Genetic Mapping of CAENORHABDITIS ELEGANS Collagen Genes Using DNA Polymorphisms as Phenotypic Markers

In Caenorhabditis elegans collagens comprise a dispersed family of 40-150 genes, the majority of which probably code for collagen proteins found in the animal's cuticle. The conserved (Gly-X-Y)n triple helix coding sequence of collagen genes has facilitated the isolation of a large number of C. elegans collagen genes by recombinant DNA methods. We have begun a study of the chromosomal organization of these genes by screening laboratory strains of C. elegans for DNA polymorphisms in the regions surrounding collagen genes. Polymorphisms near seven genes have been identified and have been used as phenotypic markers in genetic crosses to assign the genes to linkage groups II, III, IV, and X. Four genes are shown by multifactor crosses to map to a 2-3 map unit interval between unc-24 and unc-22 on chromosome IV.     

Genetic mapping of the 5S rRNA gene cluster of the nematode Caenorhabditis elegans

We have identified a restriction fragment length difference (RFLD) affecting the genomic sequences immediately flanking the 5S rRNA gene cluster in the Bristol and Bergerac strains of the nematode Caenorhabditis elegans. We have used this RFLD as a molecular marker to follow the segregation of the 5S rRNA gene cluster through a series of two- and three-factor interstrain crosses. Our results show that the 5S rRNA gene cluster maps between unc-76 and dpy-21 on the right arm of linkage group V. This genetic localization provides a linkage group V "landmark" with which to localize other cloned sequences by in situ hybridization.     

Genetic Organization of the Unc-60 Region in Caenorhabditis Elegans

We have investigated the chromosomal region around unc-60 V, a gene affecting muscle structure, in the nematode Caenorhabditis elegans. The region studied covers 3 map units and lies at the left end of linkage group (LG) V. Compared to the region around dpy-11 (at the center of LGV), the unc-60 region has relatively few visible genes per map unit. We found the same to be true for essential genes. By screening simultaneously for recessive lethals closely linked to either dpy-11 or unc-60, we recovered ethyl methanesulfonate-induced mutations in 10 essential genes near dpy-11 but in only two genes near unc-60. Four deficiency breakpoints were mapped to the unc-60 region. Using recombination and deficiency mapping we established the following gene order: let-336, unc-34, let-326, unc-60, emb-29, let-426. Regarding unc-60 itself, we compared the effect of ten alleles (including five isolated during this study) on hermaphrodite mobility and fecundity. We used intragenic mapping to position eight of these alleles. The results show that these alleles are not distributed uniformly within the gene, but map to two groups approximately 0.012 map unit apart.     

Isolation and mapping of DNA probes within the linkage group I gene cluster of Caenorhabditis elegans

We have isolated probes for DNA polymorphisms across the linkage group I gene cluster in Caenorhabditis elegans, using Tc1-linkage selection. The probes detect strain polymorphism between the wild-type strains of var. Bristol and var. Bergerac. As a result of mapping the sites hP4, hP5, hP6, hP7, hP9, and sPl, more than 1000 kilobases (kb) of cloned cosmid DNA has been positioned on the genetic map. We found there is more DNA per map unit in the center of the gene cluster than expected on the basis of the genomic average. Furthermore, the amount is not constant across the entire region but reaches a peak in the hP9 unc-13 interval. To find the coding regions, we examined DNA cross-homology between two species, Caenorhabditis elegans and Caenorhabditis briggsae. Approximately one-third of the DNA in the hP5 hP9 interval was examined for coding regions and 21 sequences were identified within 318 kb of DNA.     

Genetic and molecular analysis of the dpy-14 region in Caenorhabditis elegans.

Summary Essential genes have been identified in the 1.5 map unit (m.u.)dpy-14-unc-29 region of chromosome I inCaenorhabditis elegans. Previous work defined nine genes with visible mutant phenotypes and nine genes with lethal mutant phenotypes. In this study, we have identified an additional 28 essential genes with 97 lethal mutations. The mutations were mapped using eleven duplication breakpoints, eight deficiencies and three-factor recombination experiments. Genes required for the early stages of development were common, with 24 of the 37 essential genes having mutant phenotypes arresting at an early larval stage. Most mutants of a gene have the same time of arrest; only four of the 20 essential genes with multiple alleles have alleles with different phenotypes. From the analysis of complementing alleles oflet-389, alleles with the same time-of-arrest phenotype were classified as either hypomorphic or amorphic. Mutants oflet-605, let-534 andunc-37 have both uncoordinated and lethal phenotypes, suggesting that these genes are required for the coordination of movement and for viability. The physical and genetic maps in thedpy-14 region were linked by positioning two N2/BO polymorphisms with respect to duplications in the region, and by localizing the right breakpoint of the deficiencyhDf8 on the physical map. Using cross-species hybridization toC. briggsae, ten regions of homology have been identified, eight of which are known to be coding regions, based on Northern analysis and/or the isolation of cDNA clones.     

