Genetic Analysis of the Antennapedia Gene Complex (Ant-C) and Adjacent Chromosomal Regions of DROSOPHILA MELANOGASTER. II. Polytene Chromosome Segments 84A-84B1,2

The existence of a gene complex in the proximal right arm of chromosome 3 of Drosophila melanogaster involved in the development of the head and thorax was originally suggested by the phenotypes of several dominant homoeotic mutations and their revertants. A screen for mutations utilizing Df(3R) Antp^Ns+R17 (proximally broken in salivary region 84B1,2) yielded, among 102 recovered mutations, 17 localized by deficiency mapping to the putative homoeotic cluster. These fell into four complementation groups, two of which were characterized by homoeotic phenotypes. To explore the limits of the Antennapedia gene complex (ANT-C) more proximally, a second screen has been undertaken utilizing Df(3R)Scr, a deficiency of 84A1–B1,2.—Of 2832 chromosomes screened, 21 bearing alterations localized to polytene interval 84A–84B1,2 have been recovered. Sixteen are recessive lethals, and five showing reduced viability display a visible phenotype in surviving individuals. Complementation and phenotypic analyses revealed four complementation groups proximal to those identified in the previous screen, including two new alleles of the recessive homoeotic mutation, proboscipedia (pb). Ten of the new mutations correspond to complementation groups defined previously in the Df(3R)Antp^Ns+R17 screen four to the EbR11 group, two to the Scr group and four to the Antp group.—On the basis of the phenotypes of the 39 mutations localized to this region, plus their interactions with extant homoeotic mutations, we postulate that there are at least five functional sites comprising the ANT-C. Three have been demonstrated to be homoeotic in nature. The specific homoeotic transformations thus far observed suggest that these loci are critical for normal development of adult labial, maxillary and thoracic structures.     

Genetic Characterization of the Region between 86f1,2 and 87b15 on Chromosome 3 of DROSOPHILA MELANOGASTER

The region between 86F1,2 and 87B15 on chromosome 3 of Drosophila melanogaster, which contains about 27 polytene chromosome bands including the 87A7 heat-shock locus, has been screened for EMS-induced visible and lethal mutations. We have recovered 268 lethal mutations that fall into 25 complementation groups. Cytogenetic localization of the complementation groups by deficiency mapping is consistent with the notion that each band encodes a single genetic function. We have also screened for mutations at the 87A7 heat shock locus, using a chromosome that has only one copy of the gene encoding the 70,000 dalton heat-shock protein (hsp70). No lethal or visible mutations at 87A7 were identified from 10,719 mutagenized chromosomes, and no female-sterile mutations at 87A7 were recovered from the 1,520 chromosomes whose progeny were tested for female fertility. We found no evidence that a functional hsp70 gene is required for development under laboratory conditions.     

Genetic characterization of the 44D-45B region of the Drosophila melanogaster genome based on an F2 lethal screen

We have performed an F₂ genetic screen to identify lethal mutations that map to the 44D-45B region of the Drosophila melanogaster genome. By screening 8500 mutagenized chromosomes for lethality over Df(2R)Np3, a deficiency which encompasses nearly 1% of the D. melanogaster euchromatic genome, we recovered 125 lines with lethal mutations that represent 38 complementation groups. The lethal mutations have been mapped to deficiencies that span the 44D-45B region, producing an approximate map position for each complementation group. Lethal mutations were analyzed to determine the phase of development at which lethality occurred. In addition, we have linked some of the complementation groups to P element-induced lethals that map to 44D-45B, thus possibly providing new alleles of a previously tagged gene. Some of the complementation groups represent potentially novel alleles of previously identified genes that map to the region. Several genes have been mapped by molecular means to the 44D-45B region, but do not have any reported mutant alleles. This screen may have uncovered mutant alleles of these genes. The results of complementation tests with previously identified genes in 44D-45B suggests that over half of the complementation groups identified in this screen may be novel. Received: 13 July 1999 / Accepted: 4 November 1999     

The Genetics of a Small Autosomal Region of DROSOPHILA MELANOGASTER Containing the Structural Gene for Alcohol Dehydrogenase. II. Lethal Mutations in the Region

