SWAP pre-mRNA splicing regulators are a novel, ancient protein family sharing a highly conserved sequence motif with the prp21 family of constitutive splicing proteins.

Regulators responsible for the pervasive, nonsex-specific alternative pre-mRNA splicing characteristic of metazoans are almost entirely unknown or uncertain. We describe here a novel family of splicing regulators present throughout metazoans. Specifically, we analyze two nematode (Caenorhabditis elegans) genes. One, CeSWAP, is a cognate of the suppressor-of-white-apricot (DmSWAP) splicing regulator from the arthropod Drosophila. Our results define the ancient, conserved SWAP protein family whose members share a colinearly arrayed series of novel sequence motifs. Further, we describe evidence that the CeSWAP protein autoregulates its levels by feedback control of splicing of its own pre-mRNA analogously to the DmSWAP protein and as expected of a splicing regulator. The second nematode gene, Ceprp21, encodes an abundant nuclear cognate of the constitutive yeast splicing protein, prp21, on the basis of several lines of evidence. Our analysis defines prp21 as a second novel, ancient protein family. One of the motifs conserved in prp21 proteins--designated surp--is shared with SWAP proteins. Several lines of evidence indicate that both new families of surp-containing proteins act at the same (or very similar) step in early prespliceosome assembly. We discuss implications of our results for regulated metazoan pre-mRNA splicing.

Analysis of spliceosome assembly and the structure of a regulated intron in Drosophila in vitro splicing extracts.

We characterize spliceosome assembly in Drosophila embryonic nuclear extracts. Further, we show that these extracts contain high levels of a 5' to 3' exoribonuclease activity allowing rapid, convenient protection mapping of 5' splice site and branchpoint sequences. We use this assay to show, for the first time, that a regulated arthropod intron uses a remote branchpoint strikingly similar in structure to those observed previously in regulated vertebrate introns. These results provide new evidence that both regulated and constitutive splicing are similar in detail in vertebrates and arthropods indicating that the powerful genetic systems for analysis of splicing regulation in Drosophila are likely to be directly informative for regulated splicing throughout metazoa. In addition, we report formation of a novel class of intron-dependent complexes. Behavior of these complexes indicates that they represent a mutually exclusive, kinetically competing pathway with spliceosome assembly. We propose that this competition represents the basis for a kinetic proofreading mechanism enhancing fidelity of intron recognition. We also discuss possible implications of this model for regulated splicing.

A plasmid carrying mucA and mucB genes from pKM101 in Haemophilus influenzae and Escherichia coli.

The plasmid pMucAMucB, constructed from the Haemophilus influenzae vector pDM2, and a similar plasmid, constructed from pBR322, increased the survival after UV irradiation of Escherichia coli AB1157 with the umu-36 mutation and also caused UV-induced mutation in the E. coli strain. In H. influenzae, pMucAMucB caused a small but reproducible increase in survival after UV irradiation in wild-type cells and in a rec-1 mutant, but there was no increase in spontaneous mutation in the wild type or in the rec-1 mutant and no UV-induced mutation.

Characterization of the rec-1 gene of Haemophilus influenzae and behavior of the gene in Escherichia coli.

The rec-1 gene of Haemophilus influenzae was cloned into a shuttle vector that replicates in Escherichia coli as well as in H. influenzae. The plasmid, called pRec1, complemented the defects of a rec-1 mutant in repair of UV damage, transformation, and ability of prophage to be induced by UV radiation. Although UV resistance and recombination were caused by pRec1 in E. coli recA mutants, UV induction of lambda and UV mutagenesis were not. We suggest that the ability of the H. influenzae Rec-1 protein to cause cleavage of repressors but not the recombinase function differs from that of the E. coli RecA protein.

Mutations affecting gyrase in Haemophilus influenzae.

Mutants separately resistant to novobiocin, coumermycin, nalidixic acid, and oxolinic acid contained gyrase activity as measured in vitro that was resistant to the antibiotics, indicating that the mutations represented structural alterations of the enzyme. One Novr mutant contained an altered B subunit of the enzyme, as judged by the ability of a plasmid, pNov1, containing the mutation to complement a temperature-sensitive gyrase B mutation in Escherichia coli and to cause novobiocin resistance in that strain. Three other Novr mutations did not confer antibiotic resistance to the gyrase but appeared to increase the amount of active enzyme in the cell. One of these, novB1, could only act in cis, whereas a new mutation, novC, could act in trans. An RNA polymerase mutation partially substituted for the novB1 mutation, suggesting that novB1 may be a mutation in a promoter region for the B subunit gene. Growth responses of strains containing various combinations of mutations on plasmids or on the chromosome indicated that low-level resistance to novobiocin or coumermycin may have resulted from multiple copies of wild-type genes coding for the gyrase B subunit, whereas high-level resistance required a structural change in the gyrase B gene and was also dependent on alteration in a regulatory region. When there was mismatch at the novB locus, with the novB1 mutation either on a plasmid or the chromosome, and the corresponding wild-type gene present in trans, chromosome to plasmid recombination during transformation was much higher than when the genes matched, probably because plasmid to chromosome recombination, eliminating the plasmid, was inhibited by the mismatch.

Loss of plasmids containing cloned inserts coding for novobiocin resistance or novobiocin sensitivity in Haemophilus influenzae.

Plasmids pNov1 and pNov1s , coding for resistance and sensitivity to novobiocin, respectively, were readily lost from wild-type Haemophilus influenzae but retained in a strain lacking an inducible defective prophage. The plasmid loss could be partly or wholly eliminated by a low-copy-number mutation in the plasmid or by the presence of certain antibiotic resistance markers in the host chromosome. Release of both phage HP1c1 , measured by plaque assay, and defective phage, measured by electron microscopy, was increased when the plasmids were present. The frequency of recombination between pNov1 and the chromosome, causing the plasmid to be converted to pNov1s , could under some circumstances be decreased from the normal 60 to 70% to below 10% by the presence of a kanamycin resistance marker in the chromosome. This suggested that a gene product coded for by the plasmid, the expression of which was affected by the kanamycin resistance marker, was responsible for the high recombination frequency. Evidence was obtained from in vitro experiments that the gene product was a gyrase.