Molecular cloning and characterization of the dpy-20 gene of Caenorhabditis elegans

We describe the molecular analysis of the dpy20 gene in Caenorhabditis elegans. Isolation of genomic sequences was facilitated by the availability of a mutation that resulted from insertion of a Tc1 transposable element into the dpy-20 gene. The Tc1 insertion site in the m474:: Tc1 allele was identified and was found to lie within the coding region of dpy-20. Three revertants (two wild-type and one partial revertant) resulted from the excision of this Tc1 element. Genomic dpy-20 clones were isolated from a library of wild-type DNA and were found to lie just to the left of the unc-22 locus on the physical map, compatible with the position of dpy-20 on the genetic map. Cosmid DNA containing the dpy-20 gene was successfully used to rescue the mutant phenotype of animals homozygous for another dpy-20 allele, e1282ts. Sequence analysis of the putative dpy-20 homologue in Caenorhabditis briggsae was performed to confirm identification of the coding regions of the C. elegans gene and to identify conserved regulatory regions. Sequence analysis of dpy-20 revealed that it was not similar to other genes encoding known cuticle components such as collagen or cuticulin. The dpy-20 gene product, therefore, identifies a previously unknown type of protein that may be directly or indirectly involved in cuticle function. Northern blot analysis showed that dpy-20 is expressed predominantly in the second larval stage and that the mRNA is not at all abundant. Data from temperature shift studies using the temperature-sensitive allele e1282ts showed that the sensitive period also occurs at approximately the second larval stage. Therefore, expression of dpy-20 mRNA and function of the DPY-20 protein are closely linked temporally.     

Molecular cloning and characterization of the dpy-20 gene of Caenorhabditis elegans

We describe the molecular analysis of the dpy20 gene in Caenorhabditis elegans. Isolation of genomic sequences was facilitated by the availability of a mutation that resulted from insertion of a Tc1 transposable element into the dpy-20 gene. The Tc1 insertion site in the m474:: Tc1 allele was identified and was found to lie within the coding region of dpy-20. Three revertants (two wild-type and one partial revertant) resulted from the excision of this Tc1 element. Genomic dpy-20 clones were isolated from a library of wild-type DNA and were found to lie just to the left of the unc-22 locus on the physical map, compatible with the position of dpy-20 on the genetic map. Cosmid DNA containing the dpy-20 gene was successfully used to rescue the mutant phenotype of animals homozygous for another dpy-20 allele, e1282ts. Sequence analysis of the putative dpy-20 homologue in Caenorhabditis briggsae was performed to confirm identification of the coding regions of the C. elegans gene and to identify conserved regulatory regions. Sequence analysis of dpy-20 revealed that it was not similar to other genes encoding known cuticle components such as collagen or cuticulin. The dpy-20 gene product, therefore, identifies a previously unknown type of protein that may be directly or indirectly involved in cuticle function. Northern blot analysis showed that dpy-20 is expressed predominantly in the second larval stage and that the mRNA is not at all abundant. Data from temperature shift studies using the temperature-sensitive allele e1282ts showed that the sensitive period also occurs at approximately the second larval stage. Therefore, expression of dpy-20 mRNA and function of the DPY-20 protein are closely linked temporally.     

Actin gene family of Caenorhabditis elegans

Four actin genes have been isolated from Caenorhabditis elegans that account for all of the major actin hybridization to total genomic DNA. Actin genes I, II and III are clustered within a 12 X 10(3) base region; gene IV is unlinked to the others. All four genes have been sequenced from at least nucleotide -109 to +250. Genes I and III are identical for the first 307 coding nucleotides. Genes I and II differ in 14 positions within the first 250 coding nucleotides; one difference substitutes an aspartic acid for a glutamic acid at codon 5. Genes I and IV differ in 18 positions within the first 259 coding nucleotides without causing any amino acid differences. Genes I, II and III have introns after the first nucleotide of codon 64 and gene IV has an intron between codons 19 and 20. The four nucleotide sequences thus far define two different amino acid sequences. Both of the amino acid sequences resemble vertebrate cytoplasmic actin more than vertebrate muscle actin. A DNA polymorphism between the Bristol and Bergerac strains has been used as a phenotypic marker in genetic crosses to map the cluster of actin genes within a 2% recombination interval on linkage group V between unc-23 and sma-1 in order to begin a molecular genetic analysis of the actin loci.     