Forty-seven lethal mutations and alleles of nine visible loci (including alcohol dehydrogenase) have been mapped by both deficiency mapping and, in most cases, by recombination mapping to a small region (34D-35C) of chromosome arm 2L of Drosophila melanogaster. The lethals fall into approximately 21 complementation groups, and we estimate that the total number of lethal plus visible complementation groups within the 34-band deficiency, Df(2L)64j, is approximately 34, a remarkable numerical coincidence. The possible genetic significance of this coincidence is discussed. Lethals mapping close to the structural gene for alcohol dehydrogenase, both distally and proximally, have been identified and will be used for the construction of selective crosses for the study of exchange within this locus. Despite many abnormal cytological features (e.g., ectopic pairing, weak points) region 35 of chromosome arm 2L does not display any unusual genetic features; indeed, in terms of the amount of recombination per band and the average map distance between adjacent loci, this region is similar to that between zeste and white on the X chromosome.     

Genetic Analysis of the Adenosine3 (Gart) Region of the Second Chromosome of Drosophila Melanogaster

The Gart gene of Drosophila melanogaster is known, from molecular biological evidence, to encode a polypeptide that serves three enzymatic functions in purine biosynthesis. It is located in polytene chromosome region 27D. One mutation in the gene (ade3(1)) has been described previously. We report here forty new ethyl methanesulfonate-induced mutations selected aga!nst a synthetic deficiency of the region from 27C2-9 to ++28B3-4. The mutations were characterized cytogenetically and by complementation analysis. The analysis apparently identifies 12 simple complementation groups. In addition, two segments of the chromosome exhibit complex complementation behavior. The first, the 28A region, gave three recessive lethals and also contains three known visible mutants, spade (spd), Sternopleural (Sp) and wingless (wg); a complex pattern of genetic interaction in the region incorporates both the new and the previously known mutants. The second region is at 27D, where seven extreme semilethal mutations give a complex complementation pattern that also incorporates ade3(1). Since ade3(1) is defective in one of the enzymatic functions encoded in the Gart gene, we assume the other seven also affect the gene. The complexity of the complementation pattern presumably reflects the functional complexity of the gene product. The phenotypic effects of the mutants at 27D are very similar to those described for ade2 mutations, which also interrupt purine biosynthesis.     

The Doublesex Locus of Drosophila Melanogaster and Its Flanking Regions: A Cytogenetic Analysis

The region of the third chromosome (84D-F) of Drosophila melanogaster that contains the doublesex (dsx) locus has been cytogenetically analyzed. Twenty nine newly induced, and 42 preexisting rearrangements broken in dsx and the regions flanking dsx have been cytologically and genetically characterized. These studies established that the dsx locus is in salivary chromosome band 84E1-2. In addition, these observations provide strong evidence that the dsx locus functions only to regulate sexual differentiation and does not encode a vital function. To obtain new alleles at the dsx locus and to begin to analyze the genes flanking dsx, 59 lethal and visible mutations in a region encompassing dsx were induced. These mutations together with preexisting mutations in the region were deficiency mapped and placed into complementation groups. Among the mutations we isolated, four new mutations affecting sexual differentiation were identified. All proved to be alleles of dsx, suggesting that dsx is the only gene in this region involved in regulating sexual differentiation. All but one of the new dsx alleles have equivalent effects in males and females. The exception, dsxEFH55, strongly affects female sexual differentiation, but only weakly affects male sexual differentiation. The interactions of dsxEFH55 with mutations in other genes affecting sexual differentiation are described. These results are discussed in terms of the recent molecular findings that the dsx locus encodes sex-specific proteins that share in common their amino termini but have different carboxyl termini. The 72 mutations in this region that do not affect sexual differentiation identify 25 complementation groups. A translocation, T(2;3)Es that is associated with a lethal allele in one of these complementation groups is also broken at the engrailed (en) locus on the second chromosome and has a dominant phenotype that may be due to the expression of en in the anterior portion of the abdominal tergites where en is not normally expressed. The essential genes found in the 84D-F region are not evenly distributed throughout this region; most strikingly the 84D1-11 region appears to be devoid of essential genes. It is suggested that the lack of essential genes in this region is due to the region (1) containing genes with nonessential functions and (2) being duplicated, possibly both internally and elsewhere in the genome.     

