A molecular approach to estimating the human deleterious mutation rate

We propose a method of measuring the human genomic deleterious mutation rate based on comparison of the rate of evolution per nucleotide per generation of neutral sequences, microN, with the overall rate of evolution of unique sequence DNA, microO. Data on microN, which are based on pseudogenes, permit an estimate of the total zygotic (twice the genomic) mutation rate, UT = 2 microNn = 2(2 x 10(-8)(3 x 10(9)) approximately 10(2), where n is the number of nucleotides per genome. Data on microO can be obtained by comparison of representative samples of relatively short homologous sequences from the genomes of Homo and a related species. The fraction of the genome that is controlled by negative selection is fS = (microN - microO)/microN and the deleterious zygotic mutation rate, the expected number of new deleterious alleles carried by a zygote, is US = UTfS. If fS > 0.01, US > 1, which would have important implications for human genetics and evolutionary biology.

Suppressors of clathrin deficiency: overexpression of ubiquitin rescues lethal strains of clathrin-deficient Saccharomyces cerevisiae

Clathrin-mediated vesicular transport is important for normal growth of the yeast Saccharomyces cerevisiae. Previously, we identified a genetic locus (SCD1) that influences the ability of clathrin heavy-chain-deficient (Chc-) yeast cells to survive. With the scd1-v allele, Chc- yeast cells are viable but grow poorly; with the scd1-i allele, Chc- cells are inviable. To identify the SCD1 locus and other genes that can rescue chc1 delta scd1-i cells to viability, a multicopy suppressor selection strategy was developed. A strain of scd1-i genotype carrying the clathrin heavy-chain gene under GAL1 control (GAL1:CHC1) was transformed with a YEp24 yeast genomic library, and colonies that could grow on glucose were selected. Plasmids from six distinct genetic loci, none of which encoded CHC1, were recovered. One of the suppressor loci was shown to be UBI4, the polyubiquitin gene. UBI4 rescues only in high copy number and is not allelic to SCD1. The conjugation of ubiquitin to intracellular proteins can mediate their selective degradation. Since UBI4 is required for survival of yeast cells under stress and is induced during starvation, ubiquitin expression in GAL1:CHC1 cells was examined. After a shift to growth on glucose to repress synthesis of clathrin heavy chains, UBI4 mRNA levels were elevated > 10-fold, whereas the quantity of free ubiquitin declined severalfold relative to that of Chc+ cells. In addition, novel higher-molecular-weight ubiquitin conjugates appeared in clathrin-deficient cells. We suggest that higher levels of ubiquitin are required for turnover of mislocalized or improperly processed proteins that accumulate in the absence of clathrin and that ubiquitin may play a general role in turnover of proteins in the secretory or endocytic pathway.

[The characteristics of the expression of temperature-dependent dominant lethal mutations in Drosophila melanogaster]

The results of a series of investigations on obtaining and analysing dominant temperature-sensitive lethals (DTS-lethals) are summarized. Using EMS, both cold- and heat sensitive mutations of this type were induced in large autosomes. The cold-sensitive mutations of chromosome 3 were revealed for the first time. The effect of genetic phone on DTS lethal penetrance and expressivity was studied. The character of expression of two mutations possessing a pleiotropic action was examined. The heat-sensitive 1(2)M90DTS mutation disturbed the structure of abdominal tergites in all imago and, besides, caused an abrupt decrease in the female reproductive period. The pattern of alterations observed in oogenesis along with the result of phenogenetic analysis suggest that this gene takes part in the genetic control over the proliferation of stem oogonial cells. The cold-sensitive 1(2)M66DCS mutation caused a number of disturbances in imago thoracic structures: inability to flight, raised up wings, extremity fracture, etc. Mutant flies showed serious disorders of indirect flight muscles both at morphological and at ultrastructural levels. It was established that this mutation was a cold-sensitive allele of Mhc gene which controls the synthesis of myosine heavy chains in drosophila.