Cloning within the unc-43 to unc-31 interval (linkage group IV) of the Caenorhabditis elegans genome using Tc1 linkage selection

The region around the twitcher gene, unc-22, flanked by unc-43 on the left and by unc-31 on the right, has been intensively studied in our laboratory over the period of the last 8 years. In this paper we describe the identification and isolation of probes specific for several restriction fragment length differences (RFLDs) which lie within this region. Many RFLDs in Caenorhabditis elegans are caused by the insertion of a transposable element, Tc1. The method we used involved the isolation of Tc1-containing genomic fragments. These were recovered from a lambda gt 10 library of DNA from a specially constructed genetic strain containing the unc-43 to unc-31 interval from the BO strain and the rest of the genome from N2. Because the BO strain is rich in Tc1 insertion sites and the N2 strain has few, the majority of Tc1-bearing genomic fragments in the constructed strain were derived from the unc-22 region. Of nine such Tc1-bearing genomic fragments isolated, six were found which mapped within the region of interest. The 350 kilobases of genomic sequences isolated as a result of these studies are being used to study the molecular organization of this region. The method described here for Tc1 linkage selection is one that is rapid, general, and may be targeted to any genetically characterized region of the C. elegans genome.     

The Unc-22(iv) Region of Caenorhabditis Elegans: Genetic Analysis of Lethal Mutations

The organization of essential genes in the unc-22 region, defined by the deficiency sDf2 on linkage group IV, has been studied. Using the balancer nT1 (IV;V), which suppresses recombination over 49 map units, 294 lethal mutations on LGIV(right) and LGV(left) were recovered using EMS mutagenesis. Twenty-six of these mutations fell into the unc-22 region. Together with previously isolated lethal mutations, there is now a total of 63 lethal mutations which fall into 31 complementation groups. Mutations were positioned on the map using eight overlapping deficiencies in addition to sDf2. The lethal alleles and deficiencies in the unc-22 region were characterized with respect to their terminal phenotypes. Mapping of these lethal mutations shows that sDf2 deletes a minimum of 1.8 map units and a maximum of 2.5 map units. A minimum estimate of essential gene number for the region using a truncated Poisson calculation is 48. The data indicate a minimum estimate of approximately 3500 essential genes in the Caenorhabditis elegans genome.     

The genetic analysis of a reciprocal translocation, eT1(III; V), in Caenorhabditis elegans

The Caenorhabditis elegans mutation e873, which results in a recessive uncoordinated phenotype (formerly named Unc-72) and which had been isolated after 32P treatment (Brenner 1974), has now been found to act as a crossover suppressor and to be associated with a translocation between linkage groups (LG's) III and V. The translocation has been named, eT1(III; V); eT1 acts as a dominant crossover suppressor for both the right half of LGIII and the left half of LGV, providing a balancer for a total of 39 map units. The uncoordinated e873 phenotype has been shown to be a consequence of an inactive unc-36III gene. It was possible to demonstrate that, in translocation heterozygotes, eT1 chromosomes marked with either sma-3 or dpy-11 segregate from normal LGIII, while those marked with bli-5, sma-2 or unc-42 segregate from normal LGV. Since bli-5 and sma-2 are normally on LGIII, and dpy-11 is normally on LGV, it is concluded that: (a) eT1 is a reciprocal translocation; (b) there is a breakpoint between sma-3 and sma-2 in LGIII (the region containing unc-36) and one between dpy-11 and unc-42 in LGV; (c) there is no dominant centromere between sma-2 and bli-5 on LGIII, since in eT1 these genes are not linked to a LGIII centromere. Similarly, it is highly unlikely that there is a centromere to the left of dpy-11 on LGV. The new gene order in eT1 was determined by measuring recombination rates between markers in eT1 homozygotes. It is concluded that the new order is: dpy-1 sma-3 (break) dpy-11 unc-60, and bli-5 sma-2 (break) unc-42 unc-51.--This is the first analysis of a C. elegans translocation with respect to reciprocity, breakpoints and new gene order.     

Molecular analysis of mutations in the Caenorhabditis elegans collagen gene dpy-7.