X-ray-induced specific-locus mutations in the ad-3 region of two-component heterokaryons of Neurospora crassa. VIII. Dose-dependence of the overall spectrum

There is considerable controversy in the literature concerning the nature of X-ray-induced specific-locus mutations in various experimental organisms. To investigate this problem in Neurospora crassa a series of experiments (Webber and de Serres, 1965) was performed to study the induction-kinetics of X-ray-induced mutation in the adenine-3 (ad-3) region of a two-component heterokaryon (H-12). Subsequent genetic analyses (de Serres, 1989a,b,c, 1990a), on a series of 832 mutants recovered in these experiments, have shown that 3 different classes of ad-3 mutants were recovered, namely gene/point mutations, multilocus deletions and multiple-site mutations. Complementation studies with a series of genetic markers that define 21 genetic loci in the ad-3 and immediately adjacent genetic regions have shown that ad-3 mutants classified as multilocus deletions result from the inactivation of a series of loci in the ad-3 and immediately adjacent regions of Linkage Group I, whereas multiple-locus mutations result from combinations of gene/point mutations and multilocus deletions. Analysis of the induction kinetics of these 3 different classes, after completion of the genetic characterization of all mutants (de Serres, 1990b) demonstrated that gene/point mutations increase linearly with X-ray dose, whereas multilocus deletions and multiple-site mutations increase as the square of X-ray dose. Further analysis of allelic complementation among the gene/point mutations at the ad-3B locus (de Serres, 1990c), demonstrated that the spectrum of complementation patterns was dose-dependent: complementing mutants with nonpolarized patterns decreased and noncomplementing mutations increased with increasing X-ray dose. There was little or no change with dose in the frequency of mutants with polarized patterns. In the present report, data from studies published previously have been utilized, along with additional data from the original X-ray experiments (12-5, 12-6, 12-7, and 12-10; see Webber and de Serres, 1965) to develop composite complementation maps of the X-ray-induced specific-locus mutations in the ad-3 and immediately adjacent regions as a function of X-ray dose. This analysis of the overall spectrum of X-ray-induced specific-locus mutations in the ad-3 region demonstrated marked dose-dependence and provides an explanation for the discrepancies in the literature with regard to specific-locus studies in different experimental organisms.     

Heterogeneity of Lethals in a "Simple" Lethal Complementation Group

Of 24 ethyl methanesulphonate-induced, recessive-lethal mutations in the region 9E1-9F13 of the X chromosome of Drosophila melanogaster, eight fall into a typically homogeneous lethal complementation group associated with the raspberry (ras) locus. Mutations in this group have previously been shown to be pleiotropic, affecting not only ras but also two other genetic entities, gua 1 and pur 1, which yield auxotrophic mutations.--The eight new mutations have been characterized phenotypically in double heterozygotes with gua 1, pur 1 and ras mutations. Despite their homogeneity in lethal complementation tests, the mutations prove quite diverse. For example, two mutations have little or no effect on eye color in double heterozygotes with ras2. The differences between the lethals are allele-specific and cannot be explained as a trivial outcome of a hypomorphic series.--Taken alone, the lethal complementation studies mask the complexity of the locus and the diversity of its recessive lethal alleles. By extension, we argue that the general use of lethal saturation studies provides an unduly simplified image of genetic organization. We suggest that the reason why recessive lethal mutations rarely present complex complementation patterns is that complex loci tend to produce mutations that affect several subfunctions.     

Functional genomic analysis of the 61D-61F region of the third chromosome of Drosophila melanogaster.