Cloning and expression of the essential gene for guanylate kinase from yeast

Guanylate kinase catalyzes the reversible transfer of the terminal phosphoryl group of ATP to the acceptor molecule GMP. Detailed analysis of the in vivo function of this enzyme has been limited by the lack of any genetic data. Using oligonucleotides based on amino acid sequence information of the yeast enzyme, the Saccharomyces cerevisiae gene, GUK1, was isolated and characterized. The gene is present in single copy and maps to chromosome IV. Insertional mutagenesis of the GUK1 locus caused recessive lethality, indicating that this enzyme is necessary for vegetative cell growth. Using inducible expression systems, guanylate kinase was produced in large amounts both in S. cerevisiae and in Escherichia coli.

The lethal phenotype caused by null mutations in the Escherichia coli htrB gene is suppressed by mutations in the accBC operon, encoding two subunits of acetyl coenzyme A carboxylase

Insertion mutations in the Escherichia coli htrB gene result in the unique phenotype of not affecting growth at temperatures below 32.5 degrees C but leading to a loss of viability at temperatures above this in rich media. When htrB bacteria growing in rich media were shifted to the nonpermissive temperature of 42 degrees C, they continued to grow at a rate similar to that at 30 degrees C but they produced phospholipids at the rate required for growth at 42 degrees C. This led to the accumulation of more than twice as much phospholipid per milligram of protein compared with that in wild-type bacteria. Consistent with HtrB playing a role in phospholipid biosynthesis, one complementation group of spontaneously arising mutations that suppressed htrB-induced lethality were mapped to the accBC operon. This operon codes for the biotin carboxyl carrier protein and biotin carboxylase subunits of the acetyl coenzyme A carboxylase enzyme complex, which catalyzes the first step in fatty acid biosynthesis. Four suppressor mutations mapped to this operon. Two alleles were identified as mutations in the accC gene, the third allele was identified as a mutation in the accB gene, and the fourth allele was shown to be an insertion of an IS1 transposable element in the promoter region of the operon, resulting in reduced transcription. The suppressor mutations caused a decrease in the rate of phospholipid biosynthesis, restoring the balance between the biosynthesis of phospholipids and growth rate, thus enabling htrB bacteria to grow at high temperatures.

A tripeptide deletion in the triple-helical domain of the pro alpha 1(I) chain of type I procollagen in a patient with lethal osteogenesis imperfecta does not alter cleavage of the molecule by N-proteinase

Dermal fibroblasts from a fetus with perinatal lethal osteogenesis imperfecta synthesized normal and abnormal type I procollagen molecules. The abnormal molecules contained one or two pro alpha 1(I) chains in which glycine, alanine, and hydroxyproline at positions 874, 875, and 876 in the triple-helical region were deleted as the result of a 9-base pair genomic deletion. Molecules that contained abnormal chains were overmodified from the site of the deletion toward the amino-terminal region of the molecule. Secretion of the overmodified molecules was impaired. The thermal stability of molecules containing abnormal chains was lower than that of normally modified molecules. After cleavage of molecules with vertebrate collagenase, the temperature of thermal denaturation of the overmodified A fragments was greater than that of the fragments from the normal molecules. The rates of cleavage of the normal and the abnormal molecules by N-proteinase were indistinguishable. Our findings suggest that the tripeptide deletion introduces a shift in the phase of the chains in the triple helix. This structural change is propagated from the site of the deletion toward the amino terminus of the molecule, but the subsequent alteration in the structure of the N-proteinase cleavage site is not sufficient to cause a decrease in the rate of cleavage by the enzyme.

Two related genes encoding extremely hydrophobic proteins suppress a lethal mutation in the yeast mitochondrial processing enhancing protein

The processing enhancing protein of mitochondria (PEP) is an essential component that has been shown to participate in proteolytic removal of NH2-terminal signal peptides from precursor proteins imported into the mitochondrial matrix. Using a yeast strain bearing a PEP mutation that renders it temperature-sensitive, an approach of genetic suppression was taken in order to identify additional components that could be involved with protein import: high copy plasmids comprising a yeast genomic library were tested for ability to suppress the 37 degrees C growth defect. Two plasmids were isolated, pSMF1 and pSMF2, which suppressed the growth defect nearly as well as the cloned PEP gene itself. Sequence analysis of the rescuing genes predicted extremely hydrophobic proteins with sizes of 63 and 60 kDa, respectively. Remarkably, the predicted SMF1 and SMF2 products are 49% identical to each other overall. To test the requirement for SMF1 and SMF2, the chromosomal genes were disrupted. Individual disruption was without effect, but cells in which both genes were disrupted grew poorly. When mitochondria were prepared from the double disruption strain grown in a nonfermentable carbon source, they were morphologically normal but defective for translocation of radiolabeled precursor proteins. SMF1 protein was provisionally localized to the mitochondrial membranes using epitope tagging. We suggest that SMF1 and SMF2 are mitochondrial membrane proteins that influence PEP-dependent protein import, possibly at the step of protein translocation.