Collagens are a family of proteins contributing to the body structure of eukaryotes. They are encoded by a large and diverse gene family in the nematode Caenorhabditis elegans but by only a few genes in vertebrates. We have studied mutant alleles of the C. elegans dpy-7 gene, one of a large group of genes whose mutant phenotype is altered body form and several of which have previously been shown to encode cuticular collagens. We made use of the C. elegans physical map to screen specifically for collagen genes in the region of the X chromosome to which dpy-7 maps. This yielded a wild-type collagen gene clone which we showed, by micro-injection, could repair the dpy-7 mutant phenotype in transgenic animals. We cloned the homologous sequence from four dpy-7 mutant strains and by sequence analysis identified a single mutation in each case. All four mutations result in the substitution of a glycine with a larger residue in the conserved Gly-X-Y collagen domains. Similar substitutions in vertebrate collagens cause the heritable brittle bone disorder osteogenesis imperfecta. Whereas the human mutations are dominant, the dpy-7 mutations are recessive, and this may reflect different levels of complexity of collagenous macromolecular structures in the two organisms.     

Genetic Analysis of X-Chromosome Dosage Compensation in Caenorhabditis elegans

We have shown that the phenotypes resulting from hypomorphic mutations (causing reduction but not complete loss of function) in two X-linked genes can be used as a genetic assay for X-chromosome dosage compensation in Caenorhabditis elegans between males (XO) and hermaphrodites (XX). In addition we show that recessive mutations in two autosomal genes, dpy-21 V and dpy-26 IV, suppress the phenotypes resulting from the X-linked hypomorphic mutations, but not the phenotypes resulting from comparable autosomal hypomorphic mutations. This result strongly suggests that the dpy-21 and dpy-26 mutations cause increased X expression, implying that the normal function of these genes may be to lower the expression of X-linked genes. Recessive mutations in two other dpy genes, dpy-22 X and dpy-23 X, increase the severity of phenotypes resulting from some X-linked hypomorphic mutations, although dpy-23 may affect the phenotypes resulting from the autosomal hypomorphs as well. The mutations in all four of the dpy genes show their effects in both XO and XX animals, although to different degrees. Mutations in 18 other dpy genes do not show these effects.     

Mutations in the unc-54 myosin heavy chain gene of caenorhabditis elegans that alter contractility but not muscle structure

Reversion analysis of mutants of unc-22 IV, a gene affecting muscle structure and function in Caenorhabditis elegans, led to the isolation of six extragenic dominant suppressors of the “twitching” phenotype of unc-22 mutants. All six suppressors are new alleles of unc-54 I, the major body wall myosin heavy chain gene. Homozygous suppressor strains are slow, stiff and have normal muscle structure, whereas previously identified unc-54 alleles confer flaccid paralysis and drastic reduction in thick filament number and organization. Placement of the three suppressor mutations s74, s77 and s95 on the genetic fine structure map of unc-54 demonstrates that they are clustered near the right end of the map. Since this end of the gene corresponds to the 5′ end of the coding sequence, these suppressor mutations probably result in amino acid substitutions in the globular head of the myosin molecule, and should be of value in studies of myosin force generation.     

Macrorestriction Analysis of Caenorhabditis Elegans Genomic DNA

The usefulness of genomic physical maps is greatly enhanced by linkage of the physical map with the genetic map. We describe a ``macrorestriction mapping' procedure for Caenorhabditis elegans that we have applied to this endeavor. High molecular weight, genomic DNA is digested with infrequently cutting restriction enzymes and size-fractionated by pulsed field gel electrophoresis. Southern blots of the gels are probed with clones from the C. elegans physical map. This procedure allows the construction of restriction maps covering several hundred kilobases and the detection of polymorphic restriction fragments using probes that map several hundred kilobases away. We describe several applications of this technique. (1) We determined that the amount of DNA in a previously uncloned region is <220 kb. (2) We mapped the mes-1 gene to a cosmid, by detecting polymorphic restriction fragments associated with a deletion allele of the gene. The 25-kb deletion was initially detected using as a probe sequences located ~400 kb away from the gene. (3) We mapped the molecular endpoint of the deficiency hDf6, and determined that three spontaneously derived duplications in the unc-38-dpy-5 region have very complex molecular structures, containing internal rearrangements and deletions.     

Genetic Organization of the Region around UNC-15 (I), a Gene Affecting Paramyosin in CAENORHABDITIS ELEGANS

In the nematode Caenorhabditis elegans mutants in the gene unc-15 (I) affect the muscle protein paramyosin (Waterston, Fishpool and Brenner 1977). We have characterized 20 ethyl methanesulfonate-induced mutations in essential genes closely linked to unc-15. These lethals defined 16 new complementation groups. In the 0.65 map-unit interval around unc-15 defined by dpy-14 and unc-56, seven newly identified genes have been mapped relative to five existing genes. At present, the average distance between genes in this region is approximately 0.05 map units. Two genes, unc-15 and unc-13, are only 0.025 map units apart. Partial fine-structure maps of alleles of these two genes have been constructed. This analysis of unc-15 and genes adjacent to it is the first in a series of genetic and biochemical studies directed towards understanding the control of unc-15 expression.     