Assigning functional significance to completed genome sequences is one of the next challenges in biological science. Conventional genetic tools such as deficiency chromosomes help assign essential complementation groups to their corresponding genes. We describe an F2 genetic screen to identify lethal mutations within cytogenetic region 61D-61F of the third chromosome of Drosophila melanogaster. One hundred sixteen mutations were identified by their failure to complement both Df(3L)bab-PG and Df(3L)3C7. These alleles were assigned to 14 complementation groups and 9 deficiency intervals. Complementation groups were ordered using existing deficiencies, as well as new deficiencies generated in this study. With the aid of the genomic sequence, genetic and physical maps in the region were correlated by use of PCR to localize the breakpoints of deficiencies within a 268-kb genomic contig (GenBank accession No. AC005847). Six essential complementation groups were assigned to specific genes, including genes encoding a porphobilinogen deaminase and a Sac1-like protein.     

Lethal Mutations Flanking the 68c Glue Gene Cluster on Chromosome 3 of DROSOPHILA MELANOGASTER

We have conducted a genetic analysis of the region flanking the 68C glue gene cluster in Drosophila melanogaster by isolating lethal and semilethal mutations uncovered by deficiencies which span this region. Three different mutagens were used: ethyl methanesulfonate (EMS), ethyl nitrosourea (ENU) and diepoxybutane (DEB). In the region from 68A3 to 68C11, 64 lethal, semilethal, and visible mutations were recovered. These include alleles of 13 new lethal complementation groups, as well as new alleles of rotated, low xanthine dehydrogenase, lethal(3)517 and lethal(3)B76. Six new visible mutations from within this region were recovered on the basis of their reduced viability; all proved to be semiviable alleles of lethal complementation groups. No significant differences were observed in the distributions of lethals recovered using the three different mutagens. Each lethal was mapped on the basis of complementation with overlapping deficiencies; mutations that mapped within the same interval were tested for complementation, and the relative order of the lethal groups within each interval was determined by recombination. The cytological distribution of genes within the 68A3-68C11 region is not uniform: the region from 68A2,3 to 68B1,3 (seven to ten polytene chromosome bands) contains at least 13 lethal complementation groups and the mutation low xanthine dehydrogenase; the adjoining region from 68B1,3 to 68C5,6 (six to nine bands) includes the 68C glue gene cluster, but no known lethal or visible complementation groups; and the interval from 68C5,6 to 68C10,11 (three to five bands) contains at least three lethal complementation groups and the visible mutation rotated. The developmental stage at which lethality is observed was determined for a representative allele from each lethal complementation group.     

A Genetic Analysis of the Rose-Gespleten Region (68c8-69b5) of Drosophila Melanogaster

We describe a genetic analysis of the region 68C8-69B5 defined by Df(3L)vin-7. We have induced 35 new lethal mutations in this region, which together with 20 existing lethal mutations, visible mutations, genes identified by protein products and one gene deduced from complementation data fall into 37 complementation groups in this 35-band interval. Using existing and newly induced deficiencies we have assigned these to 11 intervals defined by deficiency breakpoints. Those mutations which fell in the same breakpoint interval as the Lsp-2 gene, which codes for the abundant larval serum protein 2, were the subject of detailed study. None was rescued by the active Lsp-2 gene transformed on to chromosome II and we conclude that, as yet, we have no lethal mutations of Lsp-2.     

Molecular Genetic Analysis of the DILUTE-SHORT EAR ( d-se) Region of the Mouse

Genes of the dilute-short ear (d-se) region of mouse chromosome 9 comprise an array of loci important to the normal development of the animal. Over 200 spontaneous, chemically induced and radiation-induced mutations at these loci have been identified, making it one of the most genetically well-characterized regions of the mouse. Molecular analysis of this region has recently become feasible by the identification of a dilute mutation that was induced by integration of an ecotropic murine leukemia virus genome. Several unique sequence cellular DNA probes flanking this provirus have now been identified and used to investigate the organization of wild-type chromosomes and chromosomes with radiation-induced d-se region mutations. As expected, several of these mutations are associated with deletions, and, in general, the molecular and genetic complementation maps of these mutants are concordant. Furthermore, a deletion breakpoint fusion fragment has been identified and has been used to orient the physical map of the d-se region with respect to the genetic complementation map. These experiments provide important initial steps for analyzing this developmentally important region at the molecular level, as well as for studying in detail how a diverse group of mutagens acts on the mammalian germline.     