Detection of gamma-ray-induced DNA damages in malformed dominant lethal embryos of the Japanese medaka (Oryzias latipes) using AP-PCR fingerprinting

Adult male fish of the medaka HNI strain exposed to 9.5 Gy or 19 Gy (0.95 Gy/min) of gamma-rays were mated with non-irradiated female fish of the Hd-rR strain. Genomic DNA was prepared from malformed individual embryos which were expected to be dominant lethal and used for AP-PCR fingerprinting. By the use of a part of the T3 promoter sequence (20 mer), which, to our knowledge, is not found in the medaka genome as an arbitrary primer, we found polymorphisms in genomic fingerprints which could distinguish the parental strains. On the other hand, we found that the fingerprints of F1 hybrids were the sum of those of their parents. Based on these findings, we analyzed the fingerprints of genomic DNA of each severely malformed embryo, because we expect that radiation-induced genomic damages resulting in severe malformation and eventually in dominant lethals should be detected as changes in paternal fingerprints of F1 hybrids. Indeed, we succeeded in detecting changes in genomic DNA as loss of some paternal bands in fingerprints of malformed embryos. One of 10 malformed embryos obtained from 9.5 Gy gamma-irradiated males had lost one band of the paternal origin and 4 of 12 malformed embryos obtained from 19 Gy gamma-irradiated males had lost 5 bands. These results indicated a possibility that quantitative as well as qualitative estimation of gamma-ray-induced DNA damages can be made by this method which does not require the functional selection based on a specific target gene.

False-negative prenatal diagnosis of restrictive dermopathy

Restrictive dermopathy is a rare autosomal recessive lethal skin dysplasia. It has been assumed that the characteristic morphologic abnormalities should allow a reliable prenatal diagnosis on fetal skin biopsies at about 20 weeks pregnancy. We report on a false-negative prenatal diagnosis.

Neutral glycolipid abnormalities in a t-complex mutant mouse embryo

The content of neutral glycolipids was studied in normal and twl/twl mutant mouse embryos at embryonic day 11 (E-11). The twl mutation is part of the T/t complex on chromosome 17 and causes embryonic lethality from defects in the developing neural tube. Previous studies suggested that the mutation could involve a defect in ganglioside biosynthesis. Although the total neutral glycolipid content was similar in the normal and mutant whole embryos (approximately 80 nmol glucose/100 mg dry weight), marked differences were detected for the distribution of specific glycolipids. The content of lactosylceramide, globotriaosylceramide, and globotetraosylceramide was significantly higher in the mutant than in the normal embryos, whereas that of glucosylceramide was significantly reduced. The Forssman glycolipid was slightly elevated. The neutral glycolipid composition was similar in embryonic head and body regions of normal embryos, suggesting that the glycolipid abnormalities observed in the mutants are expressed in most embryonic cells and tissues. These and the previously reported ganglioside abnormalities in the twl/twl mutants could result from an inherited defect in glycolipid biosynthesis.

Mouse albino-deletions: From genetics to genes in development

Six essential genes located near the mouse albino locus have been identified as required during specific periods of development. Amongst these six, each is required either during the preimplantation stages of development, at specific times during gastrulation, within 12 hrs after birth or during juvenile development. These genes were identified as a result of extensive genetic complementation analysis using embryos homozygous for the albino deletions. Although, in principal, the associated developmental abnormalities could result from loss of multiple genes, the deletion phenotype in one case is identical to that induced by chemical mutagenesis. These results indicate that the abnormalities observed in deletion homozygotes may result from single gene loss. The deletions have proven useful not only as genetic tools to localize the position of the genes, but also as molecular entry points to the regions containing these genes. The current methodology being used to isolate candidate genes from the albino region is also reviewed here.