Group A streptococcal phage T12 carries the structural gene for pyrogenic exotoxin type A

Summary In this paper we describe the meiotic pairing behavior of two free duplications in Caenorhabditis elegans. sDp1 is a duplication of approximately 30 map units of the right portion of linkage group I including unc-74 to unc-54. This duplication pairs, recombines, and apparently segregates from one of the normal homologues. A second duplication, sDp2, is a duplication of approximately 15 map units of the left portion of the linkage group. sDp2 was not observed to recombine with the normal homologue but did suppress exchange between the two normal homologues in a sDp2/ ++ / dpy-5 unc-35 heterozygote. Although a number of free duplications have been described previously in Caenorhabditis elegans, none of these have been shown to pair with normal homologues. The meiotic behavior of the duplications described in this paper can be understood assuming the existence in C. elegans chromosomes of pairing sites of the type described in D. melanogaster chromosomes (I. Sandler 1956; Hawley 1980).     

Fine-Structure Genetics of Ama-1, an Essential Gene Encoding the Amanitin-Binding Subunit of RNA Polymerase II in Caenorhabditis Elegans

A fine-structure genetic map has been constructed for ama-1 IV, an essential gene in Caenorhabditis elegans encoding the amanitin-binding subunit of RNA polymerase II. Sixteen EMS-induced recessive-lethal mutations have been positioned in the gene by determining their intragenic recombination frequencies with m118, a mutation that confers dominant resistance to alpha-amanitin. The 16 mutants, all isolated in the ama-1(m118) background, include 13 that are early larval lethals, and three that are mid-larval lethals, at 25 degrees. Six of the mutants exhibit temperature-dependence in the severity of their phenotype. Intragenic recombination between the lethal site and the parental resistance mutation was detected by means of resistance to amanitin. Recombinants were detected at frequencies as low as 2 X 10(-6). The segregation of the closely linked flanking markers, unc-17 and unc-5, revealed whether the lethal mutation was to the left or the right of m118. By adding the distances between the extreme left and right mutations, the ama-1 gene is estimated to be 0.011 map unit long, with m118 positioned 0.004 map unit from the left-most lethal mutation. To order the lethal mutations with respect to each other, viable heteroallelic strains were constructed using the free duplication, mDp1[unc-17(e113) dpy-13(+) ama-1(+)]. The heteroallelic strains were sensitive to amanitin, and recombination events between the lethal mutations were specifically selected by means of the dominant amanitin resistance encoded on the recombinant chromosome. The segregation of outside markers revealed the left-right order of the lethal mutations. The position of mutations within the gene is nonrandom. Functional domains of the ama-1 gene indicated by the various lethal phenotypes are discussed.     

Palaeohexaploid ancestry for Caryophyllales inferred from extensive gene-based physical and genetic mapping of the sugar beet genome (Beta vulgaris)

Sugar beet (Beta vulgaris) is an important crop plant that accounts for 30% of the world's sugar production annually. The genus Beta is a distant relative of currently sequenced taxa within the core eudicotyledons; the genomic characterization of sugar beet is essential to make its genome accessible to molecular dissection. Here, we present comprehensive genomic information in genetic and physical maps that cover all nine chromosomes. Based on this information we identified the proposed ancestral linkage groups of rosids and asterids within the sugar beet genome. We generated an extended genetic map that comprises 1127 single nucleotide polymorphism markers prepared from expressed sequence tags and bacterial artificial chromosome (BAC) end sequences. To construct a genome-wide physical map, we hybridized gene-derived oligomer probes against two BAC libraries with 9.5-fold cumulative coverage of the 758 Mbp genome. More than 2500 probes and clones were integrated both in genetic maps and the physical data. The final physical map encompasses 535 chromosomally anchored contigs that contains 8361 probes and 22 815 BAC clones. By using the gene order established with the physical map, we detected regions of synteny between sugar beet (order Caryophyllales) and rosid species that involves 1400-2700 genes in the sequenced genomes of Arabidopsis, poplar, grapevine, and cacao. The data suggest that Caryophyllales share the palaeohexaploid ancestor proposed for rosids and asterids. Taken together, we here provide extensive molecular resources for sugar beet and enable future high-resolution trait mapping, gene identification, and cross-referencing to regions sequenced in other plant species.