Two complementation groups mediate tetracycline resistance determined by Tn10.

The structural and regulatory tetracycline resistance genes of transposon Tn10 are located on a 2,700-base pair HpaI fragment. We have used eight tetracycline-sensitive mutations in the 2,700-base pair fragment, cloned into two compatible plasmids, to demonstrate that two complementation groups are required for tetracycline resistance. By genetic recombination with plasmids containing the regulatory or structural regions for resistance, we have determined that both complementation groups reside within the structural region. The complementation groups, designated tetA and tetB, are proximal and distal, respectively, to the promoter for the tetracycline resistance structural region. The tetB mutations are in the portion of the structural region that is known to encode the 36,000-molecular-weight, inner-membrane TET protein. The levels of tetracycline resistance expressed during complementation suggest a complex interaction between the products of the tetA and tetB loci.     

Essential Genes in the Hdf6 Region of Chromosome I in Caenorhabditis Elegans

In this paper we describe the analysis of essential genes in the hDf6 region of chromosome I of Caenorhabditis elegans. Nineteen complementation groups have been identified which are required for the growth, survival or fertility of the organism (essential genes). Since ten of these genes were represented by more than one allele, a Poisson calculation predicts a minimum estimate of 25 essential genes in hDf6. The most mutable gene in this region was let-354 with seventeen alleles. An average mutation rate of 5 x 10(-5) mutations/gene/chromosome screened was calculated for an ethyl methanesulfonate dose of 15 mM. Mutations were recovered by screening for lethal mutations using the duplication sDp2 for recovery. Our analysis shows that duplications are very effective for maintenance and mapping of large numbers of lethal mutations. Approximately 600 lethal mutations were mapped in order to identify the 54 that are in the deficiency hDf6. The hDf6 region appears to have a lower proportion of early arresting mutations than other comparably sized regions of the genome.     

Genetic analysis of the genes involved in synthesis of the lipopolysaccharide core in Escherichia coli K-12: three operons in the rfa locus.

The region of the Escherichia coli K-12 chromosome encoding the enzymes responsible for the synthesis of responsible for the synthesis of the lipopolysaccharide (LPS) core has been cloned in vivo by using a mini-Mu vector. This region, formerly known as the rfa locus, comprises 18 kb of DNA between the markers tdh and rpmBG. Results of in vitro mutagenesis of this region with MudII1734 indicate the presence of at least 17 open reading frames or genes, a number considerably higher than expected on the basis of genetic and biochemical studies. Specific insertions in different genes have been recombined into the chromosome, and the mutations have been phenotypically characterized. Complementation analysis indicates that these genes are arranged in three different operons transcribed in opposite directions. A detailed physical map of this region has been constructed on the basis of complementation analysis, fusion protein data, and phenotypic characterizations. Additionally, the role of some genes in the synthesis of LPS has been defined by complementation analysis with known Salmonella typhimurium LPS mutants. The genetic organization of this locus seems to be identical in E. coli K-12 and S. typhimurium.     

Genetic Analysis of the Heterochromatin of Chromosome 3 in Drosophila Melanogaster. II. Vital Loci Identified through Ems Mutagenesis

Chromosome 3 of Drosophila melanogaster contains the last major blocks of heterochromatin in this species to be genetically analyzed. Deficiencies of heterochromatin generated through the detachment of compound-3 chromosomes revealed the presence of vital loci in the heterochromatin of chromosome 3, but an extensive complementation analysis with various combinations of lethal and nonlethal detachment products gave no evidence of tandemly repeated vital genes in this region. These findings indicate that the heterochromatin of chromosome 3 is genetically similar to that of chromosome 2. A more thorough genetic analysis of the heterochromatic regions has been carried out using the chemical mutagen ethyl methanesulfonate (EMS). Seventy-five EMS-induced lethals allelic to loci uncovered by detachment-product deficiencies were recovered and tested for complementation. In total, 12 complementation groups were identified, ten in the heterochromatin to the left of the centromere and two to the right. All but two complementation groups in the left heterochromatic block could be identified as separate loci through deficiency mapping. The interallelic complementation observed between some EMS-induced lethals, as well as the recovery of a temperature-sensitive allele for each of the two loci, provided further evidence that single-copy, transcribed vital genes reside in the heterochromatin of chromosome 3. Cytological analysis of three detachment-product deficiencies provided evidence that at least some of the genes uncovered in this study are located in the most distal segments of the heterochromatin in both arms. This study provides a detailed genetic analysis of chromosome 3 heterochromatin and offers further information on the genetic nature and heterogeneity of Drosophila heterochromatin.     