Cell lineage-specific expression of modulo, a dose-dependent modifier of variegation in Drosophila

Variegation in Drosophila is a manifest illustration of the important role played by chromatin structure in gene expression. We have isolated mutants of modulo (mod) and shown that this gene is a dominant suppressor of variegation. Null mutants are recessive lethal with a melanotic tumour phenotype. The mod protein directly binds DNA, which indicates that it may serve to anchor multimeric complexes promoting chromatin compaction and silencing. Using a specific monoclonal antibody we examined by immunocytochemistry the accumulation pattern of mod protein during embryogenesis. The protein is first detected before the blastoderm cellularization in all somatic nuclei, precisely when pericentromeric heterochromatin becomes visible. After the first cell division, mod protein is expressed in lineages of specific embryonic primordia. Based on its dominant phenotype, expression pattern and DNA-binding activity of its product, we propose that mod regulates chromatin structure and activity in specific cell lineages.

RAD25 (SSL2), the yeast homolog of the human xeroderma pigmentosum group B DNA repair gene, is essential for viability

Xeroderma pigmentosum (XP) patients are extremely sensitive to ultraviolet (UV) light and suffer from a high incidence of skin cancers, due to a defect in nucleotide excision repair. The disease is genetically heterogeneous, and seven complementation groups, A-G, have been identified. Homologs of human excision repair genes ERCC1, XPDC/ERCC2, and XPAC have been identified in the yeast Saccharomyces cerevisiae. Since no homolog of human XPBC/ERCC3 existed among the known yeast genes, we cloned the yeast homolog by using XPBC cDNA as a hybridization probe. The yeast homolog, RAD25 (SSL2), encodes a protein of 843 amino acids (M(r) 95,356). The RAD25 (SSL2)- and XPBC-encoded proteins share 55% identical and 72% conserved amino acid residues, and the two proteins resemble one another in containing the conserved DNA helicase sequence motifs. A nonsense mutation at codon 799 that deletes the 45 C-terminal amino acid residues in RAD25 (SSL2) confers UV sensitivity. This mutation shows epistasis with genes in the excision repair group, whereas a synergistic increase in UV sensitivity occurs when it is combined with mutations in genes in other DNA repair pathways, indicating that RAD25 (SSL2) functions in excision repair but not in other repair pathways. We also show that RAD25 (SSL2) is an essential gene. A mutation of the Lys392 residue to arginine in the conserved Walker type A nucleotide-binding motif is lethal, suggesting an essential role of the putative RAD25 (SSL2) ATPase/DNA helicase activity in viability.

The developmental mutants of Xenopus

The 32 developmental mutants found in our laboratory have appeared in the course of the genetic analysis of adult Xenopus laevis issued from nuclear transfers, and of their progeny. These experiments originally were devised more than thirty years ago to test whether somatic nuclei had undergone irreversible changes during differentiation or whether they had remained totipotent. In the majority of cases, the mutations were carried by wild-caught imported frogs or their laboratory-bred progeny; however, the precise origin of several mutations has not been determined. The mutants have been subdivided into three classes: Maternal effect mutants. Three such mutants have been found; they affect the development of all the embryos from homozygous mothers independently of the genotype of the father. Developmental lethals. This class comprises 19 mutants, among which are included the previously called "autonomous lethals" caused by general metabolic defects that affect all parts of the embryos as well as the tissue- and organ-specific lethals, in several of which death occurs as a direct consequence of the anomalies. Developmental non-lethals. These are 10 mutants, suffering from specific defects not essential for survival. In addition, nucleolar mutants as well as mutants found in different species of Xenopus and mutants of Xenopus laevis found in other laboratories are also mentioned. The last part consists of an alphabetical description of the mutant phenotypes including more detailed analyses which have been carried out on several of them.

Purification and characterization of a mutant DnaB protein specifically defective in ATP hydrolysis

