(A) nuclease.

Poly(A) tail removal is the first step in the degradation pathway for some mRNAs. The purified poly(A)-binding protein (PAB)-dependent poly(A) nuclease (PAN) from yeast removes mRNA poly(A) tails in vitro by a process similar to that observed in vivo. The exonucleolytic PAN degrades poly(A) and RNA bound by PAB, and can be activated by spermidine to degrade poly(A) in the absence of PAB. The shortening of the poly(A) tail down to 10-25 nucleotides and the terminal deadenylation of this short adenine tract are kinetically distinct reactions. Poly(A) shortening rates are stimulated by the yeast a-mating factor (MFA2) RNA 3' UTR sequence, and this occurs by switching PAN from a distributive to a more processive enzyme. Terminal deadenylation rates are also stimulated to different extents by various RNAs. Inversion of the MFA2 3' UTR sequence completely inhibits the terminal deadenylation reaction owing to the presence of an inhibitory element 70 nucleotides from the poly(A) tail. Other sequence elements inserted at a similar distance from the poly(A) tail also interfere with the reaction. These data suggest that the two phases of poly(A) degradation can be regulated by mRNA sequences, and they provide a mechanistic description of how this regulation could occur in vivo.

The spo0K locus of Bacillus subtilis is homologous to the oligopeptide permease locus and is required for sporulation and competence.

Spore formation in Bacillus subtilis is a dramatic response to environmental signals that is controlled in part by a two-component regulatory system composed of a histidine protein kinase (SpoIIJ) and a transcriptional regulator (Spo0A). The spo0K locus plays an important but undefined role in the initiation of sporulation and in the development of genetic competence. spoIIJ spo0K double mutants had a more severe defect in sporulation than either single mutant. Overproduction of the spoIIJ gene product resulted in the suppression of the sporulation defect, but not the competence defect, caused by mutations in the spo0K locus. On the basis of the phenotype of the spoIIJ spo0K double mutant and the effect of overproduction of the spoIIJ gene product, a transposon insertion in the spo0K locus was isolated. The spo0K locus was cloned and sequenced. spo0K proved to be an operon of five genes that is homologous to the oligopeptide permease (opp) operon of Salmonella typhimurium and related to a large family of membrane transport systems. The requirement for the transport system encoded by spo0K in the development of competence was somewhat different than its requirement in the system encoded by spo0K in the development of competence was somewhat different than its requirement in the initiation of sporulation. Disruption of the last open reading frame in the spo0K operon caused a defect in competence but had little or no effect on sporulation. We hypothesize that the transport system encoded by spo0K may have a role in sensing extracellular peptide factors that we have shown are required for efficient sporulation and perhaps in sensing similar factors that may be necessary for genetic competence.