Peroxisomal bifunctional protein deficiency revisited: resolution of its true enzymatic and molecular basis.

In the past few years, many patients have been described who have a defect of unknown origin in the peroxisomal beta-oxidation pathway. Complementation analysis has been done by various groups to establish the extent of the genetic heterogeneity among the patients. These studies were based on the use of two established cell lines, one with a deficiency of acyl-CoA oxidase and one with a deficiency of l-bifunctional protein (l-BP), and they showed that most patients belong to the l-BP-deficient group. However, molecular analysis of the cDNA encoding l-BP in patients failed to show any mutations. The recent identification of a new d-specific bifunctional protein (d-BP) prompted us to reinvestigate the original patient with presumed l-BP deficiency. In a collaborative effort, we have now found that the true defect in this patient is at the level of the d-BP and not at the level of the l-BP. Our results suggest that most, if not all, patients whose condition has been diagnosed as l-BP are, in fact, d-BP deficient. We tested this hypothesis in nine patients whose condition was diagnosed as l-BP deficiency on the basis of complementation analysis and found clear-cut mutations in the d-BP cDNA from all patients.     

Genetic complementation of propionyl-CoA carboxylase deficiency in cultured human fibroblasts.

Propionyl-CoA carboxylase (PCC) deficiency is an inherited metabolic disorder showing considerable variability of expression. We have investigated the possibility that there is a genetic basis for the clinical heterogeneity in this disorder by examining complementation in Sendai virus mediated heterokaryons of mutant fibroblast strains. Restoration of PCC activity was monitored in individual multinucleate cells in situ using a radioautographic procedure which detects the incorporation of 14C-propionate into trichloracetic acid precipitable material. Each mutant strain incorporated negligible amounts of radioactivity compared to control strains. Activity was not restored when different mutants were mixed without virus or when homokaryons were produced by self-fusion. Seven mutant strains were fused in all pairwise combinations and examined for increased 14C-propionate incorporation in heterokaryons. Two main complementation groups were revealed. One group was composed of three mutants. The other was a complex group composed of four mutants in which intragroup complementation was demonstrated. Two mutants showing excellent complementation by radioautography were examined for complementation by the direct assay of PCC ACTIVITY. The enzyme activity of virus-treated preparations with 23% multinucleate cells was 183 U (pmol/min/mg protein) compared to 16 U for the untreated mixture (normal range 450-850 u). We conclude that PCC deficiency resulted from mutations of heterogeneous origin, although the classification of mutants into complementation groups did not correlate with patterns of clinical heterogeneity.     

Cytogenetic Analysis of Chromosome Region 73ad of Drosophila Melanogaster

The 73AD salivary chromosome region of Drosophila melanogaster was subjected to mutational analysis in order to (1) generate a collection of chromosome breakpoints that would allow a correlation between the genetic, cytological and molecular maps of the region and (2) define the number and gross organization of complementation groups within this interval. Eighteen complementation groups were defined and mapped to the 73A2-73B7 region, which is comprised of 17 polytene bands. These complementation groups include the previously known scarlet (st), transformer (tra) and Dominant temperature-sensitive lethal-5 (DTS-5) genes, as well as 13 new recessive lethal complementation groups and one male and female sterile locus. One of the newly identified lethal complementation groups corresponds to the molecularly identified abl locus, and another gene is defined by mutant alleles that exhibit an interaction with the abl mutants. We also recovered several mutations in the 73C1-D1.2 interval, representing two lethal complementation groups, one new visible mutant, plucked (plk), and a previously known visible, dark body (db). There is no evidence of a complex of sex determination genes in the region near tra.