The dnaB gene of Escherichia coli encodes an essential DNA replication enzyme. Fueled by the energy derived from the hydrolysis of ATP to ADP+P(i), this enzyme unwinds double-stranded DNA in advance of the DNA polymerase. While doing so, it intermittently stimulates primase to synthesize an RNA primer for an Okazaki fragment. To better understand the structural basis of these and other aspects of DnaB function, we have initiated a study of mutant DnaB proteins. Here, we report the purification and characterization of a mutant DnaB protein (RC231) containing cysteine in place of arginine at residue 231. The mutant protein attains a stable, properly folded structure that allows association of six promoters to form a hexamer, as is also true for wild-type DnaB. Further, the mutant protein interacts with ATP, the nonhydrolyzable ATP analog adenosine-5'-O-(3-thiotriphosphate) (ATP gamma S), ADP, and poly(dT), and it stimulates primase action. It is, however, profoundly deficient in ATP hydrolysis, helicase activity, and replication activity at the chromosomal origin of replication. In addition, while general priming reactions with wild-type DnaB and ATP elicited the synthesis of short primers, reactions with DnaB and ATP gamma S or with RC231 and either ATP or ATP gamma S stimulated the synthesis of significantly longer primers. On the basis of these observations, we suggest that primase interacts directly with DnaB throughout primer synthesis during general priming, until dissociation of DnaB from DNA or ATP hydrolysis by DnaB disrupts the interaction and leads to primer termination.

Biochemical and genetic dissection of the Saccharomyces cerevisiae RNA polymerase C53 subunit through the analysis of a mitochondrially mis-sorted mutant construct

RPC53 has previously been shown to encode an essential subunit required for tRNA gene transcription by RNA polymerase C in vivo (Mann, C., Micouin, J.-Y., Chiannilkulchai, N., Treich, I., Buhler, J.-M., and Sentenac, A. (1992) Mol. Cell. Biol. 12, in press). In this paper, we have determined that an unusual rho+ lethality associated with the rpc53::HIS3-1 disruption mutation is due to the inadvertent formation of a Pet56-C53 fusion protein. This fusion protein is missorted to mitochondria, thereby reducing the quantity of the C53 subunit available for RNA polymerase C assembly. We show that the carboxyl-terminal region of C53 contains the essential functional domain of the subunit and that a mutant RNA polymerase containing only this domain is thermolabile for its function in vivo and in vitro. The thermolability of the carboxyl-terminal C53 domain is suppressed by five different genes on multicopy plasmids, including RPC160, encoding the largest subunit of RNA polymerase C and SSD1/SRK1, which has been implicated in the activity of protein phosphatases.

Incorporation of type I collagen molecules that contain a mutant alpha 2(I) chain (Gly580-->Asp) into bone matrix in a lethal case of osteogenesis imperfecta

To understand more directly the tissue defect in osteogenesis imperfecta (OI), bone matrix was analyzed from an infant with lethal OI (type II) of defined mutation (collagen alpha 2(I)Gly580-->Asp). Pepsin-solubilized alpha 1(I) and alpha 2(I) chains and derived CNBr-peptides migrated more slowly on sodium dodecyl sulfate-polyacrylamide gel electrophoresis compared with normal human controls. The peptide alpha 2(I)CB3,5, predicted to contain the mutation site, ran as a retarded doublet band and was purified by high performance liquid chromatography and digested with V8 protease. Two peptides with amino-terminal sequences beginning at residue 576 of the alpha 2(I) chain were isolated. One had the normal sequence. The other differed in that aspartic acid replaced glycine at residue 580 as predicted from cDNA analysis, and in having an unhydroxylated proline at residue 579. From yields on microsequencing and the relative intensities of the two forms of alpha 2(I)CB3,5 on SDS-polyacrylamide gel electrophoresis, the ratio of mutant to normal alpha 2(I) chains in the infant's bone matrix was 0.7/1. Although the effects of an efficient incorporation of mutant chains on the properties of the bone matrix are unknown, it may be that in this OI case the tissue abnormalities result more from the presence of mutant protein than from an underexpression of matrix.

Fission yeast and a plant have functional homologues of the Sar1 and Sec12 proteins involved in ER to Golgi traffic in budding yeast

Sec12p and Sar1p are required for the formation of transport vesicles generated from the endoplasmic reticulum (ER) in the yeast Saccharomyces cerevisiae. Sec12p is an ER type II membrane protein that mediates the membrane attachment of the GTP-binding Sar1 protein. The SAR1 gene is a multi-copy suppressor of a thermosensitive sec12 mutation. In an attempt to identify functional homologues of Sec12p and Sar1p from other eukaryotic organisms, we screened cDNA expression libraries derived from the fission yeast Schizosaccharomyces pombe and from the plant Arabidopsis thaliana for complementation of the sec12ts mutation. Four individual cDNAs were isolated, two of which encode the S. pombe and A. thaliana homologues of Sar1p. The three Sar1 proteins are 67% identical on average. The two other cDNAs encode type II membrane proteins which were designated Stl1p for the S. pombe protein and Stl2p for the A. thaliana protein (Stl stands for Sec12p-like). Both proteins have NH2-terminal cytoplasmic domains which resemble that of Sec12p: they are similar in size and present a significant degree of amino acid identity with the cytoplasmic domain of Sec12p. In contrast, the lumenal domains of Sec12p, Stl1p and Stl2p are very different in size and do not show any appreciable homology. That Stl1p and Stl2p are functional homologues of Sec12p was confirmed by showing that expression of either cloned gene complements a sec12 null mutation. Our results indicate that some of the mechanisms regulating vesicle formation at the ER are conserved not only in yeasts, but also in plants.

The Drosophila segmentation gene runt has an extended cis-regulatory region that is required for vital expression at other stages of development

The Drosophila runt gene functions in several developmental pathways during embryogenesis. This gene was initially characterized due to the pivotal role that it plays in the genetic regulatory network that establishes the segmented body pattern. Recently it was found that this X-chromosome-linked gene is one of several dosage-sensitive, X-linked components that is involved in activating the Sex-lethal gene in blastoderm stage female embryos. Finally, this gene is also extensively re-expressed in later stages of embryogenesis in the developing nervous system where it plays an important role in the development of specific neural lineages. We have initiated an analysis of the runt cis-regulatory region in order to investigate runt's roles in these (and other) developmental pathways. Analysis of both the function and the expression patterns of runt genes with truncated cis-regulatory regions indicates that there are multiple elements that make quantitative contributions to runt regulation during segmentation. We find that sequences that are more than 8.5 kb upstream of the runt promoter are necessary for normal expression during the post-blastoderm stages of embryogenesis. Genetic experiments indicate that the post-blastoderm expression of runt is vital to the organism.

Synthetic lethal mutations suggest interactions between U5 small nuclear RNA and four proteins required for the second step of splicing

To investigate the function of the U5 small nuclear ribonucleoprotein (snRNP) in pre-mRNA splicing, we have screened for factors that genetically interact with Saccharomyces cerevisiae U5 snRNA. We isolated trans-acting mutations that exacerbate the phenotypes of conditional alleles of the U5 snRNA and named these genes SLU, for synergistically lethal with U5 snRNA. SLU1 and SLU2 are essential for the first catalytic step of splicing, while SLU7 and SLU4 (an allele of PRP17 [U. Vijayraghavan, M. Company, and J. Abelson, Genes Dev. 3:1206-1216, 1989]) are required only for the second step of splicing. Furthermore, slu4-1 and slu7-1 are lethal in combination with mutations in PRP16 and PRP18, which also function in the second step, but not with mutations in factors required for the first catalytic step, such as PRP8 and PRP4. We infer from these data that SLU4, SLU7, PRP18, PRP16, and the U5 snRNA interact functionally and that a major role of the U5 snRNP is to coordinate a set of factors that are required for the completion of the second catalytic step of splicing.

Construction of a GAL1-regulated yeast cDNA expression library and its application to the identification of genes whose overexpression causes lethality in yeast

We have constructed a galactose-inducible expression library by cloning yeast cDNAs unidirectionally under control of the GAL1 promoter in a centromeric shuttle vector. Eleven independent libraries were made each with an average size of about 1 x 10(6) clones, about 50 times larger than the reported mRNA population in a yeast cell. From this library, LEU2 and HIS3 cDNAs were recovered at a frequency of about 1 in 10(4) and in 12 out of 13 cases these were expressed in a galactose-dependent manner. Sequence analysis of leu2 and his3 complementing cDNAs indicates that they contain all the coding sequence and much of the 5' untranslated region. To test the utility of the library for the identification of genes whose overexpression confers a specific phenotype, we screened 25,000 yeast transformants for lethality on galactose. Among 15 clones that showed galactose inducible lethality were cDNAs encoding structural proteins, including ACT1 (actin), TUB2 (beta-tubulin) and ABP1 (actin-binding protein 1), and genes in signal transduction pathways, including TPK1 (a cAMP-dependent protein kinase) and GLC7 (type 1 protein phosphatase). cDNAs overexpressing NHPB (nonhistone protein B) and NSR1 (nuclear sequence recognition protein) were also found to be lethal. Among these, ACT1 was isolated four times, and NSR1 three times. The useful features of this library for cDNA cloning in yeast by complementation, and for the identification of genes whose over-expression confers specific phenotypes, are discussed.

The Drosophila couch potato protein is expressed in nuclei of peripheral neuronal precursors and shows homology to RNA-binding proteins

Through enhancer detection screens we have isolated and cloned an essential gene that is expressed in the neuronal precursors and their daughter cells in the Drosophila embryonic peripheral nervous system (PNS). The gene is named couch potato (cpo), because several partial loss-of-function alleles cause hypoactive behavior in adults. Here, we present evidence that the structure of the cpo locus is unusually complex: It spans > 100 kb, encodes three different messages, is differentially spliced, lacks an AUG initiation codon, and may encode three different proteins. Two putative Cpo proteins contain similar but nonidentical RNA-binding domains that are most homologous to the RNA-binding domains of the Drosophila embryonic lethal abnormal vision (elav) gene and a human brain protein that has been implicated in a paraneoplastic sensory neuropathy. Polyclonal antibodies raised against a fusion protein localize Cpo to the nucleus. Immunocytochemical studies demonstrate that the achaete-scute and daughterless genes are required for proper expression of cpo in the PNS but not in other cells that express cpo. On the basis of our observations, we present a model in which cpo is controlled by genes that determine cells to become PNS cells. Cpo, in turn, may control the processing of RNA molecules required for the proper functioning of the PNS.

Genetic and experimental studies on a new pigment mutant in Xenopus laevis

White lethal (wl) is a recessive mutation affecting the differentiation of the three types of chromatophores in Xenopus laevis and eventually leading to the death of the mutants around stage 50. Melanophores appear at st. 33 but differentiate abnormally, remaining pale grey, and do not proliferate after st. 41. The rare xanthophores present contain only a few differentiated pterinosomes, and the iridophores consist of noniridescent white dots. When the albino gene (ap) is combined with wl, melanophores do not differentiate. Reciprocal heterotopic and orthotopic trunk neural crest grafts have shown that the defect is intrinsic to the neural crest cells but is not due, in the case of melanophores, to a tyrosinase deficiency as revealed by the dopa reaction. The mode of action of the gene, the abnormal pattern, and lethality are discussed.

Mutants carrying conditionally lethal mutations in outer membrane genes omsA and firA (ssc) are phenotypically similar, and omsA is allelic to firA

We have previously identified the gene (the ssc gene) defective in the thermosensitive and antibiotic-supersusceptible outer membrane permeability mutant SS-C of Salmonella typhimurium and shown that this gene is analogous to the Escherichia coli gene firA (L. Hirvas, P. Koski, and M. Vaara, EMBO J. 10:1017-1023, 1991). Others have tentatively implicated firA in a different function, mRNA synthesis. Here we report that the defect in the thermosensitive outer membrane omsA mutant of E. coli (T. Tsuruoka, M. Ito, S. Tomioka, A. Hirata, and M. Matsuhashi, J. Bacteriol. 170:5229-5235, 1988) is due to a mutation in firA; this mutation changed codon 271 from serine to asparagine. The omsA-induced phenotype was completely reverted by plasmids containing wild-type firA or ssc. Plasmids carrying the omsA allele, or an identical mutant allele prepared by localized mutagenesis, under the control of lac elicited partial complementation. Transcomplementation studies with plasmids carrying various mutant alleles of the S. typhimurium gene indicated that the ability of these plasmids to complement the omsA mutation was similar to their ability to complement the ssc mutation. The antibiotic-supersusceptible phenotype of the omsA mutant closely resembled that of the ssc mutant, i.e., the omsA mutant was supersusceptible to hydrophobic antibiotics and large-peptide antibiotics against which the intact outer membrane is an effective permeability barrier. As previously demonstrated with the omsA mutant, the outer membrane of the ssc mutant became selectively ruptured after incubation for 1 h at the growth-nonpermitting temperature; 82% of the periplasmic beta-lactamase and less than 3% of the cytoplasmic marker enzyme were released into the medium. All of these findings are consistent with our concept that firA is an essential gene involved in generation of the outer